diagnostic radiography dissertation ideas

How it works

Useful Links

How much will your dissertation cost?

Have an expert academic write your dissertation paper!

Dissertation Services

Get unlimited topic ideas and a dissertation plan for just £45.00

Order topics and plan

Get 1 free topic in your area of study with aim and justification

Yes I want the free topic

Radiology Dissertation topics – Based on The Latest Study and Research

Published by Ellie Cross at December 29th, 2022 , Revised On May 16, 2024

A dissertation is an essential part of the radiology curriculum for an MD, DNB, or DMRD degree programme. Dissertations in radiology can be very tricky and challenging due to the complexity of the subject.

Students must conduct thorough research to develop a first-class dissertation that makes a valuable contribution to the file of radiology. The first step is to choose a well-defined and clear research topic for the dissertation.

We have provided some interesting and focused ideas to help you get started. Choose one that motivates you so you don’t lose your interest in the research work halfway through the process.

List of Radiology Dissertation Topics

The use of computed tomography and positron emission tomography in the diagnosis of thyroid cancer
MRI diffusion tensor imaging is used to evaluate traumatic spinal injury
Analysing digital colour and subtraction in comparison patients with occlusive arterial disorders and Doppler
Functional magnetic resonance imaging is essential for ensuring the security of brain tumour surgery
Doppler uterine artery preeclampsia prediction
Utilising greyscale and Doppler ultrasonography to assess newborn cholestasis
MRI’s reliability in detecting congenital anorectal anomalies
Multivessel research on intrauterine growth restriction (arterial, venous) Doppler speed
Perfusion computed tomography is used to evaluate cerebral blood flow, blood volume, and vascular permeability for brain neoplasms
In post-radiotherapy treated gliomas, compare perfusion magnetic resonance imaging with magnetic resonance spectroscopy to identify recurrence
Using multidetector computed tomography, pediatric retroperitoneal masses are evaluated. Tomography
Female factor infertility: the role of three-dimensional multidetector CT hysterosalpingography
Combining triphasic computed tomography with son elastography allows for assessing localised liver lesions
Analysing the effects of magnetic resonance imaging and transperineally ultrasonography on female urinary stress incontinence
Using dynamic contrast-enhanced and diffusion-weighted magnetic resonance imaging, evaluate endometrial lesions
For the early diagnosis of breast lesions, digital breast tomosynthesis and contrast-enhanced digital mammography are also available
Using magnetic resonance imaging and colour Doppler flow, assess portal hypertension
Magnesium resonance imaging enables the assessment of musculoskeletal issues
Diffusion magnetic resonance imaging is a crucial diagnostic technique for neoplastic or inflammatory brain lesions
Children with chest ailments that are HIV-infected and have a radiological spectrum high-resolution ultrasound for childhood neck lumps
Ultrasonography is useful when determining the causes of pelvic discomfort in the first trimester
Magnetic resonance imaging is used to evaluate diseases of the aorta or its branches. Angiography’s function
Children’s pulmonary nodules can be distinguished between benign and malignant using high-resolution CT
Research on multidetector computed urography for treating diseases of the urinary tract
The evaluation of the ulnar nerve in leprosy patients involves significantly high-resolution sonography
Using computed tomography and magnetic resonance imaging, radiologists evaluate musculoskeletal tumours that are malignant and locally aggressive before surgery
The function of MRI and ultrasonography in acute pelvic inflammatory disorders
Ultrasonography is more efficient than computed tomographic arthrography for evaluating shoulder discomfort
For patients with blunt abdominal trauma, multidetector computed tomography is a crucial tool
Compound imaging and expanded field-of-view sonography in the evaluation of breast lesions
Focused pancreatic lesions are assessed using multidetector CT and perfusion CT
Ct virtual laryngoscopy is used to evaluate laryngeal masses
In the liver masses, triple-phase multidetector computed tomography
The effect of increasing the volume of brain tumours on patient survival
Colonic lesions can be diagnosed using perfusion computed tomography
A role for proton MRI spectroscopy in the diagnosis and management of temporal lobe epilepsy
Functions of multidetector CT and Doppler ultrasonography in assessing peripheral arterial disease
There is a function for multidetector computed tomography in paranasal sinus illness
In neonates with an anorectal malformation, transperineal ultrasound
Using multidetector CT, comprehensive imaging of an acute ischemic stroke is performed
The diagnosis of intrauterine neurological congenital disorders requires the use of fetal MRI
Children with chest masses may benefit from multidetector computed angiography
Multimodal imaging for the evaluation of palpable and non-palpable breast lesions
As measured by sonography and in relation to fetal outcome, fetal nasal bone length at 11–28 gestational days
Relationship between bone mineral density, diffusion-weighted MRI imaging, and vertebral marrow fat in postmenopausal women
A comparison of the traditional catheter and CT coronary imaging angiogram of the heart
Evaluation of the descending colon’s length and diameter using ultrasound in normal and intrauterine-restricted fetuses
Investigation of the hepatic vein waveform in liver cirrhosis prospectively. A connection to Child Pugh’s categorisation
Functional assessment of coronary artery bypass graft patency in symptomatic patients using CT angiography
MRI and MRI arthrography evaluation of the labour-ligamentous complex lesion in the shoulder
The evaluation of soft tissue vascular abnormalities involves imaging
Colour Doppler ultrasound and high-resolution ultrasound for scrotal lesions
Comparison of low-dose computed tomography and ultrasonography with colour Doppler for diagnosing salivary gland disorders
The use of multidetector CT to diagnose lesions of the salivary glands
Low dose CT venogram and sonography comparison for evaluating varicose veins: a pilot study
Comparison of dynamic contrast-enhanced MRI and triple phase CT in patients with liver cirrhosis
Carotid intima-media thickness and coronary artery disease are examined in individuals with coronary angiography for suspected CAD
Unenhanced computed tomography assessment of hepatic fat levels in fatty liver disease
Bone mineral density in postmenopausal women and vertebral marrow fat on spectroscopic and diffusion-weighted MRI images are correlated
Evaluation of CT coronary angiography against traditional catheter coronary angiography in comparison
High-frequency ultrasonography and colour Doppler evaluation of the median nerve in carpal tunnel syndrome in contrast to nerve conduction tests
Role of MR urethrography in the surgical therapy of obliterative urethral stricture compared to conventional urethrography
High-resolution computed tomography evaluation of the temporal bone in cholesteatoma patients.
Ultrasonographic assessment of sore shoulders and linkage of clinical examination and rotator cuff diseases
A Study to Evaluate the Performance of Magnetisation Transfer Ratio in Distinguishing Neurocysticercosis from Tuberculoma
Deep learning applications in radiology diagnostics.
Radiomics for personalised cancer therapy.
AI-driven image enhancement techniques in radiology.
Role of virtual reality in radiology education.
Nanotechnology advancements in radiology imaging.
Radiogenomics for predicting treatment response.
IoT-enabled devices for remote radiology consultations.
Biomarker discovery through radiological imaging.
3D printing in pre-surgical planning for radiology.
Radiological imaging for early detection of Alzheimer’s disease.
Applications of machine learning in radiology workflow optimization.
Radiological imaging modalities for sports injuries assessment.
Role of radiology in assessing COVID-19 complications.
Interventional radiology techniques for stroke management.
Automated reporting systems in radiology.
Radiology-guided minimally invasive surgeries.
Quantitative imaging for assessing tumour heterogeneity.
Big data analytics in radiology for population health.
Augmented reality for intraoperative radiological guidance.
Radiological imaging in assessing cardiovascular risks.
Radiology applications in detecting rare diseases.
Role of radiology in precision medicine.
Artificial intelligence for improving mammography accuracy.
Radiological imaging is used to monitor Parkinson’s disease progression.
Tele-radiology applications in resource-limited settings.
Radiological imaging in pediatric orthopaedics.
Artificial intelligence for improving CT image reconstruction.
Role of radiology in assessing infectious diseases.
Radiological imaging for assessing lung fibrosis.
3D visualization techniques in radiology reporting.
Radiology applications in evaluating renal disorders.
Imaging biomarkers for predicting dementia risk.
Radiomics for predicting treatment response in prostate cancer.

Hire an Expert Writer

Orders completed by our expert writers are

Formally drafted in an academic style
Free Amendments and 100% Plagiarism Free – or your money back!
100% Confidential and Timely Delivery!
Free anti-plagiarism report
Appreciated by thousands of clients. Check client reviews

Final Words

You can use or get inspired by our selection of the best radiology diss. You can also check our list of critical care nursing dissertation topics and biology dissertation topics because these areas also relate to the discipline of medical sciences.

Choosing an impactful radiology dissertation topic is a daunting task. There is a lot of patience, time and effort that goes into the whole process. However, we have tried to simplify it for you by providing a list of amazing and unique radiology dissertation topics for you. We hope you find this blog helpful.

Also learn about our dissertation services here .

Free Dissertation Topic

Phone Number

Academic Level Select Academic Level Undergraduate Graduate PHD

Academic Subject

Area of Research

Frequently Asked Questions

How to find radiology dissertation topics.

For radiology dissertation topics:

Research recent advancements.
Identify unexplored areas.
Consult experts and journals.
Focus on patient care or tech.
Consider ethical or practical issues.
Select a topic resonating with your passion and career objectives.

Please login to bookmark

Introduction

A thesis or dissertation, as some people would like to call it, is an integral part of the Radiology curriculum, be it MD, DNB, or DMRD. We have tried to aggregate radiology thesis topics from various sources for reference.

Not everyone is interested in research, and writing a Radiology thesis can be daunting. But there is no escape from preparing, so it is better that you accept this bitter truth and start working on it instead of cribbing about it (like other things in life. #PhilosophyGyan!)

Start working on your thesis as early as possible and finish your thesis well before your exams, so you do not have that stress at the back of your mind. Also, your thesis may need multiple revisions, so be prepared and allocate time accordingly.

Tips for Choosing Radiology Thesis and Research Topics

Keep it simple silly (kiss).

Retrospective > Prospective

Retrospective studies are better than prospective ones, as you already have the data you need when choosing to do a retrospective study. Prospective studies are better quality, but as a resident, you may not have time (, energy and enthusiasm) to complete these.

Choose a simple topic that answers a single/few questions

Original research is challenging, especially if you do not have prior experience. I would suggest you choose a topic that answers a single or few questions. Most topics that I have listed are along those lines. Alternatively, you can choose a broad topic such as “Role of MRI in evaluation of perianal fistulas.”

You can choose a novel topic if you are genuinely interested in research AND have a good mentor who will guide you. Once you have done that, make sure that you publish your study once you are done with it.

Get it done ASAP.

In most cases, it makes sense to stick to a thesis topic that will not take much time. That does not mean you should ignore your thesis and ‘Ctrl C + Ctrl V’ from a friend from another university. Thesis writing is your first step toward research methodology so do it as sincerely as possible. Do not procrastinate in preparing the thesis. As soon as you have been allotted a guide, start researching topics and writing a review of the literature.

At the same time, do not invest a lot of time in writing/collecting data for your thesis. You should not be busy finishing your thesis a few months before the exam. Some people could not appear for the exam because they could not submit their thesis in time. So DO NOT TAKE thesis lightly.

Do NOT Copy-Paste

Reiterating once again, do not simply choose someone else’s thesis topic. Find out what are kind of cases that your Hospital caters to. It is better to do a good thesis on a common topic than a crappy one on a rare one.

Books to help you write a Radiology Thesis

Event country/university has a different format for thesis; hence these book recommendations may not work for everyone.

How to Write the Thesis and Thesis Protocol: A Primer for Medical, Dental, and Nursing Courses: A Primer for Medical, Dental and Nursing Courses

Amazon Kindle Edition
Gupta, Piyush (Author)
English (Publication Language)
206 Pages - 10/12/2020 (Publication Date) - Jaypee Brothers Medical Publishers (P) Ltd. (Publisher)

In A Hurry? Download a PDF list of Radiology Research Topics!

100% Privacy Guaranteed. Your information will not be shared. Unsubscribe anytime with a single click.

List of Radiology Research /Thesis / Dissertation Topics

State of the art of MRI in the diagnosis of hepatic focal lesions
Multimodality imaging evaluation of sacroiliitis in newly diagnosed patients of spondyloarthropathy
Multidetector computed tomography in oesophageal varices
Role of positron emission tomography with computed tomography in the diagnosis of cancer Thyroid
Evaluation of focal breast lesions using ultrasound elastography
Role of MRI diffusion tensor imaging in the assessment of traumatic spinal cord injuries
Sonographic imaging in male infertility
Comparison of color Doppler and digital subtraction angiography in occlusive arterial disease in patients with lower limb ischemia
The role of CT urography in Haematuria
Role of functional magnetic resonance imaging in making brain tumor surgery safer
Prediction of pre-eclampsia and fetal growth restriction by uterine artery Doppler
Role of grayscale and color Doppler ultrasonography in the evaluation of neonatal cholestasis
Validity of MRI in the diagnosis of congenital anorectal anomalies
Role of sonography in assessment of clubfoot
Role of diffusion MRI in preoperative evaluation of brain neoplasms
Imaging of upper airways for pre-anaesthetic evaluation purposes and for laryngeal afflictions.
A study of multivessel (arterial and venous) Doppler velocimetry in intrauterine growth restriction
Multiparametric 3tesla MRI of suspected prostatic malignancy.
Role of Sonography in Characterization of Thyroid Nodules for differentiating benign from
Role of advances magnetic resonance imaging sequences in multiple sclerosis
Role of multidetector computed tomography in evaluation of jaw lesions
Role of Ultrasound and MR Imaging in the Evaluation of Musculotendinous Pathologies of Shoulder Joint
Role of perfusion computed tomography in the evaluation of cerebral blood flow, blood volume and vascular permeability of cerebral neoplasms
MRI flow quantification in the assessment of the commonest csf flow abnormalities
Role of diffusion-weighted MRI in evaluation of prostate lesions and its histopathological correlation
CT enterography in evaluation of small bowel disorders
Comparison of perfusion magnetic resonance imaging (PMRI), magnetic resonance spectroscopy (MRS) in and positron emission tomography-computed tomography (PET/CT) in post radiotherapy treated gliomas to detect recurrence
Role of multidetector computed tomography in evaluation of paediatric retroperitoneal masses
Role of Multidetector computed tomography in neck lesions
Estimation of standard liver volume in Indian population
Role of MRI in evaluation of spinal trauma
Role of modified sonohysterography in female factor infertility: a pilot study.
The role of pet-CT in the evaluation of hepatic tumors
Role of 3D magnetic resonance imaging tractography in assessment of white matter tracts compromise in supratentorial tumors
Role of dual phase multidetector computed tomography in gallbladder lesions
Role of multidetector computed tomography in assessing anatomical variants of nasal cavity and paranasal sinuses in patients of chronic rhinosinusitis.
magnetic resonance spectroscopy in multiple sclerosis
Evaluation of thyroid nodules by ultrasound elastography using acoustic radiation force impulse (ARFI) imaging
Role of Magnetic Resonance Imaging in Intractable Epilepsy
Evaluation of suspected and known coronary artery disease by 128 slice multidetector CT.
Role of regional diffusion tensor imaging in the evaluation of intracranial gliomas and its histopathological correlation
Role of chest sonography in diagnosing pneumothorax
Role of CT virtual cystoscopy in diagnosis of urinary bladder neoplasia
Role of MRI in assessment of valvular heart diseases
High resolution computed tomography of temporal bone in unsafe chronic suppurative otitis media
Multidetector CT urography in the evaluation of hematuria
Contrast-induced nephropathy in diagnostic imaging investigations with intravenous iodinated contrast media
Comparison of dynamic susceptibility contrast-enhanced perfusion magnetic resonance imaging and single photon emission computed tomography in patients with little’s disease
Role of Multidetector Computed Tomography in Bowel Lesions.
Role of diagnostic imaging modalities in evaluation of post liver transplantation recipient complications.
Role of multislice CT scan and barium swallow in the estimation of oesophageal tumour length
Malignant Lesions-A Prospective Study.
Value of ultrasonography in assessment of acute abdominal diseases in pediatric age group
Role of three dimensional multidetector CT hysterosalpingography in female factor infertility
Comparative evaluation of multi-detector computed tomography (MDCT) virtual tracheo-bronchoscopy and fiberoptic tracheo-bronchoscopy in airway diseases
Role of Multidetector CT in the evaluation of small bowel obstruction
Sonographic evaluation in adhesive capsulitis of shoulder
Utility of MR Urography Versus Conventional Techniques in Obstructive Uropathy
MRI of the postoperative knee
Role of 64 slice-multi detector computed tomography in diagnosis of bowel and mesenteric injury in blunt abdominal trauma.
Sonoelastography and triphasic computed tomography in the evaluation of focal liver lesions
Evaluation of Role of Transperineal Ultrasound and Magnetic Resonance Imaging in Urinary Stress incontinence in Women
Multidetector computed tomographic features of abdominal hernias
Evaluation of lesions of major salivary glands using ultrasound elastography
Transvaginal ultrasound and magnetic resonance imaging in female urinary incontinence
MDCT colonography and double-contrast barium enema in evaluation of colonic lesions
Role of MRI in diagnosis and staging of urinary bladder carcinoma
Spectrum of imaging findings in children with febrile neutropenia.
Spectrum of radiographic appearances in children with chest tuberculosis.
Role of computerized tomography in evaluation of mediastinal masses in pediatric
Diagnosing renal artery stenosis: Comparison of multimodality imaging in diabetic patients
Role of multidetector CT virtual hysteroscopy in the detection of the uterine & tubal causes of female infertility
Role of multislice computed tomography in evaluation of crohn’s disease
CT quantification of parenchymal and airway parameters on 64 slice MDCT in patients of chronic obstructive pulmonary disease
Comparative evaluation of MDCT and 3t MRI in radiographically detected jaw lesions.
Evaluation of diagnostic accuracy of ultrasonography, colour Doppler sonography and low dose computed tomography in acute appendicitis
Ultrasonography , magnetic resonance cholangio-pancreatography (MRCP) in assessment of pediatric biliary lesions
Multidetector computed tomography in hepatobiliary lesions.
Evaluation of peripheral nerve lesions with high resolution ultrasonography and colour Doppler
Multidetector computed tomography in pancreatic lesions
Multidetector Computed Tomography in Paediatric abdominal masses.
Evaluation of focal liver lesions by colour Doppler and MDCT perfusion imaging
Sonographic evaluation of clubfoot correction during Ponseti treatment
Role of multidetector CT in characterization of renal masses
Study to assess the role of Doppler ultrasound in evaluation of arteriovenous (av) hemodialysis fistula and the complications of hemodialysis vasular access
Comparative study of multiphasic contrast-enhanced CT and contrast-enhanced MRI in the evaluation of hepatic mass lesions
Sonographic spectrum of rheumatoid arthritis
Diagnosis & staging of liver fibrosis by ultrasound elastography in patients with chronic liver diseases
Role of multidetector computed tomography in assessment of jaw lesions.
Role of high-resolution ultrasonography in the differentiation of benign and malignant thyroid lesions
Radiological evaluation of aortic aneurysms in patients selected for endovascular repair
Role of conventional MRI, and diffusion tensor imaging tractography in evaluation of congenital brain malformations
To evaluate the status of coronary arteries in patients with non-valvular atrial fibrillation using 256 multirow detector CT scan
A comparative study of ultrasonography and CT – arthrography in diagnosis of chronic ligamentous and meniscal injuries of knee
Multi detector computed tomography evaluation in chronic obstructive pulmonary disease and correlation with severity of disease
Diffusion weighted and dynamic contrast enhanced magnetic resonance imaging in chemoradiotherapeutic response evaluation in cervical cancer.
High resolution sonography in the evaluation of non-traumatic painful wrist
The role of trans-vaginal ultrasound versus magnetic resonance imaging in diagnosis & evaluation of cancer cervix
Role of multidetector row computed tomography in assessment of maxillofacial trauma
Imaging of vascular complication after liver transplantation.
Role of magnetic resonance perfusion weighted imaging & spectroscopy for grading of glioma by correlating perfusion parameter of the lesion with the final histopathological grade
Magnetic resonance evaluation of abdominal tuberculosis.
Diagnostic usefulness of low dose spiral HRCT in diffuse lung diseases
Role of dynamic contrast enhanced and diffusion weighted magnetic resonance imaging in evaluation of endometrial lesions
Contrast enhanced digital mammography anddigital breast tomosynthesis in early diagnosis of breast lesion
Evaluation of Portal Hypertension with Colour Doppler flow imaging and magnetic resonance imaging
Evaluation of musculoskeletal lesions by magnetic resonance imaging
Role of diffusion magnetic resonance imaging in assessment of neoplastic and inflammatory brain lesions
Radiological spectrum of chest diseases in HIV infected children High resolution ultrasonography in neck masses in children
with surgical findings
Sonographic evaluation of peripheral nerves in type 2 diabetes mellitus.
Role of perfusion computed tomography in the evaluation of neck masses and correlation
Role of ultrasonography in the diagnosis of knee joint lesions
Role of ultrasonography in evaluation of various causes of pelvic pain in first trimester of pregnancy.
Role of Magnetic Resonance Angiography in the Evaluation of Diseases of Aorta and its Branches
MDCT fistulography in evaluation of fistula in Ano
Role of multislice CT in diagnosis of small intestine tumors
Role of high resolution CT in differentiation between benign and malignant pulmonary nodules in children
A study of multidetector computed tomography urography in urinary tract abnormalities
Role of high resolution sonography in assessment of ulnar nerve in patients with leprosy.
Pre-operative radiological evaluation of locally aggressive and malignant musculoskeletal tumours by computed tomography and magnetic resonance imaging.
The role of ultrasound & MRI in acute pelvic inflammatory disease
Ultrasonography compared to computed tomographic arthrography in the evaluation of shoulder pain
Role of Multidetector Computed Tomography in patients with blunt abdominal trauma.
The Role of Extended field-of-view Sonography and compound imaging in Evaluation of Breast Lesions
Evaluation of focal pancreatic lesions by Multidetector CT and perfusion CT
Evaluation of breast masses on sono-mammography and colour Doppler imaging
Role of CT virtual laryngoscopy in evaluation of laryngeal masses
Triple phase multi detector computed tomography in hepatic masses
Role of transvaginal ultrasound in diagnosis and treatment of female infertility
Role of ultrasound and color Doppler imaging in assessment of acute abdomen due to female genetal causes
High resolution ultrasonography and color Doppler ultrasonography in scrotal lesion
Evaluation of diagnostic accuracy of ultrasonography with colour Doppler vs low dose computed tomography in salivary gland disease
Role of multidetector CT in diagnosis of salivary gland lesions
Comparison of diagnostic efficacy of ultrasonography and magnetic resonance cholangiopancreatography in obstructive jaundice: A prospective study
Evaluation of varicose veins-comparative assessment of low dose CT venogram with sonography: pilot study
Role of mammotome in breast lesions
The role of interventional imaging procedures in the treatment of selected gynecological disorders
Role of transcranial ultrasound in diagnosis of neonatal brain insults
Role of multidetector CT virtual laryngoscopy in evaluation of laryngeal mass lesions
Evaluation of adnexal masses on sonomorphology and color Doppler imaginig
Role of radiological imaging in diagnosis of endometrial carcinoma
Comprehensive imaging of renal masses by magnetic resonance imaging
The role of 3D & 4D ultrasonography in abnormalities of fetal abdomen
Diffusion weighted magnetic resonance imaging in diagnosis and characterization of brain tumors in correlation with conventional MRI
Role of diffusion weighted MRI imaging in evaluation of cancer prostate
Role of multidetector CT in diagnosis of urinary bladder cancer
Role of multidetector computed tomography in the evaluation of paediatric retroperitoneal masses.
Comparative evaluation of gastric lesions by double contrast barium upper G.I. and multi detector computed tomography
Evaluation of hepatic fibrosis in chronic liver disease using ultrasound elastography
Role of MRI in assessment of hydrocephalus in pediatric patients
The role of sonoelastography in characterization of breast lesions
The influence of volumetric tumor doubling time on survival of patients with intracranial tumours
Role of perfusion computed tomography in characterization of colonic lesions
Role of proton MRI spectroscopy in the evaluation of temporal lobe epilepsy
Role of Doppler ultrasound and multidetector CT angiography in evaluation of peripheral arterial diseases.
Role of multidetector computed tomography in paranasal sinus pathologies
Role of virtual endoscopy using MDCT in detection & evaluation of gastric pathologies
High resolution 3 Tesla MRI in the evaluation of ankle and hindfoot pain.
Transperineal ultrasonography in infants with anorectal malformation
CT portography using MDCT versus color Doppler in detection of varices in cirrhotic patients
Role of CT urography in the evaluation of a dilated ureter
Characterization of pulmonary nodules by dynamic contrast-enhanced multidetector CT
Comprehensive imaging of acute ischemic stroke on multidetector CT
The role of fetal MRI in the diagnosis of intrauterine neurological congenital anomalies
Role of Multidetector computed tomography in pediatric chest masses
Multimodality imaging in the evaluation of palpable & non-palpable breast lesion.
Sonographic Assessment Of Fetal Nasal Bone Length At 11-28 Gestational Weeks And Its Correlation With Fetal Outcome.
Role Of Sonoelastography And Contrast-Enhanced Computed Tomography In Evaluation Of Lymph Node Metastasis In Head And Neck Cancers
Role Of Renal Doppler And Shear Wave Elastography In Diabetic Nephropathy
Evaluation Of Relationship Between Various Grades Of Fatty Liver And Shear Wave Elastography Values
Evaluation and characterization of pelvic masses of gynecological origin by USG, color Doppler and MRI in females of reproductive age group
Radiological evaluation of small bowel diseases using computed tomographic enterography
Role of coronary CT angiography in patients of coronary artery disease
Role of multimodality imaging in the evaluation of pediatric neck masses
Role of CT in the evaluation of craniocerebral trauma
Role of magnetic resonance imaging (MRI) in the evaluation of spinal dysraphism
Comparative evaluation of triple phase CT and dynamic contrast-enhanced MRI in patients with liver cirrhosis
Evaluation of the relationship between carotid intima-media thickness and coronary artery disease in patients evaluated by coronary angiography for suspected CAD
Assessment of hepatic fat content in fatty liver disease by unenhanced computed tomography
Correlation of vertebral marrow fat on spectroscopy and diffusion-weighted MRI imaging with bone mineral density in postmenopausal women.
Comparative evaluation of CT coronary angiography with conventional catheter coronary angiography
Ultrasound evaluation of kidney length & descending colon diameter in normal and intrauterine growth-restricted fetuses
A prospective study of hepatic vein waveform and splenoportal index in liver cirrhosis: correlation with child Pugh’s classification and presence of esophageal varices.
CT angiography to evaluate coronary artery by-pass graft patency in symptomatic patient’s functional assessment of myocardium by cardiac MRI in patients with myocardial infarction
MRI evaluation of HIV positive patients with central nervous system manifestations
MDCT evaluation of mediastinal and hilar masses
Evaluation of rotator cuff & labro-ligamentous complex lesions by MRI & MRI arthrography of shoulder joint
Role of imaging in the evaluation of soft tissue vascular malformation
Role of MRI and ultrasonography in the evaluation of multifidus muscle pathology in chronic low back pain patients
Role of ultrasound elastography in the differential diagnosis of breast lesions
Role of magnetic resonance cholangiopancreatography in evaluating dilated common bile duct in patients with symptomatic gallstone disease.
Comparative study of CT urography & hybrid CT urography in patients with haematuria.
Role of MRI in the evaluation of anorectal malformations
Comparison of ultrasound-Doppler and magnetic resonance imaging findings in rheumatoid arthritis of hand and wrist
Role of Doppler sonography in the evaluation of renal artery stenosis in hypertensive patients undergoing coronary angiography for coronary artery disease.
Comparison of radiography, computed tomography and magnetic resonance imaging in the detection of sacroiliitis in ankylosing spondylitis.
Mr evaluation of painful hip
Role of MRI imaging in pretherapeutic assessment of oral and oropharyngeal malignancy
Evaluation of diffuse lung diseases by high resolution computed tomography of the chest
Mr evaluation of brain parenchyma in patients with craniosynostosis.
Diagnostic and prognostic value of cardiovascular magnetic resonance imaging in dilated cardiomyopathy
Role of multiparametric magnetic resonance imaging in the detection of early carcinoma prostate
Role of magnetic resonance imaging in white matter diseases
Role of sonoelastography in assessing the response to neoadjuvant chemotherapy in patients with locally advanced breast cancer.
Role of ultrasonography in the evaluation of carotid and femoral intima-media thickness in predialysis patients with chronic kidney disease
Role of H1 MRI spectroscopy in focal bone lesions of peripheral skeleton choline detection by MRI spectroscopy in breast cancer and its correlation with biomarkers and histological grade.
Ultrasound and MRI evaluation of axillary lymph node status in breast cancer.
Role of sonography and magnetic resonance imaging in evaluating chronic lateral epicondylitis.
Comparative of sonography including Doppler and sonoelastography in cervical lymphadenopathy.
Evaluation of Umbilical Coiling Index as Predictor of Pregnancy Outcome.
Computerized Tomographic Evaluation of Azygoesophageal Recess in Adults.
Lumbar Facet Arthropathy in Low Backache.
“Urethral Injuries After Pelvic Trauma: Evaluation with Uretrography
Role Of Ct In Diagnosis Of Inflammatory Renal Diseases
Role Of Ct Virtual Laryngoscopy In Evaluation Of Laryngeal Masses
“Ct Portography Using Mdct Versus Color Doppler In Detection Of Varices In
Cirrhotic Patients”
Role Of Multidetector Ct In Characterization Of Renal Masses
Role Of Ct Virtual Cystoscopy In Diagnosis Of Urinary Bladder Neoplasia
Role Of Multislice Ct In Diagnosis Of Small Intestine Tumors
“Mri Flow Quantification In The Assessment Of The Commonest CSF Flow Abnormalities”
“The Role Of Fetal Mri In Diagnosis Of Intrauterine Neurological CongenitalAnomalies”
Role Of Transcranial Ultrasound In Diagnosis Of Neonatal Brain Insults
“The Role Of Interventional Imaging Procedures In The Treatment Of Selected Gynecological Disorders”
Role Of Radiological Imaging In Diagnosis Of Endometrial Carcinoma
“Role Of High-Resolution Ct In Differentiation Between Benign And Malignant Pulmonary Nodules In Children”
Role Of Ultrasonography In The Diagnosis Of Knee Joint Lesions
“Role Of Diagnostic Imaging Modalities In Evaluation Of Post Liver Transplantation Recipient Complications”
“Diffusion-Weighted Magnetic Resonance Imaging In Diagnosis And
Characterization Of Brain Tumors In Correlation With Conventional Mri”
The Role Of PET-CT In The Evaluation Of Hepatic Tumors
“Role Of Computerized Tomography In Evaluation Of Mediastinal Masses In Pediatric patients”
“Trans Vaginal Ultrasound And Magnetic Resonance Imaging In Female Urinary Incontinence”
Role Of Multidetector Ct In Diagnosis Of Urinary Bladder Cancer
“Role Of Transvaginal Ultrasound In Diagnosis And Treatment Of Female Infertility”
Role Of Diffusion-Weighted Mri Imaging In Evaluation Of Cancer Prostate
“Role Of Positron Emission Tomography With Computed Tomography In Diagnosis Of Cancer Thyroid”
The Role Of CT Urography In Case Of Haematuria
“Value Of Ultrasonography In Assessment Of Acute Abdominal Diseases In Pediatric Age Group”
“Role Of Functional Magnetic Resonance Imaging In Making Brain Tumor Surgery Safer”
The Role Of Sonoelastography In Characterization Of Breast Lesions
“Ultrasonography, Magnetic Resonance Cholangiopancreatography (MRCP) In Assessment Of Pediatric Biliary Lesions”
“Role Of Ultrasound And Color Doppler Imaging In Assessment Of Acute Abdomen Due To Female Genital Causes”
“Role Of Multidetector Ct Virtual Laryngoscopy In Evaluation Of Laryngeal Mass Lesions”
MRI Of The Postoperative Knee
Role Of Mri In Assessment Of Valvular Heart Diseases
The Role Of 3D & 4D Ultrasonography In Abnormalities Of Fetal Abdomen
State Of The Art Of Mri In Diagnosis Of Hepatic Focal Lesions
Role Of Multidetector Ct In Diagnosis Of Salivary Gland Lesions
“Role Of Virtual Endoscopy Using Mdct In Detection & Evaluation Of Gastric Pathologies”
The Role Of Ultrasound & Mri In Acute Pelvic Inflammatory Disease
“Diagnosis & Staging Of Liver Fibrosis By Ultraso Und Elastography In
Patients With Chronic Liver Diseases”
Role Of Mri In Evaluation Of Spinal Trauma
Validity Of Mri In Diagnosis Of Congenital Anorectal Anomalies
Imaging Of Vascular Complication After Liver Transplantation
“Contrast-Enhanced Digital Mammography And Digital Breast Tomosynthesis In Early Diagnosis Of Breast Lesion”
Role Of Mammotome In Breast Lesions
“Role Of MRI Diffusion Tensor Imaging (DTI) In Assessment Of Traumatic Spinal Cord Injuries”
“Prediction Of Pre-eclampsia And Fetal Growth Restriction By Uterine Artery Doppler”
“Role Of Multidetector Row Computed Tomography In Assessment Of Maxillofacial Trauma”
“Role Of Diffusion Magnetic Resonance Imaging In Assessment Of Neoplastic And Inflammatory Brain Lesions”
Role Of Diffusion Mri In Preoperative Evaluation Of Brain Neoplasms
“Role Of Multidetector Ct Virtual Hysteroscopy In The Detection Of The
Uterine & Tubal Causes Of Female Infertility”
Role Of Advances Magnetic Resonance Imaging Sequences In Multiple Sclerosis Magnetic Resonance Spectroscopy In Multiple Sclerosis
“Role Of Conventional Mri, And Diffusion Tensor Imaging Tractography In Evaluation Of Congenital Brain Malformations”
Role Of MRI In Evaluation Of Spinal Trauma
Diagnostic Role Of Diffusion-weighted MR Imaging In Neck Masses
“The Role Of Transvaginal Ultrasound Versus Magnetic Resonance Imaging In Diagnosis & Evaluation Of Cancer Cervix”
“Role Of 3d Magnetic Resonance Imaging Tractography In Assessment Of White Matter Tracts Compromise In Supra Tentorial Tumors”
Role Of Proton MR Spectroscopy In The Evaluation Of Temporal Lobe Epilepsy
Role Of Multislice Computed Tomography In Evaluation Of Crohn’s Disease
Role Of MRI In Assessment Of Hydrocephalus In Pediatric Patients
The Role Of MRI In Diagnosis And Staging Of Urinary Bladder Carcinoma
USG and MRI correlation of congenital CNS anomalies
HRCT in interstitial lung disease
X-Ray, CT and MRI correlation of bone tumors
“Study on the diagnostic and prognostic utility of X-Rays for cases of pulmonary tuberculosis under RNTCP”
“Role of magnetic resonance imaging in the characterization of female adnexal pathology”
“CT angiography of carotid atherosclerosis and NECT brain in cerebral ischemia, a correlative analysis”
Role of CT scan in the evaluation of paranasal sinus pathology
USG and MRI correlation on shoulder joint pathology
“Radiological evaluation of a patient presenting with extrapulmonary tuberculosis”
CT and MRI correlation in focal liver lesions”
Comparison of MDCT virtual cystoscopy with conventional cystoscopy in bladder tumors”
“Bleeding vessels in life-threatening hemoptysis: Comparison of 64 detector row CT angiography with conventional angiography prior to endovascular management”
“Role of transarterial chemoembolization in unresectable hepatocellular carcinoma”
“Comparison of color flow duplex study with digital subtraction angiography in the evaluation of peripheral vascular disease”
“A Study to assess the efficacy of magnetization transfer ratio in differentiating tuberculoma from neurocysticercosis”
“MR evaluation of uterine mass lesions in correlation with transabdominal, transvaginal ultrasound using HPE as a gold standard”
“The Role of power Doppler imaging with trans rectal ultrasonogram guided prostate biopsy in the detection of prostate cancer”
“Lower limb arteries assessed with doppler angiography – A prospective comparative study with multidetector CT angiography”
“Comparison of sildenafil with papaverine in penile doppler by assessing hemodynamic changes”
“Evaluation of efficacy of sonosalphingogram for assessing tubal patency in infertile patients with hysterosalpingogram as the gold standard”
Role of CT enteroclysis in the evaluation of small bowel diseases
“MRI colonography versus conventional colonoscopy in the detection of colonic polyposis”
“Magnetic Resonance Imaging of anteroposterior diameter of the midbrain – differentiation of progressive supranuclear palsy from Parkinson disease”
“MRI Evaluation of anterior cruciate ligament tears with arthroscopic correlation”
“The Clinicoradiological profile of cerebral venous sinus thrombosis with prognostic evaluation using MR sequences”
“Role of MRI in the evaluation of pelvic floor integrity in stress incontinent patients” “Doppler ultrasound evaluation of hepatic venous waveform in portal hypertension before and after propranolol”
“Role of transrectal sonography with colour doppler and MRI in evaluation of prostatic lesions with TRUS guided biopsy correlation”
“Ultrasonographic evaluation of painful shoulders and correlation of rotator cuff pathologies and clinical examination”
“Colour Doppler Evaluation of Common Adult Hepatic tumors More Than 2 Cm with HPE and CECT Correlation”
“Clinical Relevance of MR Urethrography in Obliterative Posterior Urethral Stricture”
“Prediction of Adverse Perinatal Outcome in Growth Restricted Fetuses with Antenatal Doppler Study”
Radiological evaluation of spinal dysraphism using CT and MRI
“Evaluation of temporal bone in cholesteatoma patients by high resolution computed tomography”
“Radiological evaluation of primary brain tumours using computed tomography and magnetic resonance imaging”
“Three dimensional colour doppler sonographic assessment of changes in volume and vascularity of fibroids – before and after uterine artery embolization”
“In phase opposed phase imaging of bone marrow differentiating neoplastic lesions”
“Role of dynamic MRI in replacing the isotope renogram in the functional evaluation of PUJ obstruction”
Characterization of adrenal masses with contrast-enhanced CT – washout study
A study on accuracy of magnetic resonance cholangiopancreatography
“Evaluation of median nerve in carpal tunnel syndrome by high-frequency ultrasound & color doppler in comparison with nerve conduction studies”
“Correlation of Agatston score in patients with obstructive and nonobstructive coronary artery disease following STEMI”
“Doppler ultrasound assessment of tumor vascularity in locally advanced breast cancer at diagnosis and following primary systemic chemotherapy.”
“Validation of two-dimensional perineal ultrasound and dynamic magnetic resonance imaging in pelvic floor dysfunction.”
“Role of MR urethrography compared to conventional urethrography in the surgical management of obliterative urethral stricture.”

Search Diagnostic Imaging Research Topics

You can also search research-related resources on our custom search engine .

A Search Engine for Radiology Presentations

Free Resources for Preparing Radiology Thesis

Radiology thesis topics- Benha University – Free to download thesis
Radiology thesis topics – Faculty of Medical Science Delhi
Radiology thesis topics – IPGMER
Fetal Radiology thesis Protocols
Radiology thesis and dissertation topics
Radiographics

Proofreading Your Thesis:

Make sure you use Grammarly to correct your spelling , grammar , and plagiarism for your thesis. Grammarly has affordable paid subscriptions, windows/macOS apps, and FREE browser extensions. It is an excellent tool to avoid inadvertent spelling mistakes in your research projects. It has an extensive built-in vocabulary, but you should make an account and add your own medical glossary to it.

Grammarly spelling and grammar correction app for thesis

Guidelines for Writing a Radiology Thesis:

These are general guidelines and not about radiology specifically. You can share these with colleagues from other departments as well. Special thanks to Dr. Sanjay Yadav sir for these. This section is best seen on a desktop. Here are a couple of handy presentations to start writing a thesis:

Read the general guidelines for writing a thesis (the page will take some time to load- more than 70 pages!

A format for thesis protocol with a sample patient information sheet, sample patient consent form, sample application letter for thesis, and sample certificate.

Resources and References:

Guidelines for thesis writing.
Format for thesis protocol
Thesis protocol writing guidelines DNB
Informed consent form for Research studies from AIIMS
Radiology Informed consent forms in local Indian languages.
Sample Informed Consent form for Research in Hindi
Guide to write a thesis by Dr. P R Sharma
Guidelines for thesis writing by Dr. Pulin Gupta.
Preparing MD/DNB thesis by A Indrayan
Another good thesis reference protocol

Hopefully, this post will make the tedious task of writing a Radiology thesis a little bit easier for you. Best of luck with writing your thesis and your residency too!

More guides for residents :

Guide for the MD/DMRD/DNB radiology exam!
Guide for First-Year Radiology Residents
FRCR Exam: THE Most Comprehensive Guide (2022)!
Radiology Practical Exams Questions compilation for MD/DNB/DMRD !

Radiology Exam Resources (Oral Recalls, Instruments, etc )!

Tips and tricks for dnb/md radiology practical exam.

FRCR 2B exam- Tips and Tricks !
FRCR exam preparation – An alternative take!
Why did I take up Radiology?
Radiology Conferences – A comprehensive guide!
ECR (European Congress Of Radiology)
European Diploma in Radiology (EDiR) – The Complete Guide!
Radiology NEET PG guide – How to select THE best college for post-graduation in Radiology (includes personal insights)!
Interventional Radiology – All Your Questions Answered!
What It Means To Be A Radiologist: A Guide For Medical Students!
Radiology Mentors for Medical Students (Post NEET-PG)
MD vs DNB Radiology: Which Path is Right for Your Career?
DNB Radiology OSCE – Tips and Tricks

More radiology resources here: Radiology resources This page will be updated regularly. Kindly leave your feedback in the comments or send us a message here . Also, you can comment below regarding your department’s thesis topics.

Note: All topics have been compiled from available online resources. If anyone has an issue with any radiology thesis topics displayed here, you can message us here , and we can delete them. These are only sample guidelines. Thesis guidelines differ from institution to institution.

Image source: Thesis complete! (2018). Flickr. Retrieved 12 August 2018, from https://www.flickr.com/photos/cowlet/354911838 by Victoria Catterson

About The Author

Dr. amar udare, md, related posts ↓.

Radiology Exam Resources - Free PDF, presentations, ebooks, and case collections.

7 thoughts on “Radiology Thesis – More than 400 Research Topics (2022)!”

Amazing & The most helpful site for Radiology residents…

Thank you for your kind comments 🙂

Dr. I saw your Tips is very amazing and referable. But Dr. Can you help me with the thesis of Evaluation of Diagnostic accuracy of X-ray radiograph in knee joint lesion.

Wow! These are excellent stuff. You are indeed a teacher. God bless

Glad you liked these!

happy to see this

Glad I could help :).

Wish to be a BETTER Radiologist? Join 14000 Radiology Colleagues !

Enter your email address below to access HIGH YIELD radiology content, updates, and resources.

No spam, only VALUE! Unsubscribe anytime with a single click.

An official website of the United States government

The .gov means it’s official. Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

The site is secure. The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

Publications
Account settings

Preview improvements coming to the PMC website in October 2024. Learn More or Try it out now .

Advanced Search
Journal List
Wiley Open Access Collection

Identification of research priorities of radiography science: A modified Delphi study in Europe

Sanna törnroos.

1 Department of Nursing Science, University of Turku and Metropolia University of Applied Sciences, Turku Finland

Miko Pasanen

2 Department of Nursing Science, University of Turku, Turku Finland

Helena Leino‐Kilpi

3 Department of Nursing Science, University of Turku and Turku University Hospital, Turku Finland

Eija Metsälä

Associated data.

The data that support the findings of this study are openly available in Zenodo at http://doi.org/10.5281/zenodo.6322928

Radiography science is a new discipline among health sciences. It is a discipline that investigates phenomena in medical imaging, radiation therapy, and nuclear medicine. It has merged from the need to provide research evidence to support these services. The domain of the discipline needs clarification and more research should be focused on its paradigmatic issues. Radiography research priorities have been previously charted on a national level in different countries but the viewpoint has been that of the needs of the profession, not of the discipline. This study aimed to identify the priorities of the discipline. The method chosen was a modified version of the Delphi technique with two rounds. The expert panel consisted of 24 European radiography researchers with long professional experience. This study shows that the research priorities in radiography science are related to the phenomena of radiographers' profession, clinical practices, and the safe and high‐quality use of radiation and technology for medical imaging, radiotherapy, and nuclear medicine. Identifying these priorities can help focus research onto most important topics and clarify disciplinary perspective.

The research priorities in radiography science are related to the phenomena of radiographers' profession, clinical practices, and the safe and high quality use of radiation and technology for medical imaging, radiotherapy, and nuclear medicine
Eight research topics were rated high in importance. These were the benefits of using artificial intelligence in radiography, safe integration of artificial intelligence into practice, impact of new technology, evidence‐based clinical practices, radiation safety, radiation optimization, patient outcomes in medical imaging, and image interpretation.
Radiography science differs from other health sciences in its priorities

1. INTRODUCTION

The European Commission's Horizon Europe ( 2021 ), a major funder of health research, includes in its policy aims finding new ways to keep people healthy, and developing better diagnostics and more effective therapies. Almost all patients in health care go through diagnostic examinations at some stage of their care pathway. Medical imaging rates are increasing due to innovations in technology and treatment methods (Smith‐Bindman et al., 2019 ), new applications in screening (Fedewa et al., 2021 ), the rising number of older people (United Nations, 2019 ), and increases in multimorbidity (Head et al., 2021 ) and in cancer cases (Tanskanen et al., 2021 ). Cancer is a growing health problem, and radiotherapy is used in cancer treatment in about 50 per cent of cases (Baskar et al., 2012 ). Radiography is an allied health science acting in the field of diagnostic imaging and radiotherapy. The knowledge base in radiography science is a combination of patient care and high technology and consists of medical imaging, radiotherapy, and nuclear medicine (Lundgren et al., 2015 ). Research in radiography has a long history, but as a discipline of its own it is still evolving. Rapid changes in the field set demands for high‐quality research, which is difficult to execute without solid foundations and a clear disciplinary perspective. It would be vital to conduct research from the discipline's own paradigm to develop clinical practices at the grass‐roots level where the patients encounter the diagnostic and therapeutic services. Radiography science in Europe is not a unified discipline. There are differences in the education, curricula, and research practices (Couto et al., 2018 ; McNulty et al., 2016 ). Advantages of a unified discipline would be closer research collaboration between researchers and academic institutions offering radiography as a discipline, better understanding of what the focus of the discipline is and its philosophical assumptions, not to mention the benefits of sharing limited research funding of small subspecialties. In order to clarify a unified disciplinary perspective, it is important to identify the research priorities of radiography science.

1.1. Background

Radiographers consider their own research important but are not actively involved in research (Vikestad et al., 2017 ). The number of radiographers with a doctorate degree is around 0.1 to 0.3 per cent of the workforce (Andersson et al., 2020 ; Ekpo et al., 2017 ). This is significantly lower than the number of nurses with doctorates, around 1 to 1.9 per cent of the workforce (Rosenfeld et al., 2022 ; Orton et al., 2020 ). There is an active research community in the discipline but the majority of the published articles are from a small group of researchers (Snaith, 2013 ). Radiographers are engaged in research activities as assistants or collectors of data but many studies are led by other professionals due to radiographers' limited experience and confidence in conducting research (Saukko et al., 2021 ; Dennett et al., 2021 ). However, most radiography professionals tend to think that radiographers should conduct research and lead research projects (Saukko et al., 2021 ; Ooi et al., 2012 ). Advancement of research engagement would require knowledge about scientific methods, support from colleagues and other professionals, and a positive research culture in workplaces (Bolejko et al., 2021 ).In health sciences, research interests and priorities have been studied for reasons such as developing an informed set of research priorities (Shepherd et al., 2017 ), augmenting previously identified research priorities with a new group (Frankenberger et al., 2019 ), identifying research topics (Wielenga et al., 2015 ), developing a research agenda (Brenner et al., 2014 ), and prioritizing efforts and resources (Garner et al., 2021 ). In nursing science, research priorities have been set to both broad foci (such as health, practice, education, and leadership) and to various clinical categories (Strobehn et al., 2021 ). Research regarding dissertation topics in nursing identified quality of life, perception, job satisfaction, sleep, nursing roles, physical activity/exercise, turnover, leadership styles, simulation, and cancer as the most frequent topics (Strobehn et al., 2021 ). In the Nordic countries, research in nursing focuses mainly on patients' health problems (Lundgren et al., 2009 ). By contrast, in radiography, dissertations have focused on structural factors, clinical radiography, radiographic technology, and pedagogical approaches (Lundgren et al., 2019 ), indicating that radiography and nursing have diverging research priorities. The current discourse about radiography science resembles much of the discussion that nursing science faced in the early ages about its disciplinary perspective and focus (Lundgren et al., 2009 ).Areas of research interests for European radiography researchers have not previously been charted from the perspective of the discipline. Previous studies have explored the needs of the profession. Radiotherapists' research interests have been charted at the national level in Norway and Australia (Egestad & Halkett, 2016 ; Halkett et al., 2017 ). Studies in the research interests in radiotherapy indicate that the research interests are connected to patients, technical issues of radiotherapy, radiation safety, and issues of the staff (Egestad & Halkett, 2016 ). Research areas prioritized as most important were linked to the development of treatment techniques and their benefits and side effects to patients, as well as to concerns of the radiotherapist profession (Cox et al., 2010 ). Researchers have also stated patient focus and patient outcomes in radiotherapy as areas of research interest (Halkett et al., 2017 ).The College of Radiographers ( 2017 ) studied research priorities for the radiographer profession in the United Kingdom. A Delphi expert panel reached consensus in 133 priority areas. Five key themes for research were identified. These were technical innovations, patient and public experience, service and workforce transformation, accuracy and safety, and education and training. The Society of Radiographers working group for artificial intelligence (AI; Malamateniou et al., 2021 ) found that radiography research priorities should be set to investigate the impact of AI technologies on patients in medical imaging and radiotherapy, radiographer role development, and the development of practices with emerging AI‐based technology. In Finland, the research focus in radiography science is reportedly in clinical radiographers' work, technical radiation usage and radiation protection, patient care and service, and service for a health care context (Sorppanen, 2006 ). Metsälä and Fridell ( 2018 ) found that radiography science primarily has technical and practical knowledge interests, but that critical knowledge interests exist as well.

In this study, our aim is to identify research priorities in radiography science. The objective is to chart the opinions of radiography experts. We ask three questions to guide this study:

Which research topics do radiography science experts in Europe consider important for radiography science?
Which research topic do they see as most important?
Which research topics do experts in the field of radiography agree upon?

Agreement on topics is achieved when there is a consensus. The topics that reach consensus and are rated as being of high importance are considered the priorities of the discipline.

The Delphi technique was selected as the method. The Delphi technique is a widely used method in health sciences and it has been used in developing guidelines and establishing research priorities. The Delphi technique is characterized by the use of an expert panel, the members of which are anonymous to each other, and iterative rounds with feedback and the opportunity to alter one's opinion. The classical Delphi technique has at least three successive rounds but modified variations are numerous. The classical Delphi technique starts with an open first round (Varndell et al., 2021 ). The benefit of using a Delphi technique is the possibility of having an anonymous group opinion from a wide geographical area. It is especially suitable when there is a lack of agreement or incomplete knowledge (Trevelyan & Robinson, 2015 ). The Delphi technique has been widely used in identifying and building consensus on research interests and priorities in health sciences among health care professionals (e.g., Shepherd et al., 2017 ; Frankenberger et al., 2019 ).

2.1. Design

A modified Delphi method with two rounds was performed. Instead of an open first round, we used a scoping review as the starting point of our study. In an earlier study (Törnroos et al., 2021 ), we identified 117 research interests for radiography science. They formed the basis of the first‐round questionnaire. Some of the similar items were further merged by two authors (S.T. and E.M.) and eventually 84 items were included in the first‐round questionnaire. The first‐round questionnaire was piloted in Finland in August 2021 by four radiographers with experience and training in research. They commented on the readability and clarity of the questionnaire. The comments concerned the instruction text for the questionnaire, background questions about the discipline, headings, and the size of the open‐ended answer box. The questionnaire was modified accordingly. The entire Delphi process is presented in Figure 1 .

An external file that holds a picture, illustration, etc.
Object name is NHS-24-423-g001.jpg

Description of the Delphi process. The two steps comprising the top row (scoping review) conducted prior to the current study have been reported in Törnroos et al. (2021)

2.2. Expert panel sampling

Experts were recruited through the European Federation of Radiographer Societies (EFRS). A recruitment invitation was sent by the EFRS to all member societies (40 national societies and 60 academic institutions of radiography education in Europe). The criteria for a panelist were (i) minimum of a bachelor's degree in any field of radiography (diagnostics, radiation therapy, or nuclear medicine); (ii) at least two published research articles in a scientific journal in the past 5 years; (iii) clinical work experience in the field; (iv) English‐language skills (reading and writing); and (v) willingness to participate voluntarily. A total of 29 experts answered the invitation, with all but one expert meeting all the criteria. The first round of the questionnaire was thus sent to 28 experts.

2.3. Data collection and analysis

Data were collected with the REDCap platform (hosted by the University of Turku). They were analyzed with IBM SPSS Statistics version 27. Categorical variables were summarized with counts and percentages. Variables did not follow normal distribution. High rankings on importance of the topics (6 or 7) were observed with most variables, with a few outliers distorting the mean. Median values and quartiles were thus selected to describe the level of agreement. The level of consensus was set to an interquartile range (IQR) value of ≤1. IQR is a measure of dispersion for the median. IQR of less than one means that more than 50% of all opinions are within one point on the scale. It is often used in Delphi studies as an objective way of determining consensus (von der Gracht, 2012 ). Stability of the responses between rounds was measured with a bootstrapped paired t ‐test, which is a valid test for two dependent samples with non‐normal distribution (Dwivedi et al., 2017 ). A p ‐value of >0.05 indicates that there is no statistically significant difference between the responses in round two. A smaller p ‐value would indicate that there has been a significant change in the response. To test whether experts' educational background or position at work had a significant effect on their responses, we used the Fisher's extended test. We were unable to use the chi‐square test because the expected number of answers per cell was under five.

2.4. Round one

The 84 research topics (items) in the questionnaire were structured under six categories identified in the scoping review: (i) radiographer's profession (17 items); (ii) clinical practice in radiography (31 items); (iii) safe and high‐quality use of radiation (12 items); (iv) technology in radiography (8 items); (v) discipline of radiography science (5 items); and (vi) management and leadership (11 items). Panelists were asked to rate the importance of the topic to radiography science on a 7‐point Likert scale (not at all important, unimportant, low importance, neutral, somewhat important, important, and very important), where 1 represents “not at all important” and 7 is “very important.” The questionnaire contained an open‐ended question after each category, asking if there ought to be any other topics in that category. The experts were also asked to give a rationale if they considered some topic important or very important. At the end of the questionnaire, there was an open‐ended question asking if there would be any other topics outside the six categories mentioned in the questionnaire.The experts rated all items and most of the items were rated important or very important (median of 6 or 7). Only 15 items were ranked below a median of 6. The experts presented 25 new research topics for the second round. Twenty‐three new topics were placed into existing categories but two of the new topics, veterinary radiography and forensic radiography, did not fit into any pre‐existing category and were placed at the end of the second round questionnaire.

2.5. Round two

In the second round, participants received a reminder of their own answers in round one, and the median answers of the entire expert panel and the range of the answers. Participants were asked to reflect on their own answer and they were given a chance to alter their opinion or remain with the same answer. All research topics (84) and the 25 newly generated topics from the round one answers were included in the second round for a second rating (see Appendix Table A1 for all items). The experts were also asked to choose one most important topic from each of the six categories.

2.6. Ethical considerations

The Ethics Committee for Human Sciences at the University of Turku granted ethical review approval (ref 21/2021). Informed consent was received from all participants and they were provided information on how their data was processed. All data were processed according to the European Union's General Data Protection Regulation (GDPR).

3.1. Demographics of the panelists

Of the 28 experts who indicated willingness to participate, 24 experts eventually (86%) responded to the first round. There was also some attrition between rounds, and only 20 experts answered (71%) for the second round, even though two reminders were sent. The expert panelists participating in the first round were from the United Kingdom ( n = 7), Norway ( n = 4), Denmark ( n = 3), Switzerland ( n = 3), Sweden ( n = 2), Hungary ( n = 1), Italy ( n = 1), Malta ( n = 1), Portugal ( n = 1) and Spain ( n = 1). The mean age of the panelists was 50 years (range 30–70). On average, they had been working 25 years in the field of radiography (range 2–48). They had each published between 2 to 36 scientific publications in the past 5 years, with the mean being 13 publications. There were 23 degrees higher than Bachelor's. Most of the panelists were academics, with only two working as a clinical radiographer or radiotherapist. Those who described their position at work as “other” were working as clinical consultants, senior advisers, or working in a professional association (Table 1 ).

Demographics of the expert panel in round 1 and round 2

3.2. The importance of the research topics after two rounds

Out of all research topics (109 items) under the six categories identified in the scoping review, there were eight research topics that gained a high median score of 6.5 or 7 after two rounds, and the experts were like‐minded in their answers. These eight were as follows: (i) the benefits of using artificial intelligence in radiography; (ii) safe integration of artificial intelligence into practice; (iii) the impact of new technology; (iv) evidence‐based clinical practices; (v) radiation safety; (vi) radiation optimization; (vii) patient outcomes in medical imaging; and (viii) image interpretation. Another 27 research topics were rated important, with a median score of 6 and an IQR of 1. Research topics in advanced practice and patient‐centered care were also rated high in importance (median 7) but the experts' opinions were divided on these topics and they did not reach consensus (IQR of 2). The lowest rated topics that reached consensus were multidisciplinary education, role and territory of radiography, ergonomics of radiographers, workplace well‐being, complementary medicine, and the impact of radiographers' gender on the profession. There were no significant differences in answers with relation to experts' educational background or current position at work. All items included in the second round and statistical analysis are presented in Appendix Table A1 .

The expert's rationales for the topics they selected as important or very important are presented next by the six categories identified in the scoping review, under which they were structured in the questionnaire. The topics chosen as most important in each category are also described.

3.2.1. Radiographers profession

The importance of these topics was primarily rationalized by the developing needs of the profession. As technology in medical imaging and radiotherapy advances, the demands for the profession rise and more research is required for the competences and education of the professionals. Eventually this will have an impact on patient outcome and experience. The development of the radiographer profession requires research in the area.

The technical development makes it very important to be ready to acquire new competence and work in changing organizations (multidisciplinary, new technology, new procedures, new demands on the profession, etc.). (Expert 5)

Development of the profession is important as technology changes. In addition, the quality of the professionals is important for the profession to evolve. (Expert 6)

3.2.2. Clinical practice in radiography

Evidence‐based practice was deemed important for avoiding unnecessary imaging and treatment, and to improve the services and the quality in clinical practice. Patient‐centered care should be a priority and it is important to hear patient voices regarding the services they need.

Good working practices, protocols and procedures are essential in creating time and space to concentrate on the patient and his/her experiences. (Expert 13)

The radiographers work with technology, so they must know well this aspect but at the same time the radiographers are the bridge between the patient and the machine and if the interaction is not optimized, the examination and/or treatment can be compromised. The interaction with other professionals is also important to be sure that we are providing the best diagnostic/therapeutic to the patients. (Expert 4)

3.2.3. Safe and high‐quality use of radiation

Radiation protection was said to be at the heart of radiography and patient safety and the main expertise area of radiographers.

Radiographers are the professionals to handle radiation. Therefore, research in radiation is naturally performed by radiographers. (Expert 8)

Recent advances in radiotherapy dose regimens to include ultra hypofractionated treatments for prostate and breast cancer warrant further investigation of side effects and the radiobiological effect. (Expert 19)

3.2.4. Technology in radiography

Research into technological development was seen as important, as radiography operates with high technology. There was discussion about radiographers taking an active role in its development.

AI requires robust, prospective research to assess performance in a clinical setting and how this will be safely integrated into future practice. (Expert 11)

Radiographers have a lot of room to grow in the field of new technologies. They must be among the actors of these developments and must not be only the users. (Expert 16)

3.2.5. Discipline of radiography science

Research into the discipline was deemed important for the development of the discipline and research.

Research is the only way to develop Radiography as a Science and what is involved in the discipline. (Expert 24)

Good research is founded on good methods. (Expert 14)

3.2.6. Management and leadership

These topics were mostly seen as important because of their connection to smooth operation of the clinical practice and well‐being.

Everyone contributes toward smooth workflow for patient care and health and well‐being of staff. (Expert 15)

These topics are important given their link to an advanced level of radiography practice. (Expert 7)

3.2.7. The most important topic in each category

In addition to rationales, experts were asked to choose the most important topic in each category. The opinions were divided between various topics. Most support was given to “evidence‐based clinical practices” backed up by seven experts and “radiation safety” by six experts. The research topics regarded as most important from other categories were “advanced practice,” “the benefits of using artificial intelligence in radiography,” “the importance of support programs for research activity,” and “communication issues.”

3.3. Research topics that reached consensus after two rounds

Forty‐one research topics reached consensus (Table 2 ) and sixty‐eight did not. There was very little change in the experts’ opinions between rounds; only five items had a statistically significant difference ( p < 0.05) between the first and second round. There were altogether 22 topics in the category of “radiographer's profession” and 8 of them had medians of 6 or over and an IQR of 1 (36% of items), the “clinical practice in radiography” category had 38 topics of which 15 had medians of 6 or greater (39% of the items), “safe and high‐quality use of radiation” had 15 topics and 6 of these had a median of 6 or over (40% of the items), “technology in radiography” had 12 topics with 5 having a median of 6 or greater (42% of the items), “discipline of radiography science” had 8 topics and only 1 received a median of 6 (13%), and in the category of “management and leadership” there were 12 topics but none of them received a median of 6 or over with an IQR of 1. Of these six categories, “radiographer's profession,” “clinical practice in radiography,” “safe and high‐quality use of radiation,” and “technology in radiography” had quite equal proportions of high‐ranking items, while the remaining two, “discipline of radiography science” and “management and leadership,” had but a single research topic between them that was rated important by the experts of this Delphi panel. Therefore, it seems that priority in research should not be given to research topics in these two categories.

Research topics that received consensus after two rounds in each category

Abbreviations: BCa, bias‐corrected and accelerated; IQR, interquartile range.

4. DISCUSSION

The eight topics that received a high median of over 6.5 relate to the clinical practices and radiographers' profession, as well as to radiation safety and new technology in radiography. These are rather similar to the findings of the College of Radiographers (2017) for the research priorities of the radiographer profession: technical innovations, patient and public experience (about clinical practices), service and workforce transformation (in relation to advancing roles), accuracy and safety (quality and safe use of radiation), and education and training (of the radiographer profession). Similar priorities on technological development, radiation safety, patient outcomes and matters of the profession have been reported among radiotherapists (Halkett et al., 2017 ; Egestad & Halkett, 2016 ).The two topics related to artificial intelligence were rated high in importance. This is where Malamateniou et al. ( 2021 ) also recommended that priorities should be set. Artificial Intelligence‐based solutions in medical imaging and radiotherapy, and their effect on the entire discipline, including the role of the radiographer profession in the future, have been widely discussed in the radiography community for the past few years ( International Society of Radiographers and Radiological Technologists and the European Federation of Radiographer Societies, 2020 ). This might have influenced expert panelists' opinions. In the rationales given by the experts for the importance of the research areas, technological development—and in particular, the impact that rapidly developing technology has on clinical practices and the radiographer's profession—was often mentioned as the reason for conducting research in the field. When the development in the technology was used as rationale for investigating radiographers' profession, in those cases, the scope was in the competences required, rather than in the actual technology.Evidence‐based clinical practices were rated with a high median score of 7. Although discussion of evidence‐based practice, which began in the 1990s, soon came to include radiography as well (Hafslund et al., 2008 ), it still seems to be badly implemented in this field (Munn, 2020 ; Abrantes et al., 2020 ). The topic therefore is an ever‐relevant area for research. Research alone does not improve the situation; radiographers working in clinical practice would also require skills for implementation. The patient outcomes in medical imaging, another highly rated topic, relate to the same matter: how to secure effective imaging methods to improve diagnostics and eventually the patients' care. In radiation therapy, it is equally important to secure effective therapeutic procedures for the best outcome for patients.According to the expert panelists' reasoning, radiation safety and optimization are at the heart of radiography and radiographers' special expertise area. The topics were also rated high in importance. Radiation safety has improved over the years but there is still room for development and research. Constantly changing technology keeps radiation safety always topical. Even though radiation in health care is highly regulated, at least in the European Union ( 2013 ), there is indication that obsolete practices still exist (Maina et al., 2020 ; Ciraj‐Bjelac et al., 2011 ) and there are gaps in the knowledge of radiation protection measures (Faggioni et al., 2017 ).The eighth topic rated high, image interpretation, relates to a larger discussion on role extension and transfer of responsibilities from radiologists to radiographers. In the United Kingdom the role extension is well established (Hardy & Snaith, 2009 ), but there is ongoing debate surrounding the issue internationally due to a shortage of trained radiologists (van de Venter & ten Ham‐Baloy, 2019 ; Ofori‐Manteaw & Dzidzornu, 2019 ). Similar discussions of task‐shifting have been topical in other health sciences and we need more research in this area. It will be interesting to see how the rise of AI technology in image interpretation affects this discussion.Studies have shown that radiographers want to conduct research but lack the skills and confidence (Saukko et al., 2021 ; Dennett et al., 2021 ). Bolejko et al. ( 2021 ) propose a strategy for establishing a research culture that is enhanced by support from colleagues and management. We think that the implantation of research culture requires also a clear perspective of the domain of radiography science. Radiography science differs from nursing science and other health sciences in its priorities. Health and health‐related problems that are seen as priorities in nursing research (Strobehn et al., 2021 ; Lundgren et al., 2009 ) do not stand out as a priority in this study. Research into clinical practice is a shared research area in health sciences but the locus is in different areas. In the early years of nursing science, a lot of research and theories were focused on nurses and the actions they perform. As the discipline has matured, research has been directed toward the clinical problems of the patients and the essential phenomena of nursing (Tobbell, 2018 ). Radiography as a scientific discipline is still evolving, and in the future we might see the essential phenomena of radiography science emerging and the professional connection to a radiographer's work fade. In medical imaging and radiotherapy technology, change seems to be continuous. Research topics may vary over time but some phenomena that radiography science investigates are constant. Whatever improvements in technology there might be, it is important to translate the changes into clinical practice and in a manner that is suitable and safe for patients.

4.1. Limitations

The panelists of this Delphi study had a long professional history in the field of radiography and expertise in research. They represented different countries in Europe and different educational backgrounds. From some European countries there was only one expert in the panel and therefore we cannot make any generalizations that the results of this study would represent the opinion of the whole of Europe. Experts with diagnostic radiography education were over‐represented, constituting over half of the experts. Generally, of the European radiographers, about 63% have a combined qualification (diagnostic imaging, radiotherapy, and nuclear medicine), 34% diagnostic imaging only, and a small percentage are specifically qualified in radiotherapy and nuclear medicine only (McNulty et al., 2016 ). The research topics were previously identified through the literature, and the experts were asked to judge the topics in relation to their importance to radiography science (not to their own research field), so the over‐representation of diagnostic radiography researchers did not significantly bias the results. Of course, this might have had an effect on the prioritizing of research topics. It is possible that with a larger group of experts and wider geographical representation, the results of the study might be somewhat different. We received a confirmation from the EFRS that the invitation to participate in the study had been sent to all member organizations, but we could have enhanced the participation rates by advertising further.It is important to understand that achieving consensus does not mean that the correct answer has been definitively found (Keeney et al., 2006 ). For example, patient‐centered care, which has been recognized as an important research area in radiography (Halkett et al., 2012 ), was rated high in importance in this study, yet the topic did not achieve consensus. Some of the research topics might be more important to radiotherapists than to diagnostic radiographers and vice versa, but it was not the scope of this study to compare differences but rather to find commonalities that could be studied inside the discipline of radiography science. A further stated limitation of the Delphi method is a poor response rate in the sequential rounds (Keeney et al., 2006 ), and we also had a decline of participants in the second round. However, the response rate of 71% in the second round can be still considered sufficient.

5. CONCLUSIONS

This study has provided knowledge on research priorities of radiography science that are shared by experts of the Delphi panel, who were from different fields of radiography and different areas of Europe. Radiography science in this study is understood as a common field of inquiry that researchers in diagnostic imaging, radiotherapy, and nuclear medicine share. The priorities therefore are the research areas where a common ground, a consensus, can be found. We had previously discovered six main phenomena from the literature which radiography science investigates; however, the results of this study indicate that only four of them are priority areas for the discipline. The research priorities in radiography science are related to the phenomena of radiographers' profession, clinical practices, safe and high‐quality use of radiation and technology used in medical imaging, radiotherapy, and nuclear medicine. This finding is also supported by previous studies of priorities of the profession. There are several research topics inside these categories and the topics that received the most support from the experts were identified.

5.1. Relevance for clinical practice

The application of evidence‐based practices, and the development of diagnostic and therapeutic services provided in health care, require strong research evidence. This evidence can be produced with research done in radiography science. As we have now identified the priorities of radiography science, researchers in the discipline could focus their studies on these topics.

AUTHOR CONTRIBUTIONS

Study design: Sanna Törnroos, Miko Pasanen, Helena Leino‐Kilpi, Eija Metsälä. Data collection: Sanna Törnroos. Data analysis: Sanna Törnroos, Miko Pasanen. Manuscript writing: Sanna Törnroos, Helena Leino‐Kilpi, Eija Metsälä.

ACKNOWLEDGMENTS

This study was supported by the Finnish Concordia Fund with a research grant to the first author. The Fund had no role in the actual study. The coauthors did not receive funds for executing this study. We want to thank the European Federation of Radiographer Societies for its assistance with the recruitment of the expert panelists.

APPENDIX A.

All items included for round two, in same order as they appear in the questionnaire and statistical significance (Fisher's extended test) of experts' answers by the level of education, background education, and position at work, with items that were only rated in round two are marked as new

Törnroos, S. , Pasanen, M. , Leino‐Kilpi, H. , & Metsälä, E. (2022). Identification of research priorities of radiography science: A modified Delphi study in Europe . Nursing & Health Sciences , 24 ( 2 ), 423–436. 10.1111/nhs.12938 [ PMC free article ] [ PubMed ] [ CrossRef ] [ Google Scholar ]

Funding information Finnish Concordia Fund, Grant/Award Number: 20210014

DATA AVAILABILITY STATEMENT

Abrantes, A. , Ribeiro, L. , da Silva, C. , England, A. , Azevedo, K. , Almeida, R. , & Canha Reis, M. (2020). Evidence‐based radiography: A new methodology or the systematisation of an old practice? Radiography , 26 ( 2 ), 127–132. [ PubMed ] [ Google Scholar ]
Andersson, B. T. , Lundén, M. , & Lundgren, S. M. (2020). Radiographers' academic development in Sweden: Towards and after a doctoral degree . Radiography , 26 ( 4 ), 275–281. [ PubMed ] [ Google Scholar ]
Baskar, R. , Lee, K. A. , Yeo, R. , & Yeoh, K. W. (2012). Cancer and radiation therapy: Current advances and future directions . International Journal of Medical Sciences , 9 ( 3 ), 193–199. [ PMC free article ] [ PubMed ] [ Google Scholar ]
Bolejko, A. , Andersson, B. T. , Debess, J. , Fridell, K. , Henner, A. , Sanderud, A. , Saukko, E. , & Mussmann, B. R. (2021). Facilitators for and barriers to radiography research in public healthcare in Nordic countries . Radiography , 28 ( 1 ), 88–94. [ PubMed ] [ Google Scholar ]
Brenner, M. , Hilliard, C. , Regan, G. , Coughlan, B. , Hayden, S. , Drennan, J. , & Kelleher, D. (2014). Research priorities for Children's nursing in Ireland: A Delphi study . Journal of Pediatric Nursing , 29 , 301–308. [ PubMed ] [ Google Scholar ]
Ciraj‐Bjelac, O. , Beganovic, A. , Faj, D. , Gershan, V. , Ivanovic, S. , Videnovic, I. R. , & Rehani, M. M. (2011). Radiation protection of patients in diagnostic radiology: Status of practice in five eastern‐European countries, based on IAEA project . European Journal of Radiology , 79 ( 2 ), e70–e73. [ PubMed ] [ Google Scholar ]
Couto, J. G. , McFadden, S. , Bezzina, P. , McClure, P. , & Hughes, C. (2018). An evaluation of the educational requirements to practise radiography in the European Union . Radiography , 24 , 64–71. [ PubMed ] [ Google Scholar ]
Cox, J. , Halkett, G. , Anderson, C. , & Heard, R. (2010). A Delphi study on research priorities in radiation therapy: The Australian perspective . Radiography , 16 , 26–39. [ Google Scholar ]
Dennett, A. , Cauchi, T. , Harding, K. , Kelly, P. , Ashby, G. , & Taylor, N. (2021). Research interest, experience and confidence of allied health professionals working in medical imaging: A cross‐sectional survey . Journal of Medical Radiation Sciences , 68 , 121–130. [ PMC free article ] [ PubMed ] [ Google Scholar ]
Dwivedi, A. K. , Mallawaarachchi, I. , & Alvarado, L. A. (2017). Analysis of small sample size studies using nonparametric bootstrap test with pooled resampling method . Statistics in Medicine , 36 , 2187–2205. [ PubMed ] [ Google Scholar ]
Egestad, H. , & Halkett, G. (2016). A Delphi study on research priorities in radiation therapy: The Norwegian perspective . Radiography , 22 , 65–70. [ Google Scholar ]
Ekpo, E. , Snaith, B. , Harris, M. , & McEntee, M. (2017). Doctoral profile of the medical radiation sciences: A baseline for Australia and New Zealand . Journal of Medical Radiation Sciences , 64 , 195–202. [ PMC free article ] [ PubMed ] [ Google Scholar ]
European Commission . (2021). Horizon Europe . https://ec.europa.eu/info/research-and-innovation/funding/funding-opportunities/funding-programmes-and-open-calls/horizon-europe_en
European Union . (2013). Council Directive 2013/59/Euratom . https://eur-lex.europa.eu/eli/dir/2013/59/oj
Faggioni, L. , Paolicchi, F. , Bastiani, L. , Guido, D. , & Caramella, D. (2017). Awareness of radiation protection and dose levels of imaging procedures among medical students, radiography students, and radiology residents at an academic hospital: Results of a comprehensive survey . European Journal of Radiology , 86 , 135–142. [ PubMed ] [ Google Scholar ]
Fedewa, S. , Kazerooni, E. , Studts, J. , Smith, R. , Bandi, P. , Goding Sauer, A. , Cotter, M. , Sineshaw, H. , Jemal, A. , & Silvestri, G. (2021). State variation in low‐dose computed tomography scanning for lung cancer screening in the United States . Journal of the National Cancer Institute , 113 ( 8 ), 1044–1052. [ PMC free article ] [ PubMed ] [ Google Scholar ]
Frankenberger, W. , Pasmann, A. , Noll, J. , Abbadessa, M. K. , Sandhu, R. , Brodecki, D. , & Ely, E. (2019). Nursing research priorities in the pediatric emergency care applied research network (pecarn): Reaching consensus through the delphi method . Journal of Emergency Nursing , 45 , 614–621. [ PubMed ] [ Google Scholar ]
Garner, J. , Proaño, G. , Kelley, K. , Banna, J. , Emenaker, N. , & Sauer, K. (2021). Revising the Academy's research priorities: Methods of the research priorities and strategies development task force, 2017‐2019 . Journal of the Academy of Nutrition and Dietetics , 121 ( 11 ), 2275–2286.e2. [ PubMed ] [ Google Scholar ]
Halkett, G. , Cox, J. , Anderson, C. , & Heard, R. (2012). Establishing research priorities for Australian radiation therapists: What patient care priorities need to be addressed? European Journal of Cancer Care , 21 , 31–40. [ PubMed ] [ Google Scholar ]
Halkett, G. , Berg, M. , Ebert, M. , Cutt, D. , Davis, M. , Hegney, D. , House, M. , Judson, M. , Kearvell, R. , Krawiec, M. , Lester, L. , Maresse, S. , McLoone, P. , & McKay, J. (2017). Radiation therapists' perspectives on participating in research . Journal of Medical Radiation Science , 64 , 299–309. [ PMC free article ] [ PubMed ] [ Google Scholar ]
Hafslund, B. , Clare, J. , Graverholt, B. , & Wammen Nortvedt, M. (2008). Evidence‐based radiography . Radiography , 14 , 343–348. [ Google Scholar ]
Hardy, M. , & Snaith, B. (2009). Radiographer interpretation of trauma radiographs: Issues for radiography education providers . Radiography , 15 , 101–105. [ Google Scholar ]
Head, A. , Fleming, K. , Kypridemos, C. , Schofield, P. , Pearson‐Stuttard, J. , & O'Flaherty, M. (2021). Inequalities in incident and prevalent multimorbidity in England, 2004–19: A population‐based, descriptive study . The Lancet Healthy Longevity , 2 ( 8 ), e489–e497. [ Google Scholar ]
International Society of Radiographers and Radiological Technologists and the European Federation of Radiographer Societies . (2020). Artificial Intelligence and the Radiographer / Radiological Technologist Profession. A Joint Statement of the International Society of Radiographers and Radiological Technologists and the European Federation of Radiographer Societies . https://www.isrrt.org/pdf/ISRRT-EFRS-042020.pdf . [ PubMed ]
Keeney, S. , Hasson, F. , & McKenna, H. (2006). Consulting the oracle: Ten lessons from using the Delphi technique in nursing research . Journal of Advanced Nursing , 53 ( 2 ), 205–212. [ PubMed ] [ Google Scholar ]
Lundgren, S. , Valmari, G. , & Skott, C. (2009). The nature of nursing research: Dissertations in the Nordic countries . Scandinavian Journal of Caring Sciences , 23 , 402–416. [ PubMed ] [ Google Scholar ]
Lundgren, S. , Lundén, M. , & Andersson, B. (2015). Radiography – How do students understand the concept of radiography? Radiography , 21 ( 2 ), e68–e73. [ Google Scholar ]
Lundgren, S. , Andersson, B. , & Lundén, M. (2019). Radiographic research in Sweden ‐ A review of dissertations . Radiography , 25 , s25–s32. [ PubMed ] [ Google Scholar ]
Malamateniou, C. , McFadden, S. , McQuinlan, Y. , England, A. , Woznitza, N. , Goldsworthy, S. , Currie, C. , Skelton, E. , Chu, K.‐Y. , Alware, N. , Matthews, P. , Hawkesford, R. , Tucker, R. , Town, W. , Matthew, J. , Kalinka, C. , & O'Regan, T. (2021). Artificial intelligence: Guidance for clinical imaging and therapeutic radiography professionals, a summary by the Society of Radiographers AI working group . Radiography , 27 ( 4 ), 1192–1202. [ PubMed ] [ Google Scholar ]
McNulty, J. P. , Rainford, L. , Bezzina, P. , Henner, A. , Kukkes, T. , Pronk‐Larive, D. , & Vandulek, C. (2016). A picture of radiography education across Europe . Radiography , 22 ( 1 ), 5–11. [ Google Scholar ]
Maina, P. M. , Motto, J. A. , & Hazell, L. J. (2020). Investigation of radiation protection and safety measures in Rwandan public hospitals: Readiness for the implementation of the new regulations . Journal of Medical Imaging and Radiation Sciences , 51 , 629–638. [ PubMed ] [ Google Scholar ]
Metsälä, E. , & Fridell, K. (2018). Insights into the methodology of radiography science . Radiography , 24 ( 4 ), e105–e108. [ PubMed ] [ Google Scholar ]
Munn, Z. (2020). Why isn't there an evidence‐based radiography? Reflections and a call to action . Radiography , 26 ( s2 ), s14–s16. [ PubMed ] [ Google Scholar ]
Ofori‐Manteaw, B. B. , & Dzidzornu, E. (2019). Accuracy of appendicular radiographic image interpretation by radiographers and junior doctors in Ghana: Can this be improved by training? Radiography , 25 , 255–259. [ PubMed ] [ Google Scholar ]
Ooi, C.‐C. , Lee, S. , & Soh, B. (2012). A survey on the research awareness and readiness among radiographers in Singapore General Hospital (SGH) . Radiography , 18 , 264–269. [ Google Scholar ]
Orton, M.‐L. , Nelson Follin, N. , Dannapfel, P. , & Wengström, Y. (2020). Roles and functions in clinical care for registered nurses with a PhD—A systematic literature review . Scandinavian Journal of Caring Sciences , 36 , 16–26. [ PubMed ] [ Google Scholar ]
Rosenfeld, P. , Glassman, K. , Vetter, M. , & Smith, B. (2022). A comparative study of PhD and DNP nurses in an integrated health care system . Nursing Outlook , 70 , 145–153. [ PubMed ] [ Google Scholar ]
Saukko, E. , Andersson, B. T. , Bolejko, A. , Debess, J. , Fridell, K. , Henner, A. , Mussmann, B. R. , & Sanderud, A. (2021). Radiographers' involvement in research activities and opinions on radiography research: A Nordic survey . Radiography , 27 , 867–872. [ PubMed ] [ Google Scholar ]
Shepherd, V. , Wood, F. , & Hood, K. (2017). Establishing a set of research priorities in care homes for older people in the UK: A modified Delphi consensus study with care home staff . Age and Ageing , 46 , 284–290. [ PMC free article ] [ PubMed ] [ Google Scholar ]
Smith‐Bindman, R. , Kwan, M. , Marlow, E. , Theis, M. K. , Bolch, W. , Cheng, S. , Bowles, E. , Duncan, J. , Greenlee, R. , Kushi, L. , Pole, J. , Rahm, A. , Stout, N. , Weinmann, S. , & Miglioretti, D. (2019). Trends in use of medical imaging in US health care systems and in Ontario, Canada, 2000‐2016 . JAMA , 322 ( 9 ), 843–856. [ PMC free article ] [ PubMed ] [ Google Scholar ]
Snaith, B. (2013). An evaluation of author productivity in international radiography journals 2004–2011 . Journal of Medical Radiation Sciences , 60 ( 3 ), 93–99. [ PMC free article ] [ PubMed ] [ Google Scholar ]
Sorppanen, S. (2006). Focus of the clinical science of radiography and radiotherapy. A concept‐analytical study on the defining concepts and connections between them . [Doctoral dissertation, Faculty of Medicine, University of Oulu]. Jultika: University of Oulu repository. http://urn.fi/urn:isbn:951428058X (in Finnish)
Strobehn, P. K. , Bellury, L. M. , King, A. C. , & Randolph, J. J. (2021). Content analysis of dissertations for examination of priority areas of nursing science . Nursing Outlook , 69 , 982–990. [ PubMed ] [ Google Scholar ]
Tanskanen, T. , Seppä, K. , Virtanen, A. , Malila, N. , & Pitkäniemi, J. (2021). Cancer incidence and mortality in the oldest old: A Nationwide study in Finland . American Journal of Epidemiology , 190 ( 5 ), 836–842. [ PMC free article ] [ PubMed ] [ Google Scholar ]
The College of Radiographers . (2017). The College of Radiographers research priorities for the radiographic profession : A Delphi consensus study . https://www.sor.org/getmedia/4893542f-3849-4fc8-a950-e7461c4cbfe9/research_priorities_final_version.pdf_2
Tobbell, D. (2018). Nursing's boundary work. Theory development and the making of nursing science, ca. 1950–1980 . Nursing Research , 67 ( 2 ), 63–73. [ PubMed ] [ Google Scholar ]
Trevelyan, E. , & Robinson, N. (2015). Delphi methodology in health research: How to do it? European Journal of Integrative Medicine , 7 , 423–428. [ Google Scholar ]
Törnroos, S. , Leino‐Kilpi, H. , & Metsälä, E. (2021). Phenomena of radiography science ‐ a scoping review . Radiography , 27 ( 4 ), 1231–1240. [ PubMed ] [ Google Scholar ]
United Nations . (2019). World population prospects 2019 . https://population.un.org/wpp/
van de Venter, R. , & ten Ham‐Baloyi, W. (2019). Image interpretation by radiographers in South Africa: A systematic review . Radiography , 25 , 178–185. [ PubMed ] [ Google Scholar ]
Varndell, W. , Fry, M. , Lutze, M. , & Elliott, D. (2021). Use of the Delphi method to generate guidance in emergency nursing practice: A systematic review . International Emergency Nursing , 56 , 100867. [ PubMed ] [ Google Scholar ]
Vikestad, K. G. , Hafskjold, L. , Kjelle, E. , Sebuødegård, S. , & Hofvind, S. (2017). Radiographers' opinions on radiography research in Norway ‐ A national survey . Radiography , 23 , 135–140. [ PubMed ] [ Google Scholar ]
von der Gracht, H. (2012). Consensus measurement in Delphi studies: Review and implications for future quality assurance . Technological Forecasting and Social Change , 79 , 1525–1536. [ Google Scholar ]
Wielenga, J. M. , Tume, L. N. , Latour, J. M. , & van den Hoogen, A. (2015). European neonatal intensive care nursing research priorities: An e‐Delphi study . Archives of Disease in Childhood. Fetal and Neonatal Edition , 100 , F66–F71. [ PubMed ] [ Google Scholar ]

Radiology Research Paper Topics

Radiology research paper topics encompass a wide range of fascinating areas within the field of medical imaging. This page aims to provide students studying health sciences with a comprehensive collection of radiology research paper topics to inspire and guide their research endeavors. By delving into various categories and exploring ten thought-provoking topics within each, students can gain insights into the diverse research possibilities in radiology. From advancements in imaging technology to the evaluation of diagnostic accuracy and the impact of radiological interventions, these topics offer a glimpse into the exciting world of radiology research. Additionally, expert advice is provided to help students choose the most suitable research topics and navigate the process of writing a research paper in radiology. By leveraging iResearchNet’s writing services, students can further enhance their research papers with professional assistance, ensuring the highest quality and adherence to academic standards. Explore the realm of radiology research paper topics and unleash your potential to contribute to the advancement of medical imaging and patient care.

100 Radiology Research Paper Topics

Radiology encompasses a broad spectrum of imaging techniques used to diagnose diseases, monitor treatment progress, and guide interventions. This comprehensive list of radiology research paper topics serves as a valuable resource for students in the field of health sciences who are seeking inspiration and guidance for their research endeavors. The following ten categories highlight different areas within radiology, each containing ten thought-provoking topics. Exploring these topics will provide students with a deeper understanding of the diverse research possibilities and current trends within the field of radiology.

Academic Writing, Editing, Proofreading, And Problem Solving Services

Get 10% off with 24start discount code.

Diagnostic Imaging Techniques

Comparative analysis of imaging modalities: CT, MRI, and PET-CT.
The role of artificial intelligence in radiological image interpretation.
Advancements in digital mammography for breast cancer screening.
Emerging techniques in nuclear medicine imaging.
Image-guided biopsy: Enhancing accuracy and safety.
Application of radiomics in predicting treatment response.
Dual-energy CT: Expanding diagnostic capabilities.
Radiological evaluation of traumatic brain injuries.
Imaging techniques for evaluating cardiovascular diseases.
Radiographic evaluation of pulmonary nodules: Challenges and advancements.

Interventional Radiology

Minimally invasive treatments for liver tumors: Embolization techniques.
Radiofrequency ablation in the management of renal cell carcinoma.
Role of interventional radiology in the treatment of peripheral artery disease.
Transarterial chemoembolization in hepatocellular carcinoma.
Evaluation of uterine artery embolization for the treatment of fibroids.
Percutaneous vertebroplasty and kyphoplasty: Efficacy and complications.
Endovascular repair of abdominal aortic aneurysms: Long-term outcomes.
Interventional radiology in the management of deep vein thrombosis.
Transcatheter aortic valve replacement: Imaging considerations.
Emerging techniques in interventional oncology.

Radiation Safety and Dose Optimization

Strategies for reducing radiation dose in pediatric imaging.
Imaging modalities with low radiation exposure: Current advancements.
Effective use of dose monitoring systems in radiology departments.
The impact of artificial intelligence on radiation dose optimization.
Optimization of radiation therapy treatment plans: Balancing efficacy and safety.
Radioprotective measures for patients and healthcare professionals.
The role of radiology in addressing radiation-induced risks.
Evaluating the long-term effects of radiation exposure in diagnostic imaging.
Radiation dose tracking and reporting: Implementing best practices.
Patient education and communication regarding radiation risks.

Radiology in Oncology

Imaging techniques for early detection and staging of lung cancer.
Quantitative imaging biomarkers for predicting treatment response in solid tumors.
Radiogenomics: Linking imaging features to genetic profiles in cancer.
The role of imaging in assessing tumor angiogenesis.
Radiological evaluation of lymphoma: Challenges and advancements.
Imaging-guided interventions in the treatment of hepatocellular carcinoma.
Assessment of tumor heterogeneity using functional imaging techniques.
Radiomics and machine learning in predicting treatment outcomes in cancer.
Multimodal imaging in the evaluation of brain tumors.
Imaging surveillance after cancer treatment: Optimizing follow-up protocols.

Radiology in Musculoskeletal Disorders

Imaging modalities in the evaluation of sports-related injuries.
The role of imaging in diagnosing and monitoring rheumatoid arthritis.
Assessment of bone health using dual-energy X-ray absorptiometry (DXA).
Imaging techniques for evaluating osteoarthritis progression.
Imaging-guided interventions in the management of musculoskeletal tumors.
Role of imaging in diagnosing and managing spinal disorders.
Evaluation of traumatic injuries using radiography, CT, and MRI.
Imaging of joint prostheses: Complications and assessment techniques.
Imaging features and classifications of bone fractures.
Musculoskeletal ultrasound in the diagnosis of soft tissue injuries.

Neuroradiology

Advanced neuroimaging techniques for early detection of neurodegenerative diseases.
Imaging evaluation of acute stroke: Current guidelines and advancements.
Role of functional MRI in mapping brain functions.
Imaging of brain tumors: Classification and treatment planning.
Diffusion tensor imaging in assessing white matter integrity.
Neuroimaging in the evaluation of multiple sclerosis.
Imaging techniques for the assessment of epilepsy.
Radiological evaluation of neurovascular diseases.
Imaging of cranial nerve disorders: Diagnosis and management.
Radiological assessment of developmental brain abnormalities.

Pediatric Radiology

Radiation dose reduction strategies in pediatric imaging.
Imaging evaluation of congenital heart diseases in children.
Role of imaging in the diagnosis and management of pediatric oncology.
Imaging of pediatric gastrointestinal disorders.
Evaluation of developmental hip dysplasia using ultrasound and radiography.
Imaging features and management of pediatric musculoskeletal infections.
Neuroimaging in the assessment of pediatric neurodevelopmental disorders.
Radiological evaluation of pediatric respiratory conditions.
Imaging techniques for the evaluation of pediatric abdominal emergencies.
Imaging-guided interventions in pediatric patients.

Breast Imaging

Advances in digital mammography for early breast cancer detection.
The role of tomosynthesis in breast imaging.
Imaging evaluation of breast implants: Complications and assessment.
Radiogenomic analysis of breast cancer subtypes.
Contrast-enhanced mammography: Diagnostic benefits and challenges.
Emerging techniques in breast MRI for high-risk populations.
Evaluation of breast density and its implications for cancer risk.
Role of molecular breast imaging in dense breast tissue evaluation.
Radiological evaluation of male breast disorders.
The impact of artificial intelligence on breast cancer screening.

Cardiac Imaging

Imaging evaluation of coronary artery disease: Current techniques and challenges.
Role of cardiac CT angiography in the assessment of structural heart diseases.
Imaging of cardiac tumors: Diagnosis and treatment considerations.
Advanced imaging techniques for assessing myocardial viability.
Evaluation of valvular heart diseases using echocardiography and MRI.
Cardiac magnetic resonance imaging in the evaluation of cardiomyopathies.
Role of nuclear cardiology in the assessment of cardiac function.
Imaging evaluation of congenital heart diseases in adults.
Radiological assessment of cardiac arrhythmias.
Imaging-guided interventions in structural heart diseases.

Abdominal and Pelvic Imaging

Evaluation of hepatobiliary diseases using imaging techniques.
Imaging features and classification of renal masses.
Radiological assessment of gastrointestinal bleeding.
Imaging evaluation of pancreatic diseases: Challenges and advancements.
Evaluation of pelvic floor disorders using MRI and ultrasound.
Role of imaging in diagnosing and staging gynecological cancers.
Imaging of abdominal and pelvic trauma: Current guidelines and techniques.
Radiological evaluation of genitourinary disorders.
Imaging features of abdominal and pelvic infections.
Assessment of abdominal and pelvic vascular diseases using imaging techniques.

This comprehensive list of radiology research paper topics highlights the vast range of research possibilities within the field of medical imaging. Each category offers unique insights and avenues for exploration, enabling students to delve into various aspects of radiology. By choosing a topic of interest and relevance, students can contribute to the advancement of medical imaging and patient care. The provided topics serve as a starting point for students to engage in in-depth research and produce high-quality research papers.

Radiology: Exploring the Range of Research Paper Topics

Introduction: Radiology plays a crucial role in modern healthcare, providing valuable insights into the diagnosis, treatment, and monitoring of various medical conditions. As a dynamic and rapidly evolving field, radiology offers a wide range of research opportunities for students in the health sciences. This article aims to explore the diverse spectrum of research paper topics within radiology, shedding light on the current trends, innovations, and challenges in the field.

Radiology in Diagnostic Imaging : Diagnostic imaging is one of the core areas of radiology, encompassing various modalities such as X-ray, computed tomography (CT), magnetic resonance imaging (MRI), ultrasound, and nuclear medicine. Research topics in this domain may include advancements in imaging techniques, comparative analysis of modalities, radiomics, and the integration of artificial intelligence in image interpretation. Students can explore how these technological advancements enhance diagnostic accuracy, improve patient outcomes, and optimize radiation exposure.

Interventional Radiology : Interventional radiology focuses on minimally invasive procedures performed under image guidance. Research topics in this area can cover a wide range of interventions, such as angioplasty, embolization, radiofrequency ablation, and image-guided biopsies. Students can delve into the latest techniques, outcomes, and complications associated with interventional procedures, as well as explore the emerging role of interventional radiology in managing various conditions, including vascular diseases, cancer, and pain management.

Radiation Safety and Dose Optimization : Radiation safety is a critical aspect of radiology practice. Research in this field aims to minimize radiation exposure to patients and healthcare professionals while maintaining optimal diagnostic image quality. Topics may include strategies for reducing radiation dose in pediatric imaging, dose monitoring systems, the impact of artificial intelligence on radiation dose optimization, and radioprotective measures. Students can investigate how to strike a balance between effective imaging and patient safety, exploring advancements in dose reduction techniques and the implementation of best practices.

Radiology in Oncology : Radiology plays a vital role in the diagnosis, staging, and treatment response assessment in cancer patients. Research topics in this area can encompass the use of imaging techniques for early detection, tumor characterization, response prediction, and treatment planning. Students can explore the integration of radiomics, machine learning, and molecular imaging in oncology research, as well as advancements in functional imaging and image-guided interventions.

Radiology in Neuroimaging : Neuroimaging is a specialized field within radiology that focuses on imaging the brain and central nervous system. Research topics in neuroimaging can cover areas such as stroke imaging, neurodegenerative diseases, brain tumors, neurovascular disorders, and functional imaging for mapping brain functions. Students can explore the latest imaging techniques, image analysis tools, and their clinical applications in understanding and diagnosing various neurological conditions.

Radiology in Musculoskeletal Imaging : Musculoskeletal imaging involves the evaluation of bone, joint, and soft tissue disorders. Research topics in this area can encompass imaging techniques for sports-related injuries, arthritis, musculoskeletal tumors, spinal disorders, and trauma. Students can explore the role of advanced imaging modalities such as MRI and ultrasound in diagnosing and managing musculoskeletal conditions, as well as the use of imaging-guided interventions for treatment.

Pediatric Radiology : Pediatric radiology focuses on imaging children, who have unique anatomical and physiological considerations. Research topics in this field may include radiation dose reduction strategies in pediatric imaging, imaging evaluation of congenital anomalies, pediatric oncology imaging, and imaging assessment of developmental disorders. Students can explore how to tailor imaging protocols for children, minimize radiation exposure, and improve diagnostic accuracy in pediatric patients.

Breast Imaging : Breast imaging is essential for the early detection and diagnosis of breast cancer. Research topics in this area can cover advancements in mammography, tomosynthesis, breast MRI, and molecular imaging. Students can explore topics related to breast density, imaging-guided biopsies, breast cancer screening, and the impact of artificial intelligence in breast imaging. Additionally, they can investigate the use of imaging techniques for evaluating breast implants and assessing high-risk populations.

Cardiac Imaging : Cardiac imaging focuses on the evaluation of heart structure and function. Research topics in this field may include imaging techniques for coronary artery disease, valvular heart diseases, cardiomyopathies, and cardiac tumors. Students can explore the role of cardiac CT, MRI, nuclear cardiology, and echocardiography in diagnosing and managing various cardiac conditions. Additionally, they can investigate the use of imaging in guiding interventional procedures and assessing treatment outcomes.

Abdominal and Pelvic Imaging : Abdominal and pelvic imaging involves the evaluation of organs and structures within the abdominal and pelvic cavities. Research topics in this area can encompass imaging of the liver, kidneys, gastrointestinal tract, pancreas, genitourinary system, and pelvic floor. Students can explore topics related to imaging techniques, evaluation of specific diseases or conditions, and the role of imaging in guiding interventions. Additionally, they can investigate emerging modalities such as elastography and diffusion-weighted imaging in abdominal and pelvic imaging.

Radiology offers a vast array of research opportunities for students in the field of health sciences. The topics discussed in this article provide a glimpse into the breadth and depth of research possibilities within radiology. By exploring these research areas, students can contribute to advancements in diagnostic accuracy, treatment planning, and patient care. With the rapid evolution of imaging technologies and the integration of artificial intelligence, the future of radiology research holds immense potential for improving healthcare outcomes.

Choosing Radiology Research Paper Topics

Introduction: Selecting a research topic is a crucial step in the journey of writing a radiology research paper. It determines the focus of your study and influences the impact your research can have in the field. To help you make an informed choice, we have compiled expert advice on selecting radiology research paper topics. By following these tips, you can identify a relevant and engaging research topic that aligns with your interests and contributes to the advancement of radiology knowledge.

Identify Your Interests : Start by reflecting on your own interests within the field of radiology. Consider which subspecialties or areas of radiology intrigue you the most. Are you interested in diagnostic imaging, interventional radiology, radiation safety, oncology imaging, or any other specific area? Identifying your interests will guide you in selecting a topic that excites you and keeps you motivated throughout the research process.
Stay Updated on Current Trends : Keep yourself updated on the latest advancements, breakthroughs, and emerging trends in radiology. Read scientific journals, attend conferences, and engage in discussions with experts in the field. By staying informed, you can identify gaps in knowledge or areas that require further investigation, providing you with potential research topics that are timely and relevant.
Consult with Faculty or Mentors : Seek guidance from your faculty members or mentors who are experienced in the field of radiology. They can provide valuable insights into potential research areas, ongoing projects, and research gaps. Discuss your research interests with them and ask for their suggestions and recommendations. Their expertise and guidance can help you narrow down your research topic and refine your research question.
Conduct a Literature Review : Conducting a thorough literature review is an essential step in choosing a research topic. It allows you to familiarize yourself with the existing body of knowledge, identify research gaps, and build a strong foundation for your study. Analyze recent research papers, systematic reviews, and meta-analyses related to radiology to identify areas that need further investigation or where controversies exist.
Brainstorm Research Questions : Once you have gained an understanding of the current state of research in radiology, brainstorm potential research questions. Consider the gaps or controversies you identified during your literature review. Develop research questions that address these gaps and contribute to the existing knowledge. Ensure that your research questions are clear, focused, and answerable within the scope of your study.
Consider the Practicality and Feasibility : When selecting a research topic, consider the practicality and feasibility of conducting the study. Evaluate the availability of resources, access to data, research facilities, and ethical considerations. Assess the time frame and potential constraints that may impact your research. Choosing a topic that is feasible within your given resources and time frame will ensure a successful and manageable research experience.
Collaborate with Peers : Consider collaborating with your peers or forming a research group to enhance your research experience. Collaborative research allows for a sharing of ideas, resources, and expertise, fostering a supportive environment. By working together, you can explore more complex research topics, conduct multicenter studies, and generate more impactful findings.
Seek Multidisciplinary Perspectives : Radiology intersects with various other medical disciplines. Consider exploring interdisciplinary research topics that integrate radiology with fields such as oncology, cardiology, neurology, or orthopedics. By incorporating multidisciplinary perspectives, you can address complex healthcare challenges and contribute to a broader understanding of patient care.
Choose a Topic with Clinical Relevance : Select a research topic that has direct clinical relevance. Focus on topics that can potentially influence patient outcomes, improve diagnostic accuracy, optimize treatment strategies, or enhance patient safety. By choosing a clinically relevant topic, you can contribute to the advancement of radiology practice and have a positive impact on patient care.
Seek Ethical Considerations : Ensure that your research topic adheres to ethical considerations in radiology research. Patient privacy, confidentiality, and informed consent should be prioritized when conducting studies involving human subjects. Familiarize yourself with the ethical guidelines and regulations specific to radiology research and ensure that your study design and data collection methods are in line with these principles.

Choosing a radiology research paper topic requires careful consideration and alignment with your interests, expertise, and the current trends in the field. By following the expert advice provided in this section, you can select a research topic that is engaging, relevant, and contributes to the advancement of radiology knowledge. Remember to consult with mentors, conduct a thorough literature review, and consider practicality and feasibility. With a well-chosen research topic, you can embark on an exciting journey of exploration, innovation, and contribution to the field of radiology.

How to Write a Radiology Research Paper

Introduction: Writing a radiology research paper requires a systematic approach and attention to detail. It is essential to effectively communicate your research findings, methodology, and conclusions to contribute to the body of knowledge in the field. In this section, we will provide you with valuable tips on how to write a successful radiology research paper. By following these guidelines, you can ensure that your paper is well-structured, informative, and impactful.

Define the Research Question : Start by clearly defining your research question or objective. It serves as the foundation of your research paper and guides your entire study. Ensure that your research question is specific, focused, and relevant to the field of radiology. Clearly articulate the purpose of your study and its potential implications.
Conduct a Thorough Literature Review : Before diving into writing, conduct a comprehensive literature review to familiarize yourself with the existing body of knowledge in your research area. Identify key studies, seminal papers, and relevant research articles that will support your research. Analyze and synthesize the literature to identify gaps, controversies, or areas for further investigation.
Develop a Well-Structured Outline : Create a clear and well-structured outline for your research paper. An outline serves as a roadmap and helps you organize your thoughts, arguments, and evidence. Divide your paper into logical sections such as introduction, literature review, methodology, results, discussion, and conclusion. Ensure a logical flow of ideas and information throughout the paper.
Write an Engaging Introduction : The introduction is the opening section of your research paper and should capture the reader’s attention. Start with a compelling hook that introduces the importance of the research topic. Provide background information, context, and the rationale for your study. Clearly state the research question or objective and outline the structure of your paper.
Conduct Rigorous Methodology : Describe your research methodology in detail, ensuring transparency and reproducibility. Explain your study design, data collection methods, sample size, inclusion/exclusion criteria, and statistical analyses. Clearly outline the steps you took to ensure scientific rigor and address potential biases. Include any ethical considerations and institutional review board approvals, if applicable.
Present Clear and Concise Results : Present your research findings in a clear, concise, and organized manner. Use tables, figures, and charts to visually represent your data. Provide accurate and relevant statistical analyses to support your results. Explain the significance and implications of your findings and their alignment with your research question.
Analyze and Interpret Results : In the discussion section, analyze and interpret your research results in the context of existing literature. Compare and contrast your findings with previous studies, highlighting similarities, differences, and potential explanations. Discuss any limitations or challenges encountered during the study and propose areas for future research.
Ensure Clear and Coherent Writing : Maintain clarity, coherence, and precision in your writing. Use concise and straightforward language to convey your ideas effectively. Avoid jargon or excessive technical terms that may hinder understanding. Clearly define any acronyms or abbreviations used in your paper. Ensure that each paragraph has a clear topic sentence and flows smoothly into the next.
Citations and References : Properly cite all the sources used in your research paper. Follow the citation style recommended by your institution or the journal you intend to submit to (e.g., APA, MLA, or Chicago). Include in-text citations for direct quotes, paraphrased information, or any borrowed ideas. Create a comprehensive reference list at the end of your paper, following the formatting guidelines.
Revise and Edit : Take the time to revise and edit your research paper before final submission. Review the content, structure, and organization of your paper. Check for grammatical errors, spelling mistakes, and typos. Ensure that your paper adheres to the specified word count and formatting guidelines. Seek feedback from colleagues or mentors to gain valuable insights and suggestions for improvement.

Conclusion: Writing a radiology research paper requires careful planning, attention to detail, and effective communication. By following the tips provided in this section, you can write a well-structured and impactful research paper in the field of radiology. Define a clear research question, conduct a thorough literature review, develop a strong outline, and present your findings with clarity. Remember to adhere to proper citation guidelines and revise your paper before submission. With these guidelines in mind, you can contribute to the advancement of radiology knowledge and make a meaningful impact in the field.

iResearchNet’s Writing Services

Introduction: At iResearchNet, we understand the challenges faced by students in the field of health sciences when it comes to writing research papers, including those in radiology. Our writing services are designed to provide you with expert assistance and support throughout your research paper journey. With our team of experienced writers, in-depth research capabilities, and commitment to excellence, we offer a range of services that will help you achieve your academic goals and ensure the success of your radiology research papers.

Expert Degree-Holding Writers : Our team consists of expert writers who hold advanced degrees in various fields, including radiology and health sciences. They possess extensive knowledge and expertise in their respective areas, allowing them to deliver high-quality and well-researched papers.
Custom Written Works : We understand that each research paper is unique, and we tailor our services to meet your specific requirements. Our writers craft custom-written research papers that align with your research objectives, ensuring originality and authenticity in every piece.
In-Depth Research : Research is at the core of any high-quality paper. Our writers conduct comprehensive and in-depth research to gather relevant literature, scientific articles, and other credible sources to support your research paper. They have access to reputable databases and libraries to ensure that your paper is backed by the latest and most reliable information.
Custom Formatting : Formatting your research paper according to the specified guidelines can be a challenging task. Our writers are well-versed in various formatting styles, including APA, MLA, Chicago/Turabian, and Harvard. They ensure that your paper adheres to the required formatting standards, including citations, references, and overall document structure.
Top Quality : We prioritize delivering top-quality research papers that meet the highest academic standards. Our writers pay attention to detail, ensuring accurate information, logical flow, and coherence in your paper. We conduct thorough editing and proofreading to eliminate any errors and improve the overall quality of your work.
Customized Solutions : We understand that every student has unique research requirements. Our services are tailored to provide customized solutions that address your specific needs. Whether you need assistance with topic selection, literature review, methodology, data analysis, or any other aspect of your research paper, we are here to support you at every step.
Flexible Pricing : We strive to make our services affordable and accessible to students. Our pricing structure is flexible, allowing you to choose the package that suits your budget and requirements. We offer competitive rates without compromising on the quality of our work.
Short Deadlines : We recognize the importance of meeting deadlines. Our team is equipped to handle urgent orders with short turnaround times. Whether you have a tight deadline or need assistance in a time-sensitive situation, we can deliver high-quality research papers within as little as three hours.
Timely Delivery : Punctuality is a priority for us. We understand the significance of submitting your research papers on time. Our writers work diligently to ensure that your paper is delivered within the agreed-upon timeframe, allowing you ample time for review and submission.
24/7 Support : We provide round-the-clock support to address any queries or concerns you may have. Our customer support team is available 24/7 to assist you with any questions related to our services, order status, or any other inquiries you may have.
Absolute Privacy : We prioritize your privacy and confidentiality. Rest assured that all your personal information and research paper details are handled with the utmost discretion. We adhere to strict privacy policies to protect your identity and ensure confidentiality throughout the process.
Easy Order Tracking : We provide a user-friendly platform that allows you to easily track the progress of your order. You can stay updated on the status of your research paper, communicate with your assigned writer, and receive notifications regarding the completion and delivery of your paper.
Money Back Guarantee : We are committed to your satisfaction. In the rare event that you are not satisfied with the delivered research paper, we offer a money back guarantee. Our aim is to ensure that you are fully content with the final product and receive the value you expect.

At iResearchNet, we understand the challenges students face when it comes to writing research papers in radiology and other health sciences. Our comprehensive range of writing services is designed to provide you with expert assistance, customized solutions, and top-quality research papers. With our team of experienced writers, in-depth research capabilities, and commitment to excellence, we are dedicated to helping you succeed in your academic endeavors. Place your order with iResearchNet and experience the benefits of our professional writing services for your radiology research papers.

Unlock Your Research Potential with iResearchNet

Are you ready to take your radiology research papers to the next level? Look no further than iResearchNet. Our team of expert writers, in-depth research capabilities, and commitment to excellence make us the perfect partner for your academic success. With our range of comprehensive writing services, you can unlock your research potential and achieve outstanding results in your radiology studies.

Why settle for average when you can have exceptional? Our team of expert degree-holding writers is ready to work with you, providing custom-written research papers that meet your specific requirements. We delve deep into the world of radiology, conducting in-depth research and crafting well-structured papers that showcase your knowledge and expertise.

Don’t let the complexities of choosing a research topic hold you back. Our expert advice on selecting radiology research paper topics will guide you through the process, ensuring that you choose a topic that aligns with your interests and has the potential to make a meaningful contribution to the field of radiology.

It’s time to unleash your potential and achieve academic excellence in your radiology studies. Place your trust in iResearchNet and experience the exceptional quality and support that our writing services offer. Let us be your partner in success as you embark on your journey of writing remarkable radiology research papers.

Take the first step towards elevating your radiology research papers by contacting us today. Our dedicated support team is available 24/7 to assist you with any inquiries and guide you through the ordering process. Don’t settle for mediocrity when you can achieve greatness with iResearchNet. Unlock your research potential and exceed your academic expectations.

ORDER HIGH QUALITY CUSTOM PAPER

diagnostic radiography dissertation ideas

Accounting Dissertation Topics
Artificial Intelligence Research Topics
Business Management Dissertation Topics
Business Dissertation Topics 2023
Change Management Dissertation Topics
Contract Law Dissertation Topics
Computer Science Dissertation Topics
Cryptocurrency Dissertation Topics
Cyber Security Dissertation Topics
Latest Digital Marketing Dissertation Topics
Economics Dissertation Topics
Education Dissertation Topics
Finance Dissertation Topics
Geography Dissertation Topics
History Dissertation Topics
HRM Dissertation Topics
Law Dissertation Topics
Literature Dissertation Topics
MA Education Dissertation Topics
Medical Surgical Nursing Dissertation Topics
Marketing Research Paper Topics
Marketing Dissertation Topics
Nursing Dissertation Topics
Psychology Dissertation Topics
Political Science Dissertation Topics
Sociology Dissertation Topics
Waste management Dissertation Topics
Educational Psychology Dissertation Topics
Feminist Dissertation Topics
Social Media Marketing Dissertation Topics
Real Estate Dissertation Topics
Aviation Management Dissertation Topics
Criminal Law Dissertation Topics
Innovation Management Dissertation Topics
Company Law Dissertation Topics
Pediatric Nursing Dissertation Topics
Structural Engineering Dissertation Topics
Events Management Dissertation Topics
Environmental Law Dissertation Topics
Commercial Law Dissertation Topics
Education Technology Dissertation Topics
MBA Dissertation Topics
Quantity Surveying Dissertation Topics
Renewable Energy Dissertation Topics
Tourism Dissertation Topics
Journalism Dissertation Topics
Google Scholar Research Topics
Fintech Dissertation Topics
Neuroscience Dissertation Topics
Entrepreneurship Dissertation Topics
Leadership Dissertation Topics
Radiography Dissertation Topics
Ecology Dissertation Topics

Get a native to improve your language & writing

Enjoy quality dissertation help on any topic

Qualitative & Quantitative data analysis

Best Radiography Dissertation Topics 2023

A lot of elements have to be considered while forming a dissertation. The careful selection of a dissertation topic is one of the main elements among them. The fate of your radiography dissertation depends upon your selected dissertation topic.

Factors You Must Consider While Selecting Radiography Dissertation Topics:

Detailed images of internal body structures are formed by using innovative medical imaging techniques and this process is known as radiography. There are multiple factors that need to be considered while selecting radiography dissertation topics, including;

The radiology research topics must have scope for extensive research conduction. It must have a large body of content that can be explored.
Your selected topic must be original and exclusive.
The radiography dissertation topic must have its necessary dependent and independent variables.
Your topic must be feasible and have practical implications for the respective field.
The selected topic for your radiography dissertation must be clear and direct.

Get Your Customized Dissertation Topic By Our Experts

Exclusive radiography research topics for uk students:.

Radiography is an extensive field that covers a broad range of topics varying from radiation therapy to diagnostic radiography dissertation ideas. Some of the exclusive radiography topics that can be used for your dissertation topics include:

Multi-detector computed tomographic features of abdominal hernias:

Among the list of diagnostic radiology research topics, this topic aims to examine the multidetector computed tomographic characteristics of abdominal hernias. The emphasis is laid on enhancing the precision of diagnosis and investigating the possible implications for patient care.

Objectives:

To evaluate the Sensitivity and Specificity of MDCT in Abdominal Hernia Diagnosis.
To characterize Morphological Variations in Abdominal Hernias Using MDCT.
To assess the Role of MDCT in Predicting Complications and Recurrences.

Role of functional magnetic resonance imaging in making brain tumor surgery safer

While looking for radiography research ideas, you can use this approach to assess preoperative functional mapping accuracy, the impact of fMRI-guided surgical planning on patient outcomes, and the use of this technology in the context of brain tumor surgery.

Evaluate the Accuracy and Reliability of fMRI in Mapping Brain Function.
Assess the Role of fMRI in Preserving Critical Brain Functions.
Investigate the Use of fMRI in Identifying and Preserving Functional Connectivity Networks.

Comprehensive Analysis of Contrast-Induced Nephropathy in IV Iodinated Contrast-Enhanced Imaging Studies

Within the framework of diagnostic radiography research topics that make use of intravenous iodinated contrast agents, this topic focuses on the evaluation of contrast-induced nephropathy. In diagnostic radiology, improving patient safety entails examining possible risk factors and figuring out practical preventive measures.

Evaluate the Incidence and Risk Factors of Contrast-Induced Nephropathy.
Explore Monitoring Techniques for Early Detection of CIN.
Examine Patient Education and Informed Consent Regarding CIN.

Evaluation of Airway Diseases: A Contrast Between Multi-Detector CT Virtual Tracheo-Bronchoscopy and Fiberoptic Tracheo-Bronchoscopy

This aim of this topic can be set as the provision of a detailed comparison between fiberoptic tracheobronchoscopy and virtual tracheobronchoscopy in the evaluation of airway disorders. This comparison can be done by using a multi-detector computed tomography. The study intends to examine the diagnostic accuracy and clinical utility of each modality to optimize diagnostic strategies for patients with airway diseases.

Assess the Role of MDCT Virtual Tracheo-Bronchoscopy in Lesion Characterization.
Examine Patient Comfort and Safety.
Provide Recommendations for Optimal Diagnostic Approaches in Airway Diseases.

Assessment of aortic aneurysms in radiography patients chosen for endovascular repair

Among different radiography research ideas, this topic seeks to do a comprehensive radiological assessment of individuals chosen for endovascular repair in order to identify aortic aneurysms. In order to enhance patient outcomes and safety, the study attempts to evaluate the efficacy and dependability of different radiological imaging modalities in preoperative planning, sizing, and directing endovascular procedures for aortic aneurysms.

Compare CTA with Other Imaging Modalities for Aneurysm Evaluation.
Assess the Role of 3D Reconstruction in Preoperative Planning.
Analyze the Accuracy of CTA in Predicting Aortic Aneurysm Rupture Risk.

Assessing the Imaging Methods on the Reduction of Paediatric Radiation Dose

the aim is to evaluate the effectiveness of advanced imaging methods in reducing radiation dose experience in paediatric radiography.

To examine the current use of advanced imaging approaches in paediatric radiology.
To quantify the reduction of radiation dose obtained through advanced imaging methods.
To emphasis on the influence of decreased radiation exposure on diagnostic accuracy and image quality in paediatric patients.

Get Free customize Topic Now

Role of artificial intelligence in radiographic interpretation.

the aim is to identify the potential limitations and benefits of using artificial intelligence (AI) for radiographic interpretation.

To emphasis on the current studies on the applications of Artificial Intelligence in radiography.
To build an Artificial intelligence model for radiographic interpretation as well as assess its performance.
To examine the experience and perception of radiologists regarding AI-supported radiography.

Radiation Safety Compliance and Protocols in Interventional Radiology Process

the aim is to evaluate the adherence and implementation to radiation safety protocols in interventional radiology processes.

To investigate the existing radiation safety protocols and guidelines in interventional radiology.
To conduct the exploratory analysis based on interventional radiology experts to assess their compliance and awareness with safety protocols.
To suggest the strategies and policies for improving radiation safety process in interventional radiology.

Usage of Virtual Reality Simulants for Radiography Training.

The aim is to examine the usefulness of virtual reality (VR) simulants as a training tool for radiography students.

To discuss the term based on virtual reality simulants for radiography training.
To evaluate challenges faced in VR simulator on radiography student confidence and skills.
To identify the strategies for mitigating the challenges faced in VR simulator to those educated using conventional techniques.

Optimising Image Quality within CT “Computed Tomography” Angiography

the purpose is to optimise the image quality while reducing radiation dose in CT angiography processes.

To emphasis on the factors impacting radiation dose and image quality in CT angiography.
To build the techniques and strategies to improve image quality.
To assess the influence of optimised guidelines on diagnostic accuracy and patient outcomes.

Radiographic for Health of Bone in Geriatric Patients

the aim is to evaluate the role of radiography in monitoring and diagnosing bone health in geriatric patients.

To review the current radiographic approaches for evaluating bone health in elderly people.
To conduct a longitudinal research to monitor changes in bone quality and density in a geriatric people.
To compare the efficiency of radiography to other imaging modalities in detecting bone-associated conditions among elder people.

Radiation Dose Reduction Approaches in Paediatric Fluoroscopy

The purpose is to assess and develop the radiation dose reduction approaches in paediatric fluoroscopy processes.

To examine the current levels of radiation dose in paediatric fluoroscopy processes.
To adopt the techniques based on radiation dose reduction and evaluate their efficiency and effectiveness.
To assess the effect of dose reduction on patient safety and image quality in paediatric fluoroscopy.

Radiography in Emergency Medical Settings: Enhancing Accuracy and Efficiency

the aim is to enhance the accuracy and efficiency of radiographic examinations in emergency medical settings.

To explore the common bottlenecks and challenges in emergency radiography workflows.
To adopt the technology enhancements and process improvement to streamline the process of radiographic.
To assess the influence of these improvement on health care resource use and patient outcomes.

How “The Dissertation Help” Can Help You!

Our top dissertation writing experts are waiting 24/7 to assist you with your university project, from critical literature reviews to a complete masters dissertation.

The Role of Radiography for Cancer Treatment

The aim is to evaluate the contribution of radiography to treatment planning and cancer staging.

To emphasis on the current guidelines and practices for using radiography in cancer staging and diagnosis.
To analyse the relation between treatment outcomes and radiographic findings among cancer patients.
To suggest the strategies and policies for optimising the incorporation of radiography into the pathways of cancer care.

Radiographer Burnout and Wellbeing: Mitigation Strategies and its Causes

The aim is to determine the causes of radiographer burnout and generate strategies for mitigating its influences.

To conduct a survey in identifying the factors affecting to burnout in radiographers.
To support mechanisms and implement interventions to deal with burnout issues.
To assess the effectiveness and efficiency of these intervention to improve the job satisfaction and wellbeing of radiographer.

How Professional Formulate Effective Radiography Dissertation Ideas:

You can find radiography dissertation examples from online platforms for a certain amount of guidance. But; the kind of dissertation help that a student can get from a professional writing platform is unmatched. When professional writers execute radiology dissertation projects for you, they;

They originate an exclusive radiography dissertation topic from the list of radiography research topics for students.
They formulate compelling research objectives that are clear and concise.
They execute quality content that is extensively researched, carefully analyzed, and critically evaluated.
They accurately incorporate the references and strictly abide by the rules of academic guidelines.
They use proficient language and exceptional writing style to make the project more comprehensive.

Frequently Asked Questions

How do i choose a thesis for my radiology.

The first thing that you must consider is the selection of a suitable radiology dissertation topic for your thesis project. An appropriate radiology topic will set the tone of your whole project and will decide the fate of your dissertation.

What is the topic of radiography?

A topic or subject of radiography is all about the use of radiological techniques to create diagnostic images of the internal; body structures. This field provides valuable information for diagnosis and monitoring purposes.

What type of research is radiology?

Radiology explores different aspects of medical imaging and diagnostic techniques. This is why; multiple types of research are needed to reach the results varying from clinical research to technical research to translational research, etc.

Which country is best for radiography?

The United States offers high-quality research programs and training opportunities for students in the field of radiography. It provides access to advanced imaging technologies and offers perfect professional opportunities.

+44 7897 053596
[email protected]

Get an experienced writer start working

Review our examples before placing an order, learn how to draft academic papers, radiography dissertation topics.

How to Write a Unique Dissertation Title: Guidance and Illustrations

How long should my dissertation be?

Dissertation Topics

Radiography is the scientific technology of producing images of internal body organs and tissues. This revolutionary imaging technique of science has been widely used to diagnose issues of a body’s internal structure. Radiography is a helpful field for the medical diagnosis that requires extensive research. Students need to find exciting and up-to-date radiography dissertation topics .

Find Out Quality Biomedical Science Dissertation Examples

Premier Dissertations has produced a list of new dissertation topics in radiography for 2024 .

If you would like to choose any topic from the list below, simply drop us a WhatsApp or an Email .

How Does It Work ?

Fill the Form

Please fill the free topic form and share your requirements

Writer Starts Working

The writer starts to find a topic for you (based on your requirements)

3+ Topics Emailed!

The writer shared custom topics with you within 24 hours

List of Latest Radiography Research Topics 2024

Top thesis topics in radiography topics 2024, trending research topics in radiography dissertation topics, a methodical approach to choose a good radiography dissertation topic.

Selecting radiology research topics involves a methodical approach. Start by identifying your specific interests within radiography, such as diagnostic imaging, radiation therapy, or advancements in technology. Formulate a clear research aim and methodology, ensuring a focused and insightful exploration of your chosen area to contribute meaningfully to the field of radiography.

Review Our Full List of Latest Research Topics

For more radiography thesis topics and radiology research paper topics , please keep checking our website as we keep adding new topics to our existing list of titles. GOOD LUCK!

Get 3+ Free Radiography Dissertation Topics within 24 hours?

Your Number

Academic Level Select Academic Level Undergraduate Masters PhD

Area of Research

Get an Immediate Response

Discuss your requirments with our writers

Discover More:

Testimonials

Very satisfied students

This is our reason for working. We want to make all students happy, every day. Review us on Sitejabber

admin farhan

100+ Correlational Research Topics

180+ ABM Research Topics For Students | 2024

Writing Tips

Literary MlLA dissertation sample
Dissertation proposal example
Thesis and dissertation for free
How to format a business dissertation
Getting MBA dissertation sample
Thesis structure rules
PhD dissertation format
Architecture dissertation ideas
Banking dissertation topics
Composing a thesis front page
Making a nursing dissertation
Finance doctoral dissertation
Master's dissertation example
Creating dissertation quickly
Good literary essay sample
Picking up topics on criminal justice
Picking economics dissertation topics

Useful Resources

24 Brilliant Ideas For A Radiography Dissertation

Although Radiography is an interesting and unique course, it takes a lot of hard work to finally be certified in the profession. One of the steps towards getting such certification is satisfying all the requirements to have a degree awarded to you. This is where your dissertation comes in. It is time to showcase your academic capabilities through your paper and you don’t seem to be convinced on what topic or idea your paper should be based on. Well, you have come to the right place because with the help of this article, you will have an abundance of ideas to choose from and start writing your academic paper.

Before we proceed to the list of topic ideas, it is important to point out that once your topic is chosen, you should ensure that you only carry out researches for your dissertation from reputable sources. This way, you are sure of not being found guilty of misleading your target readers by presenting them with wrong information. Also, you should only gather data that is relevant to the topic or idea your paper is based on. With these said, here are 24 brilliant ideas for your radiography paper. They are as follows:

Solitary Bone Lesion – A Radiologic Analysis
Paediatric Orbital Tumours – The Role of Computerized Tomographics
Radiolucent Lesions – An Analysis of Differential Diagnosis
A Detailed Analysis of Congenital Pseuodoarthrosis Of The Tibia
The Human Skull And The Principles of Diagnosis Through X-ray
Trauma – The Role of Radiography In Determining Extent Of Damage
Hypertension And Intravenous Urography – The Relationship
Lung Diseases – An Analysis Of Radiographic Patterns
Diseases Of The Chest And Radiography – What Patients Should Know
Renal Papillary Necrosis – The Role That Radiology Plays
The Human Chest In Emphysema – A Deeper Look At Radiographic Appearances
Urinary Tract Infection – The Role Of Radiography In Early Detection
Kidney Infection In Children – What Role Does Diagnostic Imaging Play?
Postoperative Radiography And You – What You Should Know
Chest X-ray Diagnosis – What Are The Basic Principles?
Airway Diseases – The Radiologist To The Rescue
Congenital Heart Diseases – What Plain Chest Radiograph Does For You
Presence of Abdominal Masses – An Overview of Diagnostic Imaging
Malabsorption Syndroms – Where Does Radiological Investigations Come In?
Bone Diseases And Radiography – An Analysis Of The Process
An Overview Of The Observation Of Tuberculosis Of The Bones
Diagnosis Of Giant Cell Tumour – What Role Does Radiography Have To Play?
Renal Parenchymal Disease – An Overview Of Diagnosis Through Imaging
Cystic Disease Of The Kidney And Radiography – What You Should Know

Need help with thesis? Visit https://www.thesishelpers.com/ - thesis writing service.

Diagnostic Radiography BSc: L6 Research Project

L4 Preparation for Practice
L4 Principles of Imaging
L4 Imaging 1: Appendicular and Axial Skeleton, Chest, Abdomen and Pelvis
L4 Practice Placement 1
L4 Imaging 2: Gastrointestinal and Hepatobiliary Systems
L4 Personal and Professional Development
L5 Imaging 3: Trauma and Orthopaedic Imaging
L5 Imaging 4: Cardiovascular, Urinary and Reproductive Systems
L5 The Service User in Radiography
L5 Research Methods
L5 Practice Placement 2
L5 Imaging 5: Endocrine and Central Nervous Systems
L5 Clinical Imaging and Technology
L6 Research Project
L6 Imaging 6: Contemporary issues in Diagnostic Imaging
L6 Image Interpretation
L6 Becoming a Radiographer
L6 Practice Placement 3
Databases and Journals
Books and e-books
Using Images, Media and Specialist Websites
On placement / In practice
Latest Library News

Welcome to your Research Project reading list! Here you will find the resources to support you throughout your module.

Essential reading.

There is no essential reading for this module as students will develop their own literature and make use of texts from the research methods module.

Essential Links

➔ A-Z of eResources

➔ Frequently Asked Questions

➔Discover the Library

➔Referencing Help

➔ Print & Copy Services

➔ Service Updates

Library & Learning Services, University of Suffolk, Library Building, Long Street, Ipswich, IP4 1QJ

✉ Email Us: [email protected]

✆ Call Us: +44 (0)1473 3 38700

Bibliography
More Referencing guides Blog Automated transliteration Relevant bibliographies by topics
Automated transliteration
Relevant bibliographies by topics
Referencing guides

Dissertations / Theses on the topic 'Interventional radiology'

Create a spot-on reference in apa, mla, chicago, harvard, and other styles.

Consult the top 50 dissertations / theses for your research on the topic 'Interventional radiology.'

Next to every source in the list of references, there is an 'Add to bibliography' button. Press on it, and we will generate automatically the bibliographic reference to the chosen work in the citation style you need: APA, MLA, Harvard, Chicago, Vancouver, etc.

You can also download the full text of the academic publication as pdf and read online its abstract whenever available in the metadata.

Browse dissertations / theses on a wide variety of disciplines and organise your bibliography correctly.

Berry, Max. "Virtual reality simulations and interventional radiology /." Göteborg : Department. of Radiology, Institute of Clinical Sciences, The Sahlgrenska Academy at Göteborg University, 2007. http://hdl.handle.net/2077/3188.

Fermor, Paul Elliot. "Image driven fluoroscopy for interventional radiology." Thesis, University of Surrey, 2002. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.250820.

Bianchini, David <1983&gt. "Dose Optimization in Cardiovascular Interventional Radiology." Doctoral thesis, Alma Mater Studiorum - Università di Bologna, 2016. http://amsdottorato.unibo.it/7270/1/Bianchini_PhD_Thesis.pdf.

Lindgren, Johanna, and Erika Gustavsson. "Strålskydd för personal som arbetar inom Interventionell Radiologi." Thesis, Umeå universitet, Institutionen för omvårdnad, 2014. http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-89179.

De, Vos Hendrik Johannes. "Radiation dose optimization in interventional radiology and cardiology using diagnostic reference levels." Master's thesis, University of Cape Town, 2016. http://hdl.handle.net/11427/20928.

Chisha, Mike. "CT angiographic detection of cerebral aneurysms in patients with subarachnoid haemorrhage in a South African institution." Master's thesis, Faculty of Health Sciences, 2021. http://hdl.handle.net/11427/32572.

Corbin, Nadège. "Interventional magnetic resonance elastography dedicated to the monitoring of percutaneous thermal ablations." Thesis, Strasbourg, 2015. http://www.theses.fr/2015STRAD047/document.

Ahluwalia, Vishwadeep. "Optimization of Functional MRI methods for olfactory interventional studies at 3T." VCU Scholars Compass, 2009. http://scholarscompass.vcu.edu/etd/1953.

Benmakhlouf, Hamza. "Key Data for the Reference and Relative Dosimetry of Radiotherapy and Diagnostic and Interventional Radiology Beams." Doctoral thesis, Stockholms universitet, Fysikum, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:su:diva-114413.

At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 6: Manuscript.

Mont'Alverne, Francisco José Arruda. "Resultados da vertebroplastia percutânea na doença vertebral cervical." Universidade de São Paulo, 2008. http://www.teses.usp.br/teses/disponiveis/5/5151/tde-13022009-141428/.

Culver, Britt Wayne. "Technique for Repeatable Hyperosmotic Blood-Brain Barrier Disruption in the Dog." Thesis, Virginia Tech, 1997. http://hdl.handle.net/10919/36884.

Rehn, Emelie. "Modeling of scatter radiation during interventional X-ray procedures." Thesis, Linköpings universitet, Avdelningen för radiologiska vetenskaper, 2015. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-119694.

Kamran, Mudassar. "Applications of novel imaging protocols and devices in interventional neuroradiology." Thesis, University of Oxford, 2015. http://ora.ox.ac.uk/objects/uuid:ccb2550c-cb28-42f1-bd95-4dcee4ec1ff4.

Hunter, Morris. "The development of a baccalaureate degree program in medical imaging technology." CSUSB ScholarWorks, 1999. https://scholarworks.lib.csusb.edu/etd-project/1857.

Rosenqvist, Kerstin. "Transjugular intrahepatic portosystemic shunt in the treatment of symptomatic portal hypertension." Doctoral thesis, Uppsala universitet, Radiologi, 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-321538.

Ferguson, Mark R., Jason N. Wright, Anh-Vu Ngo, Sarah M. Desoky, and Ramesh S. Iyer. "Imaging of Acute Appendicitis in Children." GEORG THIEME VERLAG KG, 2017. http://hdl.handle.net/10150/625179.

Deschler, Thomas. "Développement d'un système dosimétrique pour la radiologie interventionnelle." Thesis, Strasbourg, 2018. http://www.theses.fr/2018STRAE016.

Barbosa, Leandro de Assis. "Estudo experimental dos efeitos da embolização renal com partículas de trisacryl e de polivinil acetato recoberto com polivinil álcool." Universidade de São Paulo, 2009. http://www.teses.usp.br/teses/disponiveis/5/5151/tde-24022010-143511/.

Vouche, Michael. "Radiation Segmentectomy, Radiation Lobectomy and Response Assessment after 90Yttrium Radioembolization for Hepatocellular carcinoma: Imaging and Clinical Implications." Doctoral thesis, Universite Libre de Bruxelles, 2017. http://hdl.handle.net/2013/ULB-DIPOT:oai:dipot.ulb.ac.be:2013/241979.

Daniels, Barret R. "Magnetic Resonance Guided Nasojejunal Feeding Tube Placement for Neonates." University of Cincinnati / OhioLINK, 2015. http://rave.ohiolink.edu/etdc/view?acc_num=ucin1439281638.

Arvellos, André Noronha. "Avaliação tomográfica dos parâmetros anatômicos relevantes na punção renal percutânea nos decúbitos ventral e dorsal." Universidade Federal de Juiz de Fora, 2011. https://repositorio.ufjf.br/jspui/handle/ufjf/2118.

Principi, Sara. "Development of methodologies for estimating the dose to the eye lens in interventional radiology : operational implications of the eye lens new dose limit." Doctoral thesis, Universitat Politècnica de Catalunya, 2017. http://hdl.handle.net/10803/620729.

Aberdour, Mark J. "Changes in Platelet Aggregation and Activation in Patients Undergoing Interventional Neuroradiology Procedures: Can Point-Of-Care Devices Assist in Predicting Complications?" Thesis, Griffith University, 2019. http://hdl.handle.net/10072/389745.

Hernández, Cabrera Wendy. "Páncreas Porcino: Modelo anatómico y Abordaje Endovascular para Terapias Celular y Génica." Doctoral thesis, Universidad de Murcia, 2010. http://hdl.handle.net/10803/10720.

Yabuta, Minoru. "Long-term Outcome of Percutaneous Interventions for Hepatic Venous Outflow Obstruction after Pediatric Living Donor Liver Transplantation: Experience from a Single Institute." Kyoto University, 2015. http://hdl.handle.net/2433/199187.

Iqeilan, Nabil. "Entrance Skin Dose Measurement Using GafChromic Dosimetry Film for Patients Undergoing Coronary Angiography (CA) and Percutaneous Transluminal Coronary Angiography (PTCA) Procedures." Thesis, Stockholm University, Medical Radiation Physics (together with KI), 2007. http://urn.kb.se/resolve?urn=urn:nbn:se:su:diva-7213.

Interventional radiological procedures often require long fluoroscopic exposure times and high levels of radiation exposure to patients, which often are higher than most radiological examinations except for computed tomography (CT) whose effective doses can be higher, and in addition to having radiation risks that are higher for both patient and medical staff. Therefore it is important to monitor and map the radiation entrance exposure to the patients, to minimize the probability of skin injury, and to detect areas of overlapping radiation fields. The aim of this thesis is to evaluate patient doses in interventional radiology procedures using a new GAFCHROMIC-XR TYPE R DOSIMETER MEDIA X-ray Dosimetry film, which allows mapping of the skin dose distribution, when placed closer to the skin. These radiochromic films can be characterized by a power response dose function when plotting pixel value versus air kerma and have been calibrated up to 5 Gy when using a flatbed scanner. Image analysis was performed using the red channel component of standard the RGB (Red, Green, and Blue) color space image. The association between the Maximum Entrance Skin Doses (MESD) and Dose Area Product (DAP) values for two interventional procedures; coronary angiography (CA), and percutaneous transluminal coronary angiography (PTCA) is investigated.

Wiippa, Beatrice, and Sadaf Azarnia. "Förebygger kirurgiska munskydd infektion hos patienten vid interventionell radiologi? : en litteraturöversikt." Thesis, Luleå tekniska universitet, Institutionen för hälsovetenskap, 2018. http://urn.kb.se/resolve?urn=urn:nbn:se:ltu:diva-71783.

Mignot, Leo. "Sociogenèse d’une spécialité médicale : le cas de radiologie interventionnelle." Thesis, Bordeaux, 2017. http://www.theses.fr/2017BORD0902.

Tacher, Vania. "Optimisation du guidage tri-dimensionel en radiologie interventionnelle." Thesis, Paris Est, 2017. http://www.theses.fr/2017PESC0020.

Muller, Henra. "Patient radiation dose ranges for procedures in Universitas Hospital vascular laboratories." Thesis, Bloemfontein: Central University of Technology, Free State, 2014. http://hdl.handle.net/11462/674.

Bacchim, Neto Fernando Antonio. "Caracterização das exposições ocupacionais e eficiência da dosimetria pessoal em radiologia intervencionista vascular." Botucatu, 2017. http://hdl.handle.net/11449/190996.

Izaaryene, Jalal-Jean. "Etude expérimentale de l'apport de nouvelles techniques dans les ablatermies tumorales percutanées pulmonaires." Thesis, Aix-Marseille, 2017. http://www.theses.fr/2017AIXM0195/document.

Silva, André Goyanna Pinheiro. "Tratamento endovascular das fístulas carotidocavenosas indiretas." Universidade de São Paulo, 2006. http://www.teses.usp.br/teses/disponiveis/5/5151/tde-16102014-094552/.

Conti, Mario Luiz Marques. "Tratamento endovascular das malformações arteriovenosas raquimedulares: resultados clínicos e angiográficos." Universidade de São Paulo, 2005. http://www.teses.usp.br/teses/disponiveis/5/5151/tde-10102014-122816/.

Stroszczynski, Christian. "Einsatz der Magnetresonanztomographie zur Laser-induzierten Thermotherapie." Doctoral thesis, Humboldt-Universität zu Berlin, Medizinische Fakultät - Universitätsklinikum Charité, 2002. http://dx.doi.org/10.18452/13821.

Nevala, T. (Terhi). "Endovascular treatment of an abdominal aortic aneurysm:mid-term results and management of a type II endoleak." Doctoral thesis, University of Oulu, 2010. http://urn.fi/urn:isbn:9789514261343.

Gonçalves, Octavio Meneghelli Galvão. "Estudo comparativo entre microesferas de 100-300um e 300-500um utlizadas na embolização das artérias prostáticas para o tratamento dos sintomas urinários decorrentes da hiperplasia prostática benigna." Universidade de São Paulo, 2018. http://www.teses.usp.br/teses/disponiveis/5/5151/tde-08052018-112846/.

Kastler, Adrian. "Presentation, optmization and result of new methods of infiltration and neurolysis under CT guidance in the management of pain." Thesis, Besançon, 2014. http://www.theses.fr/2014BESA3017/document.

Azevedo, Luiz Lanziotti de. "Injetor intravascular de CO2: estudo in vivo de viabilidade inicial do dispositivo e de qualidade de imagem." Universidade de São Paulo, 2016. http://www.teses.usp.br/teses/disponiveis/5/5132/tde-08042016-122000/.

Júnior, Antenor Tavares de Sá. "Alterações de difusão e perfusão cerebral por RM em angioplastia carotídea com \"stent\" sob proteção cerebral por filtros." Universidade de São Paulo, 2009. http://www.teses.usp.br/teses/disponiveis/5/5151/tde-22022010-171639/.

Hermansson, Adriana, and Elvira Hjelm. "Reducering av stråldos vid angiografi/intervention." Thesis, Uppsala universitet, Radiologi, 2018. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-351518.

Carnevale, Francisco Cesar. "Terapêutica endovascular percutânea na oclusão arterial ilíaca crônica." Universidade de São Paulo, 1999. http://www.teses.usp.br/teses/disponiveis/5/5151/tde-08012007-133924/.

Spencer, Benjamin. "On-line C-arm intrinsic calibration by means of an accurate method of line detection using the radon transform." Thesis, Université Grenoble Alpes (ComUE), 2015. http://www.theses.fr/2015GREAS044/document.

Barbé, Laurent De Mathelin Michel. "Téléopération avec retour d'efforts pour les interventions percutanées." Strasbourg : Université Louis Pasteur, 2007. http://eprints-scd-ulp.u-strasbg.fr:8080/836/01/BARBE_Laurent_2007.pdf.

Fernandez-Gutierrez, Fabiola. "Workflow analysis, modelling and simulation for improving conventional and MRI-guided vascular interventions." Thesis, University of Dundee, 2014. https://discovery.dundee.ac.uk/en/studentTheses/6b7fca49-19ba-47b0-831a-ca9677084a7a.

Abdelaziz, Salih. "Développement d'un système robotique pour la radiologie interventionnelle sous IRM." Phd thesis, Université de Strasbourg, 2012. http://tel.archives-ouvertes.fr/tel-00801844.

Cavalcante, Fernanda Rocha. "Simulação Monte Carlo de cenários de radiologia intervencionista pediátrica no código MCNPX." Universidade Federal de Sergipe, 2017. https://ri.ufs.br/handle/riufs/5271.

Nicolau, Stephane. "Un système de réalité augmentée pour guider les opérations du foie en radiologie interventionnelle." Phd thesis, Université de Nice Sophia-Antipolis, 2004. http://tel.archives-ouvertes.fr/tel-00000006.

Geijer, Håkan. "Radiation dose and image quality in diagnostic radiology : optimization of the dose - image quality relationship with clinical experience from scoliosis radiography, coronary intervention and a flat-panel digital detector /." Linköping : Univ, 2001. http://www.bibl.liu.se/liupubl/disp/disp2001/med706s.htm.

Ojala, R. (Risto). "MR-guided interventions at 0.23T:facilities, user interface, guiding technology and musculoskeletal applications." Doctoral thesis, University of Oulu, 2002. http://urn.fi/urn:isbn:9514266382.

A .gov website belongs to an official government organization in the United States.

A lock ( ) or https:// means you've safely connected to the .gov website. Share sensitive information only on official, secure websites.

About Radiation
Food Irradiation
Radiation Safety
Radiation in Your Life
Radiation and Your Health Features
Dose Reconstruction

Facts About Imaging Procedures

At a glance.

Radiation and radioactive materials are used every day in medical settings to improve health outcomes. While additional exposure to radiation can be harmful to human health in certain doses, the benefits of diagnosing or treating health problems with ionizing radiation usually outweigh the risks involved. Make sure to tell your doctor if you are or think you could be pregnant before procedures that involve radiation.

High doses of ionizing radiation can be harmful to human health. However, radiation and radioactive materials are used every day in medical settings to improve health outcomes and even save lives.

Radiation is used in many medical imaging procedures. Medical imaging procedures deliver x-ray beams, a form of ionizing radiation, to a specific part of the body. They create a digital image or film that shows the structures inside that area like bones, tissues, and organs. Healthcare providers can use these images for diagnostics, finding out what is causing your health problem, or sometimes to guide treatment.

Imaging procedures are usually performed in radiology or imaging centers in hospitals or clinics by a radiologist. Radiologists are medical professionals who are trained and certified to conduct imaging studies with radiation.

Medical radiation practices and equipment are regulated by state and federal programs to ensure safety.

There are possible short-term and long-term risks from the very low doses of radiation exposure from imaging procedures. Ionizing radiation can damage cell DNA, but in the low amounts used in each imaging procedure cells can normally repair themselves. When cells get too much radiation over time, this damage can lead to cancer.

Exposure to ionized radiation beyond daily exposures, including from imaging procedures, slightly increases the risk of developing cancer later in life.

Usually, the benefits of diagnosing or treating health problems with ionizing radiation will outweigh these risks. These procedures only deliver radiation to the area that needs imaging, protecting all other parts of the body. Procedures should always use the lowest amount of radiation needed to create a good quality image. This process is referred to as "as low as reasonably achievable" ( ALARA ).

Find more specific information on these common imaging procedures:

Radiography (x-rays) and dental x-rays
Mammography
DEXA Scans (bone density)
CT scans (computed tomography scans)
Fluoroscopy
Nuclear medicine

Find information on special considerations pregnant women and children .

Talk to your healthcare provider and radiologist about the specific benefits and risks of the procedure recommended for your specific situation. These are some of the general benefits and risks for imaging that uses radiation:

Gives healthcare providers a better view of organs, blood vessels, tissues, and bones.
Provides detailed information to help decide whether surgery is a good treatment option.
Can be used to guide medical procedures to place catheters, stents, or other devices inside the body (fluoroscopy, a type of imaging).
Each procedure contributes to a slight increase in the likelihood that you could develop cancer later in life.
Fluoroscopy for guiding surgery uses higher doses of radiation than other imaging procedures and may cause skin reddening and hair loss.
Some imaging procedures require you to drink or receive an intravenous (IV) contrast dye. This non-radioactive dye helps the radiologist see specific organs or parts of the body. Some people can have an allergic reaction to the dye.

The best way to make sure you are not getting more exposure to radiation than necessary is to keep track of imaging procedures and make sure each healthcare provider or specialist you see receives your results. This includes sending previous imaging results to any new healthcare provider before your visit.

It is important to tell your healthcare provider and the radiologist if you are pregnant or think you could be pregnant.

To help reduce your exposure and to help decide what type of imaging or testing is best for you, consider asking your health care provider:

Do any of my recent tests provide the imaging needed?
Are there other tests that do not use radiation that can provide the needed information?

For your procedure, the radiologist will use the lowest amount of radiation needed. These doses are further reduced for children. During the procedure you will often receive a lead protective shield to prevent other areas of your body that don’t need imaging from being exposed to radiation.

Other medical radiation experts include the following:

Hospital radiation safety officer
Medical physicist
Radiation physicist
Diagnostic medical physicist

Imaging Procedures That Don’t Use Radiation

Some alternative imaging procedures that do not use ionizing radiation include Magnetic Resonance Imaging (MRI) and ultrasound.

MRI procedures use magnetic fields and radio waves to produce images of specific parts of the body. Ultrasound imaging uses high-frequency sound waves to see inside the body.

You and your healthcare provider will select the best type of imaging procedure for your situation and make sure the potential benefits to your health outweigh possible risks from the procedure.

Medical X-ray Imaging
Pediatric X-ray Imaging
X-Rays, Pregnancy and You

Image Gently

What Parents should Know about Medical Radiation Safety
Educational Materials

Image Wisely

Get the Facts about Medical Imaging
My Medical Imaging History
Rad Town USA Medical X-Rays

US National Library of Medicine

Diagnostic Imaging

Radiation and Your Health

Information about what radiation is and the many sources of radiation in our lives.

IMAGES

😊 Radiography dissertation topics. 24 Ideas You Can Investigate In A
Clinicals Radiology Papers
(PDF) Clinical Audit in Diagnostic Radiography
New Radiography Dissertation Topics
(PDF) Integrating Research-informed Teaching Within The Diagnostic
(PDF) Terminology describing the profession of Diagnostic Radiography

VIDEO

DIGITAL RADIOGRAPHY (DR) || PART
5 Trending Project / Dissertation Ideas for Bsc & Msc Microbiology Students
Diagnostic Radiography
5 Things You Should Know About Diagnostic Radiography
2. QA
reasons to study diagnostic radiography

COMMENTS

60+ Best Radiology Dissertation Topics
Published by Ellie Cross at December 29th, 2022 , Revised On May 16, 2024. A dissertation is an essential part of the radiology curriculum for an MD, DNB, or DMRD degree programme. Dissertations in radiology can be very tricky and challenging due to the complexity of the subject. Students must conduct thorough research to develop a first-class ...
Radiology Thesis
A thesis or dissertation, as some people would like to call it, is an integral part of the Radiology curriculum, be it MD, DNB, or DMRD. We have tried to aggregate radiology thesis topics from various sources for reference. Not everyone is interested in research, and writing a Radiology thesis can be daunting.
PDF Diagnostic and therapeutic radiography MSc dissertations
Development of the novel, interactive e-learning package on pelvic RT late effects. Developed using Articulate 360 software with support from the hospital's blended learning team. In order to remain engaging for users, interactive material was incorporated including sliding scales and click-to-reveal boxes. To demonstrate the impact of late ...
Identification of research priorities of radiography science: A
Radiography is an allied health science acting in the field of diagnostic imaging and radiotherapy. The knowledge base in radiography science is a combination of patient care and high technology and consists of medical imaging, radiotherapy, and nuclear medicine (Lundgren et al., 2015). Research in radiography has a long history, but as a ...
150 Radiology Thesis Research Topics From AHECounselling
Topics for a Radiology dissertation. Multislice CT scan, barium swallow and their role in the estimation of the length of oesophageal tumors. Malignant Lesions-A Prospective Study. Ultrasonography is an important tool for the diagnosis of acute abdominal disease in children.
PDF Developing Practice in Radiography and Diagnostic Imaging Richard
DEVELOPING PRACTICE IN RADIOGRAPHY AND DIAGNOSTIC IMAGING Richard Price, PhD Study, University of Hertfordshire, October 2006 ABSTRACT An increase in the range and capability of imaging modalities has resulted in greater demands for radiology services. This research investigates how these changes have
Radiology Research Paper Topics
This page aims to provide students studying health sciences with a comprehensive collection of radiology research paper topics to inspire and guide their research endeavors. By delving into various categories and exploring ten thought-provoking topics within each, students can gain insights into the diverse research possibilities in radiology.
Most Popular Radiography Dissertation Research Topics
Radiography is an extensive field that covers a broad range of topics varying from radiation therapy to diagnostic radiography dissertation ideas. Some of the exclusive radiography topics that can be used for your dissertation topics include: Multi-detector computed tomographic features of abdominal hernias:
New Radiography Dissertation Topics
We have prepared the list of New Radiography Dissertation Topics 2024a. Choose any topic from the list or order free custom radiography topics now! +44 7897 053596; [email protected]; Home; ... Start by identifying your specific interests within radiography, such as diagnostic imaging, radiation therapy, or advancements in ...
24 Ideas You Can Investigate In A Radiography Dissertation
24 Brilliant Ideas For A Radiography Dissertation. Although Radiography is an interesting and unique course, it takes a lot of hard work to finally be certified in the profession. One of the steps towards getting such certification is satisfying all the requirements to have a degree awarded to you. This is where your dissertation comes in.
Diagnostic Radiography Dissertation Topics
Diagnostic Radiography Dissertation Topics - Free download as PDF File (.pdf), Text File (.txt) or read online for free. diagnostic radiography dissertation topics
Diagnostic Radiography Dissertation Examples
Diagnostic Radiography Dissertation Examples - Free download as PDF File (.pdf), Text File (.txt) or read online for free. This document discusses the challenges of completing a diagnostic radiography dissertation, including the extensive research, analysis, and adherence to academic standards required. It notes that the process can feel overwhelming due to its magnitude, pressure to produce ...
What's a good research topic for radiography? : r/Radiology
Reply. opticalsciences. •. I'd suggest even a bit more specific. There are entire books on single MR sequences (ie Haacke's book on SWI) Perhaps pick a use case (detection and discrimination of intracranial bleeds, monitoring radiation therapy damage versus tumor progression) and examine how MRI can be used for that case.
(PDF) Clinical Audit in Diagnostic Radiography
Abstract —Clinical audit is a quality improvement. process that seeks to improve imaging standards. through a systematic review of the practice. In. radiography, clinical audits have been part ...
University of Bolton Library: Radiology: Theses and Dissertations
University of Bolton Postgraduate Theses. Digital copies of UoB Postgraduate Theses can be found on the University's Institutional Repository, UBIR . You can search for a thesis by title, or browse by department. Print copies of postgraduate theses are held in the Peter Marsh Library. Please ask at the Library Helpdesk for details.
Dissertations / Theses: 'Radiography
Video (online) Consult the top 50 dissertations / theses for your research on the topic 'Radiography - Study and teaching.'. Next to every source in the list of references, there is an 'Add to bibliography' button. Press on it, and we will generate automatically the bibliographic reference to the chosen work in the citation style you need ...
Diagnostic Radiography BSc: L6 Research Project
Research Methods for Clinical Therapists E-Book by Hicks, C.M. Struggling to do a project or dissertation, evaluate published research or conduct your own research? Help is at hand with this 5th edition of Research Methods for Clinical Therapists, which explains, in a clear and simple manner, how to evaluate existing research and how to conduct ...
Dissertation Ideas for Diagnostic Radiography
Dissertation Ideas for Diagnostic Radiography - Free download as PDF File (.pdf), Text File (.txt) or read online for free. dissertation ideas for diagnostic radiography
The College of Radiographers Research Priorities for the Radiographic
A newly revised research strategy from the Society and College of Radiographers (SCoR) from 2016 to 2021 sets a clear vision to improve patient care and outcomes by continuing to develop, grow and implement a high quality evidence base. In order to meet the aims and vision of the SCoR research strategy, it is important to identify what the key ...
A study to investigate undergraduate diagnostic radiographer
Whilst United Kingdom (UK) student ambitions for role development have been surveyed previously, no literature has explored their specialisation preferences. This study aimed to explore these ambitions and preferences in final year diagnostic radiography undergraduates at a Higher-Education Institute (HEI) in the North-West of England.
Dissertations / Theses: 'Interventional radiology'
Consult the top 50 dissertations / theses for your research on the topic 'Interventional radiology.'. Next to every source in the list of references, there is an 'Add to bibliography' button. Press on it, and we will generate automatically the bibliographic reference to the chosen work in the citation style you need: APA, MLA, Harvard, Chicago ...
Diagnostic radiography dissertation
Diagnostic radiography dissertation; Watch. 3 years ago. Diagnostic radiography dissertation. Daaave1998. 2. Hey guys, I know its a specific topic but I'm kind of struggling to find topics to wrte about as my dissertation for diagnostic radiography. because of COVID I cant actually go into hospitals or anything like that so what they have said ...
Radiography dissertation
Radiography dissertation. A. zr_123. 4. Hi everyone, I'm a third year student doing diagnostic radiography but I have absolutely no idea what I can do for a dissertation. I'm focussed on quantitative research as a focus but I don't know WHAT exactly I want to base my dissertation on.
Facts About Imaging Procedures
Diagnostic medical physicist; Imaging Procedures That Don't Use Radiation. Some alternative imaging procedures that do not use ionizing radiation include Magnetic Resonance Imaging (MRI) and ultrasound. MRI procedures use magnetic fields and radio waves to produce images of specific parts of the body. Ultrasound imaging uses high-frequency ...

Useful Links

Radiology Dissertation topics – Based on The Latest Study and Research

List of Radiology Dissertation Topics

Hire an Expert Writer

Final Words

Free Dissertation Topic

Frequently Asked Questions

You May Also Like

Please login to bookmark

Introduction

Tips for Choosing Radiology Thesis and Research Topics

Books to help you write a Radiology Thesis

In A Hurry? Download a PDF list of Radiology Research Topics!

List of Radiology Research /Thesis / Dissertation Topics

Search Diagnostic Imaging Research Topics

Free Resources for Preparing Radiology Thesis

Proofreading Your Thesis:

Guidelines for Writing a Radiology Thesis:

Resources and References:

More guides for residents :

Radiology Exam Resources (Oral Recalls, Instruments, etc )!

About The Author

7 thoughts on “Radiology Thesis – More than 400 Research Topics (2022)!”

Leave a Comment Cancel Reply

Wish to be a BETTER Radiologist? Join 14000 Radiology Colleagues !

Identification of research priorities of radiography science: A modified Delphi study in Europe

Miko Pasanen

Helena Leino‐Kilpi

Eija Metsälä

1. INTRODUCTION

1.1. Background

2.1. Design

2.2. Expert panel sampling

2.3. Data collection and analysis

2.4. Round one

2.5. Round two

2.6. Ethical considerations

3.1. Demographics of the panelists

3.2. The importance of the research topics after two rounds

3.2.1. Radiographers profession

3.2.2. Clinical practice in radiography

3.2.3. Safe and high‐quality use of radiation

3.2.4. Technology in radiography

3.2.5. Discipline of radiography science

3.2.6. Management and leadership

3.2.7. The most important topic in each category

3.3. Research topics that reached consensus after two rounds

4. DISCUSSION

4.1. Limitations

5. CONCLUSIONS

5.1. Relevance for clinical practice

AUTHOR CONTRIBUTIONS

ACKNOWLEDGMENTS

APPENDIX A.

DATA AVAILABILITY STATEMENT

Radiology Research Paper Topics

100 Radiology Research Paper Topics

Academic Writing, Editing, Proofreading, And Problem Solving Services

Radiology: Exploring the Range of Research Paper Topics

Choosing Radiology Research Paper Topics

How to Write a Radiology Research Paper

iResearchNet’s Writing Services

Unlock Your Research Potential with iResearchNet

ORDER HIGH QUALITY CUSTOM PAPER

Best Radiography Dissertation Topics 2023

Factors You Must Consider While Selecting Radiography Dissertation Topics:

Get Your Customized Dissertation Topic By Our Experts

Multi-detector computed tomographic features of abdominal hernias:

Objectives:

Role of functional magnetic resonance imaging in making brain tumor surgery safer

Comprehensive Analysis of Contrast-Induced Nephropathy in IV Iodinated Contrast-Enhanced Imaging Studies

Evaluation of Airway Diseases: A Contrast Between Multi-Detector CT Virtual Tracheo-Bronchoscopy and Fiberoptic Tracheo-Bronchoscopy

Assessment of aortic aneurysms in radiography patients chosen for endovascular repair

Assessing the Imaging Methods on the Reduction of Paediatric Radiation Dose

Get Free customize Topic Now

Radiation Safety Compliance and Protocols in Interventional Radiology Process

Usage of Virtual Reality Simulants for Radiography Training.

Optimising Image Quality within CT “Computed Tomography” Angiography

Radiographic for Health of Bone in Geriatric Patients

Radiation Dose Reduction Approaches in Paediatric Fluoroscopy