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M-SC in Medical Imaging Technology at SRM Institute of Science and Technology
Chengalpattu, Tamil Nadu
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About the Specialization
What is Medical Imaging Technology at SRM Institute of Science and Technology Chengalpattu?
This Medical Imaging Technology program at SRM Institute of Science and Technology focuses on equipping students with advanced knowledge and practical skills in various imaging modalities. Recognizing the growing demand for skilled professionals in India''''s rapidly expanding healthcare sector, this program emphasizes a blend of theoretical understanding and hands-on experience, preparing graduates to operate and manage state-of-the-art diagnostic imaging equipment crucial for modern medical diagnosis.
Who Should Apply?
This program is ideal for Bachelor of Science graduates in Radiology and Imaging Technology, Physics, Chemistry, Biology, Life Science, Pharmacy, or Optometry who aspire to specialize in medical imaging. It caters to fresh graduates seeking entry into the specialized field of diagnostic imaging, as well as working professionals looking to upskill in advanced imaging techniques like CT, MRI, and Nuclear Medicine, aiming for career progression in a highly specialized domain.
Why Choose This Course?
Graduates of this program can expect to pursue rewarding careers as Diagnostic Radiographers, CT/MRI Technologists, Nuclear Medicine Technologists, and Sonographers within India''''s hospitals, diagnostic centers, and research institutions. Entry-level salaries typically range from INR 3-5 LPA, with experienced professionals earning INR 8-15 LPA or more. The program aligns with industry standards, potentially aiding in certifications and promoting growth trajectories in a critical healthcare area.
Student Success Practices
Foundation Stage
Build a Strong Core in Physics and Anatomy- (Semester 1-2)
Dedicate significant time to understanding the foundational principles of applied physics for imaging and detailed human anatomy and physiology. Utilize interactive 3D anatomy apps and online physics simulators to visualize complex concepts. Form study groups to discuss and clarify challenging topics, ensuring a robust theoretical base for advanced imaging modalities.
Tools & Resources
3D Anatomy apps (e.g., Complete Anatomy), Physics simulation software, Medical textbooks, Peer study groups
Career Connection
A solid understanding of fundamentals is critical for accurate image acquisition, interpretation, and patient positioning, forming the bedrock for becoming a competent and confident imaging technologist.
Master Radiation Safety Protocols- (Semester 1-2)
Beyond theoretical knowledge, actively seek opportunities for practical application of radiation safety measures during lab sessions and hypothetical scenarios. Familiarize yourself with AERB (Atomic Energy Regulatory Board) guidelines in India. Develop a checklist for every procedure involving radiation to ensure strict adherence to safety standards for both patients and personnel.
Tools & Resources
AERB guidelines, Radiation dosimeters (practice with mock-ups), Lab manuals, Safety protocols
Career Connection
Essential for responsible practice in any imaging facility, demonstrating professionalism and ensuring patient and occupational safety, which is a non-negotiable skill for employment.
Develop Basic Research & Statistical Skills- (Semester 2)
Engage thoroughly with the Research Methodology and Biostatistics course. Practice data collection, basic statistical analysis using software, and critically evaluate research papers. Participate in small research assignments or literature reviews early on to build confidence in scientific inquiry and data interpretation.
Tools & Resources
Microsoft Excel, R (basic level), SPSS (trial versions), Google Scholar, Institutional library databases
Career Connection
These skills are vital for evidence-based practice, contributing to medical research, and for critical evaluation of new technologies, enhancing your profile for advanced roles or academic pursuits.
Intermediate Stage
Hands-on Proficiency with CT & MRI- (Semester 3)
Maximize practical lab hours for CT and MRI. Focus on understanding scanner operation, sequence programming, patient preparation, and post-processing techniques. Seek additional observation opportunities in clinical settings if available, paying close attention to various clinical protocols and problem-solving during scans.
Tools & Resources
CT/MRI simulators (if available), PACS workstations (for image review), Clinical rotation observations, Departmental protocols
Career Connection
Direct practical experience with advanced modalities is highly valued by employers. Proficiency in operating and troubleshooting these machines makes you job-ready for specialized technologist roles.
Explore Nuclear Medicine Principles and Practice- (Semester 3)
Delve deep into the principles of radiopharmaceutical handling, gamma camera operation, and SPECT/PET imaging. Understand the physics behind radionuclide decay and image acquisition. Attend webinars or workshops on nuclear medicine to gain insights into emerging trends and specific clinical applications beyond coursework.
Tools & Resources
IAEA (International Atomic Energy Agency) resources, Online courses/webinars on nuclear medicine, Departmental QA protocols
Career Connection
Opens up career paths in nuclear medicine departments, a highly specialized and growing area within medical imaging, requiring unique skills in radiation safety and radiopharmaceutical management.
Build Professional Network & Seek Internships- (Semester 3-4)
Actively attend guest lectures, workshops, and conferences related to medical imaging technology. Connect with faculty, alumni, and visiting professionals. Proactively seek short-term internships or observerships during semester breaks at diagnostic centers or hospitals to gain real-world exposure and practical skills, enhancing your resume significantly.
Tools & Resources
LinkedIn, Professional associations (e.g., IRIA), SRM''''s career services, Industry events
Career Connection
Networking often leads to internship and placement opportunities. Real-world experience makes you a more competitive candidate and helps clarify career interests.
Advanced Stage
Excel in Dissertation/Project Work- (Semester 4)
Choose a dissertation topic that aligns with your career interests and offers practical relevance. Work closely with your supervisor, meticulously plan your research, execute data collection, and perform rigorous analysis. Aim for a publication-quality thesis, as it demonstrates advanced research capabilities and critical thinking.
Tools & Resources
Research papers databases (PubMed, Scopus), Reference management software (Mendeley, Zotero), Statistical software, Institutional library resources
Career Connection
A strong dissertation showcases your ability to contribute to the field, crucial for roles in research & development, academia, or for demonstrating advanced problem-solving skills to potential employers.
Prepare for Placements & Interviews- (Semester 4)
Begin mock interviews and resume building early in the final semester. Practice explaining your project work and clinical experiences clearly. Research potential employers (hospitals, diagnostic centers, medical device companies) and tailor your applications. Focus on showcasing your technical skills, patient care abilities, and commitment to safety.
Tools & Resources
SRM''''s placement cell, Online interview preparation platforms, Career counselors, Peer mock interviews
Career Connection
Direct preparation for the job market ensures you present your best self, increasing your chances of securing a desirable position immediately after graduation.
Develop Soft Skills & Professional Ethics- (Semester 4)
Actively work on communication, teamwork, and critical thinking skills through group projects, presentations, and interactions during clinical postings. Understand and adhere to professional ethics in patient care, confidentiality, and data handling. Participate in workshops on soft skills or medical ethics to round out your professional profile.
Tools & Resources
Communication skill workshops, Ethics in healthcare literature, Professional development resources, Mentorship from senior technologists
Career Connection
Beyond technical skills, employers seek well-rounded professionals. Strong soft skills and ethical conduct are crucial for patient interaction, team collaboration, and long-term career success in healthcare.
Program Structure and Curriculum
Eligibility:
- B.Sc. in Radiology and Imaging Technology / Medical Imaging Technology / Radiotherapy Technology / B.Sc. Physics / Chemistry / Biology / Life Science / B.Pharm / B.Optom with 50% marks.
Duration: 2 years (4 semesters)
Credits: 64 Credits
Assessment: Internal: 50%, External: 50%
Semester-wise Curriculum Table
Semester 1
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 23PHS101J | Applied Physics | Core | 4 | Physics of Imaging, Radiation Physics, Electromagnetic Spectrum, Atomic Structure and Interactions, Medical Physics Instruments |
| 23HSS101J | Human Anatomy & Physiology | Core | 4 | Gross Anatomy of Organ Systems, Systemic Physiology, Cellular and Tissue Biology, Musculoskeletal System, Cardiovascular and Respiratory System |
| 23MIT101L | Applied Physics Lab | Core | 2 | Radiation Measurement Techniques, X-ray Production Principles, Radiation Safety Protocols, Image Quality Parameters, Equipment Calibration and Testing |
| 23MIT102L | Human Anatomy & Physiology Lab | Core | 2 | Surface Anatomy Identification, Anatomical Models and Dissections, Physiological Measurements, Histology and Tissue Staining, Organ Identification and Function |
Semester 2
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 23MIT201J | Imaging Modalities – I (Radiography & Fluoroscopy) | Core | 4 | X-ray Generation and Interactions, Image Formation Principles, Digital Radiography Systems, Fluoroscopy Techniques, Image Receptors and Processors |
| 23MIT202J | Radiation Biology & Radiation Safety | Core | 4 | Cellular Effects of Radiation, Tissue Sensitivity and Response, Radiation Protection Principles, Dosimetry and Dose Limits, Regulatory Standards and Guidelines |
| 23MIT203J | Research Methodology & Biostatistics | Core | 4 | Research Design and Types, Data Collection Methods, Statistical Analysis Techniques, Hypothesis Testing, Ethical Considerations in Research |
| 23MIT201L | Imaging Modalities – I (Radiography & Fluoroscopy) Lab | Core | 2 | X-ray Machine Operation, Patient Positioning Techniques, Digital Image Processing, Radiographic Quality Control, Practical Radiation Safety |
| 23MIT202L | Radiation Biology & Radiation Safety Lab | Core | 2 | Radiation Detector Usage, Dose Measurement and Monitoring, Shielding and Collimation Techniques, Personnel Monitoring Devices, Emergency Preparedness for Radiation Incidents |
Semester 3
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 23MIT301J | Imaging Modalities – II (CT & MRI) | Core | 4 | Computed Tomography Principles, CT Image Reconstruction, Magnetic Resonance Imaging Physics, MRI Pulse Sequences, CT and MRI Artifacts |
| 23MIT302J | Nuclear Medicine Imaging | Core | 4 | Radiopharmaceuticals and Production, Gamma Camera Operation, PET/SPECT Imaging Principles, Radioisotope Applications, Quality Assurance in Nuclear Medicine |
| 23MIT303E | Elective – I (Ultrasonography & Doppler Imaging / Advanced Medical Instrumentation) | Elective | 4 | Principles of Ultrasound Imaging, Transducers and Image Optimization, Doppler Physics and Clinical Applications, Medical Sensor Technology, Bioinstrumentation Design and Signal Processing, Advanced Medical Device Design and Quality Control |
| 23MIT301L | Imaging Modalities – II (CT & MRI) Lab | Core | 2 | CT Protocol Setup and Optimization, MRI Scan Planning and Sequences, Image Post-processing Techniques, Patient Safety and Comfort in CT/MRI, System Calibration and Maintenance |
| 23MIT302L | Nuclear Medicine Imaging Lab | Core | 2 | Radiopharmaceutical Handling and Administration, Gamma Camera Operation and Acquisition, Image Processing and Interpretation, Quality Control in Nuclear Medicine, Radiation Waste Management |
Semester 4
| Subject Code | Subject Name | Subject Type | Credits | Key Topics |
|---|---|---|---|---|
| 23MIT401E | Elective – II (Interventional Radiology Procedures / Picture Archiving and Communication System (PACS) & Teleradiology) | Elective | 4 | Interventional Radiology Techniques, Angiography and Biopsy Procedures, Stenting and Embolization, PACS Architecture and DICOM Standard, Teleradiology Workflows and Implementation, Data Security and Privacy in Medical Imaging |
| 23MIT401P | Dissertation / Project Work | Project | 16 | Research Proposal Development, Extensive Literature Review, Data Collection and Methodology, Data Analysis and Interpretation, Thesis Writing and Presentation, Ethical Review and Compliance |
