B.Tech in Biomedical Engineering

01

Engineering Knowledge: Apply knowledge of mathematics, natural sciences, computing, engineering fundamentals, and biomedical engineering principles to develop solutions for complex biomedical engineering problems. (WK1, WK2, WK3, WK4)

02

Problem Analysis: Identify, formulate, review research literature, and analyze complex biomedical engineering problems by integrating concepts of physiology, biomechanics, medical instrumentation, and biomaterials, considering sustainable development. (WK1 to WK4)

03

Design/Development of Solutions: Design and develop innovative biomedical devices, prosthetics, and healthcare systems that address public health, safety, whole-life cost, and sustainability while meeting medical, regulatory, and environmental requirements. (WK5)

04

Conduct Investigations of Complex Problems: Conduct research-based investigations, including design of experiments, biomedical modeling, data interpretation, and signal/image processing, to provide valid and evidence-based conclusions in the field of biomedical engineering. (WK8)

05

Engineering Tool Usage: Develop and apply modern computational tools, medical imaging software, biosignal analysis, AI-based healthcare systems, and bioinformatics tools while recognizing their limitations and impact on biomedical research and clinical applications. (WK2 and WK6)

06

The Engineer and The World: Analyze and evaluate the societal, economic, and environmental impact of biomedical technologies, ensuring patient safety, regulatory compliance, accessibility, and ethical considerations in medical device development. (WK1, WK5, and WK7)

07

Ethics: Uphold professional ethics, human values, diversity, and inclusion while adhering to national and international regulatory frameworks such as FDA, ISO, IEC, and medical ethics guidelines. (WK9)

08

Individual and Collaborative Teamwork: Work effectively as an individual, as a team member, and as a leader in multidisciplinary teams, collaborating with engineers, medical professionals, researchers, and industry experts.

09

Communication: Communicate effectively with the engineering and medical community, regulatory authorities, and society at large, including preparing technical reports, medical device documentation, and research publications, and delivering presentations with cultural and professional sensitivity.

10

Project Management and Finance: Apply engineering management principles, financial planning, and economic decision-making to lead and execute biomedical engineering projects in healthcare, medical technology startups, and hospital infrastructure development.

11

Life-Long Learning: Recognize the need for and develop skills for independent, lifelong learning, adaptability to emerging biomedical technologies, and critical thinking in the rapidly evolving healthcare and medical technology landscape. (WK8)

01

Graduates will establish successful careers in biomedical industries, healthcare technology, medical device manufacturing, and hospitals.

02

Graduates will pursue higher education and research in biomedical engineering, biotechnology, bioinformatics, tissue engineering, AI-driven healthcare, and regulatory affairs.

03

Graduates will develop innovative healthcare solutions by leveraging expertise in biosensors, medical imaging, wearable devices, and AI-based diagnostics, fostering entrepreneurial ventures and startups in the biomedical sector.

04

Graduates will serve in research and development (R&D) in academia and Biomedical industries