Medical Device Design and Entrepreneurship

Explore key data analysis methods used in bioengineering and life sciences research. Learn how to apply statistical techniques and integrate them into your own research projects.

Learn essential skills to communicate your business ideas effectively in a variety of media, from traditional outlets to social media platforms.  You'll learn about different audiences including angel investors, venture capital and grant-funding bodies, government and regulatory bodies, and the general public.

Deepen your understanding of the key skills needed by professional engineers in the development of medical systems and devices, specifically in the preparation of regulatory approval.

Develop core skills and learn key concepts to plan, start and run a technology business in medical devices. You'll gain a critical understanding of fundraising and financial planning, contracts and law, and business negotiation, through lectures, case studies and practical workshops.

Start your research journey by exploring the market landscape for your medical device idea. In this module, you’ll analyse user needs and industry trends to build a strong case for the technology you’ll develop in your multi-term project.

Explore various aspects of medical device entrepreneurship, looking at case studies from start-ups, industry and investment firms to gain a sense of the process and challenges in developing your own business idea.

Explore the core aspects of biological and clinical measurement such as data handling, sampling and measurement.

Understand the fundamental biological and biophysical processes involved in cancer and the application of bioengineering to better understand and manage the disease.

Become familiar with the major classes of biomedical implant materials including metals, ceramics and polymers.

Cover the scope of biomimetics and investigate the principles that help engineers solve technical problems using inspiration from nature.

Please note: this is a capped module and is subject to availability.

Discover technology used in clinical settings for interfacing of the human brain to electronic circuitry.

Appreciate the role of computational and theoretical approaches to understanding the nervous system.

Explore the latest nanotechnological advances in the field of cancer diagnostics and cancer therapies.

Gain a grounding in core neuroscience concepts and understand the ‘state of the art’ with regard to research methodology.

Discover the mechanics of the musculoskeletal system, including the structure and function of the musculoskeletal tissues.

Examine how images of the body can be obtained using different forms of penetrating radiation and how different forms of imaging work.

Examine fundamental concepts in normal tissue development and discuss their imitation within a lab setting.