Aims

The aims of the course are to:

• Provide a comprehensive overview of biomedical engineering
• Outline the key principles of good engineering design in a biomedical context
• Introduce the concept of system design approach for sustainable improvement
• Describe the technology adoption pathway in healthcare

Objectives

As specific objectives, by the end of the course students should be able to:

• Conduct research and define the issues with existing medical devices or clinical procedures
• Understand how to apply engineering knowledge to solve biomedical challenges
• Communicate and work with healthcare professionals to validate the engineering designs
• Use a broader systems design toolkit to address larger and more complex issues in healthcare

Content

The course has four case studies. Students will 'major' on one case study, but will need to attend (either in person or via recorded lectures) the lectures pertaining to the other case studies to cover all the required elements of the course.

General introduction (3L total) [MPFS (1L); PJC (0.66L) ;PJC (0.33L); MPFS (0.33L); GMB (0.33L); AJF (0.33L)]

Introduction of biomedical engineering and systems approach to systems improvement; introduction of four case studies

Engineering design case study (2L) [PJC]

System approach in healthcare design; e.g. design of face mask/technology in the home; safety

Biomechanics case study (2L) [MPFS]

Knee biomechanics/kinematics; design for the knee replacement; clinical/patient acceptance

Biosignal processing case study (2L) [GMB]

Basics of anatomy, pathophysiology; design for optical brain monitoring; clinical trials

Biosensor case study (2L) [AJF]

Concept of point-of-care; microfluidic platform-assisted biosensors; manufacturing

Discussion meetings (5L) [Guest mentors (2L); all lecturers (3L)]

Short presentation sessions from guest mentors (University, NHS, industry) and panel discussions; open discussion meetings with lecturers