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Description
Purpose
This course brings together material from engineering, physics, and physiology relevant to situations in which electronic devices are in direct contact with the body. Body contact is common in clinical practice with medical devices being used for biosensing, recording biopotentials, and stimulating the body. The course focusses on interaction with the nervous system. This course is relevant to rehabilitation, intensive care, clinical neurophysiology, neuroprosthetics, etc. It should be useful to:
- Medical students who will encounter these applications in clinical practice.
- Students who intend to go on to biomedical research.
- Engineering students who go on to specify, design, test or use clinical electrical equipment.
Aims
Our aim is to prepare students to work with electronic devices that interact with people, and in particular patients. As the most common types of interactions are with the neural system, the field is generally known as neural engineering.
This course does not provide an introduction to electronics, this is expected known (see prerequisite). Rather, we focus on the knowledge, and practical experiences, required to successfully monitor and process biosignals, whether bio-potentials such as ECG and ENG, or bio-chemical signals. We also consider electrical stimulation and its many applications.
The four topics covered are: electronics (amplifiers and filters), bio-sensors (electrodes and chemical sensors), nerves (anatomy, biophysics, physiology), and applications (biopotential recording and electrical stimulation).
Learning Objectives
- To acquire knowledge and/or understanding of :
- The origins of electrophysiological signals and their characteristics.
- Essential requirements for electrodes.
- Basic principles of bio-chemical sensors
- Basic principles of electrical stimulation.
- The characteristics and limitations of biomedical amplifiers for acquisition of electrophysiological signals, and to demonstrate how these characteristics are derived from an understanding of electrophysiology, electrode properties, and electrical hazards.
- To apply this knowledge during laboratory practicals and develop laboratory skills.
- To develop problem solving and analysis skills using the knowledge accumulated from this course.
- To improve, or develop, scientific communication skills.
- To take responsibility for your own learning experience.
Teaching and exams
The teaching methods include lectures, practical sessions, tutorials , and students’ own self-directed learning, with a strong emphasis on the practical sessions and self-directed learning. Students at this level are expected to take responsibility for their learning, and work throughout the term to truly understand the material and be able to apply this to novel problems, wrote learning is insufficient.
One module represents about 150 hours of work from a student. Of these, we aim to provide about 40 contact hours, shared between lectures, practical sessions and tutorials. The rest of the time is dedicated to self-directed, independent, work, such as reading the notes, preparing for a lecture, completing coursework, revising for an assessment, writing up lab reports, researching on the applications as instructed…
The course is assessed by coursework (including Moodle quizzes and lab reports) throughout the term, and a 3 hour unseen written exam.
If you are taking this course at level 6 (typically if you are in the third year of your degree, except for the Biomedical Engineering students), the coursework is worth 20 % and the exam 80 %. For students taking this course at level 7, there is an additional element to the lab reports, making this part of the assessment worth 30 %, while the exam is worth 70 %. Note that every student takes the same exam, only the lab reports contain an additional element.
Module deliveries for 2024/25 academic year
Last updated
This module description was last updated on 8th April 2024.
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