Postgraduate Course: Lab-on-Chip Technologies (PGEE11042)

Course Outline
School	School of Engineering	College	College of Science and Engineering
Credit level (Normal year taken)	SCQF Level 11 (Postgraduate)	Availability	Not available to visiting students
SCQF Credits	10	ECTS Credits	5
Summary	This module will outline the basic concept of devices that integrate one or several laboratory functions on a single chip, and how they can offer advantages specific to their application. Such advantages include: low fluid volumes that lead to lower reagent costs and smaller biological samples for diagnostic purposes; faster analysis and response times that also provide better process control; the ability through parallel processing to provide high-throughput screening; and inherent low fabrication costs that make disposable chips economically viable. The influence of the scaling-down of dimensions on the physico-chemical behaviour of fluids and chemical reactions will also be covered. Current applications of lab-on-chip devices will be given.
Course description	Not entered

Entry Requirements (not applicable to Visiting Students)
Pre-requisites		Co-requisites
Prohibited Combinations		Other requirements	None

Course Delivery Information

Academic year 2015/16, Not available to visiting students (SS1)		Quota: None
Course Start	Semester 2
Timetable	Timetable
Learning and Teaching activities (Further Info)	Total Hours: 100 ( Lecture Hours 20, Seminar/Tutorial Hours 7, Formative Assessment Hours 1, Summative Assessment Hours 2, Programme Level Learning and Teaching Hours 2, Directed Learning and Independent Learning Hours 68 )
Assessment (Further Info)	Written Exam 100 %, Coursework 0 %, Practical Exam 0 %
Additional Information (Assessment)	80% written exam 20% coursework
Feedback	Not entered
Exam Information
Exam Diet	Paper Name		Hours & Minutes
Main Exam Diet S2 (April/May)			2:00

Learning Outcomes
On completion of this course, the student will be able to: An appreciation of the design and development of microfluidic devices that can perform many, if not all, of the functions typically associated with full-scale automated biochemical analysis devices containing pumps, mixers, heat elements, read-out electronics, etc. An understanding of how to avoid the requirement of external power sources or instrumentation by incorporating into these devices the inherent properties of the fluid and its microenvironment (capillary force, evaporation, wicking, heat transfer, diffusion, etc.) for fluid movement, mixing, heating, cooling, and catalyzing chemical reactions. An understanding of how to apply non-dimensional parameters (e.g., Knudsen, Peclet, Reynolds number) to practical flow problems.