|Delivery Type||Delivery length / details|
|Lecture||2 x 1 lectures per week|
|Practical||4 x 3 hour practicals during semester|
|Assessment Type||Assessment length / details||Proportion|
|Semester Assessment||Practical lab reports (4) Outcomes 2, 3, 4||40%|
|Semester Exam||1.5 Hours Outcomes 1, 2, 3, 4||60%|
|Supplementary Assessment||1.5 Hours Examination 60%; Assignment 40% Students must take elements of assessment equivalent to those that led to failure of the module. Outcomes 1-4||100%|
On successful completion of this module students should be able to:
1. Identify geometric and stereo isomers of organic compounds and to apply the rules to assign the correct nomenclature to simple examples of these types of isomers.
2. Identify the major acidic and basic groups in biological systems and recognise the relevance of their pK values and contribution to buffering.
3. Review the basic background physical chemistry to bioenergetics and electron transport processes in nature.
4. Describe basic analytical techniques and analyse results from these for the identification of simple compounds.
The module will cover the following chemical topics, with examples of relevant biological phenomena: acid-base equilibria, stereochemistry, thermodynamics and kinetics.
A survey of stereoisomerism and optical activity will include both the D and L system and the R and S nomenclature. Fischer projection formulae, separation of enantiomers and the concept of symmetry will be described. Again the relevance to natural compounds will be emphasised.
A study of biologically important functional groups will lead to a review of the concept of pH, acids, bases and buffers drawing particularly on the examples of amino acids. Other aspects of physical chemistry will include energetics, binding of ligands and electrochemistry, again the relevance to biological processes emphasised and with examples drawn from biology. The topics of chemical equilibria and reaction kinetics will be linked with a simple consideration of enzymes and their role in biological reactions.
The major analytical methods used in biochemistry including various forms of spectroscopy and the use of isotopes will be described.
Although the major emphasis will be on organic chemistry aspects of bio-inorganic chemistry may be discussed.
|Skills Type||Skills details|
|Application of Number||Collection and scrutiny of data in terms of quality and quantity. Data interpretation.|
|Communication||Listening skills for the lectures and subsequent discussion in practical classes. Students will develop effective written communication skills in examinations and coursework preparation.|
|Improving own Learning and Performance||Outside the formal contact hours, students will be expected to research materials, manage time and meet deadlines. The directed study elements will provide opportunity for students to explore their own learning styles and preferences and identify their needs and barriers to learning. Students will be able to review and monitor their progress and plan for improvement of personal performance.|
|Information Technology||Accessing the web for information sources and using databases to find primary literature.|
|Personal Development and Career planning|
|Problem solving||Practical classes will allow students to gain experience in designing, executing and interpreting data in biochemistry.|
|Research skills||Students will research topics beyond the depth and scope of the lecture material using both directed and independent study. Information from a variety of sources will be the object of scrutiny and comment. Practical classes will allow the development of key biological research skills at an early stage of their academic careers.|
|Subject Specific Skills||Subject specific concepts relating to biochemistry will be developed. Students will be able to demonstrate an understanding of chemical principles as applied to molecular biology, using commonplace examples.|
This module is at CQFW Level 4