- Dr Graham Stafford (Senior Lecturer - University of Sheffield)
|Delivery Type||Delivery length / details|
|Practical||10 x 4 Hour Practicals|
|Lecture||2 x 1 Hour Lectures|
|Assessment Type||Assessment length / details||Proportion|
|Semester Assessment||Mini-report 1 (2 pages)||10%|
|Semester Assessment||Mini-report 2 (2 pages)||10%|
|Semester Assessment||Mini-report 3 (2 pages)||10%|
|Semester Assessment||Mini-report 4 (2 pages)||10%|
|Semester Assessment||Protocol 1 (2,500 words)||10%|
|Semester Assessment||Protocol 2 (2,500 words)||10%|
|Semester Assessment||Protocol 3 (2,500 words)||10%|
|Semester Assessment||Research article (2,000 words)||30%|
|Supplementary Assessment||Students must take elements of assessment equivalent to those that led to failure of the module.||100%|
On successful completion of this module students should be able to:
1. Develop hypotheses into a series of experimental procedures.
2. Build novel experimental protocols from available literature
3. Implement experimental protocols
4. Report experimental protocols and research findings in appropriate formats.
The aim of this module is to give students the opportunity to acquire the necessary skills to enable them to understand, implement and devise experimental protocols. To this end, sessions will be provided that will allow students to take research questions, develop them into testable hypotheses, formulate such hypotheses into a series of experiments, devise appropriate experimental protocols, and implement those experiments.
Construction of testable hypotheses from available literature.
Defining hypotheses as a series of experiments.
Creating experimental protocols from the literature.
Modification and construction of experimental protocols.
Implementing experimental protocols.
Reporting of protocols.
Presentation of novel methodologies
Presentation of experimental results
The largest component of the module will be practical work, and experiments undertaken will provide experience under two general headings:
1. Isolation of Biomolecules (for example, purification of phosphatases, separation of proteins, etc.)
2. Analysis of Biomolecules (for example determination of phosphatase Km and Vmax parameters, determination of molecular weight, etc.)
|Skills Type||Skills details|
|Application of Number||Practical work will involve calculations using acquired data.|
|Communication||The production of balanced practical reports. Listening skills for the workshops and subsequent discussion in practical classes.|
|Improving own Learning and Performance||Outside the formal contact hours, students will be expected to research materials, manage time and meet deadlines.|
|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, interpreting data and writing-up assessed biochemical and chemical experiments.|
|Research skills||Students will research topics beyond the depth and scope of the provided 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||Students will gain experience of issues related to the planning, execution and reporting of experiments. They will be able to find, understand, modify and utilize existing protocols from the literature, and report methodologies as appropriate for a variety of media.|
|Team work||Students will work in pairs/small groups during practical sessions. They will need to discuss their experimental design and work effectively as a small team in practical classes. Feedback will be provided on how groups are working together.|
This module is at CQFW Level 5