Skip to Content

Courses

Undergraduate Programme Specification

MChem Medicinal Chemistry with a Year in Industry

Academic Year 2022/23

A programme specification is required for any programme on which a student may be registered. All programmes of the University are subject to the University's Quality Assurance processes. All degrees are awarded by Queen's University Belfast.

Programme Title MChem Medicinal Chemistry with a Year in Industry Final Award
(exit route if applicable for Postgraduate Taught Programmes)
Master of Chemistry
Programme Code MDC-MCHE-I UCAS Code F15C HECoS Code 100420 - Medicinal chemistry - 100
ATAS Clearance Required No
Mode of Study Full Time
Type of Programme Undergraduate Master Length of Programme Full Time - 5 Academic Years
Total Credits for Programme 600
Exit Awards available No

Institute Information

Teaching Institution

Queen's University Belfast

School/Department

Chemistry & Chemical Engineering

Quality Code
https://www.qaa.ac.uk/quality-code

Higher Education Credit Framework for England
https://www.qaa.ac.uk/quality-code/higher-education-credit-framework-for-england

Level 7

Subject Benchmark Statements
https://www.qaa.ac.uk/quality-code/subject-benchmark-statements

The Frameworks for Higher Education Qualifications of UK Degree-Awarding Bodies
https://www.qaa.ac.uk/docs/qaa/quality-code/qualifications-frameworks.pdf

Chemistry

Accreditations (PSRB)

Royal Society of Chemistry

Date of most recent Accreditation Visit 08-02-22

Regulation Information

Does the Programme have any approved exemptions from the University General Regulations
(Please see General Regulations)

Programme Specific Regulations

Progression from Stage 3 to Stage 4 of the degree is dependent on the achievement of a minimum of 55% average at Stage 3 and a minimum weighted average of 55% across stages 1-3. Students failing to meet this requirement will be transferred to the BSc Medicinal Chemistry programme for graduation.

The industrial placement year does not contribute to the final degree classification and is assessed on a pass/fail basis. Students failing to achieve a pass for the placement will be transferred to the MSci in Medicinal Chemistry programme before entering Stage 4

Weightings: Stage 1: 5%; Stage 2: 15%; Stage 3: 30%; Stage 4: 50%

Students with protected characteristics

Are students subject to Fitness to Practise Regulations

(Please see General Regulations)

No

Educational Aims Of Programme

Understand the core principles of chemistry with an emphasis on drug design and synthetic chemistry towards medicinal applications.

Progress directly from the MSci to graduate level employment in pharmaceutical industry and other chemistry and non-chemistry related industries or alternatively progress to postgraduate study or research.

Prepare for eligibility for professional recognition and the status “Chartered Chemist” through full membership of the Royal Society of Chemistry

Demonstrate professional skills within an academic setting through a dedicated medicinal chemistry research project

Demonstrate professional skills within an industrial setting through a year-long placement with a pharmaceutical or related company or organisation

Learning Outcomes

Learning Outcomes: Cognitive Skills

On the completion of this course successful students will be able to:

Solve previously 'unseen' scientific problems using a range of analytical and deductive techniques

Teaching/Learning Methods and Strategies

Lectures and tutorials; class tests and problem solving sessions; structured group and independent laboratory classes; guided independent study. Unseen problems are introduced with tutorial and post-laboratory questions in all topics at Stages 1 and 2 and increase in complexity into level 3 leading to the design of experiments and data acquisition to solve research questions

Methods of Assessment

Written examinations; project or extended experimental work dissertations; oral and poster presentations; experimental reports;

Develop and use reflective practices to provide practical solutions to problems by experimentation

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; research project or extended experimental work; group problem solving exercises; guided independent study. Reflective practices are developed through feedback from experimental reports, tutorial work and formative/summative class tests. By Stage 3, students are routinely applying reflective experimental design principles to their research project or extended practical programmes

Methods of Assessment

Written examinations; group and individual dissertations; oral and poster presentations; experimental reports

Critically review and reflect upon their work

Teaching/Learning Methods and Strategies

Structured group and independent laboratory classes; research project or extended experimental work; group problem solving exercises. The same principles of developing these critical analysis and review techniques as the previous Outcome apply here

Methods of Assessment

Written examinations; group and individual dissertations; oral and poster presentations; experimental reports

Make value judgments on information in the public domain

Teaching/Learning Methods and Strategies

Essays; literature searching and research project or extended experimental work dissertation. Retrieval of subject-specific material from primary literature and public domain sources are developed through essays and particularly through the group problem solving exercises which rely on critical analysis of published material

Methods of Assessment

Group and individual dissertations; oral and poster presentations.

Solve previously 'unseen' scientific problems using a range of analytical and deductive techniques

Teaching/Learning Methods and Strategies

Lectures and tutorials; class tests and problem solving sessions; structured group and independent laboratory classes; guided independent study. Unseen problems are introduced with tutorial and post-laboratory questions in all topics at Stages 1 and 2 and increase in complexity into Stage 3 leading to the design of experiments and data acquisition to solve research questions at Stage 4

Methods of Assessment

Written examinations; project or extended experimental work dissertations; oral and poster presentations; experimental reports;

Develop and use reflective practices to provide practical solutions to problems by experimentation

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; research project or extended experimental work; group problem solving exercises; guided independent study. Reflective practices are developed through feedback from experimental reports, tutorial work and formative/summative class tests. By Stages 3 and 4, students are routinely applying reflective experimental design principles to their research project or extended practical programmes

Methods of Assessment

Written examinations; group and individual dissertations; oral and poster presentations; experimental reports

Learning Outcomes: Transferable Skills

On the completion of this course successful students will be able to:

Demonstrate numeracy and literacy skills

Teaching/Learning Methods and Strategies

Lectures and workshops; structured group and independent laboratory classes; research project or extended experimental work; group problem solving exercises. Students enter the degree pathway with different levels of mathematics and there is an emphasis in Stage 1 of bringing all students to a core threshold of mathematical skills through lectures and workshops. Scientific literacy is developed through increasingly challenging and rigorous experimental reports as students progress from Stage 1 to their project extended practical dissertation

Methods of Assessment

Written examinations; project or extended experimental work dissertations; oral and poster presentations; experimental reports;

Work within a team based environment and employ interpersonal skills

Teaching/Learning Methods and Strategies

Research project or extended experimental work; group problem solving exercises. Team work starts in Stage 1 where students work in small groups in some of the laboratory classes and learn the importance of division of tasks and reliance on shared data. A centrepiece of the group exercise strategy is the extended group process design problem solving exercise at Stage 2 leading to the research project or extended practical module at Stage 3 which requires students to work effectively in existing post-graduate research groups

Methods of Assessment

Project or extended experimental work dissertations; group and individual dissertations; oral and poster presentations

Effectively exert generic problem-solving skills

Teaching/Learning Methods and Strategies

Lectures and tutorials; class tests and problem solving sessions; group problem solving exercises; guided independent study. Problem solving skills are central to this degree programme and are incorporated to a greater or lesser extent in all activities at all Stages

Methods of Assessment

Written examinations; project or extended experimental work dissertations; oral and poster presentations; experimental reports

Manage time effectively and prioritise workloads

Teaching/Learning Methods and Strategies

research project or extended experimental work; coursework deadlines, project goals, milestones and submission targets provide a framework for developing these skills

Methods of Assessment

Project or extended experimental work dissertations; group and individual dissertations;

communicate effectively with colleagues and others using both written and oral methods

Teaching/Learning Methods and Strategies

Research project or extended experimental work and dissertation; group problem solving. exercises; oral and poster presentations Written and oral presentation skills are introduced at Stage 1 through regular tutorials and a poster session on a given topic and are developed further through Stages 2 and 3 with several modules requiring oral or poster presentations and written essays and dissertations. The importance of scientific rigour in the defence of arguments is developed through these exercises

Methods of Assessment

Project or extended experimental work dissertations; group and individual dissertations; oral and poster presentations

Demonstrate data analysis and processing techniques

Teaching/Learning Methods and Strategies

Structured group and independent laboratory classes; research project or extended experimental work and dissertation; class tests and problem solving sessions; guided independent study. The processing of complex sets of information and data is developed from simple experimental results interpretation in Stage 1 through to unknown data processing in the research project or extended practical work in Stage 3.

Methods of Assessment

Project or extended experimental work dissertations; group and individual dissertations; oral and poster presentations

Learning Outcomes: Knowledge & Understanding

On the completion of this course successful students will be able to:

Read, understand and assimilate new information and subsume acquired knowledge into a concise manner and within various settings

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; research project or extended experimental work; essays and dissertations. The ability to extract, process, understand and critically analyse published material is a core key skill in this degree programme and the techniques are embedded into the course from Stage 1 to 3 using the methods listed above

Methods of Assessment

Written examinations; class tests; project or extended experimental work dissertations; oral and poster presentations; experimental reports;

Apply developed generic and subject specific IT skills

Teaching/Learning Methods and Strategies

Lectures and tutorial; IT and computer skills workshops; experimental reports; research project or extended experimental work; essays and dissertations; guided independent study. Basic IT skills for the production of professional reports using subject specific software, such as chemical structure drawing and data analysis, are introduced through workshops and computer-based classes and then developed through experimental reports and essays and dissertations

Methods of Assessment

Written examinations; class tests; project or extended experimental work dissertations; computer-based workshop or online assessment; experimental reports;

Be proficient in database and literature searching techniques

Teaching/Learning Methods and Strategies

Essays; literature searching and research project or extended experimental work dissertation; group problem solving exercises; guided independent study. Awareness of the body of published scientific work and the tools to interrogate and access that information begins in Stage 1 and is developed to the point where students use the available search techniques routinely for their research project or extended practical work in Stage 3

Methods of Assessment

Project or extended experimental work dissertations; group and individual dissertations; oral and poster presentations

Learning Outcomes: Subject Specific

On the completion of this course successful students will be able to:

Demonstrate a conceptual understanding of the fundamental aspects of organic, inorganic and physical chemistry

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; research project or extended experimental work; essays and dissertations; guided independent study; These subject-specific skills are developed from fundamental concepts in Stages 1 and 2 to the application of the concepts in industrially and commercially relevant contexts in Stages 3 and 4 where a degree of specialisation is available

Methods of Assessment

Written examinations; class tests; project or extended experimental work dissertations; experimental reports

Understand the characteristic chemistry and properties of the elements and group relationships and trends within the periodic table

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; essays and dissertations; guided independent study. See previous Learning Outcome for details of strategy

Methods of Assessment

Written examinations; class tests; project or extended experimental work dissertations; experimental reports

Demonstrate a knowledge of chemical bonding, shape and structure

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; essays and dissertations; independent guided study. See previous Learning Outcome for details of strategy

Methods of Assessment

Written examinations; class tests; project or extended experimental work dissertations; experimental reports

Understand the chemistry of functional groups and major synthetic pathways in organic chemistry.

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; essays and dissertations; guided independent study. See previous Learning Outcome for details of strategy

Methods of Assessment

Written examinations; class tests; project or extended experimental work dissertations; experimental reports

Understand the principles of thermodynamics and kinetics, including catalysis and the mechanistic interpretation of chemical reactions

Teaching/Learning Methods and Strategies

Lectures and tutorials; structured group and independent laboratory classes; essays and dissertations; guided independent study. See previous Learning Outcome for details of strategy

Methods of Assessment

Written examinations; class tests; project or extended experimental work dissertations; experimental reports

Demonstrate safe and proficient practical laboratory chemistry skills

Teaching/Learning Methods and Strategies

Structured group and independent laboratory classes; research project. Chemistry is essentially an experimental, laboratory-based subject and experimental work forms at least 25% of the degree in terms of teaching and assessment. Developing the skills to handle potentially dangerous materials and processes is central to all laboratory-based activities

Methods of Assessment

Project or extended experimental work dissertations; group and individual dissertations; oral and poster presentations; experimental reports

Be proficient in a range of analytical instrumentation

Teaching/Learning Methods and Strategies

Structured group and independent laboratory classes; research project or extended experimental work; group problem solving exercises.

Methods of Assessment

Project or extended experimental work dissertations; group and individual dissertations; oral and poster presentations; experimental reports

Demonstrate advanced knowledge of an area of new or emerging chemical research

Teaching/Learning Methods and Strategies

Students can choose up to two areas of specialisation in Stage 4 to support and complement their research project and the core medicinal chemistry material. Core material is delivered by lectures but students make extensive use of guided independent study to acquire knowledge from peer reviewed literature

Methods of Assessment

Written examinations; class tests; essays and dissertations; oral presentations

Understand the general concepts used in drug design related to the pharmacodynamic and pharmacokinetic properties of putative therapeutic agents

Teaching/Learning Methods and Strategies

Lectures and workshops; guided independent study and literature review. Strategy as in previous learning outcome

Methods of Assessment

Written examinations; class tests; essay; experimental reports

Understand the mechanisms of the modes of action of the major classes of drugs

Teaching/Learning Methods and Strategies

Lectures and workshops; guided independent study and literature review. Strategy as in previous learning outcome

Methods of Assessment

Written examinations; class tests; essay; experimental reports

Be proficient in molecular modelling of biological systems and in silico skills for drug-discovery

Teaching/Learning Methods and Strategies

Lectures and computer workshops; guided independent study and literature review. Strategy as in previous learning outcome

Methods of Assessment

Written examinations; computer-based assignments; class tests; essay;

Understand the processes leading to drug discovery including biological target identification and chemical structure optimisation

Teaching/Learning Methods and Strategies

Lectures and workshops; guided independent study and literature review. This programme diverges substantially from the main BSc programme at Stage 3 with an emphasis on the application of underlying core chemical concepts and techniques in a medicinal chemistry context

Methods of Assessment

Written examinations; class tests; essay; experimental reports

Apply professional skills within an industrial setting

Teaching/Learning Methods and Strategies

The assessed extended work placement of normally one year provides the student with an opportunity to develop many of the subject specific and transferable skills listed above within an industrial environment and context.

Methods of Assessment

Written placement report; oral presentation; oral examinations; industrial supervisor’s report;

Module Information

Stages and Modules

Module Title Module Code Level/ stage Credits

Availability

Duration Pre-requisite

Assessment

S1 S2 Core Option Coursework % Practical % Examination %
Inorganic Chemistry Level 1 CHM1102 1 30 YES YES 24 weeks N YES -- 15% 35% 50%
Organic Chemistry Level 1 CHM1101 1 30 YES YES 24 weeks N YES -- 15% 15% 70%
Physical Theory CCE1102 1 30 YES YES 24 weeks N YES -- 15% 25% 60%
Molecular Basis of Life for Medicinal Chemists BIO1103 1 20 YES -- 12 weeks N YES -- 70% 30% 0%
Introductory Mathematics for Chemists and Engineers CHE1107 1 10 YES -- 12 weeks N YES -- 100% 0% 0%
Molecular Genetics and Bioinformatics BIO2305 2 40 YES YES 24 weeks N YES -- 100% 0% 0%
Industrial and Green Chemistry CHM2006 2 20 -- YES 12 weeks N YES -- 80% 20% 0%
Organic Chemistry 2 CHM2003 2 20 YES YES 12 weeks N YES -- 10% 30% 60%
Inorganic Chemistry 2 CHM2004 2 20 -- YES 12 weeks N YES -- 5% 25% 70%
Structural Chemistry CHM2002 2 20 YES -- 12 weeks N YES -- 100% 0% 0%
Organic Chemistry 3: Structure and Reactivity CHM3002 3 20 YES YES 12 weeks N YES -- 0% 0% 100%
Advanced Practical Work in Chemistry CHM3015 3 40 YES YES 24 weeks N YES -- 100% 0% 0%
Drug Development CHM3016 3 20 -- YES 12 weeks N YES -- 20% 0% 80%
Inorganic Chemistry 3 CHM3001 3 20 YES YES 24 weeks N YES -- 15% 0% 85%
Advanced Chemistry Options CHM3005 3 20 -- YES 12 weeks N YES -- 0% 0% 100%
Year in Industry CHM3021 4 120 YES YES 36 weeks N YES -- 100% 0% 0%
Advanced Organic Synthesis CHM4002 5 20 -- YES 12 weeks N YES -- 10% 0% 90%
Options in Applied, Technical and Macromolecular Chemistry CHM4006 5 20 -- YES 12 weeks N -- YES 0% 0% 100%
Advanced Inorganic Chemistry CHM4005 5 20 YES YES 12 weeks N -- YES 0% 0% 100%
Frontiers in Drug Development (Medicinal Chemistry 4) CHM4007 5 20 YES YES 12 weeks N YES -- 0% 0% 100%
Chemical Research Project CHM4001 5 60 YES YES 24 weeks N YES -- 100% 0% 0%

Notes

No notes found.