• University of York Featured Masters Courses
  • University of Leeds Featured Masters Courses
  • Xi’an Jiaotong-Liverpool University Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • Leeds Beckett University Featured Masters Courses
  • Swansea University Featured Masters Courses
  • University of Glasgow Featured Masters Courses
  • Regent’s University London Featured Masters Courses
De Montfort University Featured Masters Courses
Southampton Solent University Featured Masters Courses
Institute for Advanced Architecture of Catalonia Featured Masters Courses
FindA University Ltd Featured Masters Courses
University of Leeds Featured Masters Courses
0 miles
Biological Sciences×

University of Edinburgh, Full Time Masters Degrees in Biological Sciences

  • Biological Sciences×
  • University of Edinburgh×
  • Full Time×
  • clear all
Showing 1 to 15 of 39
Order by 
Bioinformatics is about the application of computer-based approaches to understanding biological processes. Our programme will introduce you to the current methods used to interpret the vast amounts of data generated by modern high-throughput technologies. Read more

Programme description

Bioinformatics is about the application of computer-based approaches to understanding biological processes. Our programme will introduce you to the current methods used to interpret the vast amounts of data generated by modern high-throughput technologies.

The aim of this MSc is to equip you with a strong background in biology, plus the computing skills and knowledge necessary to navigate the vast wealth of modern biological data. On completing this programme you will be able to take up PhD studies or bioinformatics posts in academia or in industry.

The programme covers programming skills, statistical analysis and database science as well as bioinformatics. Option courses allow you to specialise in several aspects of bioinformatics.

Programme structure

The MSc comprises two semesters of taught courses followed by a research project and dissertation. The project is a key element in deciding how your career in bioinformatics should develop further. Teaching is through lectures, tutorials, seminars, computer practicals and lab demonstrations.

Compulsory courses:

Bioinformatics Programming & System Management
Bioinformatics Research Proposal
MSc Dissertation (Bioinformatics)
Statistics & Data Analysis

Optional courses:

Bioinformatics 1
Human–Computer Interaction
Information Processing in Biological Cells
Molecular Modelling and Database Mining
Quantitating Drug Binding
Text Technologies
Bioinformatics Algorithms
Bioinformatics 2
Computational Systems Biology
Data Mining and Exploration
Functional Genomic Technologies
Introduction to Website and Database Design for Drug Discovery
Molecular Phylogenetics
Next Generation Genomics
Software Architecture, Process, and Management
Drug Discovery
Introduction to Java Programming

Research:
The research project is carried out independently, but under the guidance of a supervisor, during the summer, with results presented in a dissertation. A wide range of projects is available through both the School of Biological Sciences and the School of Informatics.

Career opportunities

The programme is good preparation for further academic research or for technical or managerial roles in various commercial sectors, from medical electronics to defence.

Read less
This one-year, full time programme provides an excellent grounding for PhD or other academic study in the Biomedical Sciences. You will learn valuable research skills, biomedical laboratory techniques and a wide range of other transferable skills that will give you an advantage for the rest of your career. Read more

Research profile

This one-year, full time programme provides an excellent grounding for PhD or other academic study in the Biomedical Sciences. You will learn valuable research skills, biomedical laboratory techniques and a wide range of other transferable skills that will give you an advantage for the rest of your career. You can also choose two themes that best suit your interests and career goals.

The programme includes seminars, taught modules and two research projects in our world-recognised research laboratories. We will also cover a range of valuable transferable skills including critical analysis of research papers, learning how to write a project grant application and literature review, and data presentation and statistical analysis.

Programme structure

The programme includes core skills, seminars, taught modules and laboratory projects in our well-resourced laboratories which are at the cutting-edge of Biomedical research.

Students will carry out two 20-week long research projects selected from the themes available. An assessed research proposal is also required for the second project.

Project 1 (September to February)

Cardiovascular Biology
Cell Communication
Genomics & Biological Pathways
Mechanisms of Inflammatory Disease
Reproductive Science 1
Infectious Diseases
Stem Cells, Tissue Injury and Regenerative Medicine - new theme for September 2017

Project 2 (April to August)

Biomedical Imaging
Genes & Disease
Genomic Technologies
Molecular & Cellular Mechanism of Inflammation
Reproductive Science 2
Cancer Biology
Biological Architecture

Students may also be able to undertake projects in Integrative Neuroscience or in other areas of Biomedical Sciences, with the permission of the Programme Director. These students would be required to attend the taught element of one of the above Themes as appropriate.

Research proposal

In March, students submit a research proposal based on the work performed for Project 2. This takes the form of a grant application, as would be prepared for a research organisation, and is assessed.

Career opportunities and 'Follow-on PhDs'

This programme is an excellent stepping-stone to a PhD, or a career in Biomedical research or industry.

In addition, every year there are vacancies for PhD studentships in the School of Biomedical Sciences and staff are always on the lookout for the outstanding postgraduate students who are on this Programme to encourage them to apply.

Read less
This academically challenging and career-developing programme focuses on research and development using biological and chemical principles and systems to create new products, services and industries. Read more

Programme description

This academically challenging and career-developing programme focuses on research and development using biological and chemical principles and systems to create new products, services and industries.

You will employ elements of the developing field of synthetic biology to bring about significant changes and major innovations that address the challenges of rapidly changing human demographics, resource shortages, energy economy transition and the concomitant growth in demand for more and healthier food, sustainable fuel cycles, and a cleaner environment.

Programme structure

You will learn through a variety of activities, including:

lectures
workshops
presentations
laboratory work
field work
tutorials
seminars
discussion groups and project groups
problem-based learning activities

You will attend problem-based tutorial sessions and one-to-one meetings with your personal tutor or programme director.

You will carry out research at the frontier of knowledge and can make a genuine contribution to the progress of original research. This involves carrying out project work in a research laboratory, reviewing relevant papers, analysing data, writing reports and giving presentations.

Compulsory courses:

Applications of Synthetic Biology
Tools for Synthetic Biology
Social Dimensions of Systems & Synthetic Biology
Environmental Gene Mining & Metagenomics
Research Project Proposal
MSc Project and Dissertation

Option courses:

BioBusiness
Biochemistry
Bioinformatics
Bioinformatics Programming & System Management
Biological Physics
Biophysical Chemistry
Commercial Aspects of Drug Discovery
Data Mining & Exploration
Drug Discovery
Economics & Innovation in the Biotechnology Industry
Enzymology & Biological Production
Functional Genomic Technologies
Gene Expression & Microbial Regulation
Industry & Entrepreneurship in the Biotechnology Industry
Information Processing in Biological Cells
Intelligent Agriculture
Introduction to Scientific Programming
Molecular Modelling & Database Mining
Next Generation Genomics
Machine Learning & Pattern Recognition
Practical Skills in Biochemistry
Practical Systems Biology
Principles of Industrial Biotechnology
Stem Cells & Regenerative Medicine

Learning outcomes

By the end of the programme you will have gained:

a strong background knowledge in the fields underlying synthetic biology and biotechnology
an understanding of the limitations and public concerns regarding the nascent field of synthetic biology including a thorough examination of the philosophical, legal, ethical and social issues surrounding the area
the ability to approach the technology transfer problem equipped with the skills to analyse the problem in scientific and practical terms
an understanding of how biotechnology relates to real-world biological problems
the ability to conduct practical experimentation in synthetic biology and biotechnology
the ability to think about the future development of research, technology, its implementation and its implications
a broad understanding of research responsibility including the requirement for rigorous and robust testing of theories and the need for honesty and integrity in experimental reporting and reviewing

Career opportunities

You will enhance your career prospects by acquiring current, marketable knowledge and developing advanced analytical and presentational skills, within the social and intellectual sphere of a leading European university.

The School of Biological Sciences offers a research-rich environment in which you can develop as a scientist and entrepreneur.

Read less
This one-year, full-time MSc by Research programme aims to introduce students to modern up-to-date molecular and cellular biological research in the field of reproductive sciences, reproductive health and reproductive medicine in a stimulating, challenging and vibrant research atmosphere, at the interface between basic science and clinical patient care. Read more

Research profile

This one-year, full-time MSc by Research programme aims to introduce students to modern up-to-date molecular and cellular biological research in the field of reproductive sciences, reproductive health and reproductive medicine in a stimulating, challenging and vibrant research atmosphere, at the interface between basic science and clinical patient care.

The programme is intended for high-calibre students with biological science, medical or veterinary backgrounds.

It is advised that you contact the Programme Director, Dr Simon Riley, prior to making your application to ensure this programme meets your academic aims. Email:

The main components of the programme are two 20-week research projects, performed on a very wide range of research fields within the reproductive sciences.

Topics that can be offered include using a wide range of models and in human, studying a number of important problems associated with human reproductive health and disease in testis, ovary, the uterus during the menstrual cycle and throughout pregnancy and labour, in the fetus and neonate, and in fetal programming resulting in increased risk of chronic disease in adulthood.

The MRC Centre for Reproductive Health has arranged its research under four themes:

Reproductive Resilience, Proliferation, Differentiation, Repair
Reproductive system cancers: aetiology, pathogenesis and therapy
Optimising Lifelong Health Through Pregnancy and Perinatal Interventions
Immune-endocrine interactions in reproductive health

These theme titles illustrate some of the remarkable properties that make reproductive systems such relevant and powerful models for translational studies across a wide spectrum of human diseases and pathologies in other systems.

The MRC Centre for Reproductive Health (CRH) has close links with other internationally recognised research centres in the Queen’s Medical Research Institute QMRI and elsewhere in Edinburgh, with the Edinburgh Royal Infirmary, the Veterinary School, the University of Edinburgh science campus and the Royal Zoological Society of Scotland.

Many student projects are organised with and between these centres, reflecting the interdisciplinary research environment, where students and trainees are regarded as the ‘lifeblood’ for the future.

Programme structure

The programme provides a core grounding in basic science and interlinked medical aspects of reproductive sciences. It is delivered by undertaking a two-week basic core laboratory skills training course, followed by gaining practical experience by performing two 20 week laboratory-based research projects. Examples of research projects completed in 2016-2017 can be found here: http://www.ed.ac.uk/centre-reproductive-health/students/msc-research-reproductive-sciences

These research projects provide you with hands-on laboratory experience and training in a wide range of up-to-date techniques in molecular and cellular biology. Students also gain a wide range of generic professional and scientific skills such as developing effective communication skills, and scientific writing through project reports and a grant application.

Alongside the project work there is a series of lecture modules and seminars delivered by internationally-recognised experts in the field, together with both staff and student-led small group tutorials.

Career opportunities

This programme is the ideal route for those wishing to embark on a PhD, or in a technical laboratory role, in the field of Reproductive Health, spanning the biosciences, clinical and veterinary fields.

The broad range of skills gained is also readily transferable into careers at the clinical-laboratory interface and in the broader biosciences industry opportunities.

This programme does not amount to specific training to become a clinical embryologist.

Read less
This programme offers you an academically-challenging and career-developing study of biological systems at the molecular and cellular level. Read more

Programme description

This programme offers you an academically-challenging and career-developing study of biological systems at the molecular and cellular level.

Biochemistry is fundamental to most areas of life-science; it has a major impact on modern medical research and is essential in the pharmaceutical, nutrition, forensic, bioengineering, agricultural and environmental industries.

The programme is designed to produce highly skilled and motivated biochemists that are suitable for employment in the life-sciences or for further academic research.

You will be taught to apply chemical and physical principles to biological molecules in complex living systems in order to expand your understanding of the molecular basis of the processes which take place within these organisms.

Through a combination of taught courses, practical skills training and laboratory-based research, you will explore the structures, dynamics, interactions and metabolic pathways of biological molecules, from small molecules to large macromolecular complexes.

Programme structure

Teaching and learning activities include:

lectures
tutorials
workshops
presentations
laboratory work
practical skills training and a research project
literature and database searching
discussion groups and project groups
seminars

Students will have practical skills training and will attend problem and computer-based tutorials and workshops.

Research:
Those students progressing to MSc level will carry out their own research project at the frontier of knowledge and can make a genuine contribution to the progress of original research. This also involves reviewing relevant papers, analysing data, writing a dissertation and giving a presentation.

Learning outcomes

The programme aims to develop:

knowledge and understanding of biochemistry and awareness of the current state of research
enhanced practical skills in biochemical methods
ability to design, perform and record experiments independently
analytical skills to interpret data accurately and critically
ability to communicate biochemical information effectively in a wide range of contexts

Career opportunities

You will enhance your career prospects by acquiring knowledge of contemporary biochemistry from world experts in the field, by being trained in advanced analytical and presentation skills, and by having independent research experience in a modern, world-class laboratory.

Read less
The Institute for Bioengineering (IBioE) connects Engineering, Physical Sciences, Biology and Medicine, for innovative diagnostic and therapeutic biomedical devices and technologies. Read more

Research profile

The Institute for Bioengineering (IBioE) connects Engineering, Physical Sciences, Biology and Medicine, for innovative diagnostic and therapeutic biomedical devices and technologies.

Research themes include:

Synthetic Biology - to design and construct (e.g. to ‘engineer’) biological devices and systems, often at cellular level. Applications range from therapeutic to environmental.

Tissue Engineering - the production of 3D or 2D scaffolds or guidance cues for biological cells. Applications are largely therapeutic and also include new forms of lab-on-chip technology.

Biomedical Modelling and Measurement - understanding biological materials through modelling and measurement for applications in, for example, prosthetics, prediction of failure in blood vessels and the behaviour of bone with ageing. We also study the behaviour of biological materials experimentally and in most cases, non-invasively (e.g. via Raman and CARS spectroscopy).

Biomedical Devices and Sensors - working with colleagues in chemistry, we develop sensors on silicon for simple biological parameters (e.g. oxygen concentration) along with sensors of specific biomarkers of disease and therapy.

Training and support

The development of transferable skills is a vital part of postgraduate training and a vibrant, interdisciplinary training programme is offered to all research students by the University’s Institute for Academic Development (IAD). The programme concentrates on the professional development of postgraduates, providing courses directly linked to postgraduate study.

Courses run by the IAD are free and have been designed to be as flexible as possible so that you can tailor the content and timing to your own requirements.

Our researchers are strongly encouraged to present their research at conferences and in journal during the course of their PhD.

Every year, the Graduate School organises a Postgraduate Research Conference to showcase the research carried out by students across the Research Institutes

Our researchers are also encouraged and supported to attend transferable skills courses provided by organisations such as the Engineering and Physical Sciences Research Council (EPSRC).

Research opportunities

We offer a comprehensive range of exciting research opportunities through a choice of postgraduate research degrees: MSc by Research, MPhil and PhD.

Masters by Research

An MSc by Research is based on a research project tailored to a candidate’s interests. It lasts one year full time or two years part time. The project can be a shorter alternative to an MPhil or PhD, or a precursor to either – including the option of an MSc project expanding into MPhil or doctorate work as it evolves. It can also be a mechanism for industry to collaborate with the School.

Read less
The revolution in genetic mapping technology and the advent of whole genome sequences has turned quantitative genetics into one of the fastest growing areas of biology. Read more

Programme description

The revolution in genetic mapping technology and the advent of whole genome sequences has turned quantitative genetics into one of the fastest growing areas of biology.

Quantitative Genetics & Genome Analysis is part of a suite of programmes offering specialist routes in Animal Breeding & Genetics, Evolutionary Genetics, or Human Complex Trait Genetics.

Based in the internationally renowned Institute of Evolutionary Biology, this MSc draws from the wealth of expertise available there, as well as the teaching, research expertise and facilities of Scotland’s Rural College, the University’s Centre for Molecular Medicine, the Medical Research Council’s Human Genetics Unit and the Roslin Institute (birthplace of Dolly the sheep).

Each year the syllabus is fine-tuned to suit current issues in evolutionary, plant, human and animal genetics.

Applicants who wish to select their area of specialisation during the programme should apply for this umbrella programme. Applicants with a preferred programme option should apply via the following links:

Animal Breeding and Genetics
Evolutionary Genetics
Human Complex Trait Genetics

Programme structure

This programme consists of two semesters of taught courses followed by a research project, leading to a dissertation.

Compulsory courses:

Population and Quantitative Genetics
Genetic Interpretation
Statistics and Data Analysis
Linkage and Association in Genome Analysis
Research Proposal
Either Bioinformatics or Molecular Phylogenetics

Option courses (selected according to degree specialisation):

Quantitative Genetic Models
Molecular Evolution
Genetics of Human Complex Traits
Animal Genetic Improvement
Evolution and Climate Change
Functional Genomic Technologies

Career opportunities

You will develop the in-depth knowledge and specialised skills required to apply quantitative genetics theory to practical problems, in both the biomedical and animal science industries, and to undertake research in evolutionary genetics, population genetics and genome analysis.

Read less
The understanding of plant diversity and resources has never been more important. As we face the unprecedented challenges of climate change and environmental degradation, effective environmental surveillance and conservation depend upon detailed knowledge of plants and their habitats. Read more

Programme description

The understanding of plant diversity and resources has never been more important. As we face the unprecedented challenges of climate change and environmental degradation, effective environmental surveillance and conservation depend upon detailed knowledge of plants and their habitats.

This programme is run jointly by the University and the world-renowned Royal Botanic Garden Edinburgh (RBGE).

This programme is run jointly by the University and the world-renowned Royal Botanic Garden Edinburgh (RBGE). The RBGE is home to one of the world’s best living collections of plants (15,000 species across four sites, amounting to five per cent of known world species), a herbarium of three million preserved specimens and one of the UK’s most comprehensive botanical libraries.

RBGE offers collections-based biodiversity research opportunities across a wide spectrum of organisms and geographical regions. This diversity, coupled with the RBGE’s world-leading research in different continents, provides an unrivalled masters programme in plant biodiversity.

Programme structure

This programme is full time and consists of two semesters of lectures, practicals, workshops and investigations, followed by a four-month research project. The programme includes a two-week field course in a tropical country (recently Belize).

The programme is delivered mainly at RBGE but also at the University’s King’s Buildings campus.

There are no option elements to the programme – all courses are compulsory.

Courses
Conservation and Sustainability
Taxonomy and Plant Collections
Biodiversity of Angiosperms
Evolution of Cryptogams and Fungi
Evolution of Angiosperms
Plant Geography
Phylogenetics and Population Genetics
Biodiversity of Cryptogams and Fungi

Research:
Your research project will be chosen in consultation with your supervisor, and will link directly with active research programmes at RBGE or other research institutions.

The field trip, together with training and a short practical exam, qualifies you for the RBGE Certificate in Practical Field Botany.

Career opportunities

The programme is good preparation for roles in taxonomy, while many graduates have also continued to PhD studies. Past students have entered a wide variety of jobs at research institutions, conservation agencies and elsewhere.

Read less
The rapid transformation in the nature of drug discovery means that knowledge of related disciplines, and the technologies used, is essential for those considering a career in commercial or academic research. Read more

Programme description

The rapid transformation in the nature of drug discovery means that knowledge of related disciplines, and the technologies used, is essential for those considering a career in commercial or academic research.

This MSc will help you explore the latest methods of developing drugs and therapeutic compounds for humans and animals and disease control agents for plants.

You will learn about marketing, licensing and regulations, which are all part of the development process. Our multidisciplinary approach links structural biology, bioinformatics, chemistry and pharmacology.

You will investigate the fundamental scientific problems and techniques of drug discovery and design, alongside the challenges of developing principles for new therapeutic strategies.

You will have hands-on experience of crystallographic computer programming and computation for bioinformatics.

You will consider the moral and ethical aspects of the agrochemical and pharmaceutical industries through case studies, seminars and discussions.

Programme structure

This programme consists of two semesters of taught courses followed by a research project, leading to a dissertation.

Compulsory courses:

Applicable Mathematics
Commercial Aspects of Drug Discovery
Drug Discovery
Molecular Modelling and Database Mining
Protein Structure Determination
Project Proposal and Literature Review
Preparative Methods for Structural Biology
Quantitating Drug Binding


Optional courses:

Biobusiness
Biochemistry
Bioinformatics 1
Bioinformatics 2
Bioinformatics Algorithms
Bioinformatics Programming & System Management
Biophysical Chemistry for MSc Biochemistry
Chemical Medicine
Detailed Characterisation of Drug or Ligand Interactions Using Surface Plasmon Resonance (SPR)
Functional Genomic Technologies
Information Processing in Biological Cells
Introduction to Scientific Programming
Introduction to Website and Database Design for Drug Discovery
Practical Skills in Biochemistry
Tools for Synthetic Biology

Career opportunities

This MSc is designed to help you pursue a career in the pharmaceutical industry or relevant government agencies, and it will provide a good background for managerial or technical roles in research, design and development. It is also a solid basis from which to continue your studies to PhD level.

Read less
We offer an opportunity to train in one of the newest areas of biology. the application of engineering principles to the understanding and design of biological networks. Read more

Programme description

We offer an opportunity to train in one of the newest areas of biology: the application of engineering principles to the understanding and design of biological networks. This new approach promises solutions to some of today’s most pressing challenges in environmental protection, human health and energy production.

This MSc will provide you with a thorough knowledge of the primary design principles and biotechnology tools being developed in systems and synthetic biology, ranging from understanding genome-wide data to designing and synthesising BioBricks.

You will learn quantitative methods of modelling and data analysis to inform and design new hypotheses based on experimental data. The University’s new centre, SynthSys, is a hub for world-leading research in both systems and synthetic biology.

Programme structure

The programme consists of two semesters of taught courses followed by a research project and dissertation, which can be either modelling-based or laboratory-based.

Compulsory courses:

Applications of Synthetic Biology
Dissertation project
Information Processing in Biological Cells
Practical Systems Biology
Social Dimensions of Systems and Synthetic Biology
Tools for Synthetic Biology

Option courses:

Biobusiness
Biochemistry
Bioinformatics Algorithms
Bioinformatics Programming & System Management
Biological Physics
Computational Cognitive Neuroscience
Drug Discovery
Economics & Innovation in the Biotechnology Industry
Environmental Gene Mining & Metagenomics
Functional Genomic Technologies
Gene Expression & Microbial Regulation
Industry & Entrepreneurship in Biotechnology
Introduction to Scientific Programming
Molecular Phylogenetics
Neural Computation
Next Generation Genomics
Practical Skills in Biochemistry
Probabilistic Modelling and Reasoning
Statistics and Data Analysis
Stem Cells & Regenerative Medicine

Career opportunities

The programme is designed to give you a good basis for managerial or technical roles in the pharmaceutical and biotech industries. It will also prepare you for entry into a PhD programme.

Read less
Changing demographics and growing demand for food, fuel and agricultural and environmental sustainability are among the key challenges the world faces today. Read more

Programme description

Changing demographics and growing demand for food, fuel and agricultural and environmental sustainability are among the key challenges the world faces today.

In this MSc you will learn research and development skills to enable the creation of new products and services. You will investigate the economic basis for current biotechnology structures and areas of future demand, including the global pharmaceutical industry and carbon sequestration.

You will learn how technology can be applied to solve pressing real-world biological problems and gain the skills and expertise needed for future developments in biotechnology.

Programme structure

This programme consists of two semesters of taught courses followed by a research project or industrial placement, leading to a dissertation.

Compulsory courses:

Economics and Innovation in the Biotechnology Industry
Intelligent Agriculture
Research Project Proposal
MSc Dissertation (Biotechnology).

Option courses:

Biobusiness
Bioinformatics
Bioinformatics Programming & System Management
Drug Discovery
Commercial Aspects of Drug Discovery
Enzymology and Biological Production
Gene Expression and Microbial Regulation
Industry & Entrepreneurship in Biotechnology
Management of R&D and Product Innovation
Molecular Modelling and Database Mining
Social Dimensions of Systems and Synthetic Biology
Stem Cells and Regenerative Medicine
Biochemistry A
Principles of Industrial Biotechnology
Environmental Gene Mining and Metagenomics
Vaccines and Molecular Therapies
Programming for the Life Sciences

Research and laboratory work:
There will be a considerable practical element to the programme. You will work in a biotechnology laboratory and learn how experimental technology is designed and operated.

Industrial placement:
Your dissertation can be based on a laboratory-based project or an industrial placement. You can work with employers in the thriving Scottish biotechnology sector in areas such as multiple sclerosis research (Aquila BioMedical), vaccines research (BigDNA) or biorecovery and bioregeneration (Recyclatec).

Career opportunities

The programme will open up a wide variety of career opportunities, ranging from sales and marketing, to research and development, to manufacturing and quality control and assurance.

Read less
The revolution in genetic mapping technology and the advent of whole genome sequences have turned quantitative genetics into one of the fastest growing areas of biology. Read more

Programme description

The revolution in genetic mapping technology and the advent of whole genome sequences have turned quantitative genetics into one of the fastest growing areas of biology.

Based in the internationally renowned Institute of Evolutionary Biology, this MSc draws from the wealth of expertise available there, as well as the teaching, research expertise and facilities of Scotland’s Rural College, the University’s Centre for Genomics and Experimental Medicine, the Medical Research Council’s Human Genetics Unit and the Roslin Institute (birthplace of Dolly the sheep).

Each year the syllabus is fine-tuned to suit current issues in evolutionary, plant, human and animal genetics. This programme forms part of the quantitative genetics and genome analysis suite of programmes offering three specialist routes, which also include Human Complex Trait Genetics and Evolutionary Genetics.

Programme structure

This programme consists of two semesters of taught courses followed by a research project, leading to a dissertation.

Courses are taught via lectures, tutorials, seminars and computer practicals. Assessment is by written examinations, in-course assignments and project work.

Compulsory courses:

Population and Quantitative Genetics
Genetic Interpretation
Linkage and Association in Genome Analysis
Animal Genetic Improvement
Research Proposal
Dissertation

Option courses:

Statistics and Data Analysis
Molecular Phylogenetics
Bioinformatics
Molecular Evolution
Genetics of Human Complex Traits
Quantitative
Genetic Models
Functional Genomic Technologies
Evolution and
Climate Change; Animal Genetic Improvement
Evolutionary Quantitative Genetics

Learning outcomes

An understanding of general concepts in population and quantitative genetics and genomics
A solid grounding in the statistical methods required
In-depth knowledge of animal improvement and complex trait analysis
Development of independent research skills through individual mini- and maxi-research projects
Development of generic skills (IT skills, experience in writing scientific papers, the ability to work independently)
Presentation skills through student seminars, scientific presentation of project work and independent research projects.

Career opportunities

You will develop the in-depth knowledge and specialised skills required to apply quantitative genetics theory to practical problems, in both the biomedical and animal science industries, and to undertake research in evolutionary genetics, population genetics and genome analysis.

Read less
The revolution in genetic mapping technology and the advent of whole genome sequences have turned quantitative genetics into one of the fastest growing areas of biology. Read more

Programme description

The revolution in genetic mapping technology and the advent of whole genome sequences have turned quantitative genetics into one of the fastest growing areas of biology.

Based in the internationally renowned Institute of Evolutionary Biology, this MSc draws from the wealth of expertise available there, as well as the teaching, research expertise and facilities of Scotland’s Rural College, the University’s Centre for Molecular Medicine, the Medical Research Council’s Human Genetics Unit and the Roslin Institute (birthplace of Dolly the sheep).

Each year the syllabus is fine-tuned to suit current issues in evolutionary, plant, human and animal genetics.

This programme forms part of the quantitative genetics and genome analysis suite of programmes offering specialist routes, which also include Animal Breeding & Genetics and Human Complex Trait Genetics.

Programme structure

This programme consists of two semesters of taught courses followed by a research project, leading to a dissertation.

Courses are taught via lectures, tutorials, seminars and computer practicals. Assessment is by written examinations, in-course assignments and project work.

Compulsory courses:

Population and Quantitative Genetics
Genetic Interpretation
Linkage and Association in Genome Analysis
Research Proposal
Dissertation

Option courses:

Statistics and Data Analysis Molecular Phylogenetics Bioinformatics Molecular Evolution Genetics of Human Complex Traits Quantitative Genetic Models Functional Genomic Technologies Evolution and Climate Change Animal Genetic Improvement Evolutionary Quantitative Genetics

Learning outcomes

You will gain the knowledge and skills required to apply quantitative genetics theory to undertake research in evolutionary and quantitative genetics, population genetics and evolutionary genomics.

A thorough understanding of general concepts in population and quantitative genetics and genomics
In-depth knowledge of evolutionary genetics
A solid grounding in the statistical methods required for quantitative biology
Development of independent research skills through individual mini- and maxi-research projects
Development of generic skills (IT skills, experience in writing scientific papers, the ability to work independently)
Presentation skills through student seminars, scientific presentation of project work and independent research projects.

Career opportunities

You will develop the in-depth knowledge and specialised skills required to apply quantitative genetics theory to practical problems, in both the biomedical and animal science industries, and to undertake research in evolutionary genetics, population genetics and genome analysis.

Read less
The revolution in genetic mapping technology and the advent of whole genome sequences have turned quantitative genetics into one of the fastest growing areas of biology. Read more

Programme description

The revolution in genetic mapping technology and the advent of whole genome sequences have turned quantitative genetics into one of the fastest growing areas of biology.

Based in the internationally renowned Institute of Evolutionary Biology, this MSc draws from the wealth of expertise available there, as well as the teaching, research expertise and facilities of Scotland’s Rural College, the University’s Centre for Molecular Medicine, the Medical Research Council’s Human Genetics Unit and the Roslin Institute (birthplace of Dolly the sheep).

Each year the syllabus is fine-tuned to suit current issues in evolutionary, plant, human and animal genetics.

This programme forms part of the quantitative genetics and genome analysis suite of programmes offering specialist routes, which include Animal Breeding & Genetics and Evolutionary Genetics.

Programme structure

This programme consists of two semesters of taught courses followed by a research project, leading to a dissertation.

Courses are taught via lectures, tutorials, seminars and computer practicals. Assessment is by written examinations, in-course assignments and project work.

Compulsory courses:

Population and Quantitative Genetics
Genetic Interpretation
Linkage and Association in Genome Analysis
Genetics of Human Complex Traits
Dissertation.

Option courses:

Statistics and Data Analysis
Molecular Phylogenetics
Bioinformatics
Molecular Evolution
Quantitative Genetic Models
Functional Genomic Technologies
Evolution and Climate Change
Animal Genetic Improvement
Evolutionary Quantitative Genetics

Learning outcomes

You will gain the knowledge and skills required to apply quantitative genetics theory to practical problems in the biomedical industry, and to undertake research in quantitative and population genetics and genome analysis.

A thorough understanding of general concepts in population and quantitative genetics and genomics
In-depth knowledge of complex trait genetics in humans
A solid grounding in the statistical methods required for quantitative biology
Development of independent research skills through individual mini- and maxi-research projects
Development of generic skills (IT skills, experience in writing scientific papers, the ability to work independently)
Presentation skills through student seminars, scientific presentation of project work and independent research projects.

Career opportunities

You will develop the in-depth knowledge and specialised skills required to apply quantitative genetics theory to practical problems, in both the biomedical and animal science industries, and to undertake research in evolutionary genetics, population genetics and genome analysis.

Read less
The Institute for Adaptive and Neural Computation (IANC) is a world-leading institute dedicated to the theoretical and empirical study of adaptive processes in both artificial and biological systems. Read more

Research profile

The Institute for Adaptive and Neural Computation (IANC) is a world-leading institute dedicated to the theoretical and empirical study of adaptive processes in both artificial and biological systems. We are one of the UK’s largest and most prestigious academic teams in these fields.

We foster world-class interdisciplinary and collaborative research bringing together a range of disciplines.

Our research falls into three areas:

-machine learning
-computational neuroscience
-computational biology

In machine learning we develop probabilistic methods that find patterns and structure in data, and apply them to scientific and technological problems. Applications include areas as diverse as astronomy, health sciences and computing.

In computational neuroscience and neuroinformatics we study how the brain processes information, and analyse and interpret data from neuroscientific experiments

The focus in the computational biology area is to develop computational strategies to store, analyse and model a variety of biological data (from protein measurements to insect behavioural data).

Training and support

You carry out your research within a research group under the guidance of a supervisor. You will be expected to attend seminars and meetings of relevant research groups and may also attend lectures that are relevant to your research topic. Periodic reviews of your progress will be conducted to assist with research planning.

A programme of transferable skills courses facilitates broader professional development in a wide range of topics, from writing and presentation skills to entrepreneurship and career strategies.

The School of Informatics holds a Silver Athena SWAN award, in recognition of our commitment to advance the representation of women in science, mathematics, engineering and technology. The School is deploying a range of strategies to help female staff and students of all stages in their careers and we seek regular feedback from our research community on our performance.

Facilities

The award-winning Informatics Forum is an international research facility for computing and related areas. It houses more than 400 research staff and students, providing office, meeting and social spaces.

It also contains two robotics labs, an instrumented multimedia room, eye-tracking and motion capture systems, and a full recording studio amongst other research facilities. Its spectacular atrium plays host to many events, from industry showcases and student hackathons to major research conferences.

Nearby teaching facilities include computer and teaching labs with more than 250 machines, 24-hour access to IT facilities for students, and comprehensive support provided by dedicated computing staff.

Among our entrepreneurial initiatives is Informatics Ventures, set up in 2008 to support globally ambitious software companies in Scotland and nurture a technology cluster to rival Boston, Pittsburgh, Kyoto and Silicon Valley.

Career opportunities

The research you will undertake at IANC is perfectly suited to a career in academia, where you’ll be able to use your knowledge to advance this important field. Some graduates take their skills into commercial research posts, and find success in creating systems that can be used in everyday applications.

Read less

Show 10 15 30 per page


Share this page:

Cookie Policy    X