• University of Southampton Featured Masters Courses
  • Durham University Featured Masters Courses
  • Xi’an Jiaotong-Liverpool University Featured Masters Courses
  • Swansea University Featured Masters Courses
  • University of Cambridge Featured Masters Courses
  • Ross University School of Veterinary Medicine Featured Masters Courses
  • Anglia Ruskin University Featured Masters Courses
De Montfort University Featured Masters Courses
University of Leeds Featured Masters Courses
Imperial College London Featured Masters Courses
Nottingham Trent University Featured Masters Courses
Swansea University Featured Masters Courses
"genetic" AND "diagnosis"…×
0 miles

Masters Degrees (Genetic Diagnosis)

We have 37 Masters Degrees (Genetic Diagnosis)

  • "genetic" AND "diagnosis" ×
  • clear all
Showing 1 to 15 of 37
Order by 
The MSc in Genetic and Genomic Counselling is designed to give students a working knowledge of the principles and practice of Genetic Counselling which will qualify them to practice as Genetic and Genomic Counsellors. Read more
The MSc in Genetic and Genomic Counselling is designed to give students a working knowledge of the principles and practice of Genetic Counselling which will qualify them to practice as Genetic and Genomic Counsellors. The programme will be delivered by University of Glasgow staff in collaboration with NHS staff from the West of Scotland Genetics Service, so that a current perspective on both laboratory diagnostics and clinical services will be obtained. This programme is accredited by the UK Genetic Counsellor Registration Board.

Why this programme

-◾Teaching is based at the Queen Elizabeth University Hospital (QEUH), which includes adult services, children’s services and maternity services, as well as one of the largest diagnostic laboratories in Europe, and a new, purpose-built teaching and learning facility. The close collaboration between University and NHS staff ensures that the MSc in Genetic and Genomic Counselling provides a completely up-to-date representation of genetic services.
◾Counselling and psychology theoretical and research-focused courses are delivered by University staff trained in psychology, providing a firm foundation for the subsequent acquisition of knowledge and skills in genetic counselling facilitated by GCRB-registered Genetic Counsellors.
◾The University of Glasgow Medical Genetics Teaching Staff won the 2014 UK-wide Prospects Postgraduate Awards for the category of Best Postgraduate Teaching Team (Science, Technology & Engineering), to recognise and reward excellence and good practice; they were also finalists in the 2013 awards and are finalists in the category of "Outstanding support for students" in The Herald Higher Education Awards for Scotland in association with UWS 2016.
◾You will develop your skills in problem solving, evaluation and interpretation of diagnostic data, communication of the results of genome testing to patients, literature searches, scientific writing, oral presentations, poster presentations and team working.
◾The widely used textbook “Essential Medical Genetics” is co-authored by a member of the core teaching team, Professor Edward Tobias.

Programme structure

Component courses are as follows:

Genetic Disease in Clinical Practice

This course is designed in collaboration with the West of Scotland Genetics Service to give students a working knowledge of the principles and practice of Clinical Genetics which will allow them to evaluate, choose and interpret appropriate genetic investigations for individuals and families with genetic disease, and explore the links between genotype and phenotype.

Case Investigations in Medical Genetics

Students will work in groups to investigate complex clinical case scenarios: decide appropriate testing, analyse results from genetic tests, reach diagnoses where appropriate and, with reference to the literature, generate a concise and critical group report.

Distress or disorder: reactions to a medical diagnosis

Note: this 10 credit course may be taken by visiting students, for example as professional development.

This course outlines the process of psychosocial adjustment to a diagnosis or test result allowing participants to establish if and when a distress reaction develops into an adjustment disorder. The implications of diagnosis are explored and evidence considered allowing informed decisions about appropriate referrals to other agencies.

Patient empowerment: supporting decisions relating to new diagnoses

Note: this 10 credit course may be taken by visiting students, for example as professional development.

This course reflects on evidence and experience to explore the psychological and social impact of a diagnosis, or illness, and provides strategies to support resilience and coping in patients. Factors related to lived experience, personal beliefs and values, culture, adjustment processes, decision-making, misconceptions, secrecy and guilt are considered to equip participants in the promotion of patient-centred care.

Effective listening and communication skills

Note: this 10 credit course may be taken by visiting students, for example as professional development.

With a focus on experiential learning and student led study, this course outlines the role of counselling skills to facilitate adjustment and to allow an individual to come to terms with change in a safe way to minimise impact. The focus will be on the theory supporting counselling, developing key listening and communication skills and on establishing reflective practice.

Genetic counselling in clinical practice

This course is designed in collaboration with the West of Scotland Clinical Service, and will be delivered by NHS staff, to provide students with in depth understanding of the practical skills required in genetic counselling. The course will facilitate development of appropriate critical understanding, reflective practice and skills in relation to genetic counselling for providing accurate complex genetic information for patients and their families.

Social science research methods

The research methods course will focus on developing students’ research skills primarily in questionnaire-based qualitative and quantitative observational research methods and students will be introduced to ethics procedures for the college of MVLS.

Community placements 1 & 2

These placements, for 16 days and 20 days respectively, will each take place in one or more care settings for individuals with complex needs (adults or children or both) to enable students to gain insight into effects of complex needs on affected individuals and on their family.

Genetic counselling placement 1 & 2

These placements, for eight weeks and six weeks respectively, in different genetics centres will allow students to observe clinical practice in a variety of contexts, and to undertake relevant tasks under supervision within a clinical team that is delivering a genetic service, to enable the student to develop their own skills as a future genetic counsellor. Following each placement students will discuss and share experiences, facilitated by one of the NHS lead team and a counselling supervisor, to further develop their ability to deal with practical and emotional challenges in genetic counselling.

Clinical genomics

This course will provide an overview of the clinical applications of genomic approaches to human disorders, particularly in relation to clinical genetics, discussing the methods and capabilities of the new technologies. Tuition and hands-on experience in data analysis will be provided, including the interpretation of next generation sequencing reports.

Career prospects

The programme aims to provide students with skills to work as Genetic Counsellors. This programme is accredited by the Genetic Counsellor Registration Board (GCRB) producing graduates who are eligible for entry as a ‘trainee genetic counsellor’.

Read less
This MSc aims to provide medical and science-based students with a comprehensive knowledge and understanding of the field of reproductive science and women's health. Read more
This MSc aims to provide medical and science-based students with a comprehensive knowledge and understanding of the field of reproductive science and women's health. There is a strong focus on development of key skills and careers advice in the programme.

Degree information

Students will develop knowledge and understanding of the theoretical (including clinical) and laboratory aspects of reproductive science and women's health, specifically in the areas of basic genetics, gametogenesis and IVF, female reproductive anatomy, physiology and pathology, pregnancy and childbirth, breast and reproductive cancers, prenatal diagnosis and screening, reproductive health, and preimplantation genetic diagnosis and developing technology. They gain transferable skills including information technology, analysis of scientific papers, essay writing, seminar presentation, research techniques, peer review and laboratory skills.

Students undertake modules to the value of 180 credits.

The programme consists of eight core modules (120 credits) and a research project (60 credits).

A Postgraduate Diploma comprising eight core modules (120 credits, full-time nine months or flexible study two to five years) is offered. There are no optional modules for this programme.

Mandatory modules
-Basic Genetics and Technology
-Gametogenesis, Preimplantation Development and IVF
-Female Reproductive Physiology and Anatomy, Physiology and Pathology
-Pregnancy and Childbirth
-Breast and Reproductive Cancers
-Prenatal Diagnosis and Screening
-Reproductive Health
-Preimplantation Genetic Diagnosis and Developing Technology

Dissertation/research project
All MSc Students undertake a clinical, laboratory, audit or library-based research project, which culminates in a dissertation of 10,000 words.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials, practical demonstrations in laboratories, observation days in fetal medicine, reproductive medicine and IVF units, and student presentations. There are a number of peer-led learning activities. Assessment is through essays, patient case reports, critical reviews of papers, online problem booklet, examinations and the dissertation.

Careers

On completion of the programme, all students will have gained knowledge of both the clinical and laboratory aspects of reproductive science and women's health. This will enable the science-orientated students to go on to pursue research degrees, careers in embryology, or other careers in the field or in general science. Medically-orientated students will be able to develop their careers in the field of reproductive science and women's health.

Top career destinations for this degree:
-Research Fellow, NHS Harris Birthright Research Center for Fetal Medicine
-Trainee Embryologist, Assisted Reproduction and Gynaecological Centre
-University Teaching Assistant, King Saud University
-Medical Laboratory Assistant, Imperial College Healthcare NHS Trust
-Senior House Officer (Obstetrics and Gynaecology), NHS Health Education South London / St Thomas' Hospital (NHS

Employability
Throughout the MSc programme students learn key skills through peer-led activities, such as evaluating and presenting orally on patient cases and media coverage of scientific papers. Basic laboratory techniques are taught as are essay writing, critical evaluation of papers, debates and ethical discussions. We also offer a comprehensive careers programme involving our alumni, covering job applications, CV writing, general careers in science and specific advice on careers in embryology, clinical genetics, medicine and research degrees.

Why study this degree at UCL?

The Institute for Women's Health delivers excellence in research, clinical practice, education and training in order to make a real and sustainable difference to women's and babies' health worldwide.

The institute houses the UK's largest group of academics working in women's health and the UCL/UCL Hospitals NHS Foundation Trust collaboration at its core provides an academic environment in which students can pursue graduate studies taught by world-class researchers and clincians.

Our diversity of expertise in maternal and fetal medicine, neonatology, reproductive health and women's cancer ensures a vibrant environment in which students develop subject-specific and generic transferable skills, supporting a broad range of future employment opportunities.

Read less
This MSc aims to provide medical and science students with a comprehensive knowledge and understanding of the field of prenatal genetics and fetal medicine, specifically human genetics, human embryonic development and fetal medicine. Read more
This MSc aims to provide medical and science students with a comprehensive knowledge and understanding of the field of prenatal genetics and fetal medicine, specifically human genetics, human embryonic development and fetal medicine. There is a strong focus on the development of key skills and careers advice in the programme.

Degree information

Students will develop a knowledge and understanding of the field of prenatal genetics and fetal medicine, specifically in the areas of basic genetics and technology, genetic mechanisms, medical genetics, organogenesis and fetal development, gametogenesis and IVF, prenatal diagnosis and screening, fetal and perinatal medicine, and preimplantation genetic diagnosis and developing technology. They gain transferable skills including information technology, analysis of scientific papers, essay writing, seminar presentation, research techniques, peer review and laboratory skills.

Students undertake modules to the value of 180 credits.

The programme consists of eight core modules (120 credits) and a research project (60 credits). A Postgraduate Diploma consisting of eight core modules (120 credits, full time nine months, flexible study two to five years) is offered. There are no optional modules for this programme.

Mandatory modules
-Basic Genetics and Technology
-Gametogenesis, Preimplantation Development and IVF
-Genetic Mechanisms
-Medical Genetics
-Organogenesis and Fetal Development
-Prenatal Diagnosis and Screening
-Fetal and Perinatal Medicine
-Preimplantation Genetic Diagnosis and Developing Technology

Dissertation/report
All MSc students undertake a clinical, laboratory, audit or library-based research project, which culminates in a dissertation of 10,000 words.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials, practical demonstrations in laboratories, observation days in fetal medicine and IVF units, and student presentations. There are a number of peer-led learning activities. Assessment is through essays, patient case reports, critical reviews of papers, online problem booklet, examinations and the dissertation.

Careers

On completion of the programme, all students will have gained knowledge of both the clinical and laboratory aspects of prenatal genetics and fetal medicine. This will enable the science-orientated students to go on to pursue research degrees, careers in embryology or prenatal diagnosis, or other careers in the field or in general science. Medically-orientated students will be able to develop their careers in the field of fetal medicine.

Top career destinations for this degree:
-Ob/Gyn Surgeon, Ente Ospedaliero Cantonale
-Trainee Embryologist, Homerton University Hospital (NHS)
-PhD Medical Genetics, The Cyprus Institute of Neurology and Genetics (CI
-Clinical Research Nurse, University College London (UCL)
-Trainee Embryologist, Life Hospital

Employability
Throughout the MSc programme students learn key skills through peer-led activities, such as evaluating and presenting orally on patient cases and media coverage of scientific papers. Basic laboratory techniques are taught as are essay writing, the critical evaluation of papers, debates and ethical discussions. We also offer a comprehensive careers programme involving our alumni, covering job applications, CV writing, general careers in science and specific advice on careers in embryology, clinical genetics, medicine and research degrees.

Why study this degree at UCL?

The UCL Institute for Women’s Health delivers excellence in research, clinical practice, education and training in order to make a real and sustainable difference to women's and babies' health worldwide.

The institute houses the UK's largest group of academics working in women's health and the UCL/UCL Hospitals NHS Foundation Trust collaboration at its core provides an academic environment in which students can pursue graduate studies taught by world-class reseachers and clinicians.

Our diversity of expertise in maternal and fetal medicine, neonatology, reproductive health and women's cancer ensures a vibrant environment in which students develop subject-specific and generic transferable skills, supporting a broad range of future employment opportunities.

Read less
The increasing impact of genetics in healthcare and the development of newer sophisticated technologies requires close collaboration between research scientists, clinical laboratory scientists and clinicians to deliver a high quality service to patients. Read more
The increasing impact of genetics in healthcare and the development of newer sophisticated technologies requires close collaboration between research scientists, clinical laboratory scientists and clinicians to deliver a high quality service to patients. The Clinical Genetics MSc has a specific focus on delivery of the clinical service to patients including risk analysis and application of modern genetic and genomic technologies in medical genetics research and in diagnostics and population screening.

● This is a fully up-to-date Clinical Genetics degree delivered by dedicated, multi-award-winning teaching and clinical staff of the University, with considerable input from hospital-based Regional Genetics Service clinicians and clinical scientists.
● The full spectrum of genetic services is represented, from patient and family counselling to diagnostic testing of individuals and screening of entire populations for genetic conditions: eg the NHS prenatal and newborn screening programmes.
● The Clinical Genetics MSc Teaching Staff won the 2014 UK-wide Prospects Postgraduate Awards for the category of Best Postgraduate Teaching Team (Science, Technology & Engineering). These awards recognise and reward excellence and good practice in postgraduate education.
● The close collaboration between university and hospital staff ensures that the Clinical Genetics MSc provides a completely up-to-date representation of the practice of medical genetics and you will have the opportunity to observe during clinics at the new Queen Elizabeth University Hospital laboratory medicine building.
● The Clinical Genetics degree explores the effects of mutations and variants as well as the theoretically basis of current techniques used in NHS genetics laboratory diagnostics and recent developments in diagnostics (including microarray analysis and the use of massively parallel [“next-generation”] sequencing).
● New developments in genetics are incorporated into the lectures and interactive teaching sessions very soon after they are presented at international meetings or published, and you will gain hands-on experience and guidance in using software and online resources for genetic diagnosis and for the evaluation of pathogenesis of DNA sequence variants.
● You will develop your skills in problem solving, evaluation and interpretation of genetic data, literature searches, scientific writing, oral presentations, poster presentations and team working.
● This MSc programme will lay the academic foundations on which some students with prior MBChB or MBBS may build in pursuing careers in Clinical Genetics.
● The widely used textbook “Essential Medical Genetics” is co-authored by a member of the core teaching team, Professor Edward Tobias.
● For doctors: The Joint Royal Colleges of Physicians’ Training Board (JRCPTB) in the UK recognises the MSc in Clinical Genetics (which was established in 1984) as counting for six months of the higher specialist training in Clinical Genetics.

Programme Structure

Genetic Disease and Clinical Practice

This course is designed in collaboration with the West of Scotland Regional Genetics Service to give students a working knowledge of the principles and practice of Clinical Genetics and Genomics which will allow them to evaluate, choose and interpret appropriate genetic investigations for individuals and families with genetic disease. The link from genotype to phenotype, will be explored, with consideration of how this knowledge might contribute to new therapeutic approaches.

Distress or Disorder: Reactions to a medical diagnosis

This course outlines the process of psychosocial adjustment to a diagnosis or test result allowing participants to establish if and when a distress reaction develops into an adjustment disorder. The implications of diagnosis are explored and evidence considered allowing informed decisions about appropriate referrals to other agencies.

Patient Empowerment: Supporting decisions relating to new diagnoses

This course reflects on evidence and experience to explore the psychological and social impact of a diagnosis, or illness, and provides strategies to support resilience and coping in patients. Factors related to lived experience, personal beliefs and values, culture, adjustment processes, decision-making, misconceptions, secrecy and guilt are considered to equip participants in the promotion of patient-centred care.

Effective listening and communication skills

With a focus on experiential learning and student led study, this course outlines the role of counselling skills to facilitate adjustment and to allow an individual to come to terms with change in a safe way to minimise impact. The focus will be on the theory supporting counselling, developing key listening and communication skills and on establishing reflective practice.

Case Investigations in Medical Genetics and Genomics

Students will work in groups to investigate complex clinical case scenarios: decide appropriate testing, analyse results from genetic tests, reach diagnoses where appropriate and, with reference to the literature, generate a concise and critical group report.

Clinical Genomics

This course will provide an overview of the clinical applications of genomic approaches to human disorders, particularly in relation to clinical genetics, discussion the methods and capabilities of the new technologies. Tuition and hands-on experience in data analysis will be provided, including the interpretation of next generation sequencing reports.

Disease Screening in Populations

This course will cover the rationale for, and requirements of, population screening programmes to detect individuals at high risk of particular conditions, who can then be offered diagnostic investigations. Students will work in groups to investigate and report on, a screening programme of their choice from any country.

Dissertation

The course will provide students with the opportunity to carry out an independent investigative project in the field of Medical Genetics and Genomics.

Teaching and Learning Methods

A variety of methods are used, including problem-based learning, case-based learning, lectures and tutorials. These are supplemented by a wide range of course-specific electronic resources for additional learning and self-assessment. As a result, you will develop a wide range of skills relevant to careers in clinical genetics. These skills include team-working and data interpretation. You will use the primary scientific literature as an information resource, although textbooks such as our own Essential Medical Genetics will also be useful. You will have the options of: attending genetic counselling clinics and gaining hands-on experience and guidance in using software and online resources for genetic diagnosis and for the evaluation of pathogenicity of DNA sequence variants.

Visit the website for more information http://www.gla.ac.uk/postgraduate/taught/clinicalgenetics/#/programmestructure

Read less
The increasing impact of genetics in healthcare and the development of newer sophisticated technologies requires contributions from research scientists, clinical laboratory scientists and clinicians to investigate the causes of, and therefore permit optimal management for, diseases for which alterations in the genome, either at the DNA sequence level or epigenetic level, play a significant role. Read more
The increasing impact of genetics in healthcare and the development of newer sophisticated technologies requires contributions from research scientists, clinical laboratory scientists and clinicians to investigate the causes of, and therefore permit optimal management for, diseases for which alterations in the genome, either at the DNA sequence level or epigenetic level, play a significant role. Collaboration between staff from the University of Glasgow and the NHS West of Scotland Genetics Service enables the MSc in Medical Genetics and Genomics to provide a state-of-the-art view of the application of modern genetic and genomic technologies in medical genetics research and diagnostics, and in delivery of a high quality genetics service to patients, as well as in design of targeted therapies.

Why this programme

◾This is a fully up-to-date Medical Genetics degree delivered by dedicated, multi-award-winning teaching and clinical staff of the University, with considerable input from hospital-based Regional Genetics Service clinicians and clinical scientists.
◾The full spectrum of genetic services is represented, from patient and family counselling to diagnostic testing of individuals and screening of entire populations for genetic conditions: eg the NHS prenatal and newborn screening programmes.
◾The MSc Medical Genetics Course is based on the south side of the River Clyde in the brand new (2015) purpose built Teaching & Learning Centre, at the Queen Elizabeth University Hospitals (we are located 4 miles from the main University Campus). The Centre also houses state of the art educational resources, including a purpose built teaching laboratory, computing facilities and a well equipped library. The West of Scotland Genetic Services are also based here at the Queen Elizabeth Campus allowing students to learn directly from NHS staff about the latest developments to this service.
◾The Medical Genetics MSc Teaching Staff have won the 2014 UK-wide Prospects Postgraduate Awards for the category of Best Postgraduate Teaching Team (Science, Technology & Engineering). These awards recognise and reward excellence and good practice in postgraduate education.
◾The close collaboration between university and hospital staff ensures that the Medical Genetics MSc provides a completely up-to-date representation of the practice of medical genetics and you will have the opportunity to observe during clinics and visit the diagnostic laboratories at the new Southern General Hospital laboratory medicine building.
◾The Medical Genetics degree explores the effects of mutations and variants as well as the current techniques used in NHS genetics laboratory diagnostics and recent developments in diagnostics (including microarray analysis and the use of massively parallel [“next-generation”] sequencing).
◾New developments in medical genetics are incorporated into the lectures and interactive teaching sessions very soon after they are presented at international meetings or published, and you will gain hands-on experience and guidance in using software and online resources for genetic diagnosis and for the evaluation of pathogenesis of DNA sequence variants.
◾You will develop your skills in problem solving, experimental design, evaluation and interpretation of experimental data, literature searches, scientific writing, oral presentations, poster presentations and team working.
◾This MSc programme will lay the academic foundations on which some students may build in pursuing research at PhD level in genetics or related areas of biomedical science or by moving into related careers in diagnostic services.
◾The widely used textbook “Essential Medical Genetics” is co-authored by a member of the core teaching team, Professor Edward Tobias.
◾For doctors: The Joint Royal Colleges of Physicians’ Training Board (JRCPTB) in the UK recognises the MSc in Medical Genetics and Genomics (which was established in 1984) as counting for six months of the higher specialist training in Clinical Genetics.
◾The Medical Council of Hong Kong recognises the MSc in Medical Genetics and Genomics from University of Glasgow in it's list of Quotable Qualifications.

Programme structure

Genetic Disease: from the Laboratory to the Clinic

This course is designed in collaboration with the West of Scotland Regional Genetics Service to give students a working knowledge of the principles and practice of Medical Genetics and Genomics which will allow them to evaluate, choose and interpret appropriate genetic investigations for individuals and families with genetic disease. The link from genotype to phenotype, will be explored, with consideration of how this knowledge might contribute to new therapeutic approaches.

Case Investigations in Medical Genetics and Genomics

Students will work in groups to investigate complex clinical case scenarios: decide appropriate testing, analyse results from genetic tests, reach diagnoses where appropriate and, with reference to the literature, generate a concise and critical group report.

Clinical Genomics

Students will take this course OR Omic Technologies for Biomedical Sciences OR Frontiers in Cancer Science.

This course will provide an overview of the clinical applications of genomic approaches to human disorders, particularly in relation to clinical genetics, discussion the methods and capabilities of the new technologies. Tuition and hands-on experience in data analysis will be provided, including the interpretation of next generation sequencing reports.

Omic technologies for the Biomedical Sciences: from Genomics to Metabolomics

Students will take this course OR Clinical Genomics OR Frontiers in Cancer Science.

Visit the website for further information

Career prospects

Research: About half of our graduates enter a research career and most of these graduates undertake and complete PhDs; the MSc in Medical Genetics and Genomics facilitates acquisition of skills relevant to a career in research in many different bio-molecular disciplines.

Diagnostics: Some of our graduates enter careers with clinical genetic diagnostic services, particularly in molecular genetics and cytogenetics.

Clinical genetics: Those of our graduates with a prior medical / nursing training often utilise their new skills in careers as clinical geneticists or genetic counsellors.

Other: Although the focus of teaching is on using the available technologies for the purpose of genetic diagnostics, many of these technologies are used in diverse areas of biomedical science research and in forensic DNA analysis. Some of our numerous graduates, who are now employed in many countries around the world, have entered careers in industry, scientific publishing, education and medicine.

Read less
The Genetics of Human Disease MSc aims to provide students with an in-depth knowledge of molecular genetics, quantitative and statistical genetics and human disease and how this can be applied to improve healthcare through the development and application of diagnostic tests and therapeutic agents. Read more
The Genetics of Human Disease MSc aims to provide students with an in-depth knowledge of molecular genetics, quantitative and statistical genetics and human disease and how this can be applied to improve healthcare through the development and application of diagnostic tests and therapeutic agents.

Degree Information

The programme provides a thorough grounding in modern approaches to the understanding of the genetics of disease alongside the cutting-edge research methods and techniques used to advance our understanding of development of disease. Core modules provide a broad coverage of the genetics of disease, research skills and social aspects, whilst specialised streams in Inherited Diseases, Pharmacogenetics and Computational Genomics, in which students can qualify, and the research project allow more in-depth analysis in areas of genetics.

Students undertake modules to the value of 180 credits.

The programme consists of four core modules (60 credits) and two specialist modules (30 credits) and a research project culminating in a dissertation (90 credits).

A Postgraduate Diploma consisting of six modules (four core modules in term one and two modules within the selected stream in term two) is offered, full-time nine months.

A Postgraduate Certificate consisting of four core modules in term one (60 credits) is offered, full-time three months.

Core Modules
- Advanced Human Genetics: Research Principles
- Human Genetics in Context
- Core Skills
- Basic Statistics for Medical Sciences

Specialist modules
In term two you will take specialist modules depending on the specialist stream you select: Inherited Disease (A); Pharmacogenetics (B); Computational Genomics (C).
- Applications in Human Genetics (A)
- Either Genetics of Cardiovascular Disease or Genetics of Neurological Disease (A)
- Clinical Applications of Pharmacogenetic Tests (B)
- Anti-Cancer Personalised Medicine or Pharmacogenomics, Adverse Drug Reactions and Biomarkers (B)
- Applications in Human Genetics (C)
- Statistics for Interpreting Genetic Data (C)

Dissertation/report
Students undertake an original research project investigating topical questions in genetics and genetics of human disease which culminates in a dissertation of 12,000 to 14,000 words and an oral presentation.

Teaching and learning
Students develop their knowledge and understanding of genetics of human diseases through a combination of lectures, seminars, tutorials, presentations and journal clubs. Taught modules are assessed by unseen written examination and/or, written reports, oral presentations and coursework. The research project is assessed by the dissertation and oral presentation.

Careers

Advanced training in genetic techniques including bioinformatic and statistical approaches positions graduates well for PhD studentships in laboratories using genetic techniques to examine diseases such as heart disease, cancer and neurological disorders. Another large group will seek research jobs in the pharmaceutical industry, or jobs related to genetics in healthcare organisations.

Employability
The MSc in Genetics of Human Disease facilitates acquisition of knowledge and skills relevant to a career in research in many different biomedical disciplines. About half of our graduates enter a research career by undertaking and completing PhDs and working as research associates/scientists in academia. Some of our graduates go on to jobs in the pharmaceutical industry, while others enter careers with clinical genetic diagnosis services, particularly in molecular genetics, in healthcare organisations and hospitals around the world. Those graduates with a prior medical training often utilise their new skills as clinical geneticists.

Why study this degree at UCL?

UCL is in a unique position to offer both the basic science and application of modern genetics to improve human health. The programme is a cross-faculty initiative with teaching from across the School of Life and Medical Sciences (SLMS) at UCL.

Students will be based at the UCL Genetics Institute (UGI), a world-leading centre which develops and applies biostatistical and bioinformatic approaches to human and population genetics. Opportunities to conduct laboratory or computational-based research projects are available in the laboratories of world-leading geneticists affiliated to the UGI.

Read less
This vocational training programme is for recent biology, biomedical, biochemistry and medical graduates who want to develop a career in the field of clinical embryology and assisted reproductive technology (ART) and/or the associated reproductive sciences. Read more

This vocational training programme is for recent biology, biomedical, biochemistry and medical graduates who want to develop a career in the field of clinical embryology and assisted reproductive technology (ART) and/or the associated reproductive sciences. It provides a detailed knowledge of the underpinning theory and practices and is a laboratory-based science degree not a clinically-based infertility treatment course.

The programme emphasises all aspects of practical training for clinical embryology and assisted reproduction technology. You’ll receive hands-on training from specialist practitioners in andrology, gamete handling, IVF, ICSI, embryo culture, gamete and embryo freezing, vitrification and biopsy and will interact with established, clinical embryologists and reproductive medicine specialists. You’ll also be trained in research methods.

You will be part of a world-renowned School, being taught by and working with internationally recognised scholars.

More information

The programme has been developed by the Division of Reproduction and Early Development within the Leeds Institute of Genetics, Health and Therapeutics, in association with the clinicians and embryologists working at the Leeds Centre of Reproductive Medicine in the Leeds NHS Trust. The programme leaders have over 20 years of experience of training clinical embryologists, reproductive medicine practitioners and reproductive scientists.

You can also study this subject at Postgraduate Diploma level. 

Through a series of compulsory modules you’ll learn about:

  • the cell and molecular biology of human reproduction, fertility, andrology and embryology
  • the management and efficient running of an ART laboratory
  • the practices, genetic and epigenetic concepts of micromanipulation and techniques, such as intracytoplasmic sperm injection (ICSI) and pre-implantation genetic diagnosis (PGD)
  • advances in cryobiology and its application to gamete and embryo freezing and fertility preservation.

The programme also gives you valuable insights into the theory underpinning clinical treatments and the ethical and legal controversies surrounding assisted reproduction in humans.

Course structure

Compulsory modules

  • Research in Reproduction, Embryology & Assisted Reproduction Technology 60 credits
  • Fundamentals of Clinical Embryology 45 credits
  • IVF and Embryo Culture 35 credits
  • Micromanipulation 15 credits
  • Cryobiology and Cryopreservation 15 credits
  • Ethics and Law for Embryologists 10 credits

For more information on typical modules, read Clinical Embryology and Assisted Reproduction Technology MSc in the course catalogue

Learning and teaching

The programme is delivered using a blended learning approach, which combines lectures, seminars, tutorials, interactive group discussions, presentations and problem-based-learning sessions or case studies, with self-directed learning.

Theoretical training is complemented by the original research conducted by the student and by an extensive series of laboratory-based ART practical and skills training sessions.

The course content is enhanced by extensive online resources and the provision of printed versions of all module workbooks, as appropriate.

Assessment

Course assessments will include essays, presentations, projects, practical log books, a research dissertation and examinations.

Career opportunities

The Clinical Embryology and Associated Reproductive Technology MSc equips graduates to pursue a career in human assisted reproduction (eg clinical embryology, infertility treatment) and/or research in the reproductive sciences.

Careers support

We encourage you to prepare for your career from day one. That’s one of the reasons Leeds graduates are so sought after by employers.

The Careers Centre and staff in your faculty provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.




Read less
This module is for those with an interest in fertility who wish to improve their understanding of the principles and practices of assisted reproduction technology. Read more
This module is for those with an interest in fertility who wish to improve their understanding of the principles and practices of assisted reproduction technology. Students will gain an understanding of the complex issues surrounding modern infertility treatments and current management strategies for infertile couples.

Suitable for specialist nurse practitioners, hospital doctors, clinicians, GPs and related scientist/health professionals, teaching will be through a combination of lectures, seminars, case studies and small group work. The module is conducted at the Centre for Reproductive Medicine, University Hospital of Coventry & Warwickshire, Coventry

Topics covered include

-Definition & diagnosis of infertility.
-Hormonal control of the menstrual cycle.
-Andrology.
-Embryology & blastocyst culture.
-Initiating pregnancy.
-Micromanipulation.
-Fertility preservation.
-PCOS & OHSS.
-Male factor infertility.
-Patient support including management of recurrent miscarriage.
-Donated sperm & eggs.
-Follow up of pregnancies & children born.
-Regulation & the law.
-Ethics.
-Treatment pathways.
-Preimplantation genetic diagnosis (PGD).
-Gamete & tissue cryopreservation.
-Role of the infertility nurse.

Read less
The UCL Institute for Women’s Health is an internationally recognised centre of excellence and leading provider of postgraduate taught programmes in women’s health. Read more
The UCL Institute for Women’s Health is an internationally recognised centre of excellence and leading provider of postgraduate taught programmes in women’s health. This new MRes gives students the opportunity to take a programme with greater emphasis on research skills and experience, and on development of transferable academic and professional skills.

Degree information

Students choose taught modules and select research areas from a variety of subjects across reproductive science and women's health, spanning the four themes of the institute: maternal and fetal health; neonatology; women’s cancer; and reproductive health. Students learn how to conduct an independent research project. They will also gain practical experience and theoretical understanding in research methodologies and critical analysis.

Students undertake modules to the value of 180 credits.

The programme consists of four optional modules (60 credits) and a research project (120 credits).

Core modules
All students undertake an independent research project in women's health.

Students may choose to focus on a laboratory or non-laboratory project (such as a social or ethical-based project), or an epidemiology project (analysing cohort or registry data).

Optional modules
Students choose four optional modules; a minimum of three from the reproductive science and women's health modules listed below. One option can also be chosen from the transferable skills modules marked * below.

-Basic Genetics and Technology
-Breast and Reproductive Cancer
-Female Reproductive Anatomy, Physiology and Pathology
-Gametogenesis, Preimplantation Development and IVF
-Pregnancy and Childbirth
-Preimplantation Genetic Diagnosis and New Technology
-Prenatal Diagnosis and Screening
-Reproductive Health
-Leadership and Professional Development*
-Research Methodology and Statistics*
-Understanding Research and Critical Appraisal*

Dissertation/research project
The independent research project in women's health culminates in a dissertation of 20,000 words. Students will be involved in the conceptualisation, design, data collection, analysis, interpretation and presentation of the project. This will allow the development of research skills in a specific field as well as a range of transferable skills, including literature searching, statistical analysis and written and verbal communication.

Teaching and learning
In addition to taught modules and the long research project, there is a full induction week at the start of the programme and six careers afternoons. A comprehensive range of assessment methods cover the key research, communication and practical skills required for future employment.

Careers

The first cohort of students on this proramme will graduate in 2018. We expect the programme will prepare science-orientated students to go on to further research. Medically-orientated students may wish to develop their careers in the field of reproductive science and women’s health or undertake further research.

Employability
The programme provides students with an excellent introduction to research both in the UK and overseas. It will equip them with the general and scientific skills required to embark on lifelong careers in research and related fields.

Why study this degree at UCL?

The UCL Institute for Women's Health delivers excellence in research, clinical practice, education and training in order to make a real and sustainable difference to women's and babies' health worldwide.

The institute houses the UK's largest group of academics working in women's health. The UCL/UCL Hospitals NHS Foundation Trust collaboration provides an academic environment in which students can pursue graduate studies with world-class researchers and clincians. We offer excellent basic science facilities, opportunities to work in cutting-edge clinical and translational research, and expertise in study methodology.

A comprehensive careers programme is embedded in all our degrees. This ensures students are exposed to a range of different job opportunities. We have alumni who give talks on their disparate career journeys.

Read less
This vocational training programme is for recent biology, biomedical, biochemistry and medical graduates who want to develop a career in the field of clinical embryology and assisted reproductive technology (ART) and/or the associated reproductive sciences. Read more

This vocational training programme is for recent biology, biomedical, biochemistry and medical graduates who want to develop a career in the field of clinical embryology and assisted reproductive technology (ART) and/or the associated reproductive sciences. It provides a detailed knowledge of the underpinning theory and practices and is a laboratory-based science degree not a clinically-based infertility treatment course.

The programme emphasises all aspects of practical training for clinical embryology and assisted reproduction technology. You’ll receive hands-on training from specialist practitioners in andrology, gamete handling, IVF, ICSI, embryo culture, gamete and embryo freezing, vitrification and biopsy and will interact with established, clinical embryologists and reproductive medicine specialists.

You will be part of a world-renowned School, being taught by and working with Internationally recognised scholars.

More information

The programme has been developed by the Division of Reproduction and Early Development within the Leeds Institute of Genetics, Health and Therapeutics, in association with the clinicians and embryologists working at the Leeds Centre of Reproductive Medicine in the Leeds NHS Trust. The programme leaders have over 20 years of experience of training clinical embryologists, reproductive medicine practitioners and reproductive scientists.

You can also study this subject at Master of Science level.

Course content

Through a series of compulsory modules you’ll learn about:

  • the cell and molecular biology of human reproduction, fertility, andrology and embryology
  • the management and efficient running of an ART laboratory
  • the practices, genetic and epigenetic concepts of micromanipulation and techniques, such as intracytoplasmic sperm injection (ICSI) and pre-implantation genetic diagnosis (PGD)
  • advances in cryobiology and its application to gamete and embryo freezing and fertility preservation.

The programme also gives you valuable insights into the theory underpinning clinical treatments and the ethical and legal controversies surrounding assisted reproduction in humans.

Course structure

Compulsory modules

  • Fundamentals of Clinical Embryology 45 credits
  • IVF and Embryo Culture 35 credits
  • Micromanipulation 15 credits
  • Cryobiology and Cryopreservation 15 credits
  • Ethics and Law for Embryologists 10 credits

For more information on typical modules, read Clinical Embryology and Assisted Reproduction Technology PGDip in the course catalogue

Learning and teaching

The programme is delivered using a blended learning approach, which combines lectures, seminars, tutorials, interactive group discussions, presentations and problem-based-learning sessions or case studies, with self-directed learning.

Theoretical training is complemented by a small number of laboratory-based practical sessions.

The course content is enhanced by extensive online resources and the provision of printed versions of all module workbooks.

Assessment

Course assessments will include essays, presentations, projects, practical log books, a research dissertation and examinations.

Career opportunities

The Clinical Embryology and Associated Reproductive Technology PGDip will educate graduates who want to pursue a career in human assisted reproduction (eg clinical embryology, infertility treatment) and/or research in the reproductive sciences.

Careers support

We encourage you to prepare for your career from day one. That’s one of the reasons Leeds graduates are so sought after by employers.

The Careers Centre and staff in your faculty provide a range of help and advice to help you plan your career and make well-informed decisions along the way, even after you graduate. Find out more at the Careers website.



Read less
The Pre-Masters in Biomedical Science (Graduate Diploma in Biomedical Science) provides a discipline-specific pathway (a pre-masters year) into the taught Biomedical Blood Science masters level programme. Read more

Overview

The Pre-Masters in Biomedical Science (Graduate Diploma in Biomedical Science) provides a discipline-specific pathway (a pre-masters year) into the taught Biomedical Blood Science masters level programme. It is a one-year full-time programme designed for both home and international students, with a background in life sciences, who wish to study at postgraduate level for the MSc in Biomedical Blood Science. The programme is open to science graduates who do not meet the academic criteria for a direct entry into the MSc. The MSc in Biomedical Blood Science is accredited by the Institute of Biomedical Science (IBMS). The IBMS is the professional body of Biomedical Scientists within the United Kingdom. The IBMS aims to promote and develop the role of Biomedical Science within healthcare to deliver the best possible service for patient care and safety.

See the website https://www.keele.ac.uk/pgtcourses/biomedicalsciencegraduatediploma/

Course Aims

The overall aim is to provide the students with the academic background necessary for the masters programme and to enable them to develop and practise the subject specific academic skills required for the intensive pace of study at masters level. The course also aims to allow international students to benefit from English language support that will help them to develop their academic English language skills.

Intended learning outcomes of the programme reflect what successful students should know, understand or to be able to do by the end of the programme. Programme specific learning outcomes are provided in the Programme Specification available by request; but, to summarise, the overarching course aims are as follows:

- To provide students with core knowledge, understanding and skills relevant to Biomedical Science

- To produce skilled and motivated graduates who are suitably prepared for the MSc in Biomedical Science and for further study.

- To cultivate interest in the biosciences, particularly at the cellular and molecular level, within a caring and intellectually stimulating environment.

- To get an accurate insight into the role of Biomedical Scientists in the diagnosis, treatment and monitoring of disease.

- To develop an understanding of the analytical, clinical and diagnostic aspects of Cellular Pathology, Clinical Biochemistry, Medical Microbiology, Blood Transfusion, Clinical Immunology and Haematology pathology laboratories.

- To promote the development of a range of key skills, for use in all areas where numeracy and an objective, scientific approach to problem-solving are valued.

- To provide students with a wide range of learning activities and a diverse assessment strategy in order to fully develop their employability and academic skills, ensuring both professional and academic attainment.

- To promote the development of critical thinking, autonomous learning, independent research and communication skills to help prepare the students for the MSc in Biomedical Blood Science and for a lifetime of continued professional development.

Course Content

All the modules in this one year programme are compulsory. The programme consists of a total of 90 credits made up of one 30 credit module and four 15 credit modules. An additional English module (English for Academic Purposes) will be offered for non-native English speakers if required. This module will not form part of the overall award, but successful completion is required for progression to the Masters programme.

Modules:
- Biomedical Science and Pathology (30 credits):
The module provides the student with the knowledge and understanding of the pathobiology of human disease associated with Cellular Pathology, Clinical Immunology, Haematology, Clinical Biochemistry, Medical Microbiology and Clinical Virology. It also examines the analytical and clinical functions of three more of the major departments of a modern hospital pathology laboratory, including Haematology, Clinical Pathology, Clinical Immunology, Blood Transfusion, Clinical Biochemistry and Medical Microbiology. In addition, the module will give an accurate insight into the role of Biomedical Scientists and how they assist clinicians in the diagnosis, treatment and monitoring of disease.

- Biochemistry Research Project (non-experimental) (15 credits):
This module aims to introduce students to some of the key non-experimental research skills that are routinely used by biochemists and biomedical scientists, such as in depth literature searching, analysis of experimental data and the use of a computer as tool for both research (bioinformatics) and dissemination of information (web page construction). The student will research the literature on a specific topic, using library and web based resources and will produce a written review. In addition, the student will either process and interpret some raw experimental data provided to them.

- Advances in Medicine (15 credits):
This module will describe and promote the understanding of advances in medicine that have impacted on diagnosis, treatment, prevention of a range of diseases. It will highlight fast emerging areas of research which are striving to improve diagnosis including nanotechnology and new biochemical tests in the fields of heart disease, cancer and fertility investigations which will potentially improve patient care.

- Clinical Pathology (15 credits):
The majority of staff that contribute to the module are employees of the University Hospital of North Staffordshire (UHNS). Students will benefit from lectures and expertise in Clinical Diagnostic Pathology, Pharmacology, Biochemistry, Genetics and Inflammatory Diseases. Students will gain an insight into how patients are managed, from their very first presentation at the UHNS, from the perspective of diagnosis and treatment. The course will cover both standardised testing options and the development of new diagnostic procedures with a particular emphasis on genetic and epigenetic aspects of disease. Students will also gain an appreciation of the cost benefit of particular routes for diagnosis and treatment and the importance of identifying false positive and false negative results. Finally, the students will have the opportunity to perform their own extensive literature review of a disease-related topic that is not covered by the lectures on the course.

- Case Studies in Biomedical Science (15 credits):
This module aims to give you an understanding of the UK health trends and the factors that affect these trends. Through clinical case studies and small group tutorials, you will explore why the UK has some of the highest incidences of certain diseases and conditions in Europe and consider what factors contribute to making them some of the most common and/or rising health problems faced by this country. This will include understanding the relevant socioeconomic factors as well as understanding the bioscience of the disease process and its diagnosis and management. You will also focus on what is being done by Government and the NHS to tackle these major health problems.

- English for Academic Purposes (EAP ):
For non-native English speakers if required

Teaching & Assessment

In addition to the lecture courses and tutorials, problem based learning (PBL) using clinical scenarios is used for at least one module. Students will also be given the opportunity to undertake an independent non-experimental research project, supervised and supported by a member of staff. Web-based learning using the University’s virtual learning environment (KLE) is also used to give students easy access to a wide range of resources and research tools, and as a platform for online discussions and quizzes. Students will be given many opportunities to become familiar with word processing, spreadsheets and graphics software as well as computer-based routes to access scientific literature.

All modules are assessed within the semester in which they are taught. Most contain elements of both ‘in-course’ assessment (in the form of laboratory reports, essays, posters) and formal examination, although some are examined by ‘in-course’ assessment alone.

Additional Costs

Apart from additional costs for text books, inter-library loans and potential overdue library fines we do not anticipate any additional costs for this post graduate programme.

Find information on Scholarships here - http://www.keele.ac.uk/studentfunding/bursariesscholarships/

Read less
The MSc Molecular Genetics and Diagnostics is suitable for graduates in life sciences, biomedical sciences and allied subjects, as well as people already employed in related fields who wish to improve and update their knowledge and gain valuable experience. Read more
The MSc Molecular Genetics and Diagnostics is suitable for graduates in life sciences, biomedical sciences and allied subjects, as well as people already employed in related fields who wish to improve and update their knowledge and gain valuable experience.

The course is designed to explain the technology, theory and practical approaches of molecular genetic methods to the diagnosis and understanding of human disease.

The course has a start date in September,

The course aims to:

• Provide an advanced course of study in the theoretical and practical aspects of the genetic basis and diagnosis of human disease
• Allow students adequate time to integrate into an active research laboratory where they are able to develop the skills which are essential when considering a career in research
• Train students to carry out critical evaluation of published scientific papers so that they develop the ability to report and interpret results

The academic staff involved with the course are recognised at an international level for their work on the genetic basis of complex diseases, including chronic obstructive pulmonary disease (COPD), Alzheimer's disease and infectious disease caused by clinically relevant microbial pathogens such as Pseudomonas spp., Yersinia spp. and Staphylococcus spp. Colleagues working in Molecular Diagnostics and Clinical Genetics within the NHS also contribute to the teaching on the course.

Key Facts

• The MSc Molecular Genetics and Diagnostics was previously known as the MSc Molecular Diagnostics, and has been running since 2004
• One of the many strengths of the course is the five-month research project that is conducted in the laboratory with a member research staff within the School
• The latest Research Assessment Exercise (RAE) confirmed The University of Nottingham's position as a world class research-led institution. Over 60% of the University's RAE scores identified research as being of a level of international excellence.
• This achievement has helped put Nottingham in the world’s top 1% of Universities internationally according to the latest (2014) QS World University Ranking.
• The peer-reviewed research carried out within the Human Genetics and Molecular and Cellular Bacteriology groups is recognized as being of either international or world-class standard.
• The MSc Molecular Genetics and Diagnostics is coordinated by academic staff within the Molecular and Cellular Bacteriology Research Group, part of the School of Life Sciences. Staff are based either within the Centre for Biomedical Science, a new state of the art research and teaching centre, the adjacent medical school which itself is located in the Queen’s Medical Centre or the Nottingham City Hospital.
• Extensive IT facilities are available across all campuses, including several computer rooms within the medical school.
• The University library service provides access to more than a million books and journals. The Greenfield Medical Library houses a broadly-based collection of biomedical, nursing and healthcare-related books and periodicals and holds current subscriptions to 780 journals, reports and series titles. In addition to the print versions housed in the library, the majority of journals can be accessed electronically.

Read less
The science of human genetics has been transformed in the past decade. Following the sequencing of the entire human genome, a wealth of resources is now available to researchers aiming to identify the genetic variants that influence human health. Read more
The science of human genetics has been transformed in the past decade. Following the sequencing of the entire human genome, a wealth of resources is now available to researchers aiming to identify the genetic variants that influence human health. These findings will shed light on the underlying molecular pathology of many diseases that are poorly understood at present, eventually paving the way for novel treatment and prevention strategies. The speed at which these discoveries are being made is accelerating, and it is likely that molecular genetics will soon underpin much of modern medicine.

Career Pathways:
The MSc in Human Molecular Genetics programme is designed to prepare you for a genetics research career, either in human gene function and genetic disease, or molecular approaches to diagnosis and health care biotechnology. It provides a broad grounding in Human Genetics, with emphasis on molecular aspects, to give a solid basis for subsequent academic or industrial research, or for entry to NHS Genetics training. Approximately 40% of our students go on to do a PhD, 40% become research assistants/associates, while others go on to jobs in industry or further studies (bioinformatics/computing medicine). One or two students every year enter the NHS in clinical genetics training posts.

Programme Structure:
You will study the fundamentals of human and molecular genetics, models of inheritance for rare and common/ complex polygenic diseases, cytogenetics, analytical methods in human genetics and genomics, animal models and transgenesis, gene therapy, epigenetics, cancer genetics and an introduction to clinical genetics and genetic counselling services.

There are four weeks of intensive laboratory practical sessions, as well as computer science practicals applied to problems in genetics, genomics and bioinformatics, regular research seminars on site, student seminar and journal presentations, study group activities and a six-month full-time research project in the summer.

The programme is based on an average 20 hours contact time per week. This will vary between 15 hours in most weeks and approximately 40 hours during intensive practicals and projects. Private study time is included within the schedule: you are expected to contribute an additional 10-15 hours private study per week to the course. We do not recommend you try to support yourself by taking a part-time employment whilst studying as your work may suffer.

Assessment:
There are 3 x 3-hour written papers in late February, coursework assessments (poster presentation, analytical methods in genetics, oral presentation), a project report and a viva examination in September.

Programme Location:
The programme is primarily based at Hammersmith Campus in West London although some teaching modules are held at St Mary's Campus and the Northwick Park Campus.

Read less
Improved global life expectancy has resulted in a cancer epidemic. It is well recognised that accurate early diagnosis is an essential aspect of the administration of increasingly expensive and tailored cancer treatment care plans. Read more
Improved global life expectancy has resulted in a cancer epidemic. It is well recognised that accurate early diagnosis is an essential aspect of the administration of increasingly expensive and tailored cancer treatment care plans.

The Biomedical Sciences (Cancer Biology) MSc programme has been devised to provide knowledge of key aspects of this increasingly important disease area.

You will become familiar with the genetic and cellular changes occurring in both solid and blood-borne cancers, the current and emerging technological approaches for diagnosis of the disease and the effect on pertinent cellular changes on patient prognosis. Studies on populations and the influence of genotypic variation will ensure that you are qualified to make sense of cancer statistics.

You are able to tailor your programme by selecting from a menu of option modules and pursuing a research project in an area ranging from molecular through to cellular or tissue-based aspects of cancer.

During the course you will join our thriving research environment and will have access to excellent laboratory facilities within the Faculty. On successful completion of the course you will be equipped to take forward your career with an in-depth knowledge of this increasingly common disease area.

Modules

The following modules are indicative of what you will study on this course.

Core modules
-ADVANCED CANCER BIOLOGY
-CELL SIGNALLING AND GENETICS
-MOLECULAR SCIENCE AND DIAGNOSTICS
-POSTGRADUATE PROJECT
-POSTGRADUATE RESEARCH METHODS

Option modules
-COMMUNICATING SCIENCE
-EXTENDED POSTGRADUATE PROJECT
-IMMUNOPATHOLOGY
-IMMUNOTHERAPY
-MOLECULAR AND CELLULAR THERAPEUTICS
-SYSTEMS BIOLOGY

Associated careers

After graduation, you will be equipped with the skills and knowledge to pursue a range of cancer-focused careers including appointments in diagnostic laboratories, academic, biotechnological and pharmaceutical research.

As a graduate of this course, you will be ideally placed to play an essential role in both diagnosis and improved care of cancer patients. Opportunities are also available to pursue a career in clinical trials and in areas such as data analysis and public health.

Professional recognition

The course is accredited by the Institute of Biomedical Science (IBMS).

Read less
This course aims to inform and equip the practitioner with the necessary skills to function in a modern biomedical/clinical environment specialising in caring for the patient with a genetic disorder. Read more
This course aims to inform and equip the practitioner with the necessary skills to function in a modern biomedical/clinical environment specialising in caring for the patient with a genetic disorder.

Why Study Medical Genetics with us?

You will receive training in the skills required in the reading and interpretation of the literature and translating that into evidence-based practice. We aim to develop your research and writing skills so that you will be in a position to contribute to the scientific literature in an effective manner.

The course culminates in the Research Dissertation, which will be assessed through your production of two publishable scientific articles.

The content of the course is mapped to The Joint Royal Colleges of Physicians Training Board Speciality Training Curriculum for Clinical Genetics.

If biomedical or clinical research is your interest, successful completion of the MSc will allow you to directly register onto PhD study and join our team of researchers at the Institute of Medicine.

What will I learn?

You will study how to apply molecular approaches to the diagnosis and treatment of a range of conditions that have a genetic component. We will discuss novel approaches to prevention and treatment, plus the increasing potential of genomics. We will also consider ethical implications of interventions, and the role/nature of genetic counselling. You will carry out a research project in one of these areas.

Seminars and tutorials will be held with various healthcare professionals and clinical researchers.

How will I be taught?

Our course consists of taught modules and a Research Dissertation.

We deliver taught modules as three-day intensive courses to facilitate attendance from students in employment. Weekly support sessions and journal club supplement learning – all held in our modern facilities in Bache Hall.

How will I be assessed?

You will be assessed via clinical reviews, laboratory reports, posters, oral presentations, or data manipulation exercises.

Read less

Show 10 15 30 per page



Cookie Policy    X