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Masters Degrees (Cancer Drug Discovery)

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Exciting new opportunities for chemical intervention in disease have emerged based on a greater understanding of the molecular aspects of disease progression. Read more
Exciting new opportunities for chemical intervention in disease have emerged based on a greater understanding of the molecular aspects of disease progression. Drug discovery combines the expertise of medicinal chemists required in translating the understanding of the molecular aspects of disease progression to the identification of suitable chemical entities, and the process of optimisation that ultimately leads to the discovery of new medicines.

This exciting course run by the Institute of Cancer Therapeutics is designed to provide students with a 'state-of-the-art' education in modern drug discovery, which meets the demand of employers in the pharmaceutical industry.

Opportunities to learn the latest innovations in drug discovery are provided, including computer-aided drug design and techniques in parallel synthesis, as well as electronic data management.

Why Bradford?

-The course provides an expert view of the use of recent knowledge and up- to-the minute specialised approaches to discover novel drugs to help fight disease and increase the quality of life for patients
-It benefits from the multidisciplinary team of researchers in the field of drug design, synthesis, screening, pharmacology and toxicology both at the University and through our extensive links with experts at other universities and industry
-Students on the course will also benefit from working in excellent research laboratories in a research focused environment

Modules

Core modules
-Critical Appraisal of a Current Topic in Drug Discovery
-Principles of Drug Discovery
-Research and Analytical Methods
-Research Project in Drug Discovery

Option modules
-Molecular Basis of Cancer and Cancer Therapy
-Toxicology and Safety Pharmacology
-Case Studies in Drug Discovery
-Chemical Toolbox for Drug Discovery
-Molecular Mechanisms of Toxicity

Career support and prospects

The University is committed to helping students develop and enhance employability and this is an integral part of many programmes. Specialist support is available throughout the course from Career and Employability Services including help to find part-time work while studying, placements, vacation work and graduate vacancies. Students are encouraged to access this support at an early stage and to use the extensive resources on the Careers website.

Discussing options with specialist advisers helps to clarify plans through exploring options and refining skills of job-hunting. In most of our programmes there is direct input by Career Development Advisers into the curriculum or through specially arranged workshops.

Many students go on to study for PhDs either at Bradford or elsewhere. Recent graduates are studying at Dundee, Newcastle and Glasgow universities. Those in employment are in R&D and clinical research roles.

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- https://www.kent.ac.uk/locations/medway/. This programme builds on a very successful in-house training programme implemented by a major pharmaceutical company. Read more

This course will be held at the Medway Campus

- https://www.kent.ac.uk/locations/medway/

This programme builds on a very successful in-house training programme implemented by a major pharmaceutical company.

It was designed and conceived by pharmaceutical industry experts in drug discovery and will be delivered and assessed by experts in this field at the School of Pharmacy.

The MSc covers how fundamental science is applied to the discovery and development of medicines and the main aims are to:

- provide you with the experience of critically appraising the research questions and techniques that are routine in the pharmaceutical industry workplace

- produce graduates trained in the processes by which fundamental science is linked to the design and development of modern medicines

- provide expert preparation for students who wish to pursue a career in drug discovery, or wish to proceed to a PhD.

Visit the website https://www.kent.ac.uk/courses/postgraduate/736/applied-drug-discovery

Duration: One year full-time (campus based), two years part-time (distance learning)

About Medway School of Pharmacy

Medway School of Pharmacy is one of the few regional schools of pharmacy in the UK, a collaboration between the University of Kent and the University of Greenwich.

The impetus for the formation of the Medway School of Pharmacy came from the local community, who recognised the shortage of qualified pharmacists in all branches of the pharmacy profession in Kent.

The School is now recognised as an established school with accreditation from the General Pharmaceutical Council (GPhC) and the Health and Care Professions Council (HCPC). Graduates are employed in health disciplines in Kent and the south-east and more broadly across the UK.

Course structure

This programme is taught as either a classic one year full-time programme with attendance required on Mondays and Tuesdays for 48 weeks plus an additional study day off-campus, or delivered through distance e-learning using an interactive virtual learning environment on a two-year part-time basis.

The programme comprises 60 credits at certificate level, 60 credits at diploma level and 60 credits at Master’s level. You may choose to end your study at any one of these stages.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

Assessment

Assessment is by 100% coursework; including scientific reports, assignments, essays, a research project and portfolio entries.

Programme aims

This programme aims to:

- produce graduates trained in the processes by which fundamental science is linked to the design and development of modern medicines

- teach you an understanding of the drug discovery process

- provide you with expanded training in the biological sciences technical skills that underpin the processes of drug discovery

- provide you with the experience of critically appraising the research questions and techniques they use routinely in the workplace

- develop a variety of postgraduate level intellectual and transferable skills

- equip you with lifelong learning skills necessary to keep abreast of developments in drug discovery

- provide you with opportunities for shared multidisciplinary learning in drug discovery

- give you the experience of undertaking an independent research project

- provide expert preparation for students who wish to pursue and/or further a career in drug discovery, or wish to proceed to a higher degree (PhD) in topics related to the drug discovery process

- provide access to as wide a range of students as practicable irrespective of race, background, gender or physical disability from both within the UK and from overseas.

Research areas

- Chemistry and drug delivery

This group has laboratories with dedicated state-ofthe art drug delivery, nanotechnology, spectroscopy, chromatography and organic synthesis facilities. It brings together researchers in medicinal chemistry and drug design, nanotechnology and materials science, drug delivery and pharmaceutics encouraging a multidisciplinary approach to research. Research covers synthesis and biological evaluation of potential anti-cancer agents, structurebased drug design, QSAR predication of ADMET properties, controlled release, particle engineering, powder technology, pharmaceutical technology, and novel drug delivery systems, with a focus on respiratory drug delivery.

- Biological sciences

This group is housed in recently refurbished laboratories with dedicated state-of-the-art molecular biological, electrophysiological, tissue culture and microscopy facilities. The research is divided into four main themes; infectious diseases and allergy; neuroscience; renal and cardiovascular physiology; and pharmacology. Examples of current work include: investigation of the use of non-pathogenic virus ‘pseudotypes’ to study pathogenic RNA, study of the properties of neuronal potassium channels and their modulation and the development of new therapies for patients that have developed acute kidney injury in collaboration with a major pharmaceutical company.

- Pharmacy practice

This group conducts research in two areas: public health and medicines optimisation, with a particular focus on cardiovascular diseases and mental health. Work in public health includes studies in physical exercise, alcohol, cardiovascular screening and spirometry testing, plus pharmacovigilance. Studies in medicines optimisation include work in dementia, bipolar disorder and stroke, with an emphasis on the patient perspective.

Careers

Graduates who obtain their PhD from Kent or Greenwich are highly sought after by prospective employers, both within the UK and overseas. Destinations for doctoral graduates include university academic departments, research institutes and leading pharmaceutical and biotechnological companies.

The taught postgraduate programmes are designed to promote the continuing professional development by providing sought-after skills. The programmes are beneficial for those who wish to develop their skills and/or to take the next step in their career. While the MSc in Applied Drug Discovery produces elite drug discovery personnel, who can pursue a career in the pharmaceutical industry or academia.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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This Masters in Cancer Sciences will prepare you for a career in cancer science, whether you aim to pursue a PhD or further medical studies, or seek a career in the health services sector, in the life sciences, biotechnology or pharmaceutical industries. Read more
This Masters in Cancer Sciences will prepare you for a career in cancer science, whether you aim to pursue a PhD or further medical studies, or seek a career in the health services sector, in the life sciences, biotechnology or pharmaceutical industries. Our programme takes a “bench to bedside” approach, enabling graduates to work within a multidisciplinary environment of world-leading scientists and cancer-specialists to address the latest challenges in cancer research.

Why this programme

-University of Glasgow is rated in the UK top five and best in Scotland for Cancer Studies. You will be taught by a multidisciplinary team of world leading cancer scientists and clinicians within the Cancer Research UK Glasgow Centre.
-This MSc in Cancer Science programme is unique in the UK as it delivers integrated teaching in molecular biology, pathology and clinical service.
-The Cancer Research UK Glasgow Centre brings together scientists and clinicians from research centres, universities and hospitals around Glasgow to deliver the very best in cancer research, drug discovery and patient care. The Centre’s world leading teams have made major advances in the understanding and treatment of many cancers. For more information, please visit: http://www.wecancentre.org/
-In the first semester, each week is focused around one of the new Hallmarks of Cancer, with the focus on the molecular/cellular biology of this hallmark. A tutorial session will enable you to discuss and integrate your learning from the week. This will enable you to understand how research into the fundamental principles of cancer cell biology can translate to advances in cancer treatment.
-The aim of this MSc in Cancer Science is to train cancer researchers who can break down the barriers that currently prevent discoveries at the bench from being translated into treatments at the bedside. By understanding the science, methodology and terminology used by scientists and clinicians from different disciplines, you will learn to communicate effectively in a multidisciplinary environment, critically evaluate a wide range of scientific data and research strategies and learn how to make a significant contribution to cancer research.

Programme structure

Semester 1: Hallmarks of Cancer

This 13 week core course aims to:
 provide you with a critical understanding of the molecular and cellular events that drive cancer development and progression
 demonstrate how an understanding of these events underpins current and future approaches to cancer diagnosis and treatment
 integrate the teaching of molecular biology, cell biology, diagnosis and treatment of cancer
 describe how all these disciplines communicate and work together in the fight against cancer
 provide you with theoretical training in fundamental molecular and cell biology techniques used in cancer research
One week of practical training is provided at the start of the course. This course is assessed through a lab notebook, group assessment, critical essay and an exam that focuses on data analysis and interpretation.

Semester 2

In the second semester, you can choose from a range of 3 week optional courses, before taking the core course “Designing a Research Project”.
• Drug Discovery
• Drug Development and Clinical trials
• Viruses and Cancer
• Diagnostic technologies and devices
• Technology transfer and commercialisation of bioscience research
• Current trends and challenges in biomedical research and health
or
• Frontiers in Cancer Sciences – 5 week optional course
• Omic technologies for the biomedical sciences: from genomics to metabolomics - – 5 week optional course
or
• Designing a research project: biomedical research methodology - 6 week optional course

Semester 3

Bioscience Research Project

In this 14 week core course you will:
 have an opportunity to perform a piece of original research to investigate a hypothesis or research questions within the area of cancer research. The project may be “wet” or “dry”, depending what projects are available
 develop practical and/or technical skills, analyse data critically and draw conclusions, and suggest avenues for future research to expand your research findings
Note: students must have a minimum of grade C in semesters 1 and 2 in order to proceed to the research project.

[[Career prospects ]]
The knowledge and transferable skills developed in this programme will be suitable for those contemplating a PhD or further medical studies; those wishing to work in the health services sector; and those interested in working in the life sciences, biotechnology or pharmaceutical industries, including contract research organisations (CROs). This programme is designed for students with undergraduate degrees in the life sciences, scientists working in the pharmaceutical and biotechnology industries, and clinicians and other healthcare professionals.

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The course will provide a robust and wide-reaching education in fundamental and applied cancer biology, and focused training in laboratory research and associated methodology. Read more
The course will provide a robust and wide-reaching education in fundamental and applied cancer biology, and focused training in laboratory research and associated methodology.

Why study Cancer Biology at Dundee?

The MRes Cancer Biology is a research-centred taught Masters programme providing a focused training in molecular cancer research. It covers both the fundamental and translational science of carcinogenesis, cancer biology, diagnosis and therapy.

The programme delivers outstanding research-focused teaching from internationally-renowned scientists and clinicians.

Dundee University is internationally renowned for the quality of its cancer research and has over 50 cancer research groups: current funding for cancer research is about £40 million from research councils and charities. In 2009 the university became the first Scottish university to be awarded Cancer Centre status by the CRUK.

What's so good about studying Cancer Biology at Dundee?

The MRes Cancer Biology has been developed from the innovative collaboration between the College of Medicine, Dentistry and Nursing and the School of Life Sciences, and it complements the establishment of the Cancer Research UK (CRUK) Centre here in Dundee.

The Dundee Cancer Centre aims to enhance cancer research and apply discoveries to improve patient care. Key to this is training the next generation of cancer researchers.

Areas of particular strength at the University of Dundee are in surgical oncology for breast and colon cancer, radiation biology and clinical oncology, skin cancer and pharmacogenomics. Areas of strength in basic cancer biology are DNA replication, chromosome biology and the cell cycle, cell signalling and targets for drug discovery.

Teaching and Assessment

This course is taught by staff based in the College of Medicine, Dentistry and Nursing and the School of Life Sciences.

The MRes will be taught full-time over one year (September to August).

How you will be taught

The course will be taught through a combination of face-to-face lectures, tutorials, discussion group work and journal clubs, self-directed study and supervised laboratory research.

What you will study

The MRes degree course is taught full-time over three semesters.

The first semester provides in-depth teaching and directed study on the molecular biology of cancer, and covers:

Basic cell and molecular biology, and introduction to cancer biology
Cell proliferation, cell signalling and cancer
Cancer cell biology
Carcinogenesis, cancer treatment and prevention
Specific training in research methodology and critical analysis

Students will also be required to take part in a journal club to further develop their critical review skills.

In semesters two and three students will be individually guided to focus on a specific cancer research topic which will be the subject of a literature review and associated laboratory research project. The research project is based in laboratories with state-of-the-art facilities, and under the leadership of world-class researchers.

How you will be assessed

Exams on the taught element of the programme will be held at the end of semester one. Essays and assignments will also contribute to the final mark, and the dissertation will be assessed through the production of a thesis and a viva exam.

Places on the course are limited, so early applications are strongly encouraged.
Apply early to avoid disappointment.
Follow us on Twitter to keep up with news from the MRes Cancer Biology @Mrescancerbiol

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Overview. The MRes courses are designed to provide students with intensive laboratory-based training in research methods, supported by in-depth understanding. Read more
Overview
The MRes courses are designed to provide students with intensive laboratory-based training in research methods, supported by in-depth understanding. The aim is to prepare graduates to make contributions, as individuals and members of a team, to research-oriented activities in the biomedical industries and related service sectors, or academia. The courses are also well-suited to students wishing to upgrade a first degree, change field, or gain valuable laboratory experience before employment or a PhD. The Strathclyde Institute of Pharmacy and Biomedical Sciences represents the largest Pharmacy research group in the UK, with 55% of its staff rated as either world-leading or internationally excellent in terms of originality, significance and rigour (data: Research Assessment Exercise 2008). The University of Strathclyde has invested £30M in a world-class, pioneering centre for biomedical and pharmaceutical sciences teaching and research, opened Aug 2010. Students will find themselves in stimulating, unique environment on account of the strongly multidisciplinary nature of the Institute. Combining fundamental and applied research across the areas of bioscience and pharmacy, SIPBS builds on its record of success in drug and vaccine discovery and development. The Institute engages with industry and the health services, ensuring that its excellent fundamental research is translated into products that are of benefit to health and society. For more information on SIPBS go to http://www.strath.ac.uk/sipbs

Course outline

An MRes degree is focussed on research and students will spend 8 months undertaking a laboratory-based project.
To support their chosen research project, students choose advanced-level taught courses in a named specialisation, from the following areas:

Taught classes delivered through lectures, workshops and practical classes in four areas:
1. Transferable skills training in data mining, interpretation and presentation; experimental planning, personal effectiveness, ethics in research
2. Commercialisation and entrepreneurship
3. MRes-specific classes relevant to subject area

Biomedical Sciences

Example research projects:
1. Antileishmanial activity of extracts and compounds from Monodora myristica
2. Imaging and modelling of cancer development
3. Endothelial progenitor cell expression and differentiation
4. Targeted radiotherapy for cancer
5. The involvement of pulmonary veins in atrial fibrillation: electrical properties
6. Reducing bacterial resistance to antibiotics
7. Development of neural stem cells with increased levels of the autophagy cell survival pathway
8. Investigating the role of Sigma 54 in Pseudomonas aeruginosa virulence
9. Transcriptional network analysis of the Escherichia coli core stress response.
10. Identification of novel anti-microbial compounds targeted at biofilm formation

Drug Delivery systems

Example research projects
1. Nanoparticulate formulations of insulin and their analysis
2. Mesoporous silicas for oral delivery of cyclosporine
3. Bioprocessing of biopharmaceuticals
4. Modified and time-delayed oral solid-dose release formulations
5. Nasal formulations of poorly soluble compounds
6. Reducing bacterial resistance to antibiotics: establishing, optimising and implementing a high throughput assay to discover natural product derived inhibitors of metallo beta-lactamase.
7. Imaging of dermal formulations using Raman microscopy techniques
8. Antileishmanial activity of extracts and compounds from Monodora myristica
9. Anti-trypanosomal active triterpenoids from some African Propolis
10. Investigation into the potential therapeutic properties of marine organisms
11. Photo-triggered adhesion of mammalian cells

Drug Discovery

Projects in the areas of :
1. Drug Delivery
2. Molecular Biology
3. Pharmacology
4. Pharmaceutical Materials and Formulation
5. Toxicology

Neuroscience

Projects in the areas of:
1. Electrophysiology
2. Stem cell biology for regenerative purposes
3. Cell biology
4. Inflammation
5. In vitro culture systems
6. Functional genetics

How to Apply
Applicants should apply through the University of Strathclyde on-line application form: http://pgr.strath.ac.uk indicating "Masters by Research", and named specialisation as appropriate. Applicants are not required to submit a detailed research proposal at this stage.

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Analytical bioscience - the investigation of biomolecules as exploitable biomarkers - is a growing field, driven by improving analytical methods with increasing sensitivity. Read more
Analytical bioscience - the investigation of biomolecules as exploitable biomarkers - is a growing field, driven by improving analytical methods with increasing sensitivity. Following completion of the Human Genome Project, the pharmaceutical industry is preparing for a revolution in cancer and inherited disorder therapies.

This course is training a new generation of bioscientists to meet challenges at the interface between biology and chemistry, and to apply pharmaceutical and analytical knowledge directly to improve quality of life.

Please note: this course was previously called Analytical Bioscience and Drug Design.

Key benefits:

• Train for a career in the newly emerging industries of the post-genomic era
• Work at the interface between biology and chemistry – a truly multidisciplinary Masters degree
• Excellent career prospects in pharmaceuticals and biotechnology

Visit the website: http://www.salford.ac.uk/pgt-courses/drug-design-and-discovery

Suitable for:

This course is aimed at students who wish to acquire the specialised skills needed to design drugs for the 21st century.

Course content

This course is designed to enable you to gain a systematic knowledge, critical awareness of current problems and new insights regarding the analysis of biomolecules. There is particular reference to drug design and discovery, along with a comprehensive and critical understanding of applied techniques and their current application in research in the field of biomolecule analysis and drug design.

Format

Teaching is by lectures to provide thorough grounding in the techniques of biomolecule characterisation and drug design.

Practical sessions and workshops demonstrate techniques and methods used in biomolecule characterisation and drug design, and provide a structured opportunity for you to practise techniques and methods in analytical biosciences and drug design.

Guided reading will recommend texts, key articles and other materials in advance of, or following, lecture classes.

The research project will enable you to practice the application of appropriate, and selected, bioscientific techniques in an academic or industrial context, and demonstrate research methodologies and skills appropriate to and valuable with biomolecule characterisation and drug design.

You will be supervised by expert staff who are actively engaged in international research programmes.

Module Titles

• Research Methods 1
• Drug Pharmacology
• Drug Design
• Novel Theraputics
• Analytical Methods
• Natural Products
• Identification of Drugs
• Bioscience Enterprise
• Research Project

Assessment

• Literature Review and Presentation
• Portfolio
• Examination
• Oral Presentation
• Dissertation

Career progression

Although particularly relevant if you are looking for a career in the pharmaceutical and biotechnology industries, this course will also equip you for a career in research, teaching and many other professions including cosmetic science, animal health, food science, medical laboratory research, patent law, scientific journalism and health and safety.

Research projects may be carried out at Salford or other institutions (e.g. universities in Germany, France and the Paterson Institute, UK). We also invite visiting lecturers to share their expertise on the subject areas.

How to apply: http://www.salford.ac.uk/study/postgraduate/applying

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This full-time MSc course is designed to provide graduates with advanced knowledge, understanding and skills in the rapidly advancing field of Cancer Biology and Therapeutics. Read more
This full-time MSc course is designed to provide graduates with advanced knowledge, understanding and skills in the rapidly advancing field of Cancer Biology and Therapeutics.

The course offers advanced teaching in the cellular aspects of cancer biology together with the molecular mechanisms underlying cancer development and progression. It provides in-depth training in cancer therapeutics, encompassing biomarkers and diagnosis, therapeutic targets, drug discovery and clinical trials and chemo/radio therapy, as well as aiming to develop your theoretical and practical research skills. This postgraduate programme offers a balanced combination of theory and practice that would serve as preparation for doctoral research or as a self-contained advanced qualification in its own right.

Graduates from this course should gain a breadth and depth of cancer-focused training that will make them highly attractive candidates to start or continue a career within the healthcare sector and research establishments.

The course offers research skills training and a laboratory-based research project that can provide you with the skills required to develop research hypotheses and critically evaluate translational approaches with respect to the development of contemporary cancer therapeutics.

Distinctive features

• A broad ranging course that covers basic molecular cancer cell biology through to translational research and therapeutics.

• A course developed in collaboration with researchers, academics and clinicians and delivered by leading academic cancer researchers at Cardiff University.

• Key lectures and case study workshops delivered by practising oncologists and cancer surgeons.

• Opportunity to study at Cardiff University, one of the UK’s major teaching and research universities.

• Opportunity to undertake a research project in one of the internationally recognized cancer research groups at Cardiff.

• Close academic support from an experienced personal tutor.
Opportunity to join a vibrant postgraduate community studying at Cardiff.

Structure

This is a full-time course over one academic year. You will study 180 credits: 120 of taught material, followed by a 60 credit project.

Core modules:

Data Handling and Statistics
Cellular and Molecular Biology of Cancer
Translational Oncology and Therapeutics
Academic Research Skills
Research Methodology
Research Project

Teaching

The programme will provide advanced teaching in the cellular aspects of cancer biology together with the molecular mechanisms underlying cancer development and progression. In-depth training will be provided in the area of cancer therapeutics, encompassing biomarkers and diagnosis, therapeutic targets, drug discovery and clinical trials and chemo/radio therapy, in addition to developing the student’s theoretical and practical research skills.

Assessment

Assessment for the course will comprise a combination of exams, written essays, posters, laboratory coursework and case studies.

Career Prospects

Graduates from this course should gain a breadth and depth of cancer-focused training that could make them highly attractive candidates to start or continue a career within the healthcare sector and research establishments.

Potential employment opportunities include PhD student, research technician, medical laboratory science officer, clinical trials co-ordinator, and medical writer.

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Translational Cancer Medicine enables you to gain detailed knowledge and understanding of research methods applied to rational drug design, clinical study design, molecular and cell biology, tumour immunology, genetics and cancer imaging. Read more
Translational Cancer Medicine enables you to gain detailed knowledge and understanding of research methods applied to rational drug design, clinical study design, molecular and cell biology, tumour immunology, genetics and cancer imaging. Practical experience gained through two six-month laboratory rotations.

Key benefits

- The range of topics including advanced imaging methods is unique for this translational cancer programme

- The sponsoring laboratories and departments all have international standing and have agreed to closely supervise the trainees

- Recently released data from the Higher Education Funding Council for England (Hefce) shows that King’s College London is equal top in England (with Queen Mary, University of London) for its PhD completion rates. This programme will potentially select candidates for the PhD programme within the Division of Cancer Studies

Visit the website: http://www.kcl.ac.uk/study/postgraduate/taught-courses/translational-cancer-medicine-mres.aspx

Course detail

- Description -

Overview of subjects covered:

• Biomarkers, biostatistics and modelling
• Breast cancer
• Cancer bioinformatics
• Cancer imaging (optical)
• Cancer imaging (PET)
• Clinical trials and translational research
• Gene discovery through to therapeutic applications
• Haemato-oncology and associated genetics/genomics
• Immunology of cancers
• Molecular pathology
• Signal transduction in cancers

- Course purpose -

The programme will provide students with a detailed knowledge and understanding of research methods applied to rational drug design, clinical study design, molecular and cell biology, tumour immunology, genetics and cancer imaging, all of which are relevant to Translational Cancer Research. In addition, practical experience will be gained through two laboratory rotations of six months duration.

- Course format and assessment -

Work with 2 supervisors and their teams, 6 months in each lab

Assignments:

• 30 credit taught module:

2-3 weekly lectures during first 3 months

Throughout the year, students also attend literature reviews and journal clubs that their labs/departments organise and any other internal or external seminars deemed relevant to their projects/assignments.

The assessment for this module is an essay on the fundamentals and the overall concept of Translational Cancer Medicine

• 75 credit laboratory based research project 1:

Assessed by a written dissertation, a seminar presentation and an oral examination

• 75 credit laboratory based research project 2:

Assessed by a draft of a paper of the standard and format required by a scientific journal.

Career prospects

Future PhD studies. Clinical and non-clinical academic careers in cancer medicine.

How to apply: http://www.kcl.ac.uk/study/postgraduate/apply/taught-courses.aspx

About Postgraduate Study at King’s College London:

To study for a postgraduate degree at King’s College London is to study at the city’s most central university and at one of the top 20 universities worldwide (2015/16 QS World Rankings). Graduates will benefit from close connections with the UK’s professional, political, legal, commercial, scientific and cultural life, while the excellent reputation of our MA and MRes programmes ensures our postgraduate alumni are highly sought after by some of the world’s most prestigious employers. We provide graduates with skills that are highly valued in business, government, academia and the professions.

Scholarships & Funding:

All current PGT offer-holders and new PGT applicants are welcome to apply for the scholarships. For more information and to learn how to apply visit: http://www.kcl.ac.uk/study/pg/funding/sources

Free language tuition with the Modern Language Centre:

If you are studying for any postgraduate taught degree at King’s you can take a module from a choice of over 25 languages without any additional cost. Visit: http://www.kcl.ac.uk/mlc

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This programme is offered by the UCL Division of Medicine and the Wolfson Institute for Biomedical Research and is designed for the more research-oriented student, complementing Drug Design MSc. Read more
This programme is offered by the UCL Division of Medicine and the Wolfson Institute for Biomedical Research and is designed for the more research-oriented student, complementing Drug Design MSc. Conducting cutting-edge research within the drug industries and UCL's academic group, it offers opportunities for networking and future career development.

Degree information

This programme teaches students the latest methodologies and approaches and covers all aspects of drug design: drug discovery, computational and structural biology, screening, assay development, medicinal chemistry, and most importantly the industrial practices involved in modern drug design technology.

Students undertake modules to the value of 180 credits.

The programme consists of two core modules (30 credits), three optional modules (45 credits) and a dissertation/report (105 credits).

Optional modules - students will select three from the following Drug Design MSc modules:
-Bioinformatics and Structural Biology as applied to Drug Design
-Biological Molecules as Therapeutics
-Biophysical Screening Methods, X-ray Crystallography, Protein NMR and Phenotypic Screening
-Cheminformatics and Modelling for Drug Design
-Fragment-based Drug Design
-Target Selection – Commercial and Intellectual Property Aspects
-Target Selection – Scientific Grounds

Core modules - plus two taught transferable skills modules delivered by CALT (UCL Centre for the Advancement of Learning and Teaching):
-Investigating Research
-Researcher Professional Development

Dissertation/report
All students undertake an independent research project which culminates in a dissertation of 15,000 to 20,000 words.

Teaching and learning
The programme is delivered through a combination of lectures, seminars, tutorials and problem classes, critical journal clubs and a research project. Assessment is through coursework, practicals, laboratory work, examination, dissertation and oral presentation.

Careers

We expect students graduating from this programme to take leading roles in drug discovery and development worldwide or to undertake further PhD level research. The first cohort of students on the Drug Design MRes graduating in 2015 have found jobs in the pharmaceutical industry as well as PhD studentships in leading universities.

Employability
The advanced knowledge and skill set acquired by taking this programme will enable students to find employment in the pharmaceutical and biotech industries in a global market.

Why study this degree at UCL?

The division hosts research groups in the areas of medicine, pharmaceutical research, cell cycle, neurobiology, mitochondrial function, stem cells and cancer. Underpinning the translational aspects of the biomedical research, we have a medicinal chemistry group which conducts research where chemistry and biology intersect, using the latest techniques and developing new ones for the study of biological systems.

The division collaborates extensively within industry and academia to develop biological tools and therapeutic agents. There are plenty of opportunities to conduct translational research that has an impact on drug discovery.

Pharmaceutical and biotech companies, well established in the West, have been transferring their research and development to the East. Given these substantial developments, particularly in China and India, the programme will have a broad international appeal.

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Clinicians, scientists and students engaged in cancer research at Newcastle share a common purpose. to improve treatment outcomes for patients with cancer. Read more
Clinicians, scientists and students engaged in cancer research at Newcastle share a common purpose: to improve treatment outcomes for patients with cancer. Work covers a broad spectrum - understanding the biological and molecular differences between normal and malignant cells and using this knowledge to develop new anti-cancer drugs.

Our staff and postgraduate students are based in the Northern Institute for Cancer Research (NICR) or the School of Chemistry. The NICR incorporates the Newcastle Cancer Centre, a unique collaboration between Cancer Research UK and the North of England Children's Cancer Research Fund.

We are a major training base for the next generation of cancer researchers. Our Institute covers many areas of cancer research, including:
-Solid tumours and leukaemias
-Childhood and adult cancers
-Drug discovery and early phase clinical trials

We offer approximately 15 MD, PhD and integrated MRes/PhD studentships each year, including the Newcastle Cancer Centre training programme. Projects in all research areas are available to fully-funded international students.

Members of our postgraduate community come from a variety of subject backgrounds including biological and biomedical sciences, chemistry, genetics, pharmacy, medicine, dentistry and veterinary medicine.

We hold regular postgraduate seminars which you will be required to attend and where you will deliver presentations. You will also attend and present your data annually at national cancer research meetings and at least one international meeting.

Placements

Our Institute has close working relationships with companies in the pharmaceutical and biotechnology sectors.

A number of our studentships are direct collaborations with industrial partners, with opportunities to spend placements with these partners.

Facilities

Our staff and postgraduate students are based in the Northern Institute for Cancer Research (NICR) or the School of Chemistry (medicinal chemistry students).

Our laboratories contain a full range of contemporary genomic, bioinformatic, proteomic, synthetic chemistry and pharmacology equipment, and clinical research facilities.

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The programme is designed for graduates with a biological background and builds on existing core biosciences modules in the area of applied biotechnology. Read more
The programme is designed for graduates with a biological background and builds on existing core biosciences modules in the area of applied biotechnology. It gives a grounding in the early stage drug discovery process for those interested in careers in biotechnology or the pharmaceutical industry.

The MSc covers application of technologies to early stage drug discovery focusing on target identification, target validation, and lead discovery and design follow-up through understanding protein ligand interactions and biophysics at a molecular level in order to produce good drug candidate molecules via rational drug design.

The programme also includes site visits to biotechnology companies and industry, plus workshops/lectures from invited industrial experts.

Visit the website: https://www.kent.ac.uk/courses/postgraduate/227/drug-design

About the School of Biosciences

The School of Biosciences is among the best-funded schools of its kind in the UK, with current support from the BBSRC, NERC, MRC, Wellcome Trust, EU, and industry. It has 38 academic staff, 56 research staff (facility managers, research fellows, postdoctoral researchers and technicians), approximately 100 postgraduate students and 20 key support staff. The school's vibrant atmosphere has expanded to become a flourishing environment to study for postgraduate degrees in a notably friendly and supportive teaching and research environment.

Research in the School of Biosciences revolves around understanding systems and processes in the living cell. It has a strong molecular focus with leading-edge activities that are synergistic with one another and complementary to the teaching provision. Our expertise in disciplines such as biochemistry, microbiology and biomedical science allows us to exploit technology and develop groundbreaking ideas in the fields of genetics, molecular biology, protein science and biophysics. Fields of enquiry encompass a range of molecular processes from cell division, transcription and translation through to molecular motors, molecular diagnostics and the production of biotherapeutics and bioenergy.

In addition to research degrees, our key research strengths underpin a range of unique and career-focused taught Master’s programmes that address key issues and challenges within the biosciences and pharmaceutical industries and prepare graduates for future employment.

Course structure

The MSc in Drug Design involves studying for 120 credits of taught modules, as indicated below. The taught component takes place during the autumn and spring terms, while a 60-credit research project take place over the summer months.

The programme is taught by staff from the Biosciences, Industrial Biotechnology Centre and industrial scientists who all have experience of working with the drug industry (both large pharma and biotech).

In additional to traditional scientific laboratory reports, experience is gained in a range of scientific writing styles relevant to future employment.

Modules

The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

BI827 - Advanced Drug Design (30 credits)
BI830 - Science at Work (30 credits)
BI836 - Practical and Applied Research Skills for Advanced Biologists (30 credits)
BI840 - Cancer Therapeutics: From the Laboratory to the Clinic (15 credits)
BI852 - Advanced Analytical and Emerging Technologies for Biotechnology and Bio (30 credits)
BI857 - Cancer Research in Focus (15 credits)
CB612 - New Enterprise Startup (15 credits)
BI845 - MSc Project (60 credits)

Assessment

Assessment is by coursework and the dissertation.

Programme aims

This programme aims to:

- provide students with an academic framework to underpin your career in the pharmaceutical, biotechnology industry or applied translational research in an academic environment

- give you an understanding of the process of academic investigation in a range of academic disciplines relevant to drug design

- provide a stimulating, research-active environment for teaching and learning in which you are supported and motivated to achieve your academic and personal potential

- facilitate a valuable learning experience through a variety of teaching and assessment methods that will promote the assimilation, comprehension, analysis application, synthesis and evaluation of the knowledge base

- give you the experience of undertaking an independent research project or dissertation

- prepare students for further training and employment both in science and non-science based careers by developing transferable and cognitive skills

- develop the qualities needed for employment in situations requiring the exercise of professionalism, independent thought, personal responsibility and decision-making in complex and unpredictable circumstances

- provide access to as wide a range of students as practicable irrespective of race, background, gender or physical disability from both within the UK and from overseas.

Careers

A postgraduate degree in the School of Biosciences is designed to equip our graduates with transferable skills that are highly valued in the workplace. Our research-led ethos ensures that students explore the frontiers of scientific knowledge, and the intensive practical components provide rigorous training in cutting edge technical skills that are used in the modern biosciences while working in areas of world-leading expertise within the School.

Destinations for our graduates include the leading pharmaceutical and biotechnological companies within the UK and leading research institutes both at home and abroad.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply-online/227

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This MSc offers a comprehensive guide to all aspects of modern day drug design. It is taught by research scientists, clinicians and industry experts. Read more
This MSc offers a comprehensive guide to all aspects of modern day drug design. It is taught by research scientists, clinicians and industry experts. Our graduates have progressed to undertake or obtain PhDs or medical studentships, or have found employment in both the private and public sector.

Degree information

The programme covers all aspects of drug design, including genomics, bioinformatics, structural biology, cheminformatics, molecular modelling and fragment-based drug design, drug target selection, intellectual property and marketing. New therapies and research areas such as antibodies, siRNA, stem cells and high throughput screening are covered. Students will develop essential skills such as research methods and techniques of drug design.

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 (120 credits) is also offered. A Postgraduate Certificate (60 credits) is also offered. There are no optional modules for this programme.

Core modules
-Bioinformatics and Structural Biology
-Target Identification and High Throughput Screening
-Cheminformatics and Computer Drug Design
-Biological Molecules as Therapeutics - Antibodies, siRNA, and Stem Cells
-Biophysical Screening Methods, Protein NMR and Phenotypic Screening
-Fragment Based Drug Design (FBDD)
-Target Selection - Scientific Grounds
-Target Selection - Commercial and Intellectual Property

Dissertation/report
All MSc students undertake an independent research project which can take the form of a literature project, wet lab/computer modelling based project or an external project with an industrial sponsor.

Teaching and learning
The programme is delivered through a combination of lectures, tutorials, self study, practical sessions and discussion groups. The research project forms one third of the programme. Each of the taught modules is assessed by unseen written examination (50%) and coursework (50%). The research project is assessed by the dissertation and viva.

Careers

The programme will provide a good background for students looking to establish a career in drug design/discovery and related industries (biotech, pharma, national research laboratories and NHS agencies), and for industry professionals seeking to gain a greater understanding of new methodology. The knowledge and transferable skills delivered will also be useful for those intent on further PhD or medical studies.

Top career destinations for this degree:
-Industrial Chemistry, University of Oxford
-PhD Researcher (Molecular Biology), EMBL (European Molecular Biology Laboratory)
-Cancer Research, Imperial College London
-PhD Drug Design, University College London (UCL)
-PhD Oncology, Tianjin University

Employability
Graduates from this programme have progressed to PhD/medical studentships at different universities and research institutes around the world, including Oxford, UCL, Grenoble, EMBL, and in the USA and China. Many alumni have secured positions in research teaching and technical sales in the private and public sectors.

Why study this degree at UCL?

UCL is listed among the top five universities in the TImes Higher Education QS World University Rankings 2015/16 and is located in the centre of one of the world's finest cities. UCL is one of Europe's best and largest centres for biomedical research.

At the Wolfson Institute for Biomedical Research, we have pioneered multidisciplinary research with a particular emphasis on translating that research into useful clinical benefit. Our research expertise includes: medicinal chemistry, computational drug design, neuronal development and signalling, cell cycle control, intensive care medicine, stem cells, mitochondrial biology and cancer.

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The use of chemotherapeutic agents to target and kill cancer cells is a central strategy in the treatment of cancers. This course describes the nature of the disease at the systems, cellular and molecular levels, and focuses on the drugs which are used to treat different cancers and on how they work. Read more
The use of chemotherapeutic agents to target and kill cancer cells is a central strategy in the treatment of cancers. This course describes the nature of the disease at the systems, cellular and molecular levels, and focuses on the drugs which are used to treat different cancers and on how they work.

More about this course

Worldwide the incidence of cancer is increasing, and is expected to reach 22 million new cases per year by 2030. In addition to treatments such as radiotherapy and surgery, chemotherapy has a vital role to play in prolonging the lives of patients.

The aims of this course are to:
-Provide you with an in-depth understanding of the molecular targets at which the different classes of anticancer drugs are aimed, and of how drug therapies are evolving;
-Review the biology of cancer with respect to genetics, pathological considerations, and the molecular changes within cells which are associated with the progression of the disease;
-Enhance intellectual and practical skills necessary for the collection, analysis, interpretation and understanding of scientific data;
deliver a programme of advanced study to equip you for a future career in anti-cancer drug development.

Assessment is a combination of coursework, which includes tests and essays, the research project and its oral defence and examination.

Modular structure

The modules listed below are for the academic year 2016/17 and represent the course modules at this time. Modules and module details (including, but not limited to, location and time) are subject to change over time.

Year 1 modules include:
-Cancer Pharmacology (core, 20 credits)
-Cancer: Diagnosis and Therapy (core, 20 credits)
-Medical Genetics (core, 20 credits)
-Molecular Oncology (core, 20 credits)
-Research Project (core, 60 credits)
-Scientific Frameworks for Research (core, 20 credits)
-Advanced Drug Formulation Technologies (option, 20 credits)
-Bioinformatics and Molecular Modelling (option, 20 credits)
-Drug Discovery Technology (option, 20 credits)

After the course

This course is primarily designed for those wishing to pursue a career in anti-cancer drug development, whether in academia or within the pharmaceutical industry. The programme provides an excellent basis for further research or study.

Moving to one campus

Between 2016 and 2020 we're investing £125 million in the London Metropolitan University campus, moving all of our activity to our current Holloway campus in Islington, north London. This will mean the teaching location of some courses will change over time.

Whether you will be affected will depend on the duration of your course, when you start and your mode of study. The earliest moves affecting new students will be in September 2017. This may mean you begin your course at one location, but over the duration of the course you are relocated to one of our other campuses. Our intention is that no full-time student will change campus more than once during a course of typical duration.

All students will benefit from our move to one campus, which will allow us to develop state-of-the-art facilities, flexible teaching areas and stunning social spaces.

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Before any new therapy can be used, a thorough identification of its toxicity and safety is required. Therefore, drug toxicology and safety pharmacology are central to the chemical and pharmaceutical industries, and demand for 'pre-trained' employees is extremely high. Read more
Before any new therapy can be used, a thorough identification of its toxicity and safety is required. Therefore, drug toxicology and safety pharmacology are central to the chemical and pharmaceutical industries, and demand for 'pre-trained' employees is extremely high.

Hosted by the Institute of Cancer Therapeutics, the course addresses key aspects of preclinical drug evaluation through the study of drug discovery and development; safety pharmacology; mechanisms of drug-induced toxicities; regulatory affairs and bioanalytical sciences.

It will provide you with state-of-the-art training in the area of preclinical toxicology with an emphasis on the molecular and in vivo aspects of toxicological assessment.

It is designed for individuals with a first degree in a scientific disciple who want to specialise in new medicines development or undertake employment in the pharmaceutical industry.

Why Bradford?

-Includes seminars by scientists from regulatory agencies and pharmaceutical companies
-This course is designed to meet the demand of employers and provide you with a comprehensive overview of the drug safety discipline within the drug development process

Modules

-Critical Appraisal of a Current Topic in Safety Pharmacology
-Preclinical Models for Drug Evaluation
-Research and Analytical Methods in Pharmacology
-Toxicology and Safety Pharmacology
-Experimental Design
-Molecular Mechanisms of Toxicity
-Research Project (Safety Pharmacology)

Career support and prospects

The University is committed to helping students develop and enhance employability and this is an integral part of many programmes. Specialist support is available throughout the course from Career and Employability Services including help to find part-time work while studying, placements, vacation work and graduate vacancies. Students are encouraged to access this support at an early stage and to use the extensive resources on the Careers website.

Discussing options with specialist advisers helps to clarify plans through exploring options and refining skills of job-hunting. In most of our programmes there is direct input by Career Development Advisers into the curriculum or through specially arranged workshops.

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This programme gives you in-depth knowledge of the scientific basis of drug discovery and development, which has revolutionised the pharmaceutical industry in recent years. Read more
This programme gives you in-depth knowledge of the scientific basis of drug discovery and development, which has revolutionised the pharmaceutical industry in recent years. Our involvement with international drug companies has allowed us to keep our courses fully up-to-date. With our excellent facilities, emphasis on practical work, and teaching underpinned by the latest research, you will be qualified for research and development positions in pharmaceutical companies, as well as a wide range of other roles in industry.

About the course

The programme will have a heavy emphasis on practical work and will cover the following areas:
-Pharmacological and relevant physiological principles
-Molecular biology techniques in pharmacology
-The application of bioinformatics to drug discovery
-Quantitative aspects of pharmacology
-Case studies in drug discovery
-Molecular medicine
-Neuro-degenerative diseases
-Safety evaluationResearch project

You will undertake a practical project as part of your MSc enabling you to use our excellent facilities and to gain experience working alongside researchers in our Pharmacology Research Group. Current research projects include studies in:
-Gastrointestinal pharmacology, particularly with respect to diabetes
-Angiogenesis
-Cancer
-Cannabinoids as therapeutic agents
-Molecular pharmacology of vascular disease
-Modelling pharmacokinetics

Why choose this course?

-This is an intensive programme that will provide training in pharmacology, molecular biology and their application to drug discovery, using a problem based learning approach
-You will receive training in a range of pharmacological and molecular practical techniques as well as completing a research project
-Upon completion, you will be able to enter a successful career in the pharmaceutical industry or pursue further postgraduate research
-The School of Life and Medical Science will move into a brand new science building opening in September 2015 providing us with world class laboratories for our teaching and research. At a cost of £50M the new building provides spacious naturally lit laboratories and social spaces creating an environment that fosters multi-disciplinary learning and research

Careers

Graduates of the programme will be qualified for research and development positions in the pharmaceutical industries, to progress to a research degree or to consider regulatory, marketing or management roles in industry.

Teaching methods

Upon entering the programme, students are provided with introductory material to facilitate their transition to Master's level study. Cellular Molecular Biology is taught in parallel with Core Pharmacology, which both involve a high proportion of practical work. Students will experience a range of learning styles including conventional lectures, workshops and problem based learning. Teaching in Molecular Medicine and Pharmacovigilance & Drug Discovery Development uses case studies to foster skills such as working independently or as part of a team, demonstrating initiative and problem solving. You will also study a module in Biosciences Research Methods for Masters. All assessments are coursework only (including in-class tests), which are strategically phased throughout the course to provide regular feedback.

Structure

Modules
-Biosciences Research Methods for Masters
-Cellular Molecular Biology
-Core Pharmacology
-Drug Discovery Development and Pharmacovigilance
-Molecular Medicine
-Project-Mol Biology, Biotechnology, Pharmacology

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