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Materials are at the forefront of new technologies in medicine and dentistry, both in preventative and restorative treatment. Read more
Materials are at the forefront of new technologies in medicine and dentistry, both in preventative and restorative treatment. This programme features joint teaching within the School of Engineering and Materials Science and the Institute of Dentistry, bringing together expertise in the two schools to offer students a fresh perspective on opportunities that are available in the fields of dental materials.

* This programme will equip you with a deep understanding of the field of dental materials and the knowledge necessary to participate in research, or product development.
* An advanced programme designed to develop a broad knowledge of the principles underlying the mechanical, physical and chemical properties of Dental Materials.
* Special emphasis is placed on materials-structure correlations in the context of both clinical and non clinical applications.
* Provides an introduction to materials science, focusing on the major classes of materials used in dentistry including polymers, metals, ceramics and composites.
* Provides up-to-date information on dental materials currently used in Clinical Dentistry and in developments for the future It covers the underlying principles of their functional properties, bioactivity and biocompatibility, and also covers specific dental materials applications such as drug delivery, tissue engineering and regulatory affairs.

Why study with us?

Dental Materials is taught jointly by staff from the School of Medicine and Dentistry (SMD), and School of Engineering and Materials Science (SEMS).

Our school of medicine and dentistry is comprised of two world renowned teaching hospitals, Barts and The London School of Medicine and Dentistry, which have made, and continue to make, an outstanding contribution to modern medicine. We are ranked sixth in the UK for medicine (Complete University Guide 2012), and Dentistry was placed at number two in the UK in last Research Assessment Exercise (2008). Our Materials Department was the first of its kind established in the UK, and was placed at number 1 in the UK in the 2011 National Student Survey.

This degree is aimed at dental surgeons, dental technicians, materials scientists and engineers wishing to work in the dental support industries, and the materials health sector generally. On completion of the course you should have a good knowledge of topics related to dental materials, and in addition, be competent in justifying selection criteria and manipulation instructions for all classes of materials relevant to the practice of dentistry.

There has been a general move away from destructive techniques and interventions towards less damaging cures and preventative techniques. This programme will update your knowledge of exciting new technologies and their applications.

* The programme is taught by experts in the field of dentistry and materials; they work closely together on the latest developments in dental materials.
* Innovations in medical practice, drug development and diagnostic tools are often tested in the mouth due to simpler regulatory pathways in dentistry.
* The programme allows practitioners the opportunity to update their knowledge in the latest developments in dental materials.

Facilities

You will have access to state-of-the-art laboratories and equipment, including:

* Cell & Tissue Engineering Laboratories; five dedicated cell culture laboratories, a molecular biology facility and general purpose laboratorie
* Confocal microscopy unit incorporating two confocal microscopes, enabling advanced 3D imaging of living cells
* Mechanical Testing Facilities
* NanoVision Centre; our state-of-the-art microscopy unit bringing together the latest microscope techniques for structural, chemical and mechanical analysis at the nanometer scale
* Spectroscopy Lab
* Thermal Analysis Lab.

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In recent years the study of plant sciences has been revolutionised by the development of new tools and technologies which have allowed unprecedented progress in the study of plant biology – knowledge which is being applied to develop sustainable solutions to some of the major challenges of the 21st century. Read more

In recent years the study of plant sciences has been revolutionised by the development of new tools and technologies which have allowed unprecedented progress in the study of plant biology – knowledge which is being applied to develop sustainable solutions to some of the major challenges of the 21st century.

This course will give you specialist training in the modern molecular aspects of plant science. A large part of your teaching will be delivered by academics from the University’s Centre for Plant Sciences (CPS) linked to the latest research in their areas of expertise.

You’ll explore the wide ranges of approaches used in biomolecular sciences as applied to plant science. This will cover theory and practice of recombinant DNA and protein production, bioimaging using our confocal microscope suite, practical bioinformatics and theories behind ‘omic technologies.

You’ll also learn how to design a programme of research and write a research proposal, read and critically analyse scientific papers in plant science and biotechnology and present the findings. A highlight of the course is your individual 80 credit practical research project.

The course is 100% coursework assessed (although some modules have small in course tests). Our teaching and assessment methods are designed to develop your independent thinking, problem solving, communication skills and practical ability, making you attractive to employers or providing an excellent foundation for further study (eg PhD).

You’ll study in a faculty ranked 6th in the UK for its research impact in the recent Research Excellence Framework (REF 2014).

Our Facilities

You’ll study in a stimulating environment which houses extensive facilities developed to support and enhance our faculty’s pioneering research. As well as Faculty operated facilities, the CPS laboratories are well equipped for general plant research. There is also a plant growth unit, including tissue culture suites with culture rooms, growth rooms and flow cabinets alongside transgenic glass-houses to meet a range of growth requirements.

Course content

On this course you’ll gain an overview of a range of modern techniques and methodologies that underpin contemporary biomolecular plant sciences.

You’ll also apply your knowledge to an extended practical investigation in the form of a laboratory-based mini project, involving practical training in a range of modern molecular biology and protein engineering techniques such as gene cloning, PCR, mutagenesis, protein expression, protein purification and analysis.

A module on plant biotechnology will address current topics such as the engineering of plants, development of stress-tolerant crop varieties and techniques for gene expression and gene silencing through reading discussion and critical analysis of recent research papers.

You’ll learn from the research of international experts in DNA recombination and repair mechanisms and their importance for transgene integration and biotechnological applications; plant nutrition and intracellular communication; and the biosynthesis, structure and function of plant cell walls.

You’ll also explore the wide range of approaches used in bio-imaging and their relative advantages and disadvantages for analysing protein and cellular function. Bioinformatics and high throughput omic technologies are crucial to plant science research and you will take modules introducing you to these disciplines.

In the final part of the course you'll work on an independent laboratory-based research project related to your course options. You’ll receive extensive training in experimental design, the practical use of advanced techniques and technologies, data analysis and interpretation, and will be assigned a research project supervisor who will support and guide you through your project.

Course structure

Compulsory modules

  • Bioimaging 10 credits
  • Topics in Plant Science 10 credits
  • Practical Bioinformatics 10 credits
  • Plant Biotechnology 10 credits
  • High-throughput Technologies 10 credits
  • MSc Bioscience Research Project Proposal 5 credits
  • Research Planning and Scientific Communication 10 credits
  • Advanced Biomolecular Technologies 20 credits
  • Protein Engineering Laboratory Project 15 credits
  • Bioscience MSc Research Project 80 credits

For more information on typical modules, read Plant Science and Biotechnology MSc in the course catalogue

Learning and teaching

You’ll have access to the very best learning resources and academic support during your studies. We’ve been awarded a Gold rating in the Teaching Excellence Framework (TEF, 2017), demonstrating our commitment to delivering consistently outstanding teaching, learning and outcomes for our students.

Your learning will be heavily influenced by the University’s world-class research as well as our strong links with highly qualified professionals from industry, non-governmental organisations and charities.

You’ll experience a wide range of teaching methods including formal lectures, interactive workshops, problem-solving, practical classes and demonstrations.

Through your research project and specialist plant science modules, you’ll receive substantial subject-specific training. Our teaching and assessment methods are designed to develop you into a scientist who is able to think independently, solve problems, communicate effectively and demonstrate a high level of practical ability.

Assessment

We use a variety of assessment methods: multiple-choice testing, practical work, data handling and problem solving exercises, group work, discussion groups (face-to-face and online), computer-based simulation, essays, posters and oral presentations.

Career opportunities

The strong research element of the Plant Science and Biotechmology MSc, along with the specialist and generic skills you develop, mean you’ll graduate equipped for a wide range of careers.

Our graduates work in a diverse range of areas, ranging from bioscience-related research through to scientific publication, teacher training, health and safety and pharmaceutical market research.

Links with industry

We have a proactive Industrial Advisory Board who advise us on what they look for in graduates and on employability-related skills within our courses.

We collaborate with a wide range of organisations in the public and commercial sectors. Many of these are represented on our Industrial Advisory Board. They include:

  • GlaxoSmithKline
  • Ernst and Young
  • The Food and Environment Research Agency
  • The Health Protection Agency
  • MedImmune
  • Thermofisher Scientific
  • Hays Life Sciences
  • European Bioinformatics Institute
  • Smaller University spin-out companies, such as Lumora.

Industrial research placements

Some of our partners offer MSc research projects in their organisations, allowing students to develop their commercial awareness and build their network of contacts.



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As a graduate in the life-sciences, this MSc in Reproductive and Developmental Biology can help you reach the next stage of your career - be that PhD posts, entry to medical school, or clinical speciality training. Read more

Developing your knowledge and skills for a scientific/clinical career

As a graduate in the life-sciences, this MSc in Reproductive and Developmental Biology can help you reach the next stage of your career - be that PhD posts, entry to medical school, or clinical speciality training. With both a full-time MSc and a PGCert (Postgraduate Certificate) on offer, you can choose the pathway most suited to you, and use the specific scientific skills and the transferable skills we give you to take the next step.

Is this programme for you?

Applicants to this course are looking to improve your theoretical knowledge in the areas of reproductive and developmental biology, alongside gaining practical skills within a vibrant research environment.

Please note that we do not provide training in any technologies or techniques of Assisted Reproduction (IVF); however, previous students have gained places on the highly competitive Scientist Training Programme that is now required for those who wish to work as embryologists within the NHS.

You will need to be an independent person, who is looking for a challenge. If you're not afraid of hard work, then we would welcome an application from you.

Application

Offers are made on a first-come, first served basis. Once places are filled, we will close to new applications, so ensure that you submit your application sooner, rather than later.

You will receive notification of a conditional offer or rejection in the weeks following your submission. If you do not hear from us, it is because you have been placed on the waiting list.

Please note that we are unable to consider your application without at least one academic reference from your most recent institution.

Programme structure

Both courses start with six months of teaching on our current understanding of key topics in reproductive and developmental biology. This is split into 6 topics:

•Development of the Male and Female Reproductive Systems
•Endocrinology - Activation of the Gonads and Regulation of Gametogenesis
•Fertilisation and Early Embryo Development
•Experimental Approaches to Improved Understanding of Reproduction and Development
•Pregnancy
•Development and Stem Cell Biology

During this taught component, you will receive practical training in, for example:

•Microscopy (dissection, confocal, and fluorescence)
•QPCR
•Western Blotting

You will be assessed throughout the course component, with the PG Certificate concluding with the final examination in March. At this point, MSc students will enter their research project.

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One of the most rapidly developing areas of toxicology is the use of molecular, cell biology and omics to identify adverse outcome pathways (AOPs) and to develop a mechanistic understanding of chemical toxicity at the cellular and molecular level. Read more
One of the most rapidly developing areas of toxicology is the use of molecular, cell biology and omics to identify adverse outcome pathways (AOPs) and to develop a mechanistic understanding of chemical toxicity at the cellular and molecular level. This is not only of fundamental interest (i.e., understanding the mechanism of action) but it also relates to an increased need for a mechanistic component in chemical risk assessment and development of high throughput screens for chemical toxicity.

The MRes in Molecular Mechanistic Toxicology is a one-year full-time programme that provides students with a research-orientated training in a lively, highly interactive teaching and research environment.

Programme content

The programme is coordinated by the School of Biosciences, which is recognised internationally as a major centre for both teaching and research in Toxicology. Molecular Toxicology is a major component of the School of Biosciences research activities along with interactions with other departments including Chemistry and the Medical School.

Specific areas of active research include:

- Mechanisms of cell toxicity
- Development of novel DNA binding chemicals
- Cellular proliferation and differentiation
- Environmental genomics and metabolomics
- Molecular biomarkers of genotoxicity, oxidative stress and cellular responses
- Role of environmental and genetic factors in disease
- Learning and teaching

Two five-week taught modules are held in Semester 1 in conjunction with the taught MSc in Toxicology programme. Training in generic and laboratory research skills is also an important element of the programme. The programme also includes a six-month research project, which provides students with an opportunity for further advanced research training and hands-on experience of molecular and cellular biology techniques embedded in a research laboratory. Research projects can take place either in academic or industrial institutions.

About the School of Biosciences

As one of the top biosciences departments in the UK, our research covers the entire spectrum of cutting-edge biosciences. We are home to the Institute of Microbiology and Infection and part of the University’s Systems Science for Health initiative.
Our research focuses on a number of important themes that run through modern biological and biochemical research: Biosystems and Environmental Change; Microbiology and Infection; Molecules, Cells, Signalling and Health; and Plant Science.
Our postgraduate students join a diverse international community of staff and students. For students on research degrees, the annual Biosciences Graduate Research Symposium, organised by PhD students, is an example of an event where the whole School comes together to talk about science.
We have extensive high-technology facilities in areas such as functional genomics, proteomics and metabolomics, including a world-class Advanced Mass Spectrometry Facility. Our cutting-edge facilities extend to protein structure determination and analysis, confocal microscopy, drug discovery, horticulture, structural biology and optical imaging. The £8 million Phenome Centre Birmingham is a large metabolic phenotyping facility led by internationally recognised metabolomics and clinical experts at the University of Birmingham, in collaboration with Birmingham Health Partners.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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Neuroscience is a discipline concerned with the scientific study of the nervous system in health and disease. Research in the neurosciences is of considerable clinical impact considering the debilitating and costly effects of neurological and psychiatric disease. Read more
Neuroscience is a discipline concerned with the scientific study of the nervous system in health and disease. Research in the neurosciences is of considerable clinical impact considering the debilitating and costly effects of neurological and psychiatric disease. In this regard, a major goal of modern neuroscience research is to elucidate the underlying causes (genetic or environmental) of major brain diseases, and to produce more effective treatments for major psychiatric disorders such as schizophrenia and depression, and neurological disorders such as multiple sclerosis, Parkinson's disease, Alzheimer's disease, motor neurone disease and epilepsy. Improved treatment strategies for brain disorders relies entirely on increased understanding gained from research which integrates molecular, cellular and clinical aspects of disease. In this regard it is clear that interdisciplinary approaches are necessary to understand the complex processes which underlie brain function in health and disease. This interdisciplinary philosophy is adopted in the delivery of our M.Sc. programme in Neuroscience, which is underpinned by the diverse research expertise available within Trinity College Institute of Neuroscience (TCIN).

Course Content:

This one-year M.Sc. course aims to provide a multidisciplinary training in the neurosciences, in topics ranging from molecular to behavioural. The course is ideal for students wishing to extend their specialised knowledge, and for those wishing to convert from their original degree discipline. The programme will equip participants with the skills necessary to progress into a career in biomedical, pharmaceutical or neuropsychological research. Instruction for the course consists of approximately 200 contact hours over two academic Terms to include lectures, laboratory practical sessions, journal club workshops and student-based seminars. Modules are assessed by a mixture of in course assessment and written examinations.

Specialist modules covered include:

Form and Function of the Nervous System, Biochemical Basis of Neuropharmacology, Neuropharmacology, Drug Development, Advanced Neuroimmunology, Experimental Neuroscience, Scientific Literature Skills, Neural Engineering, Neuroimaging Technology, Current Topics in Neuroscience, Cellular Neuroscience, and Research Skills.

The third Term consists of a research project on novel aspects of Neuroscience. Trinity College Institute of Neuroscience is a dynamic research environment with research spanning molecular/cellular neuroscience to clinical/translational neuroscience. Projects across these research areas may be undertaken in consultation with an expert supervisor. For students interested in a project in cellular/molecular neuroscience a range of cellular techniques such as tissue culture, immunocytochemistry, western immunobloting and immunoprecipitation, confocal microscopy, Immunoassays, flow cytometry, Real-time PCR, and high performance liquid chromatography are available. In addition, some projects will involve assessing behavioural, electrophysiological and neurochemical endpoints using in vivo models of neurological and psychiatric disease. For those with an interest in experimentation on human subjects, projects will be offered utilizing techniques such as functional magnetic resonance imaging and neurocognitive testing. A selection of national and international projects is also available, which involve collaboration with other academic institutes and pharmaceutical companies, in Ireland, UK and across Europe.

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The objective of this course is to introduce students to an inter-disciplinary approach to research, which utilises technologies and skills from a wide spectrum of scientific, engineering and clinical disciplines to address fundamental questions originating in biology and medicine. Read more

Course Objective

The objective of this course is to introduce students to an inter-disciplinary approach to research, which utilises technologies and skills from a wide spectrum of scientific, engineering and clinical disciplines to address fundamental questions originating in biology and medicine. During the course students will carry out a number of practicals. They will be introduced to selected advanced experimental techniques used in biomedical science and industry. The techniques include:
DNA-microarray and RT-PCR, Immunostaining and Confocal Microscopy, Scanning Electron Microscopy, Atomic Force Microscopy and Nano Hardness Tester, Mass Spectrometry, various chromatography methods and Infra-red spectroscopy.

Benefits of the Course

The programme offers the Biological Sciences graduate a means of achieving the mathematical, computational, and instrumentation skills necessary to work in biomedical science. Likewise the Physical Science/Engineering graduate will gain experience in aspects of cell biology, tissue engineering, and animal studies. The course work will draw mainly from courses already on offer to undergraduates in the Science faculty, but will also include new modules developed specifically for this course. Expertise from other research institutes and from industry will be used,where appropriate.

The course covers following areas:
Material Science and Biomaterials
Applied Biomedical Sciences
Cell & Molecular Biology: Advanced Technologies
Fundamental Concepts in Pharmacology
Human Body Structure
Protein Technology
Tissue Engineering
Bioinformatics
Radiation & Medical Physics
Molecular Medicine
Regulatory Compliance in Healthcare Manufacturing
Advanced Tissue Engineering
Introduction to Business
Scientific Writing

Career Opportunities

Graduates of the MSc in Biomedical Science with undergraduate degrees in engineering and science have gone on to work within the medical device and pharmaceutical industry, hospitals and academia.

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Pharmacy at Sunderland is ranked sixth in the country, according to The Guardian University Guide 2013. Read more
Pharmacy at Sunderland is ranked sixth in the country, according to The Guardian University Guide 2013.

Course overview

Do you want to contribute to the discovery and development of drugs that could potentially improve the health and well-being of millions of people? The UK has long been a leader in this complex technical area, in which each new drug requires around $1 billion of development work.

Our research-led teaching and state-of-the-art facilities make the University of Sunderland one of the UK's top locations for pharmaceutical science. Our strong links with the pharmaceutical industry ensure a flow of guest speakers and good contacts for your chosen Masters project/dissertation. Previous projects have involved collaborations with companies such as AstraZeneca, Pfizer and Helena Biosciences.

The course covers advanced pharmaceutics, pharmaceutical analysis, drug design, pharmacology, proteomics and pharmacogenomics. You will also cover regulatory processes for medicines, in line with ICH guidelines. The course is a direct response to employers’ search for postgraduates who have a mix of theoretical and practical skills and who will push boundaries in drug development.

With a Masters course, it’s important to consider the relevance of the research interests of tutors who will supervise your dissertation. At Sunderland, our interests include pharmaceutical analysis, process chemistry, various drug discovery programmes, and drug delivery systems, including those for large biological pharmaceuticals. Our academic team have produced some ‘world-leading’ research, according to the latest Research Excellence Framework (2014).

Course content

The course mixes taught elements with self-directed research. The topic of the project / dissertation is negotiated to fit both your personal interests and the expertise of Sunderland's supportive tutors. Modules on this course include:
Core modules
-Essential Research and Study Skills (20 Credits)
-Fundamentals for Pharmaceutical Science (20 Credits)
-The Pharmaceutical R&D Cycle and its Regulation (20 Credits)

Choose four out of the five following modules
-Advanced Pharmacology (15 Credits)
-Pharmacogenomics and Proteomics (15 Credits)
-Advanced Pharmaceutical Analysis (15 Credits)
-Advanced Drug Design (15 Credits)
-Advanced Pharmaceutics (15 Credits)

Choose one Masters option
-Double Project (60 Credits)
Or
-Double Dissertation (60 Credits)
Or
-Single Project (30 Credits) and Single Dissertation (30 Credits)

Teaching and assessment

We use a wide variety of teaching and learning methods which include lectures, seminars, open learning, laboratory work and group work.

The Masters project may involve collaboration with a pharmaceutical company. Previous projects have involved collaborations with companies such as AstraZeneca, Pfizer and Helena Biosciences.

Compared to an undergraduate course, you will find that this Masters requires a higher level of independent working and problem solving. Assessment methods include laboratory reports, oral presentations, case studies, critical reviews, examinations and the Masters project.

Facilities & location

This course is based in the Sciences Complex at our City Campus, which boasts multi-disciplinary laboratories and cutting-edge equipment thanks to multi-million pound investments.

Facilities for Pharmaceutics
We have pharmaceutical-related equipment for wet granulation, spray drying, capsule filling, tablet making, mixing inhalation, film coating and freeze drying. As well as standard pharmacopoeial test methods, such as dissolution testing, friability and disintegration, we also offer highly sophisticated test methods. These include rheometry, thermal analysis (differential scanning calorimetry and hot stage microscopy), tests for powder flow, laser diffraction, photon correlation spectroscopy, image analysis and laser confocal microscopy.

Facilities for Medicinal Chemistry
Our state-of-the-art spectroscopic facility allows us to confirm the structures of new molecules that could be potential pharmaceutical products and to investigate the structures of potential medicinal substances that have been isolated from plants. We are equipped with Liquid Chromatography-Nuclear Magnetic Resonance and Mass Spectroscopy (LC-NMR/MS) platforms; this is an exceptional facility for a university. We also have low and high resolution mass spectrometry, nuclear magnetic resonance and elemental analysis equipment. Our facilities allow you to gain hands-on experience of a wide range of analytical techniques such as atomic absorption spectroscopy and infra-red spectroscopy, which are of great importance in determining both ionic/metal content of pharmaceuticals and simple chemical structures respectively. You will also gain experience of revolutionary protein and DNA separation techniques, as well as Ultra High Performance Liquid Chromatography (x8) and Gas Chromatography for separating all kinds of samples of pharmaceutical or biomedical interest.

Facilities for Pharmacology
Our highly technical apparatus will give you first-hand experience of the principles of drug action and the effects of drugs on pharmacological and cellular models. As a result, you gain a better understanding of the effects of drugs on specific receptors located throughout the human body and related physiological effects.

University Library Services
We’ve got thousands of books and e-books on pharmaceutical and biomedical science, with many more titles available through the inter-library loan service. We also subscribe to a comprehensive range of print and electronic journals so you can access the most reliable and up-to-date academic and industry articles. Some of the most important sources for your studies include:
-Embase, which is a complex database covering drug research, pharmacology, pharmaceutics, toxicology, clinical and experimental human medicine, health policy and management, public health, occupational health, environmental health, drug dependence and abuse, psychiatry, forensic medicine and biomedical engineering/instrumentation
-PsycINF, which includes information about the psychological aspects of medicine, psychiatry, nursing, sociology, pharmacology and physiology
-PubMed, which contains life science journals, online books and abstracts that cover fields such as medicine, nursing, dentistry, veterinary medicine and health care
-Science Direct, which offers more than 18,000 full-text journals published by Elsevier
-Web of Science, which covers a broad range of science areas

Learning Environment
Sunderland Pharmacy School has a rich heritage in scientific studies and our degree courses are extremely well respected in the industry. We are fully plugged into relevant medical and pharmaceutical industry bodies, with strong links and an exchange of ideas and people. Your Masters project may involve collaboration with a pharmaceutical company, including working at their sites.

Employment & careers

Graduates from this course can pursue a variety of careers in the following areas; Drug Design, Pharmaceutical Analysis and Research, Pre-clinical Research in Experimental and Biological Studies, Formulation and Product Development, Pharmacogenomics and Proteomics, Clinical Research, Product Registration, Licensing and Regulatory Affairs.

Previous Sunderland graduates have been employed in companies such as GSK, Eisai, Reckitt Benckiser, Merck, Sharp & Dohme and Norbrook Laboratories.

Some students may apply for a PhD programme or those who already hold a Pharmacy degree can pursue MSc/PG Pharmaceutical Sciences for the Overseas Pharmacist Assessment Programme (OSPAP) and go through one-year pre-registration training.

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Sunderland is the only university in the north of England to offer an Overseas Pharmacist Assessment Programme (OSPAP) that is accredited by the General Pharmaceutical Council. Read more
Sunderland is the only university in the north of England to offer an Overseas Pharmacist Assessment Programme (OSPAP) that is accredited by the General Pharmaceutical Council.

Course overview

Pharmaceutical Sciences for the Overseas Pharmacist Assessment Programme (OSPAP) is designed for those who are qualified pharmacists outside the European Economic Area and who are now looking to become registered pharmacists in the UK.

Our course is one of a small number of courses that are accredited by the General Pharmaceutical Council. Their accreditation is based on quality reviews that ensure Sunderland is meeting the required standards.

Completing the OSPAP postgraduate diploma allows for entry to the next stages of registering as a pharmacist in the UK: firstly, 52 weeks of supervised training in employment; secondly, a registration assessment.

Once all these stages are successfully completed, and assuming you have the necessary visa and work permit, you would be in a position to apply for roles as a practising pharmacist in the UK. There is virtually no unemployment of registered pharmacists in the UK.

You can also apply to undertake a Masters research project in addition to your postgraduate diploma. Pharmacy is a particular area of strength at the University of Sunderland and our Department has been teaching the subject since 1921.

Course content

The content of this course reflects the accreditation requirements of the General Pharmaceutical Council.

Modules on the course include:
-Pharmacy, Law, Ethics and Practice (60 Credits)
-Clinical Therapeutics (60 Credits)
-Research Methods for Pharmaceutical Practice and Masters Research Project (60 Credits)

Teaching and assessment

We use a wide variety of teaching and learning methods which include lectures, debate sessions, online learning packages, tutorials and seminars.

Compared to an undergraduate course, you will find that this Masters requires a higher level of independent working. Assessment methods include end-of-year examinations, practical assessments as well as assignments throughout the year.

Facilities & location

This course is based in the Sciences Complex at our City Campus, which boasts multi-disciplinary laboratories and cutting-edge equipment thanks to multi-million pound investments.

Facilities for Pharmaceutics
We have pharmaceutical-related equipment for wet granulation, spray drying, capsule filling, tablet making, mixing inhalation, film coating and freeze drying.

As well as standard pharmacopoeial test methods, such as dissolution testing, friability and disintegration, we also offer highly sophisticated test methods. These include rheometry, thermal analysis (differential scanning calorimetry and hot stage microscopy), tests for powder flow, laser diffraction, photon correlation spectroscopy, image analysis and laser confocal microscopy.

Facilities for Medicinal Chemistry
Our state-of-the-art spectroscopic facility allows us to confirm the structures of new molecules that could be potential pharmaceutical products and to investigate the structures of potential medicinal substances that have been isolated from plants.

We are equipped with Liquid Chromatography-Nuclear Magnetic Resonance and Mass Spectroscopy (LCNMR/MS) platforms; this is an exceptional facility for a university. We also have low and high resolution mass spectrometry, nuclear magnetic resonance and elemental analysis equipment.

Our facilities allow you to gain hands-on experience of a wide range of analytical techniques such as atomic absorption spectroscopy and infra-red spectroscopy, which are of great importance in determining both ionic/metal content of pharmaceuticals and simple chemical structures.

You will also gain experience of revolutionary protein and DNA separation techniques, as well as Ultra High Performance Liquid Chromatography and Gas Chromatography for separating unknown chemical mixtures.

Facilities for Pharmacology
Our highly technical apparatus will give you first-hand experience of the principles of drug action and the effects of drugs on pharmacological and cellular models. As a result, you gain a better understanding of the effects of drugs on specific receptors located throughout the human body and related physiological effects.

Simulation technology
You’ll have the opportunity to apply your training in a realistic setting with our two advanced simulation technology ‘SimMan’ models.
Each of our £57,000 SimMan mannequins has blood pressure, a pulse and other realistic physiological behaviour. The models can be pre-programmed with various medical scenarios, so you can demonstrate your pharmacological expertise in a realistic yet safe setting. Our academic team is also actively working with the SimMan manufacturers to develop new pharmacy simulations.

Pharmacy Practice
One of the most important skills of pharmacists is to communicate their expertise in a manner that the public can understand and accept.

The University has invested in a purpose-built model pharmacy complete with consultation suite. This allows you to develop skills in helping patients take the correct medicine in the right way, with optional video recording of your interaction with patients for the purposes of analysis and improvement.

In addition, we can accurately simulate hospital-based scenarios in a fully equipped ward environment where medical, nursing and pharmacy students can share learning.

University Library Services
We’ve got thousands of books and e-books on pharmaceutical and biomedical science, with many more titles available through the inter-library loan service. We also subscribe to a comprehensive range of print and electronic journals so you can access the most reliable and up-to-date academic and industry articles.

Some of the most important sources for your studies include:
-Embase, which is a complex database covering drug research, pharmacology, pharmaceutics, toxicology, clinical and experimental human medicine, health policy and management, public health, occupational health, environmental health, drug dependence and abuse, psychiatry, forensic medicine and biomedical engineering/instrumentation
-PubMed, which contains life science journals, online books and abstracts that cover fields such as medicine, nursing, dentistry, veterinary medicine and health care
-Science Direct, which offers more than 18,000 full-text journals published by Elsevier
-Web of Science, which covers a broad range of science areas

Learning Environment
Sunderland Pharmacy School has a rich heritage in scientific studies and our degree courses are extremely well respected in the industry. We are fully plugged into relevant medical and pharmaceutical industry bodies, with strong links and an exchange of ideas and people. Our vibrant learning environment helps ensure a steady stream of well-trained pharmacists whose most important concern is patient-centred pharmaceutical care.

Employment & careers

On completing this course you can register and practise in the UK as a qualified pharmacist. An entry-level pharmacist usually starts within Band 5 of the NHS pay rates (up to around £28,000). Advanced pharmacists, consultants, team managers and managers of pharmaceutical services are rated as Bands 8-9 and can earn up to £99,000. Currently there is virtually no unemployment of qualified pharmacists. Typical starting salaries for community pharmacists range from £21,000 to £35,000 depending on location, conditions of employment and experience.

Most pharmacists work in the following areas:
Community pharmacy: this involves working in pharmacies on high streets or in large stores. You will dispense prescriptions, deal with minor ailments, advise on the use of medicines and liaise with other health professionals.

Hospital pharmacy: this involves the purchasing, dispensing, quality testing and supply of medicines used in hospitals.

Primary care: this involves working in General Practice surgeries, either as an employee of the Practice or the Primary Care Trust. Roles include Medicines Management Pharmacists, who are responsible for prescribing budgets and the development of prescribing directives.

Secondary care: this involves working in hospitals to supply medicines, manage clinics, provide drug information and prescribe medicines.

Industrial pharmacists are involved in areas such as Research & Development, Quality Assurance and product registration.
Research degrees can be undertaken in many aspects of pharmacy. Sunderland Pharmacy School offers excellent facilities and a wide range of research expertise.

You can also work in areas of the pharmaceutical industry, medical writing and in education. By completing a Masters project in addition to your OSPAP postgraduate diploma it will enhance opportunities in academic roles or further study towards a PhD.

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The programme aims to provide students with training and learning opportunities in the skills and specialised knowledge needed to equip them for a career in biotechnology, molecular biotechnology or molecular biology, in particular in industry. Read more
The programme aims to provide students with training and learning opportunities in the skills and specialised knowledge needed to equip them for a career in biotechnology, molecular biotechnology or molecular biology, in particular in industry.

Practical skills will include sessions on fermentation, molecular biology, immunology, cell biology and protein chemistry, and you will go on to complete a major, supervised laboratory or computer-based research project.

Transferable skills gained via this programme will include written and oral presentation skills, statistics, and the ability to plan and write a grant application or a business plan. Subject-specific skills will include key techniques used in molecular biotechnology, specialist knowledge in theoretical and practical aspects of the subject, including: process engineering, molecular biology, functional genomics, 'omics' technologies, protein expression systems and antibody engineering. Practical skills will include fermentation, molecular biology, immunology, cell biology and protein chemistry.

Careers

While many graduates will go on to employment in biotechnology companies, you will also be employable in other life sciences industries or able to go on to further study and research.

About the School of Biosciences

As one of the top biosciences departments in the UK, our research covers the entire spectrum of cutting-edge biosciences. We are home to the Institute of Microbiology and Infection and part of the University’s Systems Science for Health initiative.
Our research focuses on a number of important themes that run through modern biological and biochemical research: Biosystems and Environmental Change; Microbiology and Infection; Molecules, Cells, Signalling and Health; and Plant Science.
Our postgraduate students join a diverse international community of staff and students. For students on research degrees, the annual Biosciences Graduate Research Symposium, organised by PhD students, is an example of an event where the whole School comes together to talk about science.
We have extensive high-technology facilities in areas such as functional genomics, proteomics and metabolomics, including a world-class Advanced Mass Spectrometry Facility. Our cutting-edge facilities extend to protein structure determination and analysis, confocal microscopy, drug discovery, horticulture, structural biology and optical imaging. The £8 million Phenome Centre Birmingham is a large metabolic phenotyping facility led by internationally recognised metabolomics and clinical experts at the University of Birmingham, in collaboration with Birmingham Health Partners.

Funding and Scholarships

There are many ways to finance your postgraduate study at the University of Birmingham. To see what funding and scholarships are available, please visit: http://www.birmingham.ac.uk/postgraduate/funding

Open Days

Explore postgraduate study at Birmingham at our on-campus open days.
Register to attend at: http://www.birmingham.ac.uk/postgraduate/visit

Virtual Open Days

If you can’t make it to one of our on-campus open days, our virtual open days run regularly throughout the year. For more information, please visit: http://www.pg.bham.ac.uk

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If you have a background in biomedical science, biology, medicine and life sciences, this course allows you to develop your knowledge in selected areas of biomedical science. Read more

If you have a background in biomedical science, biology, medicine and life sciences, this course allows you to develop your knowledge in selected areas of biomedical science.

You gain advanced knowledge and understanding of the scientific basis of disease, with focus on the underlying cellular processes that lead to disease. You also learn about the current methods used in disease diagnosis and develop practical skills in our well-equipped teaching laboratories.

As well as studying the fundamentals of pathology, you can choose one specialist subject from • cellular pathology • microbiology and immunology • blood sciences. Your work focuses on the in vitro diagnosis of disease. You develop the professional skills needed to further your career. These skills include • research methods and statistics • problem solving • the role of professional bodies and accreditation • regulation and communication.

This course is taught by active researchers in the biomedical sciences who have on-going programmes of research in the Biomolecular Sciences Research Centre together with experts from hospital pathology laboratories.

Most of your practical work is carried out in our teaching laboratories which contain industry standard equipment for cell culture, quantitative nucleic acid and protein analysis and a sophisticated suite of analytical equipment such as HPLC and gas chromatography.

Many of our research facilities including flow cytometry, confocal microscopy and mass spectrometry are also used in taught modules and projects and our tutors are experts in these techniques.

The teaching on the course is split between formal lectures and tutorials, and laboratory-based work. A third of the course is a laboratory-based research project, where full-time students are assigned to a tutor who is an active research in the biomedical research centre. Part-time students carry out their research project within the workplace under the guidance of a workplace and university supervisor.

Three core modules each have two full-day laboratory sessions and the optional module applied biomedical techniques is almost entirely lab-based. Typically taught modules have a mixture of lectures and tutorials. The research methods and statistics modules are tutorial-led with considerable input from the course leader who acts as personal tutor.

The course content is underpinned by relevant high quality research. Our teaching staff regularly publish research articles in international peer-reviewed journals and are actively engaged in research into • cancer • musculoskeletal diseases • human reproduction • neurological disease • hospital acquired infection • immunological basis of disease.

Professional recognition

This course is accredited by the Institute of Biomedical Science (IBMS) who commended us on

  • the excellent scientific content of our courses
  • the supportive nature of the staff which provides a positive student experience
  • the laboratory and teaching facilities, which provide an excellent learning environment

Course structure

The masters (MSc) award is achieved by successfully completing 180 credits.

The postgraduate certificate (PgCert) is achieved by successfully completing 60 credits.

The postgraduate diploma (PgDip) is achieved by successfully completing 120 credits.

Core modules

  • Biomedical laboratory techniques (15 credits)
  • Evidence based laboratory medicine (15 credits)
  • Cell biology (15 credits)
  • Molecular diagnostics (15 credits)
  • Research methods and statistics (15 credits)
  • Research project (60 credits)

Optional modules

  • Applied biomedical techniques (15 credits)
  • Cellular and molecular basis of disease (15 credits)
  • Cellular and molecular basis of cancer (15 credits)
  • Human genomics and proteomics (15 credits)
  • Blood sciences (30 credits)
  • Cellular pathology (30 credits)
  • Microbiology and immunology (30 credits)

Assessment

Assessment methods include written examinations and coursework such as

  • problem solving exercises
  • case studies
  • reports from practical work
  • presentations.

Research project assessment includes a written report, presentation and portfolio. 

Employability

This course enables you to start to develop your career in various applications of biomedical science including pathology, government funded research labs or the life sciences industry. It is also for scientists working in hospital or bioscience-related laboratories particularly as biomedical scientists who want to expand their knowledge and expertise in this area.



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This course is suitable if you. wish to pursue research into molecular and cell biology or disease mechanisms at PhD level. want to improve your knowledge and skills to be competitive in the life science jobs market. Read more

This course is suitable if you

  • wish to pursue research into molecular and cell biology or disease mechanisms at PhD level
  • want to improve your knowledge and skills to be competitive in the life science jobs market
  • are currently employed and seeking to improve your career prospects

Most of your practical work is carried out in our teaching laboratories which contain industry standard equipment for cell culture, quantitative nucleic acid and protein analysis and a sophisticated suite of analytical equipment such as HPLC and gas chromatography. In addition many of our research facilities such as flow cytometry, confocal microscopy and mass spectrometry are used in taught modules and research projects and our tutors are experts in these techniques.

You gain

  • a detailed and up-to-date understanding of molecular biology and cell biology
  • knowledge of how alterations or defects in cellular processes may lead to disease, such as cellular dysfunction leading to degenerative diseases, cell cycle dys-regulation in cancer, and how mutations result in genetic diseases
  • hands-on expertise in the latest techniques including cell culture, flow cytometry, real-time PCR, immuno-histochemistry and recombinant DNA technology
  • professional skills to further your career in research or the life science industry

The teaching on the course is split between formal lectures and tutorials, and laboratory-based work. A third of the course is a laboratory-based research project, where students are assigned to a tutor who is an active researcher in the biomedical research centre. Typically, taught modules have a mixture of lectures and tutorials and involve a significant amount of laboratory time. Other modules are tutorial-led with considerable input from the course leader who acts as personal tutor.

Tutors complete research within the Biomolecular Sciences Research Centre into cancer, musculoskeletal diseases, human reproduction, neurological disease, medical microbiology and immunological basis of disease. Their work is regularly published in international peer-reviewed journals, showing that the course is underpinned by relevant quality research.

Course structure

The masters (MSc) award is achieved by successfully completing 180 credits.

The postgraduate certificate (PgCert) is achieved by successfully completing 60 credits.

The postgraduate diploma (PgDip) is achieved by successfully completing 120 credits. 

Core modules:

  • Biomedical laboratory techniques (15 credits)
  • Cell biology (15 credits)
  • Molecular biology (15 credits)
  • Professional development (15 credits)
  • Research methods and statistics (15 credits)
  • Research project (60 credits)

Optional modules:

  • Biotechnology (15 credits)
  • Applied biomedical techniques (15 credits)
  • Cellular and molecular basis of cancer (15 credits)
  • Human genomics and proteomics (15 credits)

Assessment

Assessment methods include written examinations and coursework including

  • problem-solving exercises
  • case studies
  • reports from practical work.

Research project assessment includes a written report and viva voce. 

Employability

As a graduate you can find work in the expanding area of life sciences or enter a career in research. You can find careers in areas such as • medical research in universities hospital laboratories or research institutes • private industry.

The course also provides the skills and knowledge for those wishing to do research at PhD level.



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Our environmental science research is multidisciplinary, including subjects ranging from biology to geography and geosciences. Read more
Our environmental science research is multidisciplinary, including subjects ranging from biology to geography and geosciences. Supported by the global outlook and impact of the Newcastle Institute for Sustainability, you will have access to international experts, the latest facilities and a unique research support package to ensure your future success.

We offer MPhil supervision in the following subjects areas associated with environment science:

Applied and environmental biology

We conduct research on organisms and processes of commercial and environmental importance, embracing experimental approaches that encompass genomics, molecular biology, biochemistry and physiology. Our research provides evidence for the underlying molecular and physiological processes that affect animal behaviour and physiology.

Our research is driven by the desire to develop new biological systems that address health, food, energy and water security. The applied nature of our work has led to the launch of successful spin-out companies, such as Geneius. These companies offer graduate employment opportunities and make a substantial contribution to the local economy. The commercial applications that result from our research range from natural products discovery and creation of novel antimicrobials and biopesticides to sustainable methods of reducing food spoilage.

Based in the Newcastle Institute for Research on Sustainability (NIReS), our research laboratories include well-equipped molecular laboratories for polymerase chain reaction (PCR) and quantitative polymerase chain reaction (qPCR) amplification, fluorescence in situ hybridization (FISH), and facilities for the production of novel recombinant proteins, including protein engineering. Microbiological laboratories are equipped to Category 2 standard. We have the latest equipment for profiling plant leaf gas exchange and light use efficiency, high performance liquid chromatography, fluorescence and light microscopy and easy access to central facilities for confocal and electron microscopy, DNA sequencing, microarray analyses and proteomics. We also have a suite of licenced controlled environment rooms for growing transgenic plants and for housing quarantine invertebrate pests.

Applied and environmental biology research is based in the School of Biology and led by academic staff with international reputations.

Environmental change and management

We study long-term system evolution and change, developing knowledge relating to the Earth's surface and the processes that form its structure and function. We also study how human behaviour impacts on these systems and influences sustainable management.

Based in the School of Geography, Politics and Sociology, you will be part of an active research community of nearly 200 social science researchers. We pride our research on being the highest academic quality with an international focus, underpinned by a concern for informing public debate and contributing to public policy formulation.

Research in physical geography is supported by a number of laboratories:
-Newcastle Cosmogenic Isotope Facility
-Geomorphology Laboratory
-Chemical, paleoecology and organic chemistry laboratories
-Spatial Analysis Laboratory

We have over 90 academic and research staff and we will ensure that your project is supervised by experts in your field.

Geosciences

Geoscience research at Newcastle is focused on:
-Biogeochemistry, with particular strength in microbial ecology, mineralogy, organic, inorganic and isotope geochemistry
-Geoenergy, reflecting a balance between fossil fuels as a critical energy resource and the move towards a lower carbon global economy

Our biogeochemistry and geoenergy research forms a strong multi-disciplinary group. We also have links to the engineering community through our work on microbial processes of significance to oil and gas production such as reservoir souring.

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Over the last two decades there has been an explosion of interest in brain science across academia, industry and the media. Read more

Over the last two decades there has been an explosion of interest in brain science across academia, industry and the media. The integration of cognitive brain imaging with neuroscience will play a central part in discovering how the brain functions in health and disease in the 21st century, as illustrated by the Human Brain Project in Europe and The Brain Initiative in the USA. The taught Brain Sciences degree will help you gain interdisciplinary knowledge “from molecules to mind” and enable you to develop research skills in cognitive brain imaging, fundamental neuroscience and brain disorders.

Why this programme

  • You will study the Brain Sciences degree in an institute that strives to understand the brain at multiple levels of function, from cells to cognition using approaches ranging from molecular, cellular and systems level investigations to brain imaging.
  • Lectures will be given by staff who are international research leaders and who publish cutting edge research at the forefront of brain sciences.
  • You will attend seminars on a wide range of topics given by eminent external speakers visiting the Institute from around the world as part of our Current Research Topics course. 
  • You will carry out a research project working in labs equipped with technology and expertise at the forefront of brain science research, including
  • 3 Tesla fMRI system to image human brain function
  • magnetoencephalography and electroencephalography to study neural activity
  • transcranial magnetic stimulation for non-invasive brain stimulation
  • 7 Tesla experimental MRI scanner for studying models of disease 
  • confocal microscopy for high resolution cellular imaging
  • models of disease for pharmcolgical, gene and stem cell therapies.
  • You will receive training in research design, data handling, data analysis, and reporting of results.
  • The brain science programme allows student choice and flexibility. Through your choice of optional taught courses you can develop in-depth specialist knowledge to enhance further academic research as well as transferable skills for a career outside academia.
  • You will join a vibrant community of masters students from other programmes and for your research project you will be based in laboratories alongside PhD students, postdocs and senior researchers.
  • Through the range of teaching methods and assessments used you will gain skills in critical appraisal, independent working, presentations, writing scientific documents and time management.

Programme structure

The programme will consist of compulsory taught courses, selected optional courses and a research project spread over 11-12 months.

Core courses and research project

  • Fundamentals for Neuroscience Research
  • Cognitive Brain Imaging
  • The Research Cycle
  • Current Research Topics in Brain Sciences
  • Neuroscience: Animal Models of Disease and Function
  • Designing a Research Project
  • Brain Sciences Research Project

Optional courses

  • Introduction to Matlab for Biologists
  • Neuroscience: In Vivo Models
  • In Vitro and Analytical Approaches in Neuroscience
  • Bioimaging for Life Sciences
  • Current Trends and Challenges in Biomedical Research and Health
  • Technology Transfer and Commercialisation of Biomedical Research
  • Neuroinflammation 
  • Statistics and Research Design

Teaching and learning methods

Taught courses are delivered by lectures, tutorials, problem-based learning and computer-based sessions supplemented by a wide range of electronic resources for independent or group study. You will use the primary scientific literature as an information resource and through project work will develop skills in team-working, experimental design and data interpretation. Through assessment of coursework you will gain skills in oral and written communication.

Career prospects

The University of Glasgow MSc in Brain Sciences provides you with many career opportunities. 

Research:  MSc students can enter a research career, mainly by undertaking further postgraduate research studies towards a PhD, or by working in research laboratories in academic settings.

Industry: Other options include going on to work in a wide range of commercial sectors including the pharmaceutical or biotechnological industries and scientific publishing.



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This. MRes Medical and Materials Imaging. course will enable you to develop practical skills and theoretical knowledge in a specialist area of medical and materials imaging, according to your personal aspirations to prepare you for a career in industry or for PhD study. Read more

This MRes Medical and Materials Imaging course will enable you to develop practical skills and theoretical knowledge in a specialist area of medical and materials imaging, according to your personal aspirations to prepare you for a career in industry or for PhD study. You will have access to modern facilities and world leading researchers in the field.

You can gain skills in experimental lab techniques, optical techniques, writing scientific and research literature and the theory behind the practical focus.

The course gives you a unique opportunity to develop knowledge and skills in a wide range of techniques and approaches in both medical and materials imaging. Opportunities exist to use state-of-the-art equipment including: MRI magnets 2.2 Tesla, Transmission Electron, Scanning Electron and Confocal microscopes and Optical Coherence Tomography.

Modules

  • Research methodology and ethics
  • Medical imaging
  • Imaging matter: from atoms to galaxies
  • Research project

COME VISIT US ON OUR NEXT OPEN DAY!

Visit us on campus throughout the year, find and register for our next open event on http://www.ntu.ac.uk/pgevents.



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Sunderland is ranked sixth in the UK for pharmacy and pharmacology, according to The Guardian University Guide 2013. This Masters is one of the few in the UK that covers biopharmaceuticals as well as pharmaceuticals. Read more
Sunderland is ranked sixth in the UK for pharmacy and pharmacology, according to The Guardian University Guide 2013.

Course overview

This Masters is one of the few in the UK that covers biopharmaceuticals as well as pharmaceuticals. The course covers drug delivery systems for large molecules such as proteins, genes and anticancer drugs that offer innovative ways to improve the health and wellbeing of our society.

The course also covers advanced formulations and delivery of small drug molecules. There is a focus on nanotechnology, dosage forms, pharmacokinetics and statistical methods used in data analysis.

Our supportive tutors will guide the development of rigorous approaches to research including sound methodologies, good manufacturing practice, high laboratory standards and effective communication of results.

Your Masters research project will be supervised by an expert in the relevant field, possibly in collaboration with a pharmaceutical company or research institution.

This course is particularly relevant if you plan to undertake a PhD in the area of pharmaceutical sciences, biopharmaceuticals or drug delivery. It is also suitable if you are considering, or already involved in, a career in pharmaceutical-related industries, hospitals or research institutions.

Pharmacy is a particular area of strength at the University of Sunderland. We have worked with GlaxoSmithKline for over 20 years and Pfizer has funded research projects at Sunderland for over 10 years.

Course content

The course mixes taught elements with independent research and self-directed study. There is flexibility to pursue personal interests in considerable depth, with guidance and inspiration from Sunderland's supportive tutors. Modules on this course include:
-Dosage Forms and Pharmacokinetics (20 Credits)
-Delivering Gene and Therapeutic Proteins (20 Credits)
-Essential Research and Study Skills (20 Credits)
-Research Manipulation (20 Credits)
-Nanotechnology (20 Credits)
-Bioinformatics (20 Credits)
-Research Project (60 Credits)

Teaching and assessment

We use a wide variety of teaching and learning methods which include lectures, seminars, problem-based learning, laboratory work, group work and visits to relevant companies. We also welcome guest speakers from the pharmaceutical industry who deliver guest lectures and seminars.

Compared to an undergraduate course, you will find that this Masters requires a higher level of independent working. Assessment methods include written examinations, online tests and coursework, which includes oral and poster presentations.

Facilities & location

Sunderland's exceptional facilities include state-of-the-art equipment for pharmaceutics, synthetic, analytical and medicinal chemistry and pharmacology.

Facilities for Chemistry
We’ve recently spent £1 million on our new state-of-the-art analytical equipment. The analytical suite contains equipment which is industry-standard for modern clinical and pharmaceutical laboratories. Our state-of-the-art spectroscopic facility allows us to investigate the structures of new molecules and potential medicinal substances. We are equipped with Liquid Chromatography-Nuclear Magnetic Resonance and Mass Spectroscopy (LCNMR/MS) platforms; this is an exceptional facility for a university. We also have low and high-resolution mass spectrometry, nuclear magnetic resonance and elemental analysis equipment.

Our facilities allow you to gain hands-on experience of a wide range of analytical techniques such as atomic absorption spectroscopy and infra-red spectroscopy, which are of great importance in determining both ionic/metal content of pharmaceuticals and simple chemical structures. You will also gain experience of revolutionary protein and DNA separation techniques, as well as Ultra High Performance Liquid Chromatography and Gas Chromatography for separating unknown chemical mixtures.

Facilities for Pharmaceutics and Pharmacology
Our highly technical apparatus will help you gain a better understanding of the effects of drugs on specific receptors located throughout the human body and related physiological effects. In addition to equipment for standard pharmacopoeial tests, such as dissolution testing, friability and disintegration, we also have highly sophisticated test methods. These include rheometry, thermal analysis (differential scanning calorimetry and hot stage microscopy), tests for powder flow, laser diffraction, photon correlation spectroscopy, image analysis and laser confocal microscopy.

We also have equipment for wet granulation, spray drying, capsule filling, tablet making, powder mixing inhalation, film coating and freeze drying.

University Library Services
We’ve got thousands of books and e-books on pharmaceutical and biomedical sciences, with many more titles available through the inter-library loan service. We also subscribe to a comprehensive range of print and electronic journals so you can access the most reliable and up-to-date academic and industry articles. Some of the most important sources for your studies include:
-Embase, which is a complex database covering drug research, pharmacology, pharmaceutics, toxicology, clinical and experimental human medicine, health policy and management, public health, occupational health, environmental health, drug dependence and abuse, psychiatry, forensic medicine and biomedical engineering/instrumentation
-PsycINF, which includes information about the psychological aspects of medicine, psychiatry, nursing, sociology, pharmacology and physiology
-PubMed, which contains life science journals, online books and abstracts that cover fields such as medicine, nursing, dentistry, veterinary medicine and health care
-Science Direct, which offers more than 18,000 full-text journals published by Elsevier
-Web of Science, which covers a broad range of science areas

Employment & careers

On completing this course you will be equipped with the skills and understanding needed for Research & Development roles with employers such as:
-Pharmaceutical and biopharmaceutical companies
-Medical research institutes
-Hospitals

Salaries for senior pharmacologists range from £35,000 to around £80,000. Clinical laboratory scientists earn an average of £36,000. A Masters degree will also enhance opportunities in academic roles or further study towards a PhD.

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