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Take advantage of one of our 100 Master’s Scholarships to study at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Read more
Take advantage of one of our 100 Master’s Scholarships to study at Swansea University, the Times Good University Guide’s Welsh University of the Year 2017. Postgraduate loans are also available to English and Welsh domiciled students.

Swansea University is the only UK university to offer a British Blood Transfusion Society approved degree in Advanced Specialist Blood Transfusion.

This is a part-time course that will be delivered via the Work-based Learning (WBL) route with students employed in a variety of heath care settings.

The Master's level course for the Specialist Blood Transfusion has been developed in collaboration with the British Blood Transfusion Society. Members of the British Blood Transfusion Society (BBTS) will work in partnership with colleagues from the College of Human and Health Sciences in providing appropriate support for these students.

The Advanced Specialist Blood Transfusion programme team will provide academic support and facilitation of the WBL and the identified work-based mentor will provide guidance clinically.

Students can therefore be working in a setting distinct from the College and able to work at their own pace and react to learning opportunities in a real life setting.

The BBTS is a professional membership body which is committed to supporting transfusion professionals through the provision of career development and learning opportunities, thus assuring ongoing advancement of blood transfusion and its practitioners. It currently has in excess of 1600 members, representing transfusion professionals at all levels and locations.

Course Description

Whilst formal training and education has been available for doctors, clinical scientists and biomedical scientists specialising in transfusion medicine for some years, nurses and transfusion practitioners have had limited access to formal programmes of education in blood transfusion. The educational preparation of nurses and transfusion practitioners is critical to promoting safe and effective transfusion practice. The purpose of this degree in Advanced Specialist Blood Transfusion Practice is to prepare the practitioner to achieve the level of expertise that the BBTS has detailed in its curriculum framework for nurses and transfusion practitioners working in UK Blood Services and the wider NHS.

The programme reflects, in part, the content of the original framework for the BBTS Specialist Certificate in Blood Transfusion Science Practice (2008). The framework for the BBTS Specialist Certificate in Transfusion Science Practice for nurses and practitioners working in blood transfusion and associated specialties was compiled by representatives from the BBTS Professional Affairs and Education nursing sub-committee, the UK Blood Services and NHS hospital transfusion team representatives.

The format of work-based learning is well established within the College and concurs with modern learning philosophies, enabling students to learn in their working environment whilst being mentored by experts in their field of practice. This learning enables the employer to support students within their workplace. The student professionally develops whilst continuing to work in their workplace environment.

The CHHS will deliver the Advanced Specialist Blood Transfusion Practice programme in partnership with the BBTS, who will provide subject expertise and curriculum guidance.

This programme is offered on a part-time basis, and will normally take three years to complete.

The MSc programme in Advanced Specialist Blood Transfusion comprises 6 modules (120 credits) and a dissertation (60 credits). The first year will comprise of three 20-credit core modules and the second year will comprise of two 30-credit composite modules. In the final year, students complete the dissertation module (60 credits).

PGDip students undertake the same first and second year modules, but do not undertake the dissertation.

PGCert students undertake the first year modules only.

Modules

Modules on the Advanced Specialist Blood Transfusion programme typically include:

The Work Place Learning Journey
The History, Science and Practice of Blood Transfusion
Clinical Governance and its Impact on Managing Adverse Events in Blood Transfusion
Advanced Specialist Practice in Blood Transfusion
Advanced Clinical Governance and Contemporary Issues
Professional Practice in Advanced Specialist Blood Transfusion

Who should take this programme?

Nurses and other allied health care professionals (e.g. ODPs) may be interested in studying for a Master's or postgraduate qualification in Advanced Specialist Blood Transfusion Practice.

Staff Expertise

The core team for the College of Human and Health Sciences have professional backgrounds in either haematology and/or work-based learning. The programme manager, Mrs Heulwen Morgan-Samuel, has extensive clinical experience in general medical nursing, and has developed expertise in the care of cancer patients, including palliative care, and teaches on many palliative care and oncology modules. She is also the designated lead for haematology nursing in the College. She has published a number of research studies in peer reviewed journals specifically on infection control for the immune-compromised patient and the role of the nurse lecturer in supporting students. Heulwen Morgan- Samuel’s research interests include factors that enhance learning within the clinical environment, student support, principles of care and education for oncology nurses. She has co-edited a revised edition of the Fundamentals of Nursing book which is aimed at the pre registration nursing curriculum designated.

Teaching and learning is based on the best research evidence available, and the programme manager will work in close collaboration with members of the British Blood Transfusion Society (BBTS). Their membership includes professionals from all levels across the transfusion community, maintaining clinical and academic currency, to support and enhance practice in this field. The aim of BBTS is to “play a leading role in safe and effective transfusion practice by delivering high quality education and training, setting standards and promoting research and development and innovation” (BBTS, 2015).

Employability

Healthcare professionals employed in the field of blood transfusion that require advanced level education in the speciality would benefit from this degree in Advanced Specialist Blood Transfusion.

It is relevant to those wishing to build on their knowledge of blood transfusions within their existing career, but would also be beneficial to those currently working in an environment that manages blood transfusion who wish to focus and develop their career within this field of practice, as well as being a stepping stone for research study. The knowledge, understanding and skills developed would enhance students' expertise and would build on current practice within their own workplaces.

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The Postgraduate Certificate in Blood Component Transfusion enables experienced non-medical Healthcare Practitioners (HCPs) to make the clinical decision and provide the written instruction for blood component transfusion to patients within their own clinical specialty, and within their own areas of competence and expertise. Read more
The Postgraduate Certificate in Blood Component Transfusion enables experienced non-medical Healthcare Practitioners (HCPs) to make the clinical decision and provide the written instruction for blood component transfusion to patients within their own clinical specialty, and within their own areas of competence and expertise.

Key Features of PGCert in Blood Component Transfusion

- An All Wales programme and a core component of the preparation of non-medical staff for the role of authorising transfusion of blood components
- The course underpins the All Wales Policy for non-medical authorisation of blood component transfusion

Teaching and Employability:

- Developed in conjunction with the Welsh Blood Service on behalf of the Welsh Government
- Students must be working in a relevant clinical area whilst completing this programme

This innovative course prepares appropriate non-medical practitioners to adopt an extended role in making the decision to transfuse and in providing the written instruction for transfusion of blood components thereby;

- Streamlining the patient pathway
- Providing a holistic approach
- Safeguarding the patient, the Healthcare professional and the employer

The Blood Component Transfusion course is accredited by Swansea University and delivered in conjunction with the Welsh Blood Service Better Blood Transfusion Team.

The Blood Component Transfusion course will run over one academic year, comprises one theoretical and one work based learning module and is jointly delivered by a clinical teaching team and lecturers from the College of Human and Health Sciences. Participants are assessed by multiple choice examination, observed clinical practice with formal assessment, and a portfolio of evidence.

Modules

Modules on the Blood Component Transfusion may include:

Principles of Safe Practice in Clinical Transfusion Management
Developing Autonomous Practice
Advancing Your Own Practice

Postgraduate Community

Students on the Blood Component Transfusion course will benefit from the staff expertise of he core team for the College of Human and Health Sciences who has professional backgrounds in either haematology and/ or work-based learning.

The College of Human and Health Sciences has a vibrant postgraduate community with students drawn from a variety of backgrounds and nationalities. The College is known for its friendly, welcoming and supportive environment, which combined with its extensive facilities, state-of-the-art technology and superb beachside location, helps to ensure that students benefit from an exceptional student experience.

In addition, Blood Component Transfusion students have access to a wide range of excellent facilities and equipment for realistic workplace experiences.

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The School of Life Science has developed an extremely active and successful undergraduate, Biomedical Science programme. We have embraced specialists working in local NHS Trusts to develop outstanding, collaborative relationships covering key diagnostic and clinical specialties. Read more

Overview

The School of Life Science has developed an extremely active and successful undergraduate, Biomedical Science programme. We have embraced specialists working in local NHS Trusts to develop outstanding, collaborative relationships covering key diagnostic and clinical specialties. Not only do students benefit from the inclusion of such specialist practitioners onto our teaching programmes, but could also be offered highly competitive research opportunities working within the hospital itself.

This MSc programme builds on this wealth of experience and best practice to enable well-qualified students to develop their scientific training and employability skills within a Biomedical context. The need for innovation and a multidisciplinary approach to Biomedical Science has never been more important. The teaching strategies embedded within this programme embrace these principles in its pursuit of Clinical Biochemistry, Medical Immunology and Haematology.

IBMS Accreditation

This programme is accredited by the Institute of Biomedical Science (IBMS) as the professional body of Biomedical Scientists within the United Kingdom. The IBMS aims to promote and develop the role of Biomedical Science within healthcare to deliver he best possible service for patient care and safety.

Accreditation is a process of peer review and recognition by the profession of the achievement of quality standards for delivering Masters level programmes.

Individuals awarded a Masters degree accredited by the Institute are eligible for the title of Chartered Scientist and the designation CSci if they meet the other eligibility criteria of corporate membership and active engagement in Continued Professional Development. A Masters level qualification is also one of the entry criteria for the Institute’s Higher Specialist Examination and award of the Higher Specialist Diploma, a pre-requisite for the membership grade of Fellowship and designation FIBMS.

The aim of IBMS accreditation is to ensure that, through a spirit of partnership between the Institute and the University, a good quality degree is achieved that prepares the student for employment in circumstances requiring sound judgement, critical thinking, personal responsibility and initiative in complex and unpredictable professional environments.

The Institute lists 10 advantages of IBMS accreditation:
1. Advances professional practice to benefit healthcare services and professions related to biomedical science.

2. Develops specific knowledge and competence that underpins biomedical science.

3. Provides expertise to support development of appropriate education and training.

4. Ensures curriculum content is both current and anticipatory of future change.

5. Facilitates peer recognition of education and best practice and the dissemination of information through education and employer networks.

6. Ensures qualification is fit for purpose.

7. Recognises the achievement of a benchmark standard of education.

8. The degree award provides access to professional body membership as a Chartered Scientist and for entry to the Higher Specialist Diploma examination.

9. Strengthens links between the professional body, education providers employers and students.

10. Provides eligibility for the Higher Education Institution (HEI) to become a member of HUCBMS (Heads of University Centres of Biomedical Science)

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

Course Aims

The main aim of the programme is to provide multidisciplinary, Masters Level postgraduate training in Biomedical Blood Science. This will involve building on existing, undergraduate knowledge in basic science and applying it to clinical, diagnostic and research applications relevant to Clinical Biochemistry, Medical Immunology and Haematology.

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

- To develop students’ knowledge and understanding of different theoretical perspectives, methodological approaches, research interests and practical applications within Blood Science

- To explore and explicitly critique the clinical, diagnostic and research implications within the fields of Clinical Biochemistry,

- Medical Immunology and Haematology, and to place this in the context of a clinical laboratory, fully considering the potential implications for patients, health workers and research alike

- To develop a critical awareness of Biomedical ethics and to fully integrate these issues into project management including grant application and business planning

- To support student autonomy and innovation by providing opportunities for students to demonstrate originality in developing or applying their own ideas

- To direct students to integrate a complex knowledge base in the scrutiny and accomplishment of professional problem-solving scenarios and project development

- To enable student acquirement of advanced laboratory practical competencies and high level analytical skills

- To promote and sustain communities of practice that allow students to share best practice, encourage a multidisciplinary approach to problem-solving and to develop extensive communication skills, particularly their ability to convey complex, underpinning knowledge alongside their personal conclusions and rationale to specialist and nonspecialist listeners

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

Course Content

This one year programme is structured so that all taught sessions are delivered in just two days of the working week. Full-time students are expected to engage in independent study for the remaining 3 days per week. Consolidating taught sessions in this way allows greater flexibility for part-time students who will be expected to attend one day a week for two academic years, reducing potential impact in terms of workforce planning for employers and direct contact for students with needs outside of their academic responsibilities.

Semester 1 will focus on two main areas, the first being Biomedical ethics, grant application and laboratory competencies. The second area focuses on the clinical and diagnostic implications of Blood Science for patients and health workers, with the major emphasis being on Clinical Biochemistry.

Semester 2 will also focus on two main themes; firstly, business planning methodological approaches, analytical reasoning and research. Secondly, the clinical and diagnostic implications of Blood Science for patients and health workers, with the major emphasis being on Haematology and Immunology.

Compulsory Modules (each 15 credits) consist of:
- Biomedical Ethics & Grant Proposal
- Project Management & Business Planning
- Advanced Laboratory Techniques*
- Research Methodologies *
- Case Studies in Blood Science I
- Case Studies in Blood Science II
- Clinical Pathology I
- Clinical Pathology II

*Students who have attained the IBMS Specialist Diploma and are successfully enrolling with accredited prior certified learning are exempt from these two modules.

Dissertation – Biomedical Blood Science Research Project (60 credits)

This research project and final dissertation of 20,000 words is an excellent opportunity for students to undertake laboratory based research in their chosen topic and should provide an opportunity for them to demonstrate their understanding of the field via applications in Biomedical Science. Biomedical Science practitioners are expected to complete the laboratory and data collection aspects of this module in conjunction with their employers.

Requirements for an Award:
In order to obtain the Masters degree, students are required to satisfactorily accrue 180 M Level credits. Students who exit having accrued 60 or 120 M Level credits excluding the ‘Dissertation – Biomedical Blood Science Research Project’ are eligible to be awarded the Postgraduate Certificate (PgC) and Postgraduate Diploma (PgD) respectively

Teaching and Learning Methods

This programme places just as much emphasis on developing the way in which students approach, integrate and apply new knowledge and problem-solving as it is with the acquisition of higher level information. As such, particular emphasis is placed on developing critical thinking, innovation, reflective writing, autonomous learning and communication skills to prepare candidates for a lifetime of continued professional development.

The teaching and learning methods employed throughout this programme reflect these principles. For example, there is greater emphasis on looking at the subject from a patient-orientated, case study driven perspective through problem-based learning (PBL) that encourages students to think laterally, joining up different pieces of information and developing a more holistic level of understanding.

Assessment

The rich and varied assessment strategy adopted by this programme ensure student development of employability
and academic skills, providing an opportunity to demonstrate both professional and academic attainment. Assessment design is
largely driven by a number of key principles which include: promotion of independent learning, student autonomy, responsibility for personal learning and development of innovation and originality within one’s chosen area of interest. Note that not all modules culminate in a final examination.

Additional Costs

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

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

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This innovative distance learning MSc in Blood Science focuses on the diagnostic techniques, QA/QC and regulatory issues within this emerging field combining haematology, immunology, transfusion and clinical biochemistry developed from increasing automation within pathology. Read more
This innovative distance learning MSc in Blood Science focuses on the diagnostic techniques, QA/QC and regulatory issues within this emerging field combining haematology, immunology, transfusion and clinical biochemistry developed from increasing automation within pathology.

The course now benefits from accreditation by the Institute of Biomedical Science enabling students to take full advantage of the opportunities for knowledge and career development that this affords.

More about this course

This MSc distance-learning course is designed to promote a deep understanding of the emerging mixed disciplinary area of blood science. You will examine different theoretical perspectives, methodological approaches, research interests and practical applications within the subject area, as an independent learner.

Designed with input from current practitioners in the field, the course is suitable for biomedical science practitioners and graduates of biomedical or related life sciences. The programme covers areas relevant to staff working within or wishing to work in blood science departments within pathology.

Delivered as a flexible distance-learning programme through our e-Portal WebLearn, you will be able to continue to work whilst studying. The self-guided eLearning materials have been specially designed to support your engagement with the course content.

Each module has a module leader who is responsible for developing the curriculum and coordinating the production of the eLearning materials. Some sessions are ‘broadcast live’ with modules running face-to-face so you can engage with tutors, lecturers and other students. You can also contact your module leader and discuss ideas with other students via email, discussion boards, and during live peer-to-peer support sessions.

Your final research project is to be conducted in your place of work with joint supervision provided by your laboratory training officer and a member of staff from the School of Human Sciences. For those not working in a suitable laboratory, research may be conducted at London Metropolitan University with additional bench fees for materials.

The course is designed to support professionals in their career development in the healthcare profession, biomedical/biotechnology industry or in academia and has the potential to lead on to doctoral studies.

This course has many benefits:
-You can study at your own pace, with the support of our Biomedical Science team - no attendance required.
-Single modules can be undertaken to gain continuing professional development (CPD) points.
-You can start your course either in the September or January of the academic year.

Exercises and short phase tests will be used to provide you with feedback on your progress. Summative assessment of students’ knowledge base and their understanding will be incorporated into formal in-course tests/exercises, personal learning logs and end of module assessments completed at the end of each unit.

MSc research project assessment will culminate in the presentation of a dissertation and a poster presentation (via face-to-face messaging system or similar technology).

Professional accreditation

This course is accreditated by the Institute of Biomedical Science (IBMS), enabling students to take full advantage of the opportunities for knowledge and career development that this affords.

Students are eligible for eStudent Membership of the IBMS. Single modules taken for CPD obtain 100 points per 10 credits with the IBMS. It is also recommended by the Canadian Society for Medical Laboratory Science (CSMLS).

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:
-Advanced Immunology (core, 20 credits)
-Bioethics, Research and Grant Proposal (core, 20 credits)
-Clinical Biochemistry (core, 20 credits)
-Haematology (core, 20 credits)
-Research Project (Biomedical Science) (core, 60 credits)
-Transfusion Science (core, 20 credits)
-Haemoglobinopathies (option, 10 credits)
-Introduction to Anatomy and Physiology in Health and Disease (option, 20 credits)
-Introduction to Cell Biology (option, 10 credits)
-Introduction to Cellular Pathology (option, 10 credits)
-Introduction to Clinical Genetics (option, 20 credits)
-Introduction to General Microbiology (option, 10 credits)
-Introduction to Medical Microbiology (option, 20 credits)
-Introduction to Molecular Biology and Genetics (option, 10 credits)
-Introduction to Toxicology (option, 10 credits)

After the course

This course provides an extension of knowledge allowing practising biomedical scientists to be considered for promotion at work. Healthcare scientists are training in this discipline area too.

Career opportunities include employment in NHS hospital laboratories and other health-related areas. Graduates will also be well placed to apply for research studentships.
This course allows students to be considered for promotion at work.

Graduates with two years relevant professional experience can apply for the Member grade of membership

PhD research, pharmacology, biotechnology and similar employment opportunities are available.

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This MSc is for biomedical scientists registered with the Health and Care Professions Council (HCPC) who want to undertake flexible, part-time study towards a masters qualification in a specialist area of clinical pathology. Read more
This MSc is for biomedical scientists registered with the Health and Care Professions Council (HCPC) who want to undertake flexible, part-time study towards a masters qualification in a specialist area of clinical pathology.

The degree programme has been informed by consultation with laboratory managers and NHS training staff. It consists of specialist modules in the blood sciences that explore the theoretical, applied and professional aspects of clinical haematology, transfusion science and biochemistry.

Designed to complement the professional qualifications of the Institute of Biomedical Science (IBMS), the course allows you to expand your knowledge and skills in diagnostic laboratory medicine; to apply these skills to clinical diagnosis, laboratory management and research; and to develop as a reflective practitioner, all within the context of the Modernising Scientific Careers (MSC) initiative.

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The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. Read more
The M.Sc. in Medical Physics is a full time course which aims to equip you for a career as a scientist in medicine. You will be given the basic knowledge of the subject area and some limited training. The course consists of an intense program of lectures and workshops, followed by a short project and dissertation. Extensive use is made of the electronic learning environment "Blackboard" as used by NUI Galway. The course has been accredited by the Institute of Physics and Engineering in Medicine (UK).

Syllabus Outline. (with ECTS weighting)
Human Gross Anatomy (5 ECTS)
The cell, basic tissues, nervous system, nerves and muscle, bone and cartilage, blood, cardiovascular system, respiratory system, gastrointestinal tract, nutrition, genital system, urinary system, eye and vision, ear, hearing and balance, upper limb – hand, lower limb – foot, back and vertebral column, embryology, teratology, anthropometrics; static and dynamic anthropometrics data, anthropometric dimensions, clearance and reach and range of movement, method of limits, mathematics modelling.

Human Body Function (5 ECTS)
Biological Molecules and their functions. Body composition. Cell physiology. Cell membranes and membrane transport. Cell electrical potentials. Nerve function – nerve conduction, nerve synapses. Skeletal muscle function – neuromuscular junction, muscle excitation, muscle contraction, energy considerations. Blood and blood cells – blood groups, blood clotting. Immune system. Autonomous nervous system. Cardiovascular system – electrical and mechanical activity of the heart. – the peripheral circulation. Respiratory system- how the lungs work. Renal system – how the kidneys work. Digestive system. Endocrine system – how hormones work. Central nervous system and brain function.

Occupational Hygiene (5 ECTS)
Historical development of Occupational Hygiene, Safety and Health at Work Act. Hazards to Health, Surveys, Noise and Vibrations, Ionizing radiations, Non-Ionizing Radiations, Thermal Environments, Chemical hazards, Airborne Monitoring, Control of Contaminants, Ventilation, Management of Occupational Hygiene.

Medical Informatics (5 ECTS)
Bio statistics, Distributions, Hypothesis testing. Chi-square, Mann-Whitney, T-tests, ANOVA, regression. Critical Appraisal of Literature, screening and audit. Patient and Medical records, Coding, Hospital Information Systems, Decision support systems. Ethical consideration in Research.
Practicals: SPSS. Appraisal exercises.

Clinical Instrumentation (6 ECTS)
Biofluid Mechanics: Theory: Pressures in the Body, Fluid Dynamics, Viscous Flow, Elastic Walls, Instrumentation Examples: Respiratory Function Testing, Pressure Measurements, Blood Flow measurements. Physics of the Senses: Theory: Cutaneous and Chemical sensors, Audition, Vision, Psychophysics; Instrumentation Examples: Evoked responses, Audiology, Ophthalmology instrumentation, Physiological Signals: Theory Electrodes, Bioelectric Amplifiers, Transducers, Electrophysiology Instrumentation.

Medical Imaging (10 ECTS)
Theory of Image Formation including Fourier Transforms and Reconstruction from Projections (radon transform). Modulation transfer Function, Detective Quantum Efficiency.
X-ray imaging: Interaction of x-rays with matter, X-ray generation, Projection images, Scatter, Digital Radiography, CT – Imaging. Fundamentals of Image Processing.
Ultrasound: Physics of Ultrasound, Image formation, Doppler scanning, hazards of Ultrasound.
Nuclear Medicine : Overview of isotopes, generation of Isotopes, Anger Cameras, SPECT Imaging, Positron Emitters and generation, PET Imaging, Clinical aspects of Planar, SPECT and PET Imaging with isotopes.
Magnetic Resonance Imaging : Magnetization, Resonance, Relaxation, Contrast in MR Imaging, Image formation, Image sequences, their appearances and clinical uses, Safety in MR.

Radiation Fundamentals (5 ECTS)
Review of Atomic and Nuclear Physics. Radiation from charged particles. X-ray production and quality. Attenuation of Photon Beams in Matter. Interaction of Photons with Matter. Interaction of Charged Particles with matter. Introduction to Monte Carlo techniques. Concept to Dosimetry. Cavity Theory. Radiation Detectors. Practical aspects of Ionization chambers

The Physics of Radiation Therapy (10 ECTS)
The interaction of single beams of X and gamma rays with a scattering medium. Treatment planning with single photon beams. Treatment planning for combinations of photon beams. Radiotherapy with particle beams: electrons, pions, neutrons, heavy charged particles. Special Techniques in Radiotherapy. Equipment for external Radiotherapy. Relative dosimetry techniques. Dosimetry using sealed sources. Brachytherapy. Dosimetry of radio-isotopes.

Workshops / Practicals
Hospital & Radiation Safety [11 ECTS]
Workshop in Risk and Safety.
Concepts of Risk and Safety. Legal Aspects. Fundamental concepts in Risk Assessment and Human Factor Engineering. Risk and Safety management of complex systems with examples from ICU and Radiotherapy. Accidents in Radiotherapy and how to avoid them. Principles of Electrical Safety, Electrical Safety Testing, Non-ionizing Radiation Safety, including UV and laser safety.
- NUIG Radiation Safety Course.
Course for Radiation Safety Officer.
- Advanced Radiation Safety
Concepts of Radiation Protection in Medical Practice, Regulations. Patient Dosimetry. Shielding design in Diagnostic Radiology, Nuclear Medicine and Radiotherapy.
- Medical Imaging Workshop
Operation of imaging systems. Calibration and Quality Assurance of General
radiography, fluoroscopy systems, ultrasound scanners, CT-scanners and MR scanners. Radiopharmacy and Gamma Cameras Quality Control.

Research Project [28 ECTS]
A limited research project will be undertaken in a medical physics area. Duration of this will be 4 months full time

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As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts. Read more
As well as giving a solid scientific understanding, the course also addresses commercial, ethical, legal and regulatory requirements, aided by extensive industrial contacts.

Programme Structure

The MSc programmes in Biomedical Engineering are full-time, one academic year (12 consecutive months). The programmes consist of 4 core taught modules and two optional streams. Biomedical, Genetics and Tissue Engineering stream has 3 modules, all compulsory (individual course pages). The second option, Biomedical, Biomechanics and Bioelectronics Engineering stream consists of 5 modules. Students choosing this option will be required to choose 60 credit worth of modules.

The taught modules are delivered to students over two terms of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

Core Modules
Biomechanics and Biomaterials (15 credit)
Design and Manufacture (15 credit)
Biomedical Engineering Principles (15 credit)
Innovation, Management and Research Methods (15 credit)
Plus: Dissertation (60 credit)

Optional Modules

60 credit to be selected from the following optional modules:
Design of Mechatronic Systems (15 credit)
Biomedical Imaging (15 credit)
Biofluid Mechanics (15 credit)
Artificial Organs and Biomedical Applications (15 credit)
Applied Sensors Instrumentation and Control (30 credit)

Module Descriptions

Applied Sensors Instrumentation and Control

Main topics:

Sensors and instrumentation – Sensor characteristics and the principles of sensing; electronic interfacing with sensors; sensor technologies – physical, chemical and biosensors; sensor examples – position, displacement, velocity, acceleration, force, strain, pressure, temperature; distributed sensor networks; instrumentation for imaging, spectroscopy and ionising radiation detection; 'lab-on-a-chip'.

Control – Control theory and matrix/vector operations; state-space systems, multi-input, multi-output (MIMO) systems, nonlinear systems and linearization. Recurrence relations, discrete time state-space representation, controllability and observability, pole-placement for both continuous and discrete time systems, Luenberger observer. Optimal control systems, Stochastic systems: random variable theory; recursive estimation; introduction to Kalman filtering (KF); brief look at KF for non-linear systems and new results in KF theory.

Artificial Organs and Biomedical Applications

Main topics include: audiology and cochlear implants; prostheses; artificial limbs and rehabilitation engineering; life support systems; robotic surgical assistance; telemedicine; nanotechnology.

Biofluid Mechanics

Main topics include: review of the cardiovascular system; the cardiac cycle and cardiac performance, models of the cardiac system, respiratory system and respiratory performance, lung models, physiological effects of exercise, trauma and disease; blood structure and composition, blood gases. oxygenation, effect of implants and prostheses, blood damage and repair, viscometry of blood, measurement of blood pressure and flow; urinary system: anatomy and physiology, fluid and waste transfer mechanisms, urinary performance and control, effects of trauma, ageing and disease; modelling of biofluid systems, review of mass, momentum and energy transfers related to biological flow systems, fluid mechanics in selected topics relating to the cardiovascular and respiratory systems; measurements in biomedical flows.

Biomechanics and Biomaterials

Main topics include: review of biomechanical principles; introduction to biomedical materials; stability of biomedical materials; biocompatibility; materials for adhesion and joining; applications of biomedical materials; implant design.

Biomedical Engineering Principles

Main topics include: bone structure and composition; the mechanical properties of bone, cartilage and tendon; the cardiovascular function and the cardiac cycle; body fluids and organs; organisation of the nervous system; sensory systems; biomechanical principles; biomedical materials; biofluid mechanics principles, the cardiovascular system, blood structure and composition, modelling of biofluid systems.

Biomedical Imaging

Principle and applications of medical image processing – Basic image processing operations, Advanced edge-detection techniques and image segmentation, Flexible shape extraction, Image restoration, 3D image reconstruction, image guided surgery

Introduction of modern medical imaging techniques – Computerized tomography imaging (principle, image reconstruction with nondiffracting sources, artifacts, clinical applications)

Magnetic resonance imaging (principle, image contrast and measurement of MR related phenomena, examples of contrast changes with changes of instrumental parameters and medical applications)

Ultrasound imaging (description of ultrasound radiation, transducers, basic imaging techniques: A-scan, B-scan and Doppler technique; clinical application)

Positron emission tomography (PET imaging) (principle, radioactive substance, major clinical applications)

Design and Manufacture

Main topics include: design and materials optimisation; management and manufacturing strategies; improving clinical medical and industrial interaction; meeting product liability, ethical, legal and commercial needs.

Design of Mechatronic Systems

Microcontroller technologies. Data acquisition. Interfacing to power devices. Sensors (Infrared, Ultrasonic, etc.). Optoelectronic devices and signal conditioning circuits. Pulse and timing-control circuits. Drive circuits. Electrical motor types: Stepper, Servo. Electronic Circuits. Power devices. Power conversion and power electronics. Line filters and protective devices. Industrial applications of digital devices.

Innovation and Management and Research Methods

Main topics include: company structure and organisation will be considered (with particular reference to the United Kingdom), together with the interfacing between hospital, clinical and healthcare sectors; review of existing practice: examination of existing equipment and devices; consideration of current procedures for integrating engineering expertise into the biomedical environment. Discussion of management techniques; design of biomedical equipment: statistical Procedures and Data Handling; matching of equipment to biomedical systems; quality assurance requirements in clinical technology; patient safety requirements and protection; sterilisation procedures and infection control; failure criteria and fail-safe design; maintainability and whole life provision; public and environmental considerations: environmental and hygenic topics in the provision of hospital services; legal and ethical requirements; product development: innovation in the company environment, innovation in the clinical environment; cash flow and capital provision; testing and validation; product development criteria and strategies.

Dissertation

The choice of Dissertation topic will be made by the student in consultation with academic staff and (where applicable) with the sponsoring company. The topic agreed is also subject to approval by the Module Co-ordinator. The primary requirement for the topic is that it must have sufficient scope to allow the student to demonstrate his or her ability to conduct a well-founded programme of investigation and research. It is not only the outcome that is important since the topic chosen must be such that the whole process of investigation can be clearly demonstrated throughout the project. In industrially sponsored projects the potential differences between industrial and academic expectations must be clearly understood.

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

Overview

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

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

Course Aims

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

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

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

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

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

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

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

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

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

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

Course Content

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

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

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

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

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

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

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

Teaching & Assessment

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

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

Additional Costs

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

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

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This programme offers a fascinating range of subjects, including molecular biology, genetics, biochemistry, microbiology, immunology, tissue engineering, clinical medicine, laboratory management and statistics. Read more
This programme offers a fascinating range of subjects, including molecular biology, genetics, biochemistry, microbiology, immunology, tissue engineering, clinical medicine, laboratory management and statistics.

It is accredited by the Institute of Biomedical Science and is based at one of the largest transfusion centres in the world, enabling visits to manufacturing, testing and tissue typing sections. You will learn from specialist lecturers based at the University, NHS Blood and Transplant (NHSBT), and NHS hospitals, and have an opportunity to become fully embedded in an NHS environment while you develop your knowledge.

The programme will give you extensive practical experience of transfusion and transplantation, allowing you to gain skills that directly relate to your future career. As well as being academically interesting, this continually developing area of healthcare science has a major impact on patients' quality of life.

The programme:
-Is one of just two specialist full-time courses in transfusion and transplantation, and is a recommended course at level seven in the Career Framework for Health.
-Gives you the opportunity to carry out your MSc project with NHSBT research staff within the transfusion centre.
-Has high contact hours, with teaching each day and practical classes.
-Includes a large skills component (eg writing in different formats, conference and publication skills, assignments with specific study aims).
-Includes laboratory management, a key skill required at level seven.
-Attracts a diverse range of students (about 50 per cent overseas students), including new graduates, those working in blood centres or blood transfusion/haematology in hospitals, or training to lecture in transfusion.

Programme structure

The programme comprises eight taught units that run from September to March and a research project that begins in May and runs until August. Example project topics have included:
-A study on red cell antibody formation in trauma patients
-Optimisation of platelet antigen detection using recombinant proteins
-Expression of red cell membrane proteins during large-scale red cell culture
-A comparison of stem cell mobilisation drugs for stem cell transplantation

Taught units
-Transfusion and Transplantation Science:
-Pathology of Transfusion and Transplantation Science
-Provision of Blood, Cells, Tissues and Organs
-Clinical Transfusion and Transplantation
-Transfusion and Transplantation in Practice (two units)
-Biostatistics
-Research and Laboratory Management

Assessments are designed to teach skills such as comprehension, scientific writing in different formats and conference skills, and to further knowledge in subject areas not covered in the lectures. Students must pass the taught component to be able to progress to the project.

Part-time students complete the Postgraduate Certificate components in their first year and the Postgraduate Diploma in the second. The project is usually taken during year three to complete the MSc.

Careers

Some of the career paths that graduates have followed include: blood transfusion and fetal medicine research, working for a bone marrow donor laboratory or bone marrow registry, biostatistics, graduate entry to medical school, NHS Clinical Scientist Training programme, and progression to PhD study in several areas including cancer biology and stem cell regeneration.

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Haematologists specialise in disorders of the blood and blood-forming tissues, and their contribution to patient care is fundamental and wide-ranging. Read more
Haematologists specialise in disorders of the blood and blood-forming tissues, and their contribution to patient care is fundamental and wide-ranging. Whether you’re analysing data from patients' samples, matching donated blood with someone who needs a transfusion or researching cures for blood cancers, your work will improve and save countless lives.


Why study MSc Biomedical Science -Haematology and Transfusion Science at Middlesex?

Our Biomedical Science courses have a burgeoning international reputation, due to our world-class research in areas including biomarkers, public health and bio modelling. Our Centre for Investigative and Diagnostic Oncology has pioneered techniques for cancer diagnosis and treatment, and the Haematology department is very active in research into blood cancers, HIV and AIDS.

Our course has a strong practical element, with an emphasis on developing laboratory skills and gaining hands-on experience of diagnostic techniques. Our teaching and research facilities surpass those at some UK medical schools, with £3 million specialist labs equipped with the most up-to-date technology- the perfect place to work on your own research project. You’ll learn to use cutting-edge equipment, including MALDI-TOF mass spectrometers and flow cyto meters; we have a molecular biology laboratory for techniques such as DNA sequencing, real-time PCR, electrophoresis and HPLC, fully-equipped proteomics facilities, a microbiology lab and an incredibly modern cell culture facility.

Course highlights

- Course leader Dr Colin Casimir is famed for his research into the biology of haemopoietic stem cells and gene therapy for haematologic conditions. He is the holder of a number of international patents, and his research has been published in top international journals, including the British Journal of Haematology.
- Other teaching staff include Dr Stephen Butler, a world expert on cancer biomarkers and reproductive biochemistry; Dr Ajit Shah, a former principal scientist at GlaxoSmithKline; and Dr Lucy Ghali, an expert in immunohistochemistry. Guest lecturers include Peter Gregory, haematology services manager at Barnet and Chase Farm Hospitals Trust.
- Our staff are supportive and hands-on – ever-ready with advice on your studies, they’re also known for their strong pastoral care and for going the extra mile for their students. All our teaching staff are involved in research.
- The course is accredited by the Institute of Biomedical Science, so on graduation you’ll have fulfilled the academic requirement for Licentiate membership of the institute; you can apply for student membership while you study.
- We work with London hospitals and NHS laboratories to ensure you’re fully versed in both the latest practice and the latest research. - You’ll visit diagnostic laboratories and of course, our location gives you easy access to the British Library, the Science Museum, the Royal Institution and more.

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The MSc in Haematology is designed to enable you to develop an up-to-date, advanced understanding of the disorders of blood and blood-forming tissues. Read more
The MSc in Haematology is designed to enable you to develop an up-to-date, advanced understanding of the disorders of blood and blood-forming tissues. Utilising critical analytical skills, you will evaluate new developments in research into the blood sciences.

Why Study Haematology with us?

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

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

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

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

What will I learn?

Our course investigates in detail mechanistic models of haematopoiesis and how knowledge of stem cell theory can inform the treatment of anaemia or leukaemia. Blood carries many hormones and cytokines; these can be used as biomarkers of disease, and we will examine the problems associated with some of these measurements. You will also review current guidelines and their evidence base in the therapeutic management of haematological problems, and explore potential new therapies.

How will I be taught?

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

How will I be assessed?

You will be assessed via coursework assignments, which may focus on clinical reviews, laboratory reports, posters, oral presentations, or data manipulation exercises.

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This part-time programme is organised with the support of the Scottish National Blood Transfusion Service (SNBTS). Read more

Programme description

This part-time programme is organised with the support of the Scottish National Blood Transfusion Service (SNBTS). In the fields of Transfusion, Transplantation and Tissue Banking, SNBTS has a leading international reputation and the programme is accredited by the Institute of Biomedical Sciences (IBMS), the professional body for Biomedical Scientists in the United Kingdom.

The programme has been designed to be aligned to the NHS requirements and stipulations relating to career progression for Biomedical Scientists, Clinical Scientists and other healthcare professionals working in these fields.

The programme will give you in-depth expertise and knowledge of the science, regulations and international practices in transfusion, transplantation and tissue banking, for those aiming for more senior management roles in healthcare organisations.

The programme covers the following areas:

Fundamentals of Transfusion Science
Quality and GMP
Blood Donation Processing and Testing
Immunology and Molecular Biology of Transfusion
Clinical Blood Banking
Transplantation and Tissue Banking
Information technology and Donation
Biopharmaceutical Transfusion and Clinical Trials
Management and Communication
Governance/Ethics/Risks of Transfusion
Research skills

Programme structure

The programme involves eight, one-week modules that combine lectures, tutorials and assessments. A variety of learning experiences and assessment tasks will stimulate interest, encourage participation and develop transferable skills. Self-directed learning between modules will require to be undertaken by students participating in this programme.

Throughout the programme, summative and formative assessment techniques will be employed.

After two years you will take three exams for the diploma qualification. If you are successful, you can carry out a research project in the third year to achieve your masters qualification.

Career opportunities

This programme is designed to help you progress within health services in transfusion, transplantation and tissue banking fields.

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The Master of Science in Exercise and Nutrition Science prepares students to work in government, business, the sports industry and in education as practitioners on professional interdisciplinary teams. Read more
The Master of Science in Exercise and Nutrition Science prepares students to work in government, business, the sports industry and in education as practitioners on professional interdisciplinary teams. The program is for students seeking a terminal degree as well as for those seeking a strong foundation for further study and research. The program offers three entry points throughout the academic year, and courses are scheduled to allow an efficient timeline to degree completion for full-time students. Students are provided experiential learning opportunities both inside and outside of the classroom, and are prepared for both the Certified Sports Nutritionist (CISSN) and Certified Strength and Conditioning Specialist (CSCS) examinations, the premier certifications in strength and conditioning and sports nutrition, upon graduation if they choose to pursue certification.

Visit the website http://www.ut.edu/msexercisenutrition/

High-Tech Facilities

Having published more than 100 papers and abstracts, and secured several hundred thousand dollars in funding over the last three years, the students and staff working in the UT Human Performance Research Lab have become nationally and internationally recognized. The lab is one of the most sophisticated and advanced human performance and sport nutrition laboratories in the world, allowing students the opportunity to advance their skills in human performance testing. Equipment contained in the lab includes:

- AMTI force plate for power and velocity

- Dynavision for vision training, reaction time and cognitive function

- Tendo units for movement, specifically power and velocity

- Ultrasonography to measure skeletal muscle size, locate soft tissue injuries and quantify blood flow and blood vessel diameter

- Wingate peak power bikes for anaerobic power testing

- Electromyography for neural function and skeletal muscle activation

- Metabolic carts for VO2 max and resting metabolism measures

- Dual X-ray absorbtiometry for bone mineral density, lean mass and fat mass

- Minus 80°C freezer to maintain the integrity of biological samples

- High tech motion analysis and heavy duty motorized treadmills with 40-degree incline ability

- BTR Primus isokinetic, isotonic and isometric dynomometers for measurement of force, power and velocity in virtually any plane

- Blood lactate analyzers to examine metabolic stress and lactate threshold

- A fully equiped strength and conditioning laboratory

Converging Exercise and Nutrition Sciences Like Never Before

Most university programs segregate the study of exercise and nutrition sciences. The goal of UT’s M.S. in Exercise and Nutrition Science is to examine the relationship between the two fields in regard to optimizing athletic performance. The program combines advanced concepts from exercise physiology and strength and conditioning to teach students how nutrition can impact each area. Through numerous hands-on experiences and rigorous classroom study, students gain an unparalleled awareness of the intersection of these sciences.

Learning by Doing

M.S.-ENS students “learn by doing” through performance-based programming, which prepares practitioners to work with a wide variety of athletes. The department’s advanced labs and technology help students prepare for the real world. UT’s relationships with numerous local athletic teams such as the Tampa Bay Buccaneers and Tampa Bay Lightning allow students put their theories to test. UT faculty and students have also conducted extensive research with more than a dozen high-impact companies that are involved in exercise and nutrition/supplementation. These collaborations give students an insider’s view of the industry and provide a strong network for post-graduation jobs.

Internationally Recognized

Based on the rigor and innovation of the M.S.-ENS program, the International Society of Sports Nutrition recognized it as the first graduate program in Florida to offer approved coursework for preparation for the CISSN examination.

Outstanding Faculty

The program’s highly respected faculty has achieved national and international reputations for academic and applied success in their respective fields.

- J.C. Andersen, Ph.D. – pain and sports medicine

- Mary Martinasek, Ph.D. – mixed-method research inquiry and health program evaluation

- Jay O’Sullivan, Ph.D. – internships in exercise and nutrition science

- Ronda Sturgill, Ph.D. – kinesiology and program evaluation

- Eric Vlahov, Ph.D. – exercise physiology, nutrition and sports psychology

Flexible Program

Our highly flexible program allows students to complete the program within one year. With three entry points into the program, students are able to take classes throughout the year and take time off as needed.

Find out how to apply here - http://www.ut.edu/apply

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Biomedical scientists are key contributors to modern healthcare, including disease diagnosis, monitoring of therapy and research into disease mechanisms. Read more
Biomedical scientists are key contributors to modern healthcare, including disease diagnosis, monitoring of therapy and research into disease mechanisms. This course offers postgraduate training in a selected biomedical science discipline, either Haematology and Blood Transfusion Science, Clinical Biochemistry and Immunology or Infection Science, together with opportunities to advance skills and knowledge in laboratory management and accreditation, plus modern developments such as genomics and stem cell technology. The MSc course is accredited by the IBMS; individual modules may also be studied for CPD accreditation.

The MSc Biomedical Science with Professional Experience is an extended full-time Masters programme with a substantive professional experience component. Within the professional experience modules, students have the option of undertaking an internship with a host organisation or, alternatively, campus-based professional experience. Internships are subject to a competitive application and selection process and the host organisation may include the University.

Internships may be paid or unpaid, and this will depend on what is being offered and agreed with the host organisation. Students who do not wish to undertake an internship or are not successful in securing an internship will undertake campus-based professional experience, which will deliver similar learning outcomes through supervised projects and activities designed to offer students the opportunity to integrate theory with an understanding of professional practice.

WHY CHOOSE THIS COURSE?

This IBMS accredited course allows students who have studied biomedical sciences at undergraduate level both at home and overseas to develop their skills and knowledge, whether they are considering future employment within biomedical science laboratories or research routes. It will also benefit practitioners already in HCPC registered posts to aid career progression. The course can be studied on either a full time or part time basis, and individual modules can be taken for CPD.

The course offers the opportunity to specialise in a key area of biomedical science, extend practical laboratory experience and develop transferable and research skills to enhance future employability.

WHAT WILL I LEARN?

Students will study Professional and Laboratory Skills in Biomedical Science, Research Skills plus they elect to study one of the following modules:
-Haematology and Blood Transfusion Sciences
-Infection Science
-Clinical Biochemistry and Immunology

And two of the following modules:
-Genomics and Regenerative Medicine
-Independent Study in Biomedical Science
-Evidence Based practice in Biomedical Science
-Quality Management and ISO standards
-Laboratory Management, Leadership and Training (suitable for current HCPC practitioners in management roles)
-Introduction to Laboratory Leadership, Management and Training (suitable for students who are not currently in management roles)

Additionally, the understanding gained from these modules will be demonstrated and applied in either the University-based project (12 months full-time or 24 months part-time, on course HLST132), or the professional experience modules giving students the option of undertaking an internship with a host organisation or, alternatively, campus-based professional experience.

HOW WILL THIS COURSE ENHANCE MY CAREER PROSPECTS?

MSc Biomedical Science graduates will be well placed to consider employment in several different areas of life sciences including the NHS, for example as a Trainee Biomedical Scientist in a pathology discipline or entry to the Scientist Training Programme.

Employment in commercial diagnostic laboratories, research organisations and sales and marketing are also options graduates may wish to consider. Opportunities are available both in the UK and overseas.

Examples of possible career routes include:
-NHS laboratories and similar private laboratories, PHE laboratories, the Blood Transfusion service
-University research laboratories
-Bioscience/Life Sciences private companies
-Laboratory Quality Assurance and Management

WORK PLACEMENTS

If you elect for the Extended Masters programme MSc Biomedical Science with Professional Experience (HLST139) you may apply for an internship lasting 2 semesters.

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If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017. Read more
If you’re an international fee-paying student you could be eligible for a £3,000 discount when you start your course in January 2017.
http://www.shu.ac.uk/VCAwardJanuary2017

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.

For more information, see the website: https://www.shu.ac.uk/study-here/find-a-course/mscpgdippgcert-biomedical-sciences

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

Full time – 14 months to Masters. Part time – typically 2 years to Masters. The certificate and diploma are shorter January and September intakes.

Course structure
The masters (MSc) award is achieved by successfully completing 180 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
45 credits from
-Applied biomedical techniques (15 credits)
-Cellular and molecular basis of disease (15 credits)
-Cellular and molecular basis of cancer (15 credits)
-Human genomics (subject to approval) (15 credits)
-Blood sciences (30 credits)
-Cellular pathology (30 credits)
-Microbiology and immunology (subject to approval) (30 credits)

The Postgraduate Certificate (PgCert) is achieved by successfully completing 60 credits. The Postgraduate Diploma (PgDip) is achieved by successfully completing 120 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.

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