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Masters Degrees (Vector)

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This course combines theoretical and practical training in biology and control of disease vectors and the human pathogens they transmit. Read more
This course combines theoretical and practical training in biology and control of disease vectors and the human pathogens they transmit. Students will gain specialised skills in the molecular biology of infectious diseases, and will cover all aspects of major vector-borne diseases. The course also offers a thorough grounding in the systematics of medically important arthropods, processes regulating vector populations, and the biology of vector–parasite and vector–vertebrate interactions.

Graduates enter operational control programmes, applied basic research and academic fields. Students benefit from close interaction with staff who have extensive international expertise.

The James Busvine Memorial Medal and Prize, donated by Professor James Busvine in 1987, is awarded each year for outstanding performance.

- Full programme specification (pdf) (http://www.lshtm.ac.uk/edu/qualityassurance/medic_progspec.pdf)
- Intercalating this course (http://www.lshtm.ac.uk/study/intercalate)

Visit the website http://www.lshtm.ac.uk/study/masters/msbcdv.html

Objectives

By the end of this course students should be able to:

- demonstrate advanced knowledge and understanding of the biology of vectors and intermediate hosts of human pathogens together with methods for their control

- describe the biology, pathogenesis and diagnosis of parasitic infections in humans and relate these to human health and disease control strategies

- demonstrate a range of specialised technical and analytical skills relevant to vectors and vector-borne diseases

- design and carry out a research project on biology or control of disease vectors, analyse and interpret the results and prepare a report including a critical literature review

- design, undertake and evaluate vector control interventions, and show written and verbal competence in communicating scientific information

Structure

Term 1:
There is a one-week orientation period that includes an introduction to studying at the School, sessions on key computing and study skills and an introduction to major groups of pathogens, followed by three compulsory core modules:

- Parasitology & Entomology
- Analysis & Design of Research Studies
- Critical Skills for Tropical Medicine

Sessions on basic computing, molecular biology and statistics are run throughout the term for all students.

Terms 2 and 3:
Students take a total of five modules, one from each timetable slot (Slot 1, Slot 2 etc.). Some modules can be taken only after consultation with the Course Director.

*Recommended modules

- Slot 1:
Epidemiology & Control of Malaria*
Designing Disease Control Programmes in Developing Countries
Molecular Biology & Recombinant Techniques

- Slot 2:
Advanced Diagnostic Parasitology*
Design & Analysis of Epidemiological Studies
Statistical Methods in Epidemiology

- Slot 3:
Vector Sampling, Identification & Incrimination (compulsory)

- Slot 4:
Vector Biology & Vector Parasite Interactions*
Epidemiology & Control of Communicable Diseases
Molecular Biology Research Progress & Applications
Population Dynamics & Projections

- Slot 5:
Integrated Vector Management (compulsory)

Further details for the course modules - http://www.lshtm.ac.uk/study/currentstudents/studentinformation/msc_module_handbook/section2_coursedescriptions/tbcd.html

Residential Field Trip

There is a compulsory one week field course, after the Term 3 examinations, on vector and parasite sampling and identification methods. The cost of £630 is included in the field trip fee.

Project Report

During the summer months (July - August), students complete a field or laboratory research project on an appropriate entomological topic, for submission by early September.

Titles of some of the recent summer projects completed by students on this MSc

Due to our collaborative networking, students are given the opportunity to conduct research projects overseas. This unique experience provides students with skills that are highly desirable to potential employers. The majority of students who undertake projects abroad receive financial support for flights from the School's trust funds set up for this purpose.

Find out how to apply here - http://www.lshtm.ac.uk/study/masters/msbcdv.html#sixth

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IN BRIEF. Innovative, collaborative course taught jointly by the University of Salford and Keele University. Significant practical training in parasitology including intensive residential field trip to Yorkshire’s Malham Tarn. Read more

IN BRIEF:

  • Innovative, collaborative course taught jointly by the University of Salford and Keele University
  • Significant practical training in parasitology including intensive residential field trip to Yorkshire’s Malham Tarn
  • Excellent platform for a research career
  • Part-time study option
  • International students can apply

COURSE SUMMARY

The two contributing universities - Salford and Keele - have considerable complementary research experience in the biology of parasites and the vectors which transmit them. This has led to the development of this pioneering joint masters degree, focusing on the molecular aspects of parasite infections and vector biology. It aims to provide you with a sound insight into the biology of parasites and their control.

This course will educate you in contemporary studies of research on immunological and molecular aspects of selected parasites and vector/parasite relationships. You will also gain research experience in parasitology and/or entomology. Individual research projects can be based in either of the two institutions, choosing a topical aspect of parasitology, or vector biology.

TEACHING

Teaching is delivered by research active staff from the University of Salford and Keele University. Teaching sessions are primarily based at Salford, though the facilities at Keele are also utilised with transport being provided for classes based at Keele.  

Teaching sessions include lectures, laboratory practicals, field work, tutorials, guest lectures and guided reading. Your Dissertation can be based at Salford or Keele.

Part-time students study Fundamentals of Parasitology and Molecular Biology of Parasites in year 1, Vector Biology and Control, and Research Skills (Parasitology) in year 2.  Students may wish to complete the Dissertation in year 2, or year 3 depending upon commitments.

ASSESSMENT

The Research Skills (Parasitology) and Dissertation modules are assessed by coursework. The remaining modules are assessed by coursework and examination.

CAREER PROSPECTS

Graduates from this course have entered employment as research assistants or research laboratory technicians in pharmaceuticals, drug design and pesticide research. Other career paths have included pollution microbiologists with water authorities, and work in hospital laboratories investigating the haematology, molecular biology and immunology of infectious diseases.

This MSc also equips students for PhD research and former students have gone on to study at international universities that include our partner university in Toledo (USA). Several students at Toledo have now completed their PhD studies and have gained employment at US Ivy League Institutes (Harvard Medical School and Cornell).

FURTHER STUDY

After completion of this course you may wish to specialise in a chosen subject area in one of the School’s two main research centres: Ecosystems and Environment Research Centre (EERC) or Biomedical Research Centre (BRC).



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This course has been running for over 25 years and is one of only three in the country. The two contributing universities of Keele and Salford have considerable complementary research experience in the biology of parasites and the insect vectors that transmit them. Read more

Overview

This course has been running for over 25 years and is one of only three in the country. The two contributing universities of Keele and Salford have considerable complementary research experience in the biology of parasites and the insect vectors that transmit them. This has led to the development of this unique, joint MSc degree between the two institutions, focusing on the ecology and molecular biology of parasitism, immunology of infection, treatment of infection, the ecology and molecular biology or insect vectors, and the control of their natural populations. The teaching is undertaken by staff from the two institutions and mostly based at Salford with specialized laboratory sessions at Keele. Students are able to carry out an extensive research project in the research laboratories of one of the two universities. The strong focus on the molecular aspects of parasitic infections, vector biology, and vector control, will appeal to recent graduates wishing to further their training before embarking upon a research career in Entomology, Parasitology, Molecular Biology or Immunology; to those considering a career in Biotechnology; and to overseas students seeking specialist training before entering a career in managing parasitological or vector-related research and control appropriate to their own country.

The vast majority of the teaching team on the course are internationally recognized experts in their field of research. As an example, most of the Keele teaching team belong to the Centre for Applied Entomology and Parasitology which is highly rated for its world-leading research and excellent research facilities. Therefore the course provides a unique opportunity to set a foot in the real world of research in Parasitology and Medical Entomology.

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

Course Aims

The aims of the course are to provide:
- A sound insight into the biology of parasitic diseases their transmission and control of the vectors

- Contemporary studies of current research on immunological and molecular aspects of selected parasites and vector/parasite relationships

- Training in research and modern techniques in the study of vectors and parasites

Teaching & Assessment

Assessment is through a variety of methods including exams, essays and practical work. MSc students will be required in addition to carry out a research project and write it up in a dissertation.

All Masters students must pass modules 1-5 at 50% to give them 180 credits. Students gaining 120 credits will be awarded a Postgraduate Diploma. Students gaining 60 credits will be awarded a Postgraduate Certificate.

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.

Scholarships

There are substantial scholarships available, please see this link: http://www.keele.ac.uk/studentfunding/bursariesscholarships/internationalfunding/postgraduate/
or
http://www.keele.ac.uk/studentfunding/bursariesscholarships/

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This course provides core training in the theoretical and practical aspects of medical parasitology, covering the protozoan and metazoan parasites of humans and the vectors which transmit them. Read more
This course provides core training in the theoretical and practical aspects of medical parasitology, covering the protozoan and metazoan parasites of humans and the vectors which transmit them. Students will gain specialised skills to enable them to pursue a career in research, control or teaching related to medical parasitology.

Graduates enter a range of global health fields ranging from diagnostics through to applied basic research and operational control to higher degree studies and academic/teaching-related positions.

The Patrick Buxton Memorial Medal and Prize is awarded to the best student of the year. Founded by relatives of Patrick Alfred Buxton, Professor in Entomology, who died in 1955.

- Full programme specification (pdf) (http://www.lshtm.ac.uk/edu/qualityassurance/mp_progspec.pdf)
- Intercalating this course (http://www.lshtm.ac.uk/study/intercalate)

Visit the website http://www.lshtm.ac.uk/study/masters/msmp.html

Additional Requirements

An additional preferred requirement for the MSc Parasitology is an interest in parasites of public health importance and disease transmission. Any student who does not meet the minimum entry requirement above but who has relevant professional experience may still be eligible for admission. Qualifications and experience will be assessed from the application.

Objectives

By the end of this course students should be able to demonstrate:

- detailed knowledge and understanding of the biology, life cycles, pathogenesis, and diagnosis of parasitic infections in humans and their relevance for human health and control

- detailed knowledge and understanding of the biology and strategies for control of the vectors and intermediate hosts of human parasites

- carry out practical laboratory identification of parasite stages both free and in tissues and diagnose infections

- specialised skills in: advanced diagnostic, molecular, immunological, genetic, chemotherapeutic, ecological and/or control aspects of the subject

- the ability to design a laboratory or field-based research project, and apply relevant research skills

- prepare a written report including a critical literature review of relevant scientific publications, and show competence in communicating scientific findings

Structure

Term 1:
There is a two-week orientation period that includes an introduction to studying at the School, sessions on key computing and study skills and an introduction to major groups of pathogens, followed by three compulsory core modules:

- Parasitology & Entomology
- Analysis & Design of Research Studies
- Critical Skills for Tropical Medicine

Recommended module: Molecular Biology

Sessions on basic computing, molecular biology and statistics are run throughout the term for all students.

Terms 2 and 3:
Students take a total of five modules, one from each timetable slot (Slot 1, Slot 2 etc.). Some modules can be taken only after consultation with the Course Director.

*Recommended modules

- Slot 1:
Epidemiology & Control of Malaria*
Molecular Biology & Recombinant DNA Techniques*
Advanced Immunology 1
Designing Disease Control Programmes in Developing Countries

- Slot 2:
Advanced Diagnostic Parasitology*
Advanced Immunology 2
Design & Analysis of Epidemiological Studies
Statistical Methods in Epidemiology

- Slot 3:
Vector Sampling, Identification & Incrimination*
Advanced Training in Molecular Biology
Spatial Epidemiology in Public Health
Tropical Environmental Health

- Slot 4:
Immunology of Parasitic Infection: Principles*
Molecular Biology Research Progress & Applications*
Vector Biology & Vector Parasite Interactions*
Epidemiology & Control of Communicable Diseases
Genetic Epidemiology

- Slot 5 :
Antimicrobial Chemotherapy*
Integrated Vector Management*
Molecular Cell Biology & Infection*
AIDS

Further details for the course modules - http://www.lshtm.ac.uk/study/currentstudents/studentinformation/msc_module_handbook/section2_coursedescriptions/tmpa.html

Residential Field Trip

There is a compulsory one week field course, after the Term 3 examinations, on vector and parasite sampling and identification methods.The cost of £630 is included in the field trip fee.

Project Report

During the summer months (July - August), students complete a research project, for submission by early September. This may be based on a critical review of an approved topic, analysis of a collection of results or a laboratory study.Students undertaking projects overseas will require additional funding of up to £1,500 to cover costs involved.

The majority of students who undertake projects abroad receive financial support for flights from the School's trust funds set up for this purpose.

Find out how to apply here - http://www.lshtm.ac.uk/study/masters/msmp.html#sixth

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This course develops the careers of doctors whose interest is the practice of medicine in tropical and low- and middle-income countries. Read more
This course develops the careers of doctors whose interest is the practice of medicine in tropical and low- and middle-income countries. The course offers a wide choice of modules and provides training in clinical tropical medicine at the Hospital for Tropical Diseases.

The Diploma in Tropical Medicine & Hygiene (DTM&H):
All students going on the MSc will take the Diploma in Tropical Medicine & Hygiene. Students with a prior DTM&H, or holding 60 Masters level credits from the East African Diploma in Tropical Medicine & Hygiene may apply for exemption from Term 1 via accreditation of prior learning.

Careers

Graduates from this course have taken a wide variety of career paths including further research in epidemiology, parasite immunology; field research programmes or international organisations concerned with health care delivery in conflict settings or humanitarian crises; or returned to academic or medical positions in low- and middle-income countries.

Awards

The Frederick Murgatroyd Award is awarded each year for the best student of the year. Donated by Mrs Murgatroyd in memory of her husband, who held the Wellcome Chair of Clinical Tropical Medicine in 1950 and 1951.

- Full programme specification (pdf) (http://www.lshtm.ac.uk/edu/qualityassurance/tmih_progspec.pdf)

Visit the website http://www.lshtm.ac.uk/study/masters/mstmih.html

Objectives

By the end of this course students should be able to:

- understand and describe the causation, pathogenesis, clinical features, diagnosis, management, and control of the major parasitic, bacterial, and viral diseases of developing countries

- demonstrate knowledge and skills in diagnostic parasitology and other simple laboratory methods

- understand and apply basic epidemiological principles, including selecting appropriate study designs

- apply and interpret basic statistical tests for the analysis of quantitative data

- critically evaluate published literature in order to make appropriate clinical decisions

- communicate relevant medical knowledge to patients, health care professionals, colleagues and other groups

- understand the basic sciences underlying clinical and public health practice

Structure

Term 1:
All students follow the course for the DTM&H. Term 1 consists entirely of the DTM&H lectures, seminars, laboratory practical and clinical sessions, and is examined through the DTM&H examination and resulting in the award of the Diploma and 60 Master's level credits at the end of Term 1.

Terms 2 and 3:
Students take a total of five study modules, one from each timetable slot (Slot 1, Slot 2 etc.). Recognising that students have diverse backgrounds and experience, the course director considers requests to take any module within the School's portfolio, provided that this is appropriate for the student.

*Recommended modules

- Slot 1:
Clinical Infectious Diseases 1: Bacterial & Viral Diseases & Community Health in Developing Countries*
Clinical Virology*
Epidemiology & Control of Malaria*
Advanced Immunology 1
Childhood Eye Disease and Ocular Infection
Designing Disease Control Programmes in Developing Countries
Drugs, Alcohol and Tobacco
Economic Evaluation
Generalised Liner Models
Health Care Evaluation
Health Promotion Approaches and Methods
Maternal & Child Nutrition
Molecular Biology & Recombinant DNA Techniques
Research Design & Analysis
Sociological Approaches to Health
Study Design: Writing a Proposal

- Slot 2:
Clinical Infectious Diseases 2: Parasitic Diseases & Clinical Medicine*
Conflict and Health*
Design & Analysis of Epidemiological Studies*
Advanced Diagnostic Parasitology
Advanced Immunology 2
Clinical Bacteriology 1
Family Planning Programmes
Health Systems; History & Health
Molecular Virology; Non Communicable Eye Disease
Population, Poverty and Environment
Qualitative Methodologies
Statistical Methods in Epidemiology

- Slot 3:
Clinical Infectious Diseases 3: Bacterial & Viral Diseases & Community Health in Developing Countries*
Control of Sexually Transmitted Infections*
Advanced Training in Molecular Biology
Applied Communicable Disease Control
Clinical Immunology
Current Issues in Safe Motherhood & Perinatal Health
Epidemiology of Non-Communicable Diseases
Implementing Eye Care: Skills and Resources
Medical Anthropology and Public Health
Modelling & the Dynamics of Infectious Diseases
Nutrition in Emergencies
Organisational Management
Social Epidemiology
Spatial Epidemiology in Public Health
Tropical Environmental Health
Vector Sampling, Identification & Incrimination

- Slot 4:
Clinical Infectious Diseases 4: Parasitic Diseases & Clinical Medicine*
Epidemiology & Control of Communicable Diseases*
Ethics, Public Health & Human Rights*
Global Disability and Health*
Immunology of Parasitic Infection: Principles*
Analytical Models for Decision Making
Clinical Bacteriology 2
Design & Evaluation of Mental Health Programmes
Environmental Epidemiology
Evaluation of Public Health Interventions
Genetic Epidemiology
Globalisation & Health
Molecular Biology Research Progress & Applications
Nutrition Related Chronic Diseases
Population Dynamics & Projections
Reviewing the Literature
Sexual Health
Survival Analysis and Bayesian Statistics
Vector Biology & Vector Parasite Interactions

- Slot 5:
AIDS*
Antimicrobial Chemotherapy*
Mycology*
Advanced Statistical Methods in Epidemiology
Analysing Survey & Population Data
Applying Public Health Principles in Developing Countries
Environmental Health Policy
Integrated Vector Management
Integrating Module: Health Promotion
Molecular Cell Biology & Infection
Nutrition Programme Planning
Pathogen Genomics
Principles and Practice of Public Health

Further details for the course modules - http://www.lshtm.ac.uk/study/currentstudents/studentinformation/msc_module_handbook/section2_coursedescriptions/ttmi.html

Project Report:
During the summer months (July - August), students complete a research project in a subject of their choice, for submission by early September. Projects may involve writing up and analysing work carried out before coming to the School, a literature review, or a research study proposal. Some students gather data overseas or in the UK for analysis within the project. Such projects require early planning.

Students undertaking projects overseas will require additional funding of up to £1,500 to cover costs involved. The majority of students who undertake projects abroad receive financial support for flights from the School's trust funds set up for this purpose.

Find out how to apply here - http://www.lshtm.ac.uk/study/masters/mstmih.html#sixth

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This is a multidisciplinary programme that bridges the fields of epidemiology, laboratory sciences and public health. It includes a strong practical component and the opportunity to undertake a research project overseas. Read more
This is a multidisciplinary programme that bridges the fields of epidemiology, laboratory sciences and public health. It includes a strong practical component and the opportunity to undertake a research project overseas. The course will train students in all aspects of the control of infectious diseases and prepare them for a career in a range of organisations.

This course will equip students with specialised skills that will facilitate a career in the control of infectious diseases as staff of health ministries, health departments, national or international disease control agencies, aid organisations or universities.

The majority of the research projects are performed overseas, with collaborating public health or research organisations and NGOs. Students are encouraged to take advantage of this overseas opportunity, which is crucial to the nature of the course.

- Full programme specification (pdf) (http://www.lshtm.ac.uk/edu/qualityassurance/cid_progspec.pdf)
- Intercalating this course (http://www.lshtm.ac.uk/study/masters/intercalating/index.html)

Visit the website http://www.lshtm.ac.uk/study/masters/mscid.html

Objectives

By the end of this course students should be able to:

- investigate the transmission of endemic and epidemic infections

- select appropriate methods of control

- design, implement and evaluate co-ordinated control methods

- assess constraints of local public health delivery systems

- manage available resources in the context of the control of infectious diseases

- focus their efforts on particular geographical regions or specific diseases

Structure

Term 1:

After orientation, students take two compulsory modules: Basic Statistics and Introduction to Disease Agents & Their Control, which focus on the life cycle and characteristics of infectious disease agents according to their principal transmission routes; the principal intervention strategies used to combat infectious diseases; and examples of successes, partial successes and failures in intervention programmes against infectious diseases.

In addition, students take one of the following module combinations:

- Basic Epidemiology; Health Economics; and Health Policy, Process and Power
- Extended Epidemiology and Health Economics or Health Policy, Process and Power

An interdisciplinary approach is emphasised which takes account of the social, political and economic context in which health systems operate.

Terms 2 and 3:

Students take a total of five study modules, one from each timetable slot (Slot 1, Slot 2 etc.). The list below shows recommended modules. There are other modules which may be taken only after consultation with the Course Directors.

*Recommended modules

- Slot 1:

Designing Disease Control Programmes in Developing Countries*
Epidemiology & Control of Malaria*
Health Care Evaluation*
Childhood Eye Disease and Ocular Infections
Clinical Infectious Diseases 1: Bacterial & Viral Diseases & Community Health in Developing Countries
Clinical Virology
Economic Evaluation
Health Promotion Approaches and Methods
Maternal & Child Nutrition
Research Design & Analysis
Study Design: Writing a Study Proposal.

- Slot 2:

Clinical Bacteriology 1*
Conflict and Health*
Design & Analysis of Epidemiological Studies*
Population, Poverty and Environment*
Statistical Methods in Epidemiology*
Advanced Diagnostic Parasitology
Clinical Infectious Diseases 2: Parasitic Diseases & Clinical Medicine
Health Systems
Qualitative Methodologies

- Slot 3:

Applied Communicable Disease Control*
Control of Sexually Transmitted Infections*
Current Issues in Safe Motherhood & Perinatal Health*
Economic Analysis for Health Policy*
Medical Anthropology & Public Health*
Spatial Epidemiology in Public Health*
Tropical Environmental Health*
Vector Sampling, Identification & Incrimination*
Basic Parasitology
Clinical Infectious Diseases 3: Bacterial & Viral Diseases & Community Health in Developing Countries
Modelling & the Dynamics of Infectious Diseases
Nutrition in Emergencies
Organisational Management
Social Epidemiology

- Slot 4:

Clinical Bacteriology 2*
Epidemiology & Control of Communicable Diseases*
Analytical Models for Decision Making
Clinical Infectious Diseases 4: Parasitic Diseases & Clinical Medicine
Ethics, Public Health & Human Rights
Globalisation & Health; Sexual Health
Vector Biology & Parasite Infections

- Slot 5:

AIDS*
Applying Public Health Principles in Developing Countries*
Integrated Vector Management*
Advanced Statistical Methods in Epidemiology
Antimicrobial Chemotherapy
Integrating Module: Health Promotion
Integrating Module: Health Services Management
Mycology
Nutrition Programme Planning
Principles and Practice of Public Health

Further details for the course modules - http://www.lshtm.ac.uk/study/currentstudents/studentinformation/msc_module_handbook/section2_coursedescriptions/tcid.html

Project Report:
During the summer months (July - August), students complete a research project studying aspects of an intervention programme, for submission by early September. If appropriate, this may take the form of an optional period in a relevant overseas location. Most students on this course undertake projects overseas. Students undertaking projects overseas will require additional funding of up to £1,500 to cover costs involved.

Find out how to apply here - http://www.lshtm.ac.uk/study/masters/mscid.html#sixth

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Postgraduate Loans are now Open for Home/EU students. -. https://www.gov.uk/postgraduate-loan/how-to-apply. Scholarships & Discounts available. Read more

Postgraduate Loans are now Open for Home/EU students - https://www.gov.uk/postgraduate-loan/how-to-apply

Scholarships & Discounts available

This programme provides advanced contemporary training in parasitology and the study of disease vectors. The broad scope of the programme ranges from the biology, immunology, ecology and population biology of the organisms to public health, disease epidemiology and tropical health issues. In addition to providing a solid foundation in parasite and vector biology, the programme provides practical experience of essential techniques, as well as significant theoretical and practical knowledge in all important and topical areas of the field. Following the taught component, participants complete a dissertation including a period of applied research either overseas or in Liverpool.

AIMS

LSTM education courses are taught within a dynamic environment by staff working at the cutting-edge of research in tropical medicine and global health. They are designed to enable the professional development of the student, to be relevant to students from both the UK and overseas and to promote approaches to study that will enable students to continue their learning into the future. 

This course aims to: 

To equip students with the knowledge and practical skills needed to develop a career in research, training or control of parasitic and vector-borne diseases.

To provide practical experience of a range of specialised technical and analytical skills relevant to the study of parasites and disease vectors.

To enable students to conduct independent research in the laboratory and/or field.

To produce graduates who are experienced, committed, informed, proactive and effective professionals, capable of taking substantial and leading professional roles.

To facilitate high quality learning that is informed by critical analysis of current research.

To develop independent and reflective approaches to study that will enable graduates to continue to learn in the future.

CAREERS

Over many years, we have educated hundreds of Masters students, many of whom have established successful careers in research in the academic or private sectors, or who have gone on to work in development as part of government or NGO teams. Graduates of the MSc Biology & Control of Parasites and Disease Vectors typically follow careers in research (some in LSTM) or training in areas related to the control of infectious disease, in particular parasitic and vector-borne tropical diseases. Other careers paths have led to teacher training, working overseas for NGO’s, military and public health-related careers.



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Geographical Information Systems (GIS) has grown rapidly to become a major component of information technology, creating distinctive methods of data analysis, algorithms and software tools. Read more

Why take this course?

Geographical Information Systems (GIS) has grown rapidly to become a major component of information technology, creating distinctive methods of data analysis, algorithms and software tools.

This course emphasises the acquisition of practical GIS skills. We use a wide range of industry-standard software tools and a structured approach to the analysis of spatial data through project work.

What will I experience?

On this course you can:

Get hands-on experience of using instruments such as GPS, Total Stations and 3D laser scanners
Be taught by experts, who have extensive industrial and consultancy experience and strong research portfolios
Practise your GIS data collection skills in a range of environments

What opportunities might it lead to?

The wide range of career opportunities across public and private sectors and in university-based research, coupled with the rapid rate of technological change, mean that major organisations and industrial firms are finding it essential to update their skills through advanced study. We therefore aim to meet this demand by tailoring our course to the needs of both regional and national markets.

Here are some routes our graduates have pursued:

Environmental consultancies
Geographical information science specialists
Working for the Environmental Agency
Working for the Ordnance Survey

Module Details

The academic year is divided into two parts. The first part comprises the lecture, workshop, practical and field work elements of the course, followed by a dissertation which will take approximately five months to complete.

Here are the units you will study:

Principles of Geographic Information Science: Beginning with an overview of the development of GIS, the first part of this unit examines data sources and data capture, as well as hardware and software tools. The second part deals with vector-based data structures and data management, followed by vector GIS operations, such as overlay and buffering. You will undertake a project to create a GIS of your own, which may be presented as a seminar session. Practical exercises are undertaken using MapInfo. You will then go on to develop an understanding of raster-based approaches to GIS, cartographic modelling and related areas of image processing which are often applied in remote sensing. Topics include raster data models and data compression techniques, raster GIS and cartographic modelling, imaging systems and image processing, geometric correction techniques and GIS/remote sensing integration in the raster domain. Practical work uses MapInfo, ArcGIS - ArcMap and ERDAS Imagine.

GIS and Database Management Systems: Your major focus on this unit will be the use of industry-standard methods and tools to develop competence in the successive stages of database design, development and implementation. You will have an introduction to data analysis techniques, followed by an examination of alternative types of database system and the rules of relational database design. There is extensive treatment of the SQL query language in standard databases and for attribute query within a GIS. You will be introduced to advanced topics including database programming and computer-aided database design. You will also consider the Object-Relational databases and spatial data types, explore the use of spatial queries using the ORACLE relational database management system and examine procedural database programming and web database connectivity. Practical work for this unit uses the ORACLE relational database management system, running in full client-server mode.

Applied Geographic Information Systems: On this unit you will develop a general, inferential, model-based approach to the analysis of quantitative data within a geographical framework. You will examine a range of underlying concepts including model specification, bias, linearity, robustness and spatial autocorrelation. You will subsequently develop these in the context of a unified framework for analysis. Practical work is based on ArcGIS - ArcMap.

Research Methods and Design: This unit will introduce you to the basic principles of research design and methodology, enabling you to develop a critical approach to the selection and evaluation of appropriate methods for different types of research problem.

Modelling and Analysis and the Web: This unit gives you the chance to consider the use of GIS technology for creating terrain models and explore the basics of photogrammetry, as well as analytical and digital techniques for photogrammetric data capture. You will also look at Orthophotography, LiDAR and RADAR systems. ArcGIS is used for spatial analysis, such as buffering and overlay techniques. You will also explore and exemplify data transfer between GIS software systems and technologies for internet-based GIS.

Dissertation: This provides an opportunity for you to pursue a particular topic to a greater depth than is possible within the taught syllabus. It can take a variety of forms, for example GIS-based analysis of original data sources and digital datasets, case studies of GIS adoption in public or private sector organisations, the development of new software tools/applications or the design of GIS algorithms. The final submission takes the form of an extended written report or dissertation of a maximum of 15,000 words.

Programme Assessment

The course provides a balanced structure of lectures, seminars, tutorials and workshops. You will learn through hands-on practical sessions designed to give you the skills in laboratory, computer and field techniques. The course also includes extensive field work designed to provide field mapping and data collection skills.

The majority of assessment takes the form of practical exercises and project-based activity. This enables you to become familiar with industry-standard software systems and develop your skills by applying your newfound expertise in areas that particularly interest you.

Student Destinations

GIS technology is now very widely deployed in many organisations ranging from utility companies, telecommunications networks, civil engineering, retailing, local and national government, international charities and NGOs, the National Health Service, environmental organisations, banking and finance, and insurance. GIS has become an essential part of the world's information infrastructure.

You can expect to go on to find work in organisations such as local authorities, health authorities, conservation organisations, banks and insurance companies, amongst others. Many of our previous graduates are now employed all over the world, working on a whole variety of GIS-related projects in a very wide range of different organisations and industries.

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This programme is intended for those who wish to enhance their understanding of the role of microorganisms in animal health and disease, and provides an excellent grounding in molecular biology, immunology, epidemiology and microbiology. Read more

This programme is intended for those who wish to enhance their understanding of the role of microorganisms in animal health and disease, and provides an excellent grounding in molecular biology, immunology, epidemiology and microbiology.

This grounding leads into the study of the complex mechanisms of host/microbe interactions that are involved in the pathogenesis of specific animal diseases, and provides insights into diagnosis and interventions, such as vaccines, essential for disease control.

You will enhance your critical and analytical skills and gain hands-on experience in the diagnosis of veterinary diseases, such that you may identify problems, formulate hypotheses, design experiments, acquire and interpret data, and draw conclusions.

Programme structure

This programme is studied full-time over one academic year.

Example module listing

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Who is the programme for?

This is a full or part-time programme, intended mainly for graduates, those already working in veterinary diagnostic/research laboratories and staff from other laboratories who want to enhance their understanding of the role of microorganisms in animal health and disease.

Pharmaceutical research personnel, policymakers, veterinarians, public health personnel and environmental biologists will also benefit.

Part-time and short course study

Most modules are offered as standalone short courses. The fee structure for short courses is different to that for registered students, and details may be obtained via admissions enquiries, please refer to the contact details on this page.

The option to study the MSc on a part-time basis is only available following successful completion of three modules as stand-alone/CPD. Please contact the for further information.

Programme partners

This Masters programme is delivered by a consortium comprising the University of Surrey and two world class veterinary microbiology institutions: the BBSRC funded Pirbright Institute (PI), and the Government sponsored Animal & Plant Health Agency (APHA).

The Veterinary Medicines Directorate (VMD) and Public Health England (PHE) also contribute to the programme.

Visits

You will have the unique opportunity to gain hands-on experience in the diagnosis of important veterinary diseases within the world reference laboratories of the APHA and Pirbright Institute (PI).

There will also be an opportunity to visit Public Health England (PHE) to gain a detailed knowledge of how zoonotic diseases outbreaks are investigated, and to visit the Veterinary Medicines Directorate (VMD), a livestock abattoir and an intensive livestock farm.

Colleagues from the CEFAS laboratory will also contribute to the programme, and further research training will be provided during your practical research project.

Educational aims of the programme

This is a one year full-time programme aimed at preparing graduates to work in a range of fields in which a detailed understanding of veterinary microbiology is a valuable asset.

These fields include research, commerce, government and policy, reference laboratory and diagnostic work, epidemiology and disease mapping, veterinary science, farming especially animal production, wild and zoo animal conservation and education.

As such, it is intended that graduates will achieve the highest levels of professional understanding of veterinary microbiology within a range of contexts.

The programme combines the study of the theoretical foundations of, and scholarly approaches to, understanding the application and various practices of veterinary microbiology within the contexts described above along with the development of practical and research skills.

The main aims are to enable students to:

  • Acquire sound knowledge of the major principles of veterinary microbiology
  • Develop the skills to perform relevant interpretation and evaluation of data
  • Apply those acquired skills in practice through research
  • To utilise acquired knowledge and evaluative skills to communicate successfully with stakeholders

Programme learning outcomes

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas.

The learning outcomes have been aligned with the descriptor for qualification at level 7 given in the Framework for Higher Education Qualifications (FHEQ) produced by the Quality Assurance Agency (QAA) for Higher Education.

Knowledge and understanding

Following completion of the programme, students should display knowledge of:

  • The main principles of current veterinary microbiology
  • The methods and approaches used for the molecular characterisation, and diagnosis of disease agents
  • The main principles of infectious diseases epidemiology
  • The analysis of disease and disease carriage that impact on the development and application of control measures to combat diseases
  • Modes of control of infectious diseases
  • Modes of transmission
  • The various aspects of host pathology and immune responses to disease agents
  • Analytical skills to allow interpretation of data and formulation of conclusions

Intellectual/cognitive skills

Following completion of the programme, students should be able to:

  • Critically appraise scholarly and professional writing on a wide range of subjects pertaining to the various aspects of veterinary microbiology
  • Critically analyse experimental data to enable the formulation of hypotheses
  • Design relevant experiments to test formulated hypotheses
  • Efficiently analyse new developments in technology and critically assess their utilisation to answer existing and new problems

Professional practical skills

Following completion of the programme, students should be able to:

  • Plan and execute an experiment/investigation, act autonomously and demonstrate originality
  • Analyse numerical data using appropriate computer tools including specialist computer packages
  • Communicate experiments at a project level, including report writing
  • Perform specific specialised experimental skills

Global opportunities

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.



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This programme is delivered jointly by the School and the Royal Veterinary College (RVC). It addresses a broad range of topics under the One Health paradigm and provides a foundation in the principles of diseases in the context of sociological systems, global health and food safety. Read more
This programme is delivered jointly by the School and the Royal Veterinary College (RVC). It addresses a broad range of topics under the One Health paradigm and provides a foundation in the principles of diseases in the context of sociological systems, global health and food safety. Students develop skills related to methodology, transdisciplinary interactions and using a systems approach.

This course is also available as a Postgraduate Diploma

Graduates from this programme will have the knowledge and skills provided by experienced scientists in order to be able to respond rapidly and effectively to outbreaks of disease as well as controlling endemic disease at the interface between humans, animals and the environment.

Visit the website http://www.lshtm.ac.uk/study/masters/onehealth.html

Objectives

By the end of this course, students should be able to:

- understand the One Health concept and approach problem solving using a transdisciplinary methodology

- understand the origin, context and drivers of infectious disease at the human, animal and environment interface

- evaluate impacts of multi-host infections on human, animal and ecosystem health and economics directly, or indirectly via food, vectors or the environment

- develop a One Health systems approach to complex disease issues in monitoring, surveillance, diagnosis, prevention and control

- critically review published literature

- design and complete a research project (MSc only)

Structure

Term 1:
There is a one-week orientation period that includes an introduction to studying at the School and the Royal Veterinary College, followed by four compulsory modules:

- Foundations of One Health
- Introduction to Disease Agents for One Health
- Infectious Disease Emergence
- Introduction to One Health Epidemiology

Terms 2 and 3:
All students take three compulsory modules:

- One Health Economics
- One Health Skills
- Medical Anthropology and Public Health

In addition, students choose a fourth module from the following:

- Vector Biology and Vector-Parastite Interactions
- Environmental Epidemiology
- Epidemiology and Control of Communicable Diseases
- Globalisation and Health

Project report (MSc only):
During the summer months (July - August), students complete a research project on a topic in one health, for submission by early September.

Assessment:
Assessment takes place by eight end-of-module examinations, in-course assignments and by project report and an oral examination.

Intercalating this course

Undergraduate medical students can take a year out either to pursue related studies or work. The School welcomes applications from medical students wishing to intercalate after their third year of study from any recognised university in the world.

Why intercalate with us?:
Reputation: The School has an outstanding international reputation in public health & tropical medicine and is at the forefront of global health research. It is highly rated in a number of world rankings including:

- World’s leading research-focused graduate school (Times Higher Education World Rankings, 2013)
- Third in the world for social science and public health (US News Best Global Universities Ranking, 2014)
- Second in UK for research impact (Research Exercise Framework 2014)
- Top in Europe for impact (Leiden Ranking, 2015)

Highly recognised qualification: possessing a Master's from the School will give you a focused understanding of health and disease, broaden your career prospects and allow you to be immersed in research in a field of your choice.

Valuable skills: you will undertake an independent research project (summer project) in your chosen topic, equipping you with research skills that will distinguish you in a clinical environment. While your medical qualification will give you a breadth of knowledge; undertaking an intercalated degree will allow you to explore your main area of interest in greater depth.

Alumni network: the School has a strong international and diverse alumni community, with more than 20,000 alumni in over 180 countries.

MSc vs. BSc: undertaking an MSc is an excellent opportunity to develop in-depth specialist knowledge in your chosen topic and enhance your skills in scientific research. Postgraduate qualifications are increasingly sought after by clinicians and possessing a Masters qualification can assist you in your future career progression.

Find out how to apply here - http://www.lshtm.ac.uk/study/masters/onehealth.html#sixth

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Changing environmental, social and agricultural conditions are a threat to animal and human health and welfare. Many infectious diseases can pass between animals and humans, while food production, human diet and community stability are harmed by diseases that infect livestock and wildlife. Read more
Changing environmental, social and agricultural conditions are a threat to animal and human health and welfare.

Many infectious diseases can pass between animals and humans, while food production, human diet and community stability are harmed by diseases that infect livestock and wildlife. Emerging veterinary infectious diseases and human diseases, such as highly pathogenic avian influenza viruses, emphasise the threat posed by these issues.

The One Health approach recognises the relationship between health and disease at the human, animal and environment interfaces and has become an important focus in both medical and veterinary science. It promotes a “whole of society” treatment of health hazards and a systemic change of perspective in the management of risk.

Under the microscope

If you are interested in One Health and the control of infectious disease (particularly in the developing world), then this unique course could be for you. We welcome applications from individuals with a background in public health, veterinary sciences, animal or biological sciences, social and environmental sciences, ecology and wildlife health. If you are interested in this field, but do not have the relevant background, please speak with the course directors who can consider such cases on an individual basis.

The course is delivered jointly by the RVC, University of London and the London School of Hygiene and Tropical Medicine (LSHTM).

The course

The MSc consists of eight modules of 15 credits each, plus a compulsory research project (MSc only) of 60 credits -15 credits for integration of One Health principles learnt through development of and writing a research proposal and 45 credits for the empirical or trans-disciplinary innovative study.

The MSc consists of the following modules:
- Foundations of One Health
- Introduction to disease agents for One Health
- Infectious disease emergence core module
- Introduction to One Health epidemiology and surveillance
- Economics of One Health
- One Health skills development
- Medical anthropology and public health
- Optional module choice from; vector biology and vector parasite interactions, environmental epidemiology, epidemiology and control of communicable diseases, and globalisation and health
- Research project (MSc only)

How will I learn?

The MSc may be completed full-time in one year or part-time over two to three years, and consists of eight taught modules and a research project.

The PGDiploma is shorter (eight modules with no research project component) and may be completed in two terms.

The course starts in September each year and you will split your time between the RVC and LSHTM. Students studying the MSc will then undertake a four-month research project in an area and country of their choice.

Learning outcomes

The course will provide you with:

- A comprehensive foundation on the principles of diseases in the context of socio-ecological systems, global health and food safety
- Knowledge and skills in relation to One Health methodologies, transdisciplinary interactions and in using a systems approach

At the end of the course you will be able to:

- Understand the One Health concept and approach problem solving using a trans-disciplinary methodology
- Understand the origin, context and drivers of infectious disease at the human, animal and environment interface
- Evaluate impacts of multi-host infections on human, animal and ecosystem health and economics directly, or indirectly, via food, disease vectors or the environment.
- Develop a One Health systems approach to complex disease issues in monitoring, surveillance, diagnosis, prevention and control
- Critically review published literature
- Design a research project (MSc students only)

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The Department of Mathematics offers graduate courses leading to M.Sc., and eventually to Ph.D., degree in Mathematics. The Master of Science program aims to provide a sound foundation for the students who wish to pursue a research career in mathematics as well as other related areas. Read more
The Department of Mathematics offers graduate courses leading to M.Sc., and eventually to Ph.D., degree in Mathematics. The Master of Science program aims to provide a sound foundation for the students who wish to pursue a research career in mathematics as well as other related areas. The department emphasizes both pure and applied mathematics. Research in the department covers algebra, number theory, combinatorics, differential equations, functional analysis, abstract harmonic analysis, mathematical physics, stochastic analysis, biomathematics and topology.

Current faculty projects and research interests:

• Ring Theory and Module Theory, especially Krull dimension, torsion theories, and localization

• Algebraic Theory of Lattices, especially their dimensions (Krull, Goldie, Gabriel, etc.) with applications to Grothendieck categories and module categories equipped with torsion theories

• Field Theory, especially Galois Theory, Cogalois Theory, and Galois cohomology

• Algebraic Number Theory, especially rings of algebraic integers

• Iwasawa Theory of Galois representations and their deformations Euler and Kolyvagin systems, Equivariant Tamagawa Number
Conjecture

• Combinatorial design theory, in particular metamorphosis of designs, perfect hexagon triple systems

• Graph theory, in particular number of cycles in 2-factorizations of complete graphs

• Coding theory, especially relation of designs to codes

• Random graphs, in particular, random proximity catch graphs and digraphs

• Partial Differential Equations

• Nonlinear Problems of Mathematical Physics

• Dissipative Dynamical Systems

• Scattering of classical and quantum waves

• Wavelet analysis

• Molecular dynamics

• Banach algebras, especially the structure of the second Arens duals of Banach algebras

• Abstract Harmonic Analysis, especially the Fourier and Fourier-Stieltjes algebras associated to a locally compact group

• Geometry of Banach spaces, especially vector measures, spaces of vector valued continuous functions, fixed point theory, isomorphic properties of Banach spaces

• Differential geometric, topologic, and algebraic methods used in quantum mechanics

• Geometric phases and dynamical invariants

• Supersymmetry and its generalizations

• Pseudo-Hermitian quantum mechanics

• Quantum cosmology

• Numerical Linear Algebra

• Numerical Optimization

• Perturbation Theory of Eigenvalues

• Eigenvalue Optimization

• Mathematical finance

• Stochastic optimal control and dynamic programming

• Stochastic flows and random velocity fields

• Lyapunov exponents of flows

• Unicast and multicast data traffic in telecommunications

• Probabilistic Inference

• Inference on Random Graphs (with emphasis on modeling email and internet traffic and clustering analysis)

• Graph Theory (probabilistic investigation of graphs emerging from computational geometry)

• Statistics (analysis of spatial data and spatial point patterns with applications in epidemiology and ecology and statistical methods for medical data and image analysis)

• Classification and Pattern Recognition (with applications in mine field and face detection)

• Arithmetical Algebraic Geometry, Arakelov geometry, Mixed Tate motives

• p-adic methods in arithmetical algebraic geometry, Ramification theory of arithmetic varieties

• Topology of low-dimensional manifolds, in particular Lefschetz fibrations, symplectic and contact structures, Stein fillings

• Symplectic topology and geometry, Seiberg-Witten theory, Floer homology

• Foliation and Lamination Theory, Minimal Surfaces, and Hyperbolic Geometry

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Postgraduate Loans are now Open for Home/EU students. -. https://www.gov.uk/postgraduate-loan/how-to-apply. Scholarships & Discounts available. Read more

Postgraduate Loans are now Open for Home/EU students - https://www.gov.uk/postgraduate-loan/how-to-apply

Scholarships & Discounts available

Molecular biology and genomics play an increasingly important and exciting role in research on medically important parasites and arthropods, and this award provides advanced training in this field. It provides an important foundation of knowledge of the basic biology of parasites and vectors, followed by specialised modules on the molecular and cellular biology and functional genomics of parasites and vectors, as well as related public health, and tropical health issues. There is a significant practical component throughout the programme, and the laboratory work undertaken provides a wide range of techniques that would be highly relevant to a future research career. Following the taught component, participants complete a dissertation including a period of applied research either overseas or in Liverpool.

AIMS

LSTM education courses are taught within a dynamic environment by staff working at the cutting-edge of research in tropical medicine and global health. They are designed to enable the professional development of the student, to be relevant to students from both the UK and overseas and to promote approaches to study that will enable students to continue their learning into the future. 

This course aims to: 

Equip students with the knowledge and practical skills to develop a career in molecular research in parasitology or vector biology.

Provide practical experience of a range of specialised technical and analytical skills relevant to the study of the molecular biology of parasites and disease vectors.

Enable students to conduct independent research in the laboratory and/or field.

Produce graduates who are experienced, committed, informed, proactive and effective professionals, capable of taking substantial and leading professional roles.

Facilitate high quality learning that is informed by critical analysis of current research.

Develop independent and reflective approaches to study that will enable graduates to continue to learn in the future.

CAREERS

Many alumni of LSTM hold prominent positions in health ministries, universities, hospitals, and international organisations throughout the world. Graduates are competitively placed to begin PhD programmes, seek employment as research assistants, work in developing countries with a wide variety of employers, or return to previous employers with enhanced knowledge and skills with which to advance their existing careers. Graduates of the MSc Molecular Biology of Parasites and Disease Vectors have undergone excellent general preparation for a career in laboratory research in biological sciences, in which molecular biology is widely applied, and are particularly well placed for careers in research or training in areas related to the molecular biology of parasitic and vector-borne tropical diseases.

TESTIMONIALS

Professor Mark Taylor "Parasitology at LSTM studies how best to treat and control parasitic diseases such as malaria and the Neglected Tropical Diseases. We cover the entire spectrum of translational research from the discovery of new drugs, vaccines and diagnostics through to large scale global programmes aimed at eliminating diseases such as elephantiasis and river blindness. In addition to the traditional parasites and their vectors, we also work on other important tropical diseases such as snakebite, arboviruses, and tuberculosis."



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About the Course. This 1 year course leads to an internationally recognised MRes qualification that provides training in transferable skills essential for those wishing to pursue post-graduate PhD, commercial or industrial research opportunities. Read more

About the Course

This 1 year course leads to an internationally recognised MRes qualification that provides training in transferable skills essential for those wishing to pursue post-graduate PhD, commercial or industrial research opportunities. Focusing on parasites and the diseases that they cause, you will gain expert knowledge in the detection, prevention and control of protozoan as well as metazoan animal and human pathogens. You will be trained in specialisms including biochemistry, molecular biology, whole organism/cell culture and manipulation, bioinformatics, proteomics, transcriptomics, genomics, functional genomics, drug discovery, vaccinology, biomarker discovery, genetics/epigenetics, epidemiology, vector/intermediate host biology and ecology.

At the end of the course you will understand how interdisciplinary methods can be brought to bear on controlling some of the deadliest infectious organisms on the planet and be ready to pursue your career in parasitology.

Why study Parasite Control at Aberystwyth?

Parasitism is the most successful lifestyle on the planet and leads to diverse and highly-damaging infectious diseases of agricultural, veterinary and biomedical significance. Therefore, a greater understanding of the parasite species responsible for these conditions and the means by which they are controlled remain a priority for scientists, health care professionals and farmers in this 21st Century. For example, it is recognised that parasitic worms infect greater than 1 billion people worldwide with some species causing between $700 million-$1 billion USDs in economic losses per annum. The development of novel, creative and integrated control strategies are urgently needed to combat the growing threat of changing parasite distributions due to climate change, human migration, animal transportation and farming practices. This MRes course will provide you with a range of vocational skills and prepare you for professional employment or further post-graduate PhD studies in Parasitology or related disciplines (i.e. infectious diseases, public health, epidemiology, etc.).

IBERS continuously maintained an excellent internationally-recognised reputation in parasitological research since the 1930s. One of the British Society of Parasitology’s founding members and two of its past presidents were IBERS Parasitologists. More recently, IBERS appointments and University investments have increased critical mass in Parasitology leading to the formation of the Parasitology and Epidemiology Research Group (in 2007) as well as the Barrett Centre for Helminth Control (in 2016). The creation of both research groupings has facilitated greater interactions with animal health and pharmaceutical/biotech companies as well as increased research grant capture derived from government, research council and charitable funding bodies.

Why study at Aberystwyth?

With 360 members of staff (principle investigators, technicians and post-doctoral fellows), 1350 undergraduate students and more than 150 postgraduate students, IBERS is the largest research and teaching institute within Aberystwyth University. Excellence in teaching was recognised by outstanding scores in the National Student Satisfaction Survey (NSS 2017) and being awarded University of the Year for Teaching Quality by the Times and Sunday Times Good University Guide 2018. Employability data from the Recent Destinations of Leavers from Higher Education (DLHE, 2017) shows that 97% of IBERS graduates were in work or further study six months after leaving Aberystwyth University. The economic and social impact of IBERS research was recognised in 2011 when IBERS won the national BBSRC Excellence with Impact Award.  

Course Details

An aspect of this course that uniquely positions itself from other Masters level Parasitology courses in the UK is the 12-month dissertation project (Semesters 1-3). Working under the supervision of active researchers in the field, you will collaboratively develop a research project on diverse topics such as (but not inclusive) intermediate host and vector control, anthelmintic drug and target discovery, biomarker identification, visual cue selection for arthropod vectors, mathematical modelling of disease transmission, host responses to parasite biomolecules, parasite and host population studies and functional genomics manipulation of parasites. A list of available projects and supervisors will be advertised closer to the start of each academic year. Your supervisor/supervisory team will mentor you in hypothesis and discovery driven experimental design, provide training in lab-based and computer-assisted methodologies, arrange instruction in analytical techniques, aid in the trouble-shooting of experimental challenges, assist you in the interpretation of results and prepare you for successful oral presentations. You will also be guided in how to most efficiently communicate your results during the dissertation write-up. It is expected that during this year long research project you will become an expert in your topic.   

Please refer to our couse web pages for full details of course modules.

Employability

Careers

This course is an ideal training programme for those wishing to:

-         Pursue PhD studies;

-         Work in industry, charities or funding bodies;

-         Improve animal and human health;

-         Influence governmental policies.

 

Skills

Throughout this course you will:

·        Develop strong data collection/analysis, fieldwork and laboratory skills;

·        Enhance your scientific communication and team work skills;

·        Write for a range of audiences including academics and the wider public;

·        Enhance your analytical abilities, critical thinking and problem solving skills;

·        Develop study and research skills;

·        Direct and sustain a self-initiated programme of study underpinned by good time management skills;

·        Work effectively and independently;

·        Hone your project management skills to deliver a demanding combination of research, analysis, communication and presentation

 

How will I learn?

During the one year of full-time study students complete 40 60 credits of core modules centred on parasitology, parasite control and a further 20 credits focusing on laboratory techniques & research methodologies. The taught modules are assessed by scientific writing assignments (such as reports, critical reviews, essays and journalistic articles), presentations, contribution to group discussions in seminars and online assignments. The core element of this course is the 120 credit MRes Dissertation, during which students will have supervision meetings to give them guidance before undertaking a prolonged period of experimental work/data gathering, research, and writing up of the dissertation. All postgraduate students in IBERS also have a named personal tutor, with whom they can discuss personal or domestic concerns that impact on their studies. Subsequent successful submission of your dissertation leads to the award of an MRes.



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Mechanical Engineering is the application of physical science to practical problem solving. Read more
Mechanical Engineering is the application of physical science to practical problem solving. As a Mechanical Engineer you could be working on anything from a simple component such as a switch, to more complex machines such an internal combustion engine or an entire system such as an automobile or a factory production line.

The MSc degree in Mechanical Engineering is a 1 calendar year conversion programme that is part of a suite of programmes offered in Mechanical Engineering at Queen Mary University of London. This programme is aimed at students who already have a science background (e.g. biology, mathematics, chemistry, physics), and who wish to convert to a career in Mechanical Engineering.

The Mechanical Engineering degree programmes at QMUL are delivered by a large number of specialist academic staff, who, in addition to their teaching, are involved in internationally recognised research in a wide range of topics, including:

Energy generation and conversion, including alternative and sustainable sources
Heat transfer and fluid mechanics
Computational engineering, both solids and fluids
Control engineering
Robotics
Materials science, including structural and functional materials
The programme structure is modular in format. During Semester A, students will take the compulsory module Engineering Methods, which exposes them to essential engineering techniques and philosophy. Depending on their background, they will further take 3 conversion modules from Vector Calculus, Energy Conversion Analysis, Computer Aided Engineering and Materials Selection. In Semester B students have the choice to specialise in one of the main areas of Solid Mechanics, Robotics and Automation, and Thermofluids and Combustion.

A 60 credit research project is to be undertaken using our research activities and our state of the art facilities. Several high performance computing clusters owned by the university support a full spectrum of computational research. Our well equipped laboratories include a wide range of IC engines, heat transfer facilities, wind tunnels, an anechoic chamber, a UK CueSim Flight Simulator and France-Price Induction Jet engine test bench, and materials synthesis and characterisation labs. Nanotechnology research is further supported by the facilities and expertise provided by Nanoforce, a company directly associated with the School.

* All new courses are required to undergo a two-stage internal review and approval process before being advertised to students. Courses that are marked "subject to approval" have successfully completed the first stage of this process. Applications are welcome but we will not make formal offers for this course until it has passed this second (and final) stage.

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