Synthetic Biology PhD
The overall aim of the Synthetic Biology is to address major environmental, health and societal challenges by engineering biological systems such that they display functions that do not exist in nature, as well as re-designing existing biological systems so that they perform new functions. Our research focuses on three key areas of activity.
- Gene therapy: Some diseases and disorders happen because certain genes work incorrectly or no longer work at all. We are designing therapeutic interventions for human diseases and disorders by developing the technologies to correct defective genes. Our current projects within this area look at vector development for effective gene therapy, assessing and avoiding the risks of gene therapy (genotoxicity) and using the technologies of gene therapy to give new insights into cancer development.
- Microbial bioengineering: The most exploitable and engineerable organisms are bacteria, so we want to harness their capacity and diversity to create white technologies –those which cause no harm. Our research uses integrated genomics strategies to direct bacterial engineering for a number of translational applications. We look at possible ways to create novel bacteria –bacteria that can produce clean proteins, for example, or bacteria that can improve the performance of cement. Using bioengineered microbes, we look at ways to degrade environmental pollutants; generate products using alternatives to petrochemicals; and reuse waste biomaterials from biomass and biodiesel manufacture. There are even investigations within our theme into ways of addressing antibiotic resistance in medically important bacteria. We are exploring other areas, and are open to developing new lines of research that will make the best use of the strain and widely applicable tools for strain assessment and development, especially when they are directed at projects that have sustainability as part of what they seek to achieve.
- Computer sciences, statistics and maths: We are working on data analysis, bioinformatics, and system modelling to inform synthetic system 30 design and efficient laboratory engineering strategies. These outcomes will support our other strands of research.
Find out about the exciting research we do: browse profiles of our experts, discover the research groups and their inspirational research activities you too could be part of. We’ve also made available extensive reading materials published by our academics and PhD students.
Intakes
- Jan
- April
- Oct
Application Processing Time in Days: 30
Minimum English Language Requirements
| English Level Description | IELTS (1.0 -9.0) | TOEFL IBT (0-120) | TOEFL CBT (0-300) | PTE (10-90) | |
|---|---|---|---|---|---|
| Expert | 9 | 120 | 297-300 | 86-90 | |
| Very Good | 8.5 | 115-119 | 280-293 | 83-86 | |
| Very Good | 8 | 110-114 | 270-280 | 79-83 | |
| Good | 7.5 | 102-109 | 253-267 | 73-79 | |
| Good | 7 | 94-101 | 240-253 | 65-73 | |
| Competent | 6.5 | 79-93 | 213-233 | 58-65 | |
| Competent | 6 | 60-78 | 170-210 | 50-58 | |
| Modest | 5.5 | 46-59 | 133-210 | 43-50 | |
| Modest | 5 | 35-45 | 107-133 | 36-43 | |
| Limited | 4 | 32-34 | 97-103 | 30-36 | |
| Extremely Limited | < 4 | < 31 | < 93 | < 30 |
Job Opportunity Potential
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Skills Awards and Programmes
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Moving on as a graduate
We're still here for you after you finish your degree - up to 3 years after graduation
PSW Opportunity
2 Years PSW is applicable after the course completing (Bachelors level or above)
Admission Requirement / Eligibility Criteria
The general University entrance requirement for registration for a research degree is normally a First or Upper Second Class Honours degree (1st or 2:1).
An interview may be required as part of the admissions process, and if so it would be conducted by one of the academic staff members remotely via Skype, phone or other means.
A minimum score of 55%-75%. Offers within the grade range are determined by the higher education institution attended.
If you require a Tier 4 visa to study in the UK, you must prove knowledge of the English language so that we can issue you a Certificate of Acceptance for Study (CAS). To do this, you will need an IELTS for UKVI or Trinity SELT test pass gained from a test centre approved by UK Visas and Immigration (UKVI) and on the Secure English Language Testing (SELT) list. This must have been taken and passed within two years from the date the CAS is made.
English language requirements
IELTS: 7 (min 6 in all areas)
Pearson: 64 (51 in all subscores)
BrunELT: 70% (min 60% in all areas)
TOEFL: 100 (min 20)
- Course Code: SYNTHBIODFTD
- Course Type: Full Time
- Course Level: Doctoral Degree/PhD
- Duration: 03 Year
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Total Tuition Fee:
59565 GBP
Annual Cost of Living: 12006 GBP
Application Fee: N/A
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