Research group

Microfluidics and Sensors

Two fingers wearing globes holding a microchip

Microfluidics is the interdisciplinary study of the behaviour, manipulation and application of fluid at the microscale. It underpins the concept of the lab-on-a-chip, where multiple key components and operations are integrated onto one small platform.

About

 

This is an important underlying technology with applications across a diverse range of fields including medicine, chemistry and oceanic research. 

Scientists across the Institute of Life Sciences have been driving microfluidics research and application forward for more than two decades. With a translational approach many of our fundamental science discoveries have resulted in novel micro-engineered devices which have paved the way for how patients are treated in hospital.  

Our research teams span fields from engineering and physics to medicine and biology and are carrying out research into areas such as single cell analysis, organ-on-a-chip, neuroscience, clinical diagnostics, personalised medicine and environmental monitoring. Our scientists use microfluidic devices and systems to find solutions to some of today’s biggest challenges including antimicrobial resistance and ocean climate changes. 

As well as using microfluidics to provide engineering solutions for biological and healthcare applications our scientists are also training the next generation of microfluidics experts. Our postgraduate students work alongside international leaders in their field, shaping and developing research projects as well as conducting their own research investigations. 

Staff and students alike also have access to cutting-edge facilities which contain state of the art analytical equipment, dedicated cell and tissue culture laboratory and rapid prototyping clean rooms. 

People, projects and publications

People

Dr Jeremy Blaydes

Associate Professor

Research interests

  • Transcriptional responses to pathways: roles in the causes and treatment of cancer Intra-cellular stress-response pathways are activated in response to potentially deleterious conditions in the cell’s environment. In single celled organisms these pathways are generally involved in ensuring the survival and replication of the individual cell. In complex multi-cellular organisms such as man, they are critical in maintaining the normal function of each organ in the body, and the survival of the organism as a whole. Stress-response pathways play a key role in the patho-physiology and treatment of many diseases, including cancer.At almost every stage of the development of a tumour, cells are exposed to some form of stress. Examples include exposure to toxic compounds or radiation, loss of contact with other cells or the extra-cellular matrix, lack of oxygen (hypoxia), acidic pH, the activation of oncogenes, induction of cellular senescence, oxidative damage or depletion of essential metabolites. In some circumstances, the activation of a stress-response pathway will actually help the tumour cell to survive and proliferate. In other situations the response is cell cycle arrest or programmed cell death (apoptosis), providing a barrier to further tumour development that the tumour may ultimately circumvent through the acquisition of a mutation in one of the genes within the stress-response pathway. The p53 tumour suppressor protein is a key component of one such stress-response pathway, and virtually all cancers loose functionality of the p53-stress response pathway. Many current and prospective treatments for cancer work by either inhibiting, or re-activating stress response pathways.Our work focuses on the role of regulators of gene transcription in the response of cancer cells to stress. We have a long-standing interest in the p53 protein, a stress-activated transcriptional activator. We have also developed interests in other pathways which regulate gene transcription and cancer cell proliferation in response to stress and changes in cell metabolism. We aim to determine the role of these pathways in the development of cancer, and establish the potential for targeting components of the pathways for cancer therapy.Our group is based in the purpose-built Somers Cancer Research Building. Modern, well equipped laboratories provide us with an excellent research environment, and the opportunity to interact with researchers working on related areas of cancer biology.
  • Some Example Projects: Regulation of HDM2 and HDMX proteins The HDM2 oncoprotein is the major negative regulator of p53 function in the cell. In the late 1990s work from a number of groups, including Blaydes et al , demonstrated that HDM2 could be targeted in cancer cells to re-activate the p53 stress-response pathway. Subsequently, small molecule inhibitors of HDM2 have been developed that show great promise in pre-clinical trials. We have undertaken a series of projects examining how HDM2, and its paralogue HDMX is regulated in cancer cells (see Phillips et al, 2010, 2008, 2007, 2006a, 2006b and Phelps et al 2005, 2003). A particular interest of our work has been how HDM2 and HDMX protein synthesis is controlled in response to cell-signalling pathways in different cell types, and how this affects p53 function in these cells.
  • Role of CtBP transcriptional repressors in cancer cell proliferation and survival In common with p53, CtBP1 and CtBP2 proteins were discovered through their physical association with a viral oncoprotein. We have shown that CtBPs also interact with HDM2 protein, and can consequently regulate p53 function (Mirnezami et al, 2003). The main function of CtBPs is as transcriptional co-repressors. They are involved in a range of cellular processes, depending upon the transcriptional repressor that recruits them to DNA, and they suppress the transcription of genes that cause apoptosis (reviewed in Bergman et al, 2006a). CtBP activity is modified by UV radiation and glycolytic metabolism, suggesting that CtBPs regulate cell survival in response to cellular stress. From 2004 The Breast Cancer Campaign has funded work in our laboratory to study the role of CtBPs in breast cancer. Our studies have progressed from studies of the basic mechanisms whereby CtBPs control breast cancer proliferation and survival (Birts et al 2011 and Bergman et al 2009, 2006a) to their impact on the response to current chemotherapies (Birts et al 2010) to the demonstration that CtBPs are themselves a therapeutically tractable potential molecular target for cancer therapy (Birts et al 2013). Our group was named Breast Cancer Campaign “Team of the Year 2011” on the basis of this work.
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Professor Jeremy Frey

Professor of Physical Chemistry

Accepting applications from PhD students

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Professor Jeremy Webb

Professor of Microbiology

Research interests

  • Microbial biofilms and their control
  • Adaptive biology and evolution of microorganisms
  • Biofilm-associated infection

Accepting applications from PhD students

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Miss Jessica Boxall

CORE eCRF Data Analyst

Research interests

  • Public Health
  • Nutrition
  • Food Security
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Professor Jessica Teeling

Prof of Experimental Neuroimmunology

Research interests

  • Neuroimmunology
  • Systemic inflammation
  • Oral microbiome

Accepting applications from PhD students

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Professor Jo Slater-Jefferies PhD, MBA, CMgr, MCMI

CEO-National Biofilms Innovation Centre
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Professor Joanna Sofaer

Professor of Archaeology

Research interests

  • The role of cultural and community assets in health and wellbeing
  • The relationship between heritage and wellbeing
  • The social value of archaeology 

Accepting applications from PhD students

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Professor Joanne Turney

Professor of Fashion and Textiles

Accepting applications from PhD students

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Professor Joerg Wiedenmann

Professor of Biological Oceanography

Research interests

  • Coral Reef Biology and Ecology
  • Coral Bleaching
  • Nutrient biology of coral reefs

Accepting applications from PhD students

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Dr Joern Werner

Reader in Structural Biology
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Interdisciplinary research teams collaborate across engineering technologies with applications in medicine, biology and environment to create novel and disruptive research activity in areas including diagnostics, infectious diseases and water testing.
Professor of Bioelectronics

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