Current research projects
Studying our Master of Research (MRes) Science allows you to focus your research interests on one or two areas of science and work towards translating your learning into research related outputs – such as a submission for a peer-reviewed publication; a peer reviewed research/knowledge transfer grant application, or a presentation.
MRes Science can be studied either full time (1-year) or part time (2-years). You will develop a wide variety of skills, experience and competence on this course, and the MRes will provide a thorough grounding for students moving towards Doctoral (PhD) studies, or pursuing research related activities as a career.
Please note this list of projects is not exhaustive and you'll need to meet and discuss the project you're interested in with a member of research staff before you apply.
MRes Science - Pharmacy and Biomedical Science research projects:
- In vitro modelling of gender-biased mental disorder using neural stem cells
- Computational modelling of the human blood-brain barrier to tackle multidrug resistance and neurodegenerative disorders
- Unravelling the therapeutic potential of bioactive ingredients in food supplements for effective nerve repair
- Mechanisms of Fin Regeneration in Zebrafish
- Screening Environmental Microbes for PET Degradation Capabilities
- Machine learning-based prediction of i-motif structures from Nanopore sequencing signal data
- Nanopore sequencing of cell-free DNA for early identification of prosthetic joint infection (PJI)
- Immunomodulatory potential of bacterial exosomes
- Development of targeted therapy for colon cancer
- Early cancer diagnosis with unique Raman spectroscopic solutions for cancer biomarker and/or location detection
- Investigating mechanisms of mitochondrial and nuclear genome stability
- Optimisation of lipid nanoparticles (LNPs) for targeted gene delivery to cancer cells
- Modified triplex-forming oligonucleotides as therapeutic agents
- Targeted delivery of large macromolecular cargoes to subcellular environments
- Protection of the stem cell state of embryonic muscle stem cells
- Effects of mechanical stimulation in the proliferation and differentiation of mesenchymal stem cells into the osteogenic lineage
- High-throughput discovery of novel antibiotics using synthetic microbiology
- State of the art correlative imaging application in the study of morphological and functional behaviour of chondrocytes cultured in traditional 2D culture versus 3D printed scaffolds
- Investigating the role of IgLON proteins in zebrafish neural development using CRISPR knockout approaches
- Transition between heart and skeletal muscle competence
- Integration of heart precursors into the beating heart
- Development of the vasculature supplying the brain
- Outgrowth of the myotome and closure of the ventral body wall
In vitro modelling of gender-biased mental disorder using neural stem cells
Supervisor: Dr Ryo Sekido
Many mental disorders and neurological diseases preferentially affect men or women. The gender biases in disease susceptibility can be mainly caused by either genetic/epigenetic or sex hormonal differences between males and females. However, the underlying molecular mechanisms are not fully understood.
Schizophrenia is a psychiatric disorder showing gender biases in symptoms and prognosis. A truncation mutation in the Disc1 gene was discovered in humans and a model mouse carrying a similar Disc1 truncation, namely Disc1tr, was generated. Since Disc1 gene expression begins in neural stem cells in the embryonic brain, neurodevelopmental origin of schizophrenia has been proposed.
In this project, we use male (XY) and female (XX) neural stem cells isolated from wildtype and the Disc1tr mutant mice. The four genetically different neural stem cells, such as XY, XX, XYDisc1tr and XXDisc1tr, will be differentiated into specific types of neurons (e.g. GABAergic and glutaminergic neurons) and glia (e.g. astrocytes and oligodendrocytes) in vitro. Sex hormones, such as testosterone or oestrogen, will be added to the in vitro differentiation system. We will characterise molecular and cellular differences between the four genotypes in the presence or absence of sex hormones. Not only will this project reveal critical factors responsible for gender biases in schizophrenia but it will also provide an insight into gender-specific treatment for other mental and neurological disorders.
Computational modelling of the human blood-brain barrier to tackle multidrug resistance and neurodegenerative disorders
Supervisor: Dr. Christian Jorgensen
By 2050 the number of people living with neurodegenerative disorders are set to double. Alzheimer’s disease in particular is set to become a public health emergency. Similarly, it's currently very difficult to treat brain cancers, including glioblastomas, in part due to the difficulty in achieving high bioavailability and brain distribution of chemotherapeutics at the tumour site. It's hoped that by employing precision medicine with molecular modelling one could improve the understanding of the role of the blood-brain barrier (BBB) in limiting the delivery of therapeutics, as well as how pumps can be regulated to improve the delivery fraction.
In addressing these problems, the BBB and its components plays a central role in the difficult task of treating central nervous system disorders (Alzheimer’s, Parkinson) and brain tumors, due to its exquisite barrier selectivity towards small molecules, with 98% of molecules being unable to cross it. This is further complicated by the P-glycoprotein (P-gp) efflux pumps in endothelium of the BBB that pump out xenobiotics from the brain. This pumping action is the root cause of multidrug resistance to chemotherapeutics in the treatment of brain cancers and gliomas. Recent confocal imaging evidence indicates that multiple BBB components, including the endothelium and its glycocalyx contribute differentially to the selectivity, and that the BBB is a multibarrier system. In our recent studies we have developed an atomic-detail model of the endothelium (Jorgensen et al., ACS Omega, 2021), as well as a a model of P-glycoprotein (Jorgensen et al. J. Med. Chem. 2023), and we have developed general approaches to measure the permeability across the endothelium (Jorgensen et al. JCAMD, 2023).
In this project, you'll build state-of-the-art computational models of the blood-brain barrier and learn to do sophisticated free-energy calculations to further our understanding of how molecules bind to the P-gp pump, and thus help in the fight towards multidrug resistance.
Unravelling the therapeutic potential of bioactive ingredients in food supplements for effective nerve repair
Supervisor: Dr. Bennett Au and Dr. Murphy Wan
The mature neurons in the adult mammalian central nervous system (CNS) lose their ability to regenerate their injured axons, leading to permanent and irreversible functional deficits in patients with severe CNS injuries such as spinal cord injury, traumatic brain injury and traumatic optic neuropathy. While the injured neurons in the peripheral nervous system (PNS) can retain some ability to regrow their axons, the rate of axon regeneration is extremely slow (1-2mm/day). This often results in an incomplete functional recovery in patients with proximal peripheral nerve injury (e.g. brachial plexus nerve injury) largely due to chronic denervation and failure in re-establishment of functional connections between damaged nerves and their target muscles. Recent studies from us (Au et. al, PNAS, 2022; Au et. al, npj Regenerative Medicine; Au et. al, Neuron, 2023) and others demonstrated that enhancing the intrinsic regenerative capacity of injured neurons not only permitted the regrowth of injured neurons, but also allow partial or even full functional recovery after traumatic injuries to the nervous system. This allows us to develop novel therapeutics that target the intrinsic growth capacity of injured neurons for effective nerve repair.
Using a multidisciplinary approach spanning from primary neuronal cultures, fluorescence/confocal microscopy, immunohistochemistry and multi-omics analysis, we aim to investigate the therapeutic potential of several bioactive ingredients derived from food supplement, and test whether these compounds can enhance the intrinsic growth capacity of injured neurons and promote in vivo axon regeneration after PNS and CNS injuries. Ultimately, we believe the outcome of this project will offer hopes to improve the functional outcomes and quality of life of patients with traumatic injuries to their nervous system.
Mechanisms of Fin Regeneration in Zebrafish
Supervisor: Jordi Cayuso
One of the aims of regenerative medicine is to design strategies that will enable us to repair damaged human tissues so that they can regain their function. Unfortunately, most human tissues have lost the capacity to regenerate and thus, they do not recover their functionality after injury or disease, e.g., spinal cord injury or cardiac infarction. In contrast, the zebrafish have the ability to regenerate most tissues, including the brain, limbs and heart. In this project, we will harness this extraordinary ability of zebrafish to understand the mechanisms of tissue regeneration.
The Eph/Ephrin signalling system is an important pathway that mediates communication between cells and is key for the formation of the nervous system, maintenance of stem cell pools and the formation of boundaries between tissues. We recently identified that Eph/Ephrin signalling is also critical for the regeneration of several tissues, including the caudal fin in zebrafish. Using this system as a model of study, we aim to obtain a better understanding of the processes that lead to successful tissue regeneration and to identify how Eph/Ephrin signalling directs these processes. This will be achieved through the analysis of the regenerating fin at the cellular and molecular level using a combination of wound healing, inflammation and growth markers and techniques such as gene knockdown, confocal microscopy, immunohistochemistry and data analysis.
The outcomes of this study will lead to a better understanding of the fundamental processes involved in tissue regeneration and will contribute to identify new strategies to improve regenerative outcomes in humans.
Screening Environmental Microbes for PET Degradation Capabilities
Supervisors: Dr Sam Robson and Prof Joy Watts
Accumulation of plastics in the environment is one of the major global challenges facing us today. Natural enzymes, such as those produced by micro-organisms (e.g., bacteria), may hold the key to breaking down plastics, with the potential to be deployed on an industrial scale.
The Centre for Enzyme Innovation (CEI) at the ϳԹ aims to identify and exploit such enzymes from the environment. They have developed a biobank of environmental samples collected from a range of sources, with potential for plastic-degrading enzymes to be present (waste sites, recycling plants, fuel tanks, sea sponges, etc.). The successful candidate will explore these samples to identify and characterise potential enzyme targets of interest for further research, and potential use for industrial deployment in the future.
In this project, you'll first select bacterial isolates of interest from the CEI biobank, culture these isolates, and perform DNA extraction in order to carry out PCR screening for known PET-degrading genes. Any isolates indicating a positive result from this PCR screening will then undergo confirmatory tests using microbiological techniques developed within the CEI (including screening using Coomassie blue staining of M9 agar and 5% PEG), as well as a novel technique developed by Charnock, 2021.
During this screening project, you'll undergo whole genome sequencing and RNA sequencing, providing the successful candidate with experience of Nanopore sequencing, bioinformatics analysis, and data exploration (e.g. de novo genome assembly, gene annotation).
Machine learning-based prediction of i-motif structures from Nanopore sequencing signal data
Supervisors: Dr Sam Robson, Dr Daniela Lopes Cardoso, Dr Garry Scarlett and Dr Fiona Myers
The aim of this project is to identify novel methods for the detection of non-standard 4-stranded ‘i-motif’ DNA structures from commonly used biophysical assays. In particular, this project will combine biophysics and genomics with machine learning approaches, to develop cutting-edge approaches for the high-throughput identification of these structures. As we understand more about the role that such structures play in metabolism and cellular function, such advanced approaches will be necessary to accurately distinguish i-motif from B-form DNA.
The i-motif is a non-standard DNA structure, very different to the typical Watson-Crick double-helix shape. The currently accepted sequence-specific definition of an i-motif over-estimates the number and misses potential i-motif forming sequences that do not follow the standard precisely. In particular, work by our collaborator Dr John Brazier has shown that the loops present in the 4-stranded structure are of great importance in the structure formation. It was previously believed that the i-motif structure was not biologically relevant and would not be seen under normal physiological conditions. However, recent evidence has directly visualised i-motif structures in the genomes of living cells under such cellular conditions. This, along with other recent evidence, strongly suggests that i-motifs play a currently under-explored role in molecular function and genomic regulation.
We have recently studied the effect of i-motifs on helicase enzymes, which act to unwind DNA during replication and translation. By using Oxford Nanopore Technologies (ONT) flow cells as real time helicase models, we have shown that helicase activity is affected by the secondary structure of i-motifs, resulting in a change to the translocation speed through the nanopore and effects at the raw signal transduction level. The successful candidate will further explore this effect and help to develop machine learning models for the prediction of i-motif structures from nanopore sequencing data.
This project will provide a powerful toolkit for identification of i-motif structures, and will link with further work within the group. This work will help in understanding the role that i-motifs play in development and disease, leading to a greater understanding of the complex machinery underpinning gene regulation, and the identification of novel targets for small molecule therapeutics.
Nanopore sequencing of cell-free DNA for early identification of prosthetic joint infection (PJI)
Supervisors: Dr Sam Robson and Dr Sharon Glaysher
Prosthetic joint infection (PJI) represents one of the most common reasons for failure among hip and knee arthroplasty, with an incidence of around 1-2%. Infection can occur early (within days of surgery) or late (over a year after surgery), and no specific early markers for infection onset exist. Given the significant costs to the NHS for corrective revision surgery, the added suffering and risks to patients from surgery, and the risk of enhancing antimicrobial resistance through the use of broad-spectrum antibiotics, a more specific predictive test for early onset of infection is required.
Over 80% of human infection is estimated to be a result of biofilm formation. Biofilms are an accumulation of microorganisms on a surface, resulting in a functional community which provides antibiotic resistance and a beneficial environment for the growth of pathogenic species that would otherwise be removed by the body’s defences. Biofilms can rupture, allowing pathogens to spread infection. To date, biofilm development and diversity on periprosthetic implants is poorly understood. It is not known whether biofilms associated with PJI differ from those in infection-free patients, or whether characteristic biofilms are associated with providing a microenvironment suitable for PJI-associated pathogens to thrive.
In this project, you'll explore the possibility of early detection of PJI from cell free DNA from blood samples collected from individuals who have undergone hip joint prosthetic replacement. This data will link to a wider-scale data set exploring the characteristic microbiome of hip joint prosthetic biofilms. This has the possibility of providing a relatively non-invasive diagnostic tool for PJI detection, with potential benefits for many.
Immunomodulatory potential of bacterial exosomes
Supervisor: Dr Murphy Wan
Bacterial exosomes are extracellular vesicles that are secreted by Gram-positive and Gram-negative bacteria. They contain a wide range of molecules, including proteins, lipids, and nucleic acids. In recent years, several studies have shown that bacterial exosomes play an important role in intercellular communication, host-pathogen interactions, and immune modulation.
In particular, bacterial exosomes have been shown to have an immunomodulatory effect on host immune cells. They can suppress or activate immune responses depending on the type of bacteria and the host's immune status. For example, some bacterial exosomes have been shown to inhibit T-cell proliferation and induce regulatory T cells, while others can activate macrophages and dendritic cells.
Understanding the mechanisms behind the immunomodulatory effect of bacterial exosomes is crucial for the development of new therapies for infectious and autoimmune diseases. Therefore, the aim of our research is to investigate the mechanisms underlying the immunomodulatory effect of bacterial exosomes.
Development of targeted therapy for colon cancer
Supervisor: Dr Murphy Wan
Globally, colorectal cancer (CRC) is one of the top most commonly diagnosed cancers according to the World Health Organisation. The global burden of CRC is expected to increase by 60% to more than 2.2 million new cases and 1.1 million deaths by 2030. Current management of CRC include the use of chemotherapy drugs, such as fluorouracil or irinotecan, and radiotherapy. However, these standard treatments often incur high cost and cause various side effects and organ toxicities resulting in a lower quality of life for patients. As such, there is an urgent need to develop less costly alternatives to chemotherapy.
This project will focus on discovery of novel therapies for cancer, which involves the design of colon-targeted delivery system and evaluation of the anti-cancer potential of the novel drug system through the uses of different analytical, cellular and molecular techniques in experimental models – including cell culture and in vivo models. This is a multidisciplinary project involves collaboration and interaction with experts from other fields. You'll receive training in all relevant areas, but not limited to analytical chemistry, nutrition, molecular biology, immunology, toxicology, with an emphasis on integration of different omics technologies for in-depth investigation of disease mechanisms and discoveries of novel biomarkers that can be translated in future clinical settings.
Early cancer diagnosis with unique Raman spectroscopic solutions for cancer biomarker and/or location detection
Supervisor: Dr Priyanka Dey
It's estimated that 1 in 3 cancer deaths could be prevented if detected early – when treatment is more effective. Traditional tissue biopsies, or the new-era cancer imaging technologies, are unable to provide the vital early diagnosis that can make the difference in prognosis. In contrast, the detection of biomarkers, which are disease-specific biological molecules found in the body, provides one of the best ways, in principle, to detect cancers at an earlier stage. For example, prostate-specific antigen (PSA) was proposed as a biomarker in the 1980s. Although it's still used clinically, its prediction accuracy or specificity for prostate cancer diagnosis is debatable. Therefore, multiple biomarkers must be identified from specific cancer cell lines, which when detected simultaneously, could help diagnose the specific cancer types early. The project will explore the bioanalytical technique of Raman spectroscopy as a non-staining, non-histopathological, fast method to detect subtle changes in the chemical structures of the biomarkers-of-interest. This can aid in biomarker screening and lead to accurate diagnosis with high cancer specificity and progression monitoring capabilities.
Investigating mechanisms of mitochondrial and nuclear genome stability
Supervisor: Dr Robert Baldock
Defects in cellular DNA repair mechanisms are associated with numerous human diseases, including cancer. The absence of these key pathways leads to increased genomic instability and altered cellular function. Research has identified a number of DNA repair proteins that protect nuclear DNA, they're also localised in mitochondria – although their functional role remains unclear. This MRes project will help characterise the role of these proteins in protecting the mitochondrial and nuclear genomes, as well as identifying their potential role in disease progression. You'll gain experience in a number of molecular biology and cell biology techniques and use bioinformatic approaches to generate and test novel insights.
Optimisation of lipid nanoparticles (LNPs) for targeted gene delivery to cancer cells
Supervisor: Dr Roja Hadianamrei
Pharmaceutical and biomedical research is shifting towards using biological drugs (peptides, proteins, nucleic acids) instead of small molecule drugs for treatment of a wide range of diseases including infectious diseases, endocrine and metabolic disorders, neurodegenerative diseases, and most notably cancer. Despite great advances in the field, there is still so much room for research to fill in the gaps and optimise current practices. This project is aimed at developing lipid nanoparticles (LNPs) with optimised physicochemical properties for the delivery of small interfering RNA (siRNA) to cancer cells. It's an interdisciplinary project combining pharmaceutical science, nanomedicine, molecular and cell biology.
siRNA are synthetic noncoding RNA which are capable of silencing selected genes in order to down regulate the unwanted proteins. LNPs are the new generation of non-viral gene vectors which have gained increasing attention in the last few years due to their successful application in mRNA based Covid vaccines. Applications of siRNA encapsulated in LNPs for gene therapy is a new promising approach in the treatment of metabolic diseases and cancer. The first FDA approved siRNA drug, Patisiran (ONPATTRO), consisting of siRNA encapsulated in LNPs, has entered the market in the USA and EU in 2019.
Building on my previous research in development of siRNA-based therapeutics for cancer and metabolic disorders using LNPs, and peptides in academia and pharmaceutical industry, I'm now working on the development of new LNP formulations for the targeted delivery of new types of siRNA to cancer cells. In this project, a new library of LNPs will be generated using microfluidics. The effect of formulation and process parameters on the physicochemical properties of the LNPs will be studied using design of experiment (DOE) approach. The LNPs with optimised physicochemical properties will then be tested for their ability to deliver siRNA to cancer cells and induce gene silencing. Working on this project will provide you with knowledge and practical skills in DOE, preparation of LNPs using microfluidics, analytical techniques (such as DLS, GE, UV and fluorescence spectroscopy), cell culture and cellular assays (transfection and gene silencing).
Modified triplex-forming oligonucleotides as therapeutic agents
Supervisor: Dr David Rusling
Oligonucleotides are short synthetic strands of DNA or RNA that can be used to treat or manage a wide range of diseases, for example by silencing specific genes. In recent years, various oligonucleotides have made it through clinical trials and have now reached the clinic to some fanfare. They often elicit their affects via antisense or RNAi mechanisms by acting on messenger RNA molecules and modulating protein expression inside living cells. Although this has been hugely successful, a better strategy, at least in principle, would be to use oligonucleotides to target genomic DNA directly and prevent messenger RNA expression altogether. Oligonucleotides that might prove useful in this manner are known as triplex-forming oligonucleotides, on account of their binding to specific duplex sequences and generating a triplex structure.
Our research group has recently overcome a long-standing problem associated with these molecules using . We are now at the stage of developing these molecules as gene-targeting agents and this MRes project will help us in attaining that goal. The student will gain experience in a wide variety of biochemical, biophysical and biological techniques used to characterise the formation of triplex DNA, and the project will involve a large amount of assay design and optimisation.
Targeted delivery of large macromolecular cargoes to subcellular environments
Supervisor: Dr Bruce R Lichtenstein
One of the grand challenges in biology is the targeted delivery of macromolecular complexes to specific sites in eukaryotic cells.
Recent mRNA vaccines highlight the potential of delivered macromolecules to effect physiological changes in organisms, but we still remain quite distant from our goal of making selective changes to cellular physiology down to the organelle level. To meet this challenge, extracellular macromolecules must be delivered to sites of interest within selected eukaryotic cells. Our recent work with engineering AB5 toxins highlights the flexibility of these carriers to transport cargoes of unconstrained identity into eukaryotic cells.
This project will define the limits of the delivery system towards applications in targeted therapies and cell engineering, by examining the delivery of supramolecular protein assemblies targeted to different subcellular environments. This research project would suit a biology, biochemistry, or biomedical student with interest in molecular biology, protein engineering, tissue culture, and confocal or super-resolution microscopy.
Protection of the stem cell state of embryonic muscle stem cells
Supervisor: Dr Susanne Dietrich
Adult muscle stem cells repair skeletal muscle after mild forms of injury. Yet when cultured in vitro to rebuild muscle of patients suffering from muscle loss by severe accidents or muscle disease, these cells lose their stem cell properties as well as their ability to generate muscle. The embryonic version of the adult muscle stem cells seems to be able to retain stem cell features and myogenic capacity. The project will use gene misexpression approaches to challenge embryonic muscle stem cells in the chicken embryo model, and to explore how the stem cell protective mechanism works. The work will contribute to the knowledge and understanding needed to generate muscle stem cells better suited for therapy.
Effects of mechanical stimulation in the proliferation and differentiation of mesenchymal stem cells into the osteogenic lineage
Supervisor: Dr Marta Roldo
In the UK 300,000 bone fractures occur a year, mainly due to age related diseases such as osteoporosis. These have a great impact on patients’ quality of life and the NHS budget. Many of these fractures are complex and unable to self-heal. They can often be treated with implantation of bone from the patient, or using bone substitute materials. In both cases there are serious limitations to the success of the current treatment options. New strategies must be developed.
Scientific knowledge suggests that the most promising strategy is the development of novel materials. These should provide a support over which staminal cells can change into bone-forming cells, and moreover they should work as a platform for the controlled delivery of drugs. Furthermore, it is known that forces applied to bone fractures have a role in the repair process, so developing a material able to harness the positive effect of these forces is a promising strategy.
We have developed promising new materials - the aim of this study is to investigate the relationship between their chemical and physical characteristics and how their potential to induce bone repair is affected by the forces applied to them. This work will provide protocols and tools to better understand how we can exploit mechanical forces as a method to stimulate the bone to repair itself and how materials for bone repair can be combined with mechanical forces to result in highly effective and safe treatments for bone repair.
High-throughput discovery of novel antibiotics using synthetic microbiology
Supervisor: Dr Roger Draheim
Antimicrobial resistance (AMR) is a frequent problem in the treatment of disease caused by several clinical bacterial pathogens. In the European Union, antibiotic resistant infections kill nearly 25,000 patients and represent a total expenditure of £1.5 billion per year. In response, the Chief Medical Officer (CMO) of the United Kingdom termed antibiotic resistance “a major area of concern” and proposed its inclusion on the National Security Risk Assessment, which prioritises major disruptive risks to national security.
Furthermore, the CMO suggested that the UK government facilitate global action, especially concerning the development of novel antibiotics. However, given the expensive research, development and clinical testing required to bring an antibiotic to market, coupled with the fact that they are taken for limited time courses and not for life, makes them a very unattractive prospect for pharmaceutical companies.
This MRes project is responsible for implementation of a novel “biological antibiotic screening” platform. The overall aim of this project is to develop this screening technology in order to sharply reduce the economic cost required for antibiotic discovery to the point where it becomes adopted as the de facto standard within the pharmaceutical industry. This multidisciplinary project will be conducted within newly renovated laboratory space and spans a broad range of biological sciences including molecular biology, microbiology, biochemistry, high throughput screening and collection/management of large data sets (i.e. big data). Applicants will ideally have previous experience in one or more of these topics, although will receive training in all relevant areas.
In addition, students will have access to a vast number of training resources available at through the Graduate School including those geared toward improving presentation skills, time-management and project organisation skills, reviewing literature, thesis writing, data analysis and statistics, and other various related training modules.
State of the art correlative imaging application in the study of morphological and functional behaviour of chondrocytes cultured in traditional 2D culture versus 3D printed scaffolds
Supervisor: Dr Marta Roldo
We offer an exciting opportunity for an MRes student to work in collaboration with scientists at the in Oxford.
Cartilage is an avascular tissue with poor nutrient infiltration and oxygen diffusion. These issues can hinder healing after injury or trauma. A particular problem in cartilage wound healing is the formation of fibrocartilage, which is functionally and biomechanically inferior to the native tissue. Current therapies to facilitate cartilage regeneration (e.g. autografting, microfractures and autologous chondrocyte implantation) having limited success in restoring functional tissue.
Cartilage tissue engineering (CTE), or the implantation of biocompatible scaffolds loaded with chondrocytes or stem cells, could be a turning point in the treatment of cartilage damage. A deep understanding of the interactions between cells and the biomaterials used for their delivery is key to the development of novel CTE therapies.
The aim of this project is to understand, through non-destructive high-resolution cryo x-ray tomography, correlative fluorescence microscopy and gene expression, the effect that the culture environment in a 3D scaffold has on the morphology and function of chondrocytes. Current cell culture practices and analytical techniques are limited providing a 2D environment for cell growth which results in a cell behaviour dissimilar from the in vivo realty. The state of the art facilities at Diamond, beamline B24, will allow the study of cells in a 3D environment that will be created by 3D printing of hydrogels with the newly acquired .
This project will provide the student with training in state of the art techniques uniquely available through the collaboration between the University and Diamond. The project is multidisciplinary and involves biology, physics, bioengineering and biomaterials, and will provide the student with a unique set of skills that are very competitive in the current job and research market.
This project will be co-supervised by: Prof Gordon Blunn, Dr Gialuca Tozzi and Dr Maria Harkiolaki (University of Oxford).
Investigating the role of IgLON proteins in zebrafish neural development using CRISPR knockout approaches
Supervisors: Jordi Cayuso and Sassan Hafizi
Cell adhesion molecules are involved in multiple key processes in all tissues of the body. The IgLON family of cell adhesion molecules are characterised by containing three immunoglobulin domains at the N-terminus and a membrane-anchored C-terminus. IgLONs interact with other cell surface proteins either on the same cell or between two cells, which is a mechanism to regulate signal transduction for distinct cellular functions emanating from receptor activation. In the brain, IgLONs have been shown to mediate neurite outgrowth, neuronal survival and synapse formation. Furthermore, mutations in IgLON genes that may impair these key functions have been associated with neuropsychiatric disorders. Two of the family members, OPCML and NEGR1, show prominent expression in the brain; however, little is currently known about their distinct roles in the brain in terms of their molecular interactions, cellular functions and the consequent physiological effects. As both proteins are evolutionarily conserved in the zebrafish (Danio rerio), we will use this model to probe the expression and function of both IgLONs in zebrafish, and the consequences of their genetic ablation on neuroglial development, cellular biology and potentially behavioural parameters.During this project you will learn state-of-the-art genome editing techniques using CRISPR/Cas9 tools, and will have the opportunity to master important techniques in biomedical research including molecular cloning, in situ hybridisation for mRNA detection, and confocal imaging.
The results of this project should yield novel information on the interrelated or exclusive roles of these two IgLON proteins in the key processes underlying nervous system development. In turn, this has implications for understanding the origins of neurological and psychiatric disorders, which are prevalent worldwide and moreover ever-increasing healthcare challenges for the future.
Transition between heart and skeletal muscle competence
Supervisor: Dr Susanne Dietrich
In human heart failure, heart muscle cells partly switch to a skeletal muscle phenotype. This phenomenon may represent a return to a phase in embryonic development when cells in the head mesoderm lose the ability (competence) to form heart muscle and instead embark on generating the skeletal muscles for the head and face. The underlying mechanisms are not known. Preliminary data suggest that the mutual repression of heart and skeletal muscle genes (genetic control) as well as the opening-up and closing of gene loci (epigenetic control) may be responsible. This project will use gene misexpression strategies as well as larger scale transcriptomic and epigenomic approaches in the chicken embryo, an established model for human heart and skeletal muscle development. The project is basic discovery research, but will contribute to our understanding of heart failure in humans.
Integration of heart precursors into the beating heart
Supervisor: Dr Susanne Dietrich
Cardiovascular diseases are the most prevalent cause of death worldwide. Repair cells for the heart can be made in vitro, but when introduced into the heart e.g. after a heart attack, they beat according to their own rhythm, causing potentially fatal arrhythmias. Notably, cell addition and integration are part of normal embryonic heart development; in fact, they are required to build the right ventricle, parts of the atria, and the mature in- and outflow tract.
Preliminary data from our lab suggested that both the properties of the integrating cells as well as signals from the environment are important. To unravel the underlying mechanism, tissue recombination experiments in vivo and in vitro will be used. Moreover, larger scale ‘omics’ approaches will be used to establish which genes the integrating cells may use. The work will be performed in the chicken embryo, an established model for human heart development. The project is basic discovery research, but will hopefully in the future allow to recapitulate cell integration in a human patient.
Development of the vasculature supplying the brain
Supervisor: Dr Susanne Dietrich
The brain contributes only 2% of our body weight, but consumes 20% of the oxygen and 25% of the body’s glucose. When the brain first develops, it is not vascularised. Where the angioblasts (=vascular endothelial precursor cells) for the brain come from, and how they assemble around the brain is not known. This project will trace the origin of potential precursor cells with fluorescent dyes. Pharmacological inhibitors as well as agonists of cell-cell-signalling pathways will be used to establish, which mechanisms control angioblast formation and aggregation. The responses to treatment will be monitored, assaying for the expression of marker genes by antibody staining and in situ hybridisation. As a model, we have chosen the chicken embryo for its large size and accessibility. The project is basic discovery research, but will contribute to our understanding of congenital vascular defects in humans.
Outgrowth of the myotome and closure of the ventral body wall
Supervisor: Dr Susanne Dietrich
Gastroschisis and omphalocele are birth defects resulting from a failure in body wall closure. Body wall closure may be driven by the outgrowing dermomyotome which delivers the abdominal skeletal musculature. Several genes are expressed in the driving front of the growing dermomyotome, most prominently Msc. This is in contrast to limb levels where Lbx1 is expressed, and where cells are released to undertake long-range migration into the limbs. This project will use Msc and Lbx1 misexpression and knock-down in the chicken embryo to test whether both genes repress each other, thereby either driving or preventing dermomyotome outgrowth and body wall closure.
Other Research Projects
Discover the current research projects available in each of our schools and departments:
- Department of Psychology
- School of Sport, Health and Exercise Science
- School of the Environment, Geography and Geosciences
- School of Pharmacy and Biomedical Sciences
- School of Health and Care Professions
- School of Biological Sciences
- School of Earth and Environmental Sciences
- Dental Academy
Please note, this list is not exhaustive and you'll need to meet and discuss the project you're interested in with a member of research staff before you apply.