Probing the tumour microenvironment in-vivo with ultra-strong gradient MRI

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    Cardiff University
    United Kingdom
    Formal sciences
    Professions and applied sciences
    Social sciences



This PhD project is well suited to students who would like to combine their knowledge of programming, computational modelling, physics and mathematics to better understand the structural changes in biological tissue in health and disease. The project would suit a physics, engineering, maths or computer science graduate with an interest in neuroscience and brain physiology. Equally it would suit a neuroscientist with a strong mathematical and computational interest.

Diffusion MRI (dMRI) is the preferred tool to study tissue-microstructure in health and disease. Notwithstanding the increasing amount of studies showcasing the sensitivity of dMRI features to diseases, it is increasingly apparent that the ultimate aim of being unambiguously specific to microstructural characteristics cannot be achieved with current methodology [1]. At Cardiff University Brain Research Imaging Centre (CUBRIC), we are developing MRI methodology and have access to an MRI system with ultra-strong gradients (one of four worldwide) to boost the performance of dMRI [2].

In addition, an emerging zeitgeist in microstructural-MRI is that combining multiple MRI-modalities will yield a more complete picture of tissue-physiology [2,3,4]. This has renewed hope of establishing biophysical models for healthy and diseased tissue. We have recently developed multi-modal MRI protocols to establish correlations between physical and chemical tissue-properties: diffusion MRI provides information on the size, shape, and orientation of tissue-compartments, while relaxometry can add complementary information on chemical composition [4]. This rich data has the potential to improve the disentanglement of different tissue-compartments and to use approaches with fewer assumptions than commonly used biophysical models, which is important in disease-characterisation where the number and properties of tissue-constituents are unknown. So far, these efforts have been solely focussed on the healthy brain.

This project aims to develop an efficient multi-contrast MRI framework for comprehensive microstructure-characterisation in the context of oncology with ultra-strong gradients.

In the wake of the dramatic successes seen with checkpoint inhibitors in oncology, more and more targeted therapeutic options are becoming available for an ever-wider range of tumours. With the breadth of therapeutic options, it is becoming ever more relevant to identify response, or lack thereof, as early as possible. Unfortunately, conventional RECIST-like measures of response are neither very insightful, nor very sensitive for early changes. As such, there is a need to develop markers of response that provide early, in-vivo, mechanistic insights in tissue change.

Multi-contrast MRI measurements provide new windows to probe diffusion and relaxation simultaneously; relaxation provides a rich source of information complementary to diffusion e.g. on the molecular interactions of the system of spins. This simultaneous characterisation has demonstrated superior separation of tissue compartments, and improved tissue classification, e.g. for tumour gradation [5,6].

In this project, we aim to further develop and optimise integrated acquisition protocols to measure a rich set of tissue characteristics in the context of oncology. Simulations and phantom experiments will be employed to evaluate the measures, as well as a proof-of-concept study in patients in collaboration with the Velindre Cancer Centre.

This project is supervised by Dr Chantal Tax, Professor Derek Jones and Dr. Marius de Groot.

Brain Imaging (CUBRIC) - Our research facilities include one of Europe’s most powerful brain scanners, as well as a purpose-built environment for patients and volunteers taking part in medical research and clinical trials https://www.cardiff.ac.uk/cardiff-university-brain-research-imaging-cent...


1. Jelescu IO, Veraart J, Fieremans E, Novikov DS. Degeneracy in model parameter estimation for multi-compartmental diffusion in neuronal tissue. NMR Biomed. 2016;29(1):33-47.

2. Jones DK, Alexander DC, Bowtell R, Cercignani M, Dell’Acqua F, McHugh DJ, Miller KL, Palombo M, Parker GJM, Rudrapatna US, et al. Microstructural imaging of the human brain with a ‘super-scanner’: 10 key advantages of ultra-strong gradients for diffusion MRI. Neuroimage. May 2018.

3. Cercignani M, Bouyagoub S. Brain microstructure by multi-modal MRI: Is the whole greater than the sum of its parts? Neuroimage. 2018;182:117-127.

4. de Almeida Martins, J. P., Tax, C. M., Szczepankiewicz, F., Jones, D. K., Westin, C. F., & Topgaard, D., Transferring principles of solid-state and Laplace NMR to the field of in vivo brain MRI. Magnetic Resonance, 2020, 1.1: 27-43.

5. Yu AC, Badve C, Ponsky LE, Pahwa S, Dastmalchian S, Rogers M, et al. Development of a Combined MR Fingerprinting and Diffusion Examination for Prostate Cancer. Radiology. 2017;283:729–38.

6. Szczepankiewicz, F., van Westen, D., Englund, E., Westin, C. F., Ståhlberg, F., Lätt, J., ... & Nilsson, M. (2016). The link between diffusion MRI and tumor heterogeneity: mapping cell eccentricity and density by diffusional variance decomposition (DIVIDE). NeuroImage, 142, 522-532.

What is funded

The studentship will commence in January 2021 and will cover your tuition fees (at UK/EU level) as well as a maintenance grant. In 2020 the maintenance grant for full-time students was £15,285 per annum . As well as tuition fees and a maintenance grant, all School of Psychology students will have access to courses offered by the University’s Doctoral Academy and become members of the University Doctoral Academy.

Full awards are open to UK and EU Nationals.

International candidates are welcomed but they would need to cover the difference in Home/EU and Overseas fees.


As only one studentship is available and a very high standard of applications is typically received, the successful applicant is likely to have a very good first degree (a First or Upper Second class BSc Honours or equivalent) and/or be distinguished by having relevant research experience.

How to Apply

You can apply online - consideration is automatic on applying for a PhD in Psychology, with a January 2021 start date (programme code RFPDPSYB).

Please use our online application service at https://www.cardiff.ac.uk/study/postgraduate/research/programmes/program...


The responsibility for the funding offers published on this website, including the funding description, lies entirely with the publishing institutions. The application is handled uniquely by the employer, who is also fully responsible for the recruitment and selection processes.