project . 2021 - 2026 . On going


Portable, accessible and sustainable magnetic resonance
Open Access mandate for Publications
European Commission
Funder: European CommissionProject code: 101021218 Call for proposal: ERC-2020-ADG
Funded under: H2020 | ERC | ERC-ADG Overall Budget: 2,493,720 EURFunder Contribution: 2,493,720 EUR
Status: On going
01 Sep 2021 (Started) 31 Aug 2026 (Ending)
Open Access mandate
Research data: No

MRI is a key modality in clinical care, with well over 150 million scans performed annually for diagnosis and treatment monitoring. Its major strengths are multi-contrast and the lack of ionizing radiation. However, its Achilles-heel is cost: typically millions of euros to purchase, site, and maintain, and also requires highly skilled technicians. As a result, MRI is available only in larger hospitals in the developed world, and unlike other imaging modalities plays little role in population screening. In the developing world, MRI systems are far too expensive and complex to purchase and maintain, and over 70% of the world’s population has zero access to MRI, which could be critical in treating diseases such as hydrocephalus, stroke, head trauma and viral infections. The aims of PASMAR are to develop new low-field MRI systems which will enable a role in medical screening in the developed world, as well as providing an affordable, sustainable and accessible platform for the developing world. The major thrust of PASMAR is methodological, designing new types of low-cost low-field systems for specific clinical applications, and optimizing all aspects of system performance to overcome the challenge of much lower MRI signal. I aim to develop, in consultation with clinical colleagues locally and via ongoing collaborations with engineers and clinicians in Africa, specialized systems which can be used for adult/pediatric brain, orthopedics and lung/spine scanning, as well as new types of inexpensive handheld ultra-lightweight surface scanners. These take advantage of the enormous flexibility of designing permanent magnet arrays with completely new geometries, targeted for specific organs. I will focus on portability to maximize patient reach and minimize siting requirements, accessibility via dramatically reduced system costs, and sustainability via modular and open source design to allow local maintenance and repair.

Data Management Plans