Sir Peter Mansfield Imaging Centre
Lead Research Organisation:
University of Nottingham
Department Name: Sch of Physics & Astronomy
Abstract
Nottingham has considerable expertise and a long track record of success in the development of MRI. It also has strong research programmes in gastroenterology, liver disease, metabolism, sports medicine, orthopaedics, respiratory medicine, mental health, hearing and radiological sciences. This proposal aims to combine these strengths to establish a world-leading centre, the SPMIC, to drive the development and application of medical imaging. A key feature is that the centre will be set up to share our facilities and expertise, as well as the data that we acquire, with other centres. We are requesting funding for a number of items of equipment which will transform our current facilities:
1. We were the first group in the UK to install and develop a 7T MR scanner, which is the highest field MR scanner generally available worldwide. Ultra-high field MR considerably increases the sensitivity of MRI and MRS, and our work and that of others has proven the capabilities of 7T MR in the brain. There is now another 7T scanner in Oxford, and we are pleased to note that other UK groups are recognizing the advantages of 7T and are applying for such scanners through this call. We are happy to share the experience gained in pioneering MR studies at 7T. We now need to add whole body capability to our 7T scanner, to exploit the capabilities of 7T outside of the brain. We are ideally placed to do this because of our experience in using MR in experimental studies.
2. We have a long track record of using MR to study nutrition, metabolism and gastrointestinal disorders. However we are currently limited by the fact that many subjects in these studies are too large to fit into a standard MR scanner, limiting the study of obese patients. We also have considerable experience of studying the effects of exercise on the physiology and metabolism of skeletal muscle and the brain. We need to use the non-invasive capabilities of MR in this work, but are hampered by the problems involved in scanning subjects undertaking exercise. We have an exercise bike designed for use inside an MR scanner, but this is difficult to use in a conventional scanner because of the narrow bore. We have therefore requested funding for wide-bore 3T MR.
3. We have developed strong technical expertise relating to two recently-developed methods for increasing the sensitivity of MR: hyperpolarized (HP) inert gases (e.g. xenon and krypton) and dynamic nuclear polarization (DNP). Both of these techniques have the potential to produce a step change in the way MR is used clinically. We will exploit the increased sensitivity of HP inert gases in the study of lung disease and will also undertake completely novel studies that involve using DNP to study metabolism in muscles and in the brain.
4. We have made lots of progress in understanding the brain's function by using electrophysiology techniques (MEG and EEG). We will build on this by installing "real time" capability on our MEG scanner, which will allow us to perform experiments where we stimulate a subject based on their ongoing brain state.
5. As part of our hearing research, we want to study brain activation in patients who have received a cochlear implant, but MEG and MRI cannot be used for these experiments. We will therefore purchase fNIRS equipment to monitor how these patients adapt to their implants. We will site this equipment in a specially-designed room adjacent to our MR scanners, to ensure that the new facilities are as convenient as possible for patients who take part in multi-modal studies.
6. Patients often do not like having MRI scans, and one of the main reasons is acoustic noise. We will use active noise cancellation headphones to reduce the noise levels in our MR scanners. We will also install systems to detect and correct for head motion in MRI; this will greatly improve the quality of images obtained from patients who often find it hard to keep still; invaluable for clinical studies of patient
1. We were the first group in the UK to install and develop a 7T MR scanner, which is the highest field MR scanner generally available worldwide. Ultra-high field MR considerably increases the sensitivity of MRI and MRS, and our work and that of others has proven the capabilities of 7T MR in the brain. There is now another 7T scanner in Oxford, and we are pleased to note that other UK groups are recognizing the advantages of 7T and are applying for such scanners through this call. We are happy to share the experience gained in pioneering MR studies at 7T. We now need to add whole body capability to our 7T scanner, to exploit the capabilities of 7T outside of the brain. We are ideally placed to do this because of our experience in using MR in experimental studies.
2. We have a long track record of using MR to study nutrition, metabolism and gastrointestinal disorders. However we are currently limited by the fact that many subjects in these studies are too large to fit into a standard MR scanner, limiting the study of obese patients. We also have considerable experience of studying the effects of exercise on the physiology and metabolism of skeletal muscle and the brain. We need to use the non-invasive capabilities of MR in this work, but are hampered by the problems involved in scanning subjects undertaking exercise. We have an exercise bike designed for use inside an MR scanner, but this is difficult to use in a conventional scanner because of the narrow bore. We have therefore requested funding for wide-bore 3T MR.
3. We have developed strong technical expertise relating to two recently-developed methods for increasing the sensitivity of MR: hyperpolarized (HP) inert gases (e.g. xenon and krypton) and dynamic nuclear polarization (DNP). Both of these techniques have the potential to produce a step change in the way MR is used clinically. We will exploit the increased sensitivity of HP inert gases in the study of lung disease and will also undertake completely novel studies that involve using DNP to study metabolism in muscles and in the brain.
4. We have made lots of progress in understanding the brain's function by using electrophysiology techniques (MEG and EEG). We will build on this by installing "real time" capability on our MEG scanner, which will allow us to perform experiments where we stimulate a subject based on their ongoing brain state.
5. As part of our hearing research, we want to study brain activation in patients who have received a cochlear implant, but MEG and MRI cannot be used for these experiments. We will therefore purchase fNIRS equipment to monitor how these patients adapt to their implants. We will site this equipment in a specially-designed room adjacent to our MR scanners, to ensure that the new facilities are as convenient as possible for patients who take part in multi-modal studies.
6. Patients often do not like having MRI scans, and one of the main reasons is acoustic noise. We will use active noise cancellation headphones to reduce the noise levels in our MR scanners. We will also install systems to detect and correct for head motion in MRI; this will greatly improve the quality of images obtained from patients who often find it hard to keep still; invaluable for clinical studies of patient
Technical Summary
This project will establish the Sir Peter Mansfield Imaging Centre (SPMIC) at the University of Nottingham. This will form a multidisciplinary centre that combines the University's strengths in the development of medical imaging technologies (particularly MRI) and experimental and in translational medicine in an environment that will foster productive new collaborations and synergies. A major goal will be to share our resources, expertise and data with other leading groups and centres.
The SPMIC will be housed across two sites, one dedicated to experimental studies and the second dedicated to more acute medical studies. The SPMIC will be equipped with the following new facilities
- MultiX capability on our existing 7T MR scanner for whole body imaging
- A wide-bore 3T MR scanner suitable for scanning large or claustrophobic patients, or for undertaking exercise studies
- A vertical MR scanner, for weight-bearing studies of the musculoskeletal system, and also for studies of the effect of posture on gastrointestinal and lung function, and studies of respiratory patients who cannot lie down.
- A dedicated electrophysiology lab, close to the 7T scanner, with Magnetoencephalography (MEG) and electroencephalography (EEG), as well as a functional near infrared system (fNIRS) to be used in patients undergoing cochlear implantation
- Dynamic Nuclear Polarization (DNP) facilities for hyperpolarization of 13C for use in humans
- Hyperpolarized gas facilities for use in humans (xenon and krypton)
- Optical motion detection cameras which we will interface to our MR scanners to provide prospective motion correction
- Active noise cancellation headphones to improve patient acceptance of MRI.
We will use these facilities to undertake innovative studies in gastroenterology, liver disease, metabolism including sports medicine, orthopaedics, respiratory medicine, mental health, hearing and radiological sciences.
The SPMIC will be housed across two sites, one dedicated to experimental studies and the second dedicated to more acute medical studies. The SPMIC will be equipped with the following new facilities
- MultiX capability on our existing 7T MR scanner for whole body imaging
- A wide-bore 3T MR scanner suitable for scanning large or claustrophobic patients, or for undertaking exercise studies
- A vertical MR scanner, for weight-bearing studies of the musculoskeletal system, and also for studies of the effect of posture on gastrointestinal and lung function, and studies of respiratory patients who cannot lie down.
- A dedicated electrophysiology lab, close to the 7T scanner, with Magnetoencephalography (MEG) and electroencephalography (EEG), as well as a functional near infrared system (fNIRS) to be used in patients undergoing cochlear implantation
- Dynamic Nuclear Polarization (DNP) facilities for hyperpolarization of 13C for use in humans
- Hyperpolarized gas facilities for use in humans (xenon and krypton)
- Optical motion detection cameras which we will interface to our MR scanners to provide prospective motion correction
- Active noise cancellation headphones to improve patient acceptance of MRI.
We will use these facilities to undertake innovative studies in gastroenterology, liver disease, metabolism including sports medicine, orthopaedics, respiratory medicine, mental health, hearing and radiological sciences.
Planned Impact
This grant will have impact in a number of arenas:
Medical care: the aim of this project is to increase the pull-through of developments in medical imaging into novel solutions for patient care via experimental medicine or stratification for personalized medicine in arenas in which Nottingham has particular translational strengths. The primary mechanism to achieve this will be the establishment of the new interdisciplinary SPMIC, equipped with state of the art facilities that will enable innovative studies in stratified and experimental medicine. This pull-through to medical care will be accelerated by the close integration of clinicians and basic scientists. The following organizations will be integral to the SPMIC and will ensure rapid translation of developments into the clinic: NIHR Biomedical Research Units in Gastrointestinal and Liver Diseases and Hearing (joint with the MRC Institute for Hearing Research, IHR), the ARUK Centre for Sport, Exercise and Osteoarthritis (with Oxford), the MRC-ARUK Centre for Musculoskeletal Ageing Research (with Birmingham), the ARUK National Pain Centre, the Institute of Mental Health (IMH) and the Respiratory Disease Research Centre. We also have many other partnerships and collaborations with clinical networks that will ensure rapid pull-through (detailed in the Case for Support and the letters of support).
Medical Imaging Community: We are confident that the outputs of the SPMIC will be adopted rapidly by other workers in the field. Following on from the success of MEGUK partnership, we are committed to the establishment of a network of 7T facilities in the UK (UK7T) and to developing a national network for HP lung imaging, and are keen to establish links with the UK Dementia Platform.
Industry: We have long experience of working closely with medical imaging equipment suppliers as evidenced by the letters of support included with this application. In particular we will: work with Philips on the MultiX upgrade at 7T; collaborate with MRcoils on the modelling required to install the abdominal transceiver coil and with Rapid on the development of a range of RF coils for 7T; work very closely with the manufacture of the vertical MR scanner, to maximize the performance of the system, to exploit its clinical potential, and to provide multinuclear capability; continue to work with MISL on real-time MEG capability and processing software; collaborate with GE on developing hyperpolarized [1-13C]acetate capability on the SpinLab polarizer; build on a long history of developing active noise cancellation for MR, working with Optoacoustics to increase the range of pulse sequences on which active noise cancellation can be applied; continue a fruitful collaboration with Brain Products GmbH focusing on developing improved approaches to combined EEG-fMRI. In addition, KinetiCor are excited about the possibility of working with us to interface their motion camera to the Philips and GE platforms, as evidenced by the support they have offered us.
We have a sustained track record of collaboration with the food industry who have made considerable use of our expertise in characterizing the effects of different food products on the gut and brain, as well as strong research links with pharmaceutical companies. Significant further impact is expected to arise from continued successful collaboration with partners in these industries.
Education: We have an excellent track record in training MR physicists (>140 PhD students in physics in the last 3 decades, many of whom now hold senior posts in academia, industry and the NHS). We jointly run the EPSRC/MRC Oxford Nottingham Biomedical Imaging Centre for Doctoral Training, and coordinate the HiMR Marie Curie Initial Training Network. We are a part of the MEGUK partnership which currently trains 8 PhD students. We run taught postgraduate courses which will increase awareness of the potential of medical imaging in stratified and experimental medicine.
Medical care: the aim of this project is to increase the pull-through of developments in medical imaging into novel solutions for patient care via experimental medicine or stratification for personalized medicine in arenas in which Nottingham has particular translational strengths. The primary mechanism to achieve this will be the establishment of the new interdisciplinary SPMIC, equipped with state of the art facilities that will enable innovative studies in stratified and experimental medicine. This pull-through to medical care will be accelerated by the close integration of clinicians and basic scientists. The following organizations will be integral to the SPMIC and will ensure rapid translation of developments into the clinic: NIHR Biomedical Research Units in Gastrointestinal and Liver Diseases and Hearing (joint with the MRC Institute for Hearing Research, IHR), the ARUK Centre for Sport, Exercise and Osteoarthritis (with Oxford), the MRC-ARUK Centre for Musculoskeletal Ageing Research (with Birmingham), the ARUK National Pain Centre, the Institute of Mental Health (IMH) and the Respiratory Disease Research Centre. We also have many other partnerships and collaborations with clinical networks that will ensure rapid pull-through (detailed in the Case for Support and the letters of support).
Medical Imaging Community: We are confident that the outputs of the SPMIC will be adopted rapidly by other workers in the field. Following on from the success of MEGUK partnership, we are committed to the establishment of a network of 7T facilities in the UK (UK7T) and to developing a national network for HP lung imaging, and are keen to establish links with the UK Dementia Platform.
Industry: We have long experience of working closely with medical imaging equipment suppliers as evidenced by the letters of support included with this application. In particular we will: work with Philips on the MultiX upgrade at 7T; collaborate with MRcoils on the modelling required to install the abdominal transceiver coil and with Rapid on the development of a range of RF coils for 7T; work very closely with the manufacture of the vertical MR scanner, to maximize the performance of the system, to exploit its clinical potential, and to provide multinuclear capability; continue to work with MISL on real-time MEG capability and processing software; collaborate with GE on developing hyperpolarized [1-13C]acetate capability on the SpinLab polarizer; build on a long history of developing active noise cancellation for MR, working with Optoacoustics to increase the range of pulse sequences on which active noise cancellation can be applied; continue a fruitful collaboration with Brain Products GmbH focusing on developing improved approaches to combined EEG-fMRI. In addition, KinetiCor are excited about the possibility of working with us to interface their motion camera to the Philips and GE platforms, as evidenced by the support they have offered us.
We have a sustained track record of collaboration with the food industry who have made considerable use of our expertise in characterizing the effects of different food products on the gut and brain, as well as strong research links with pharmaceutical companies. Significant further impact is expected to arise from continued successful collaboration with partners in these industries.
Education: We have an excellent track record in training MR physicists (>140 PhD students in physics in the last 3 decades, many of whom now hold senior posts in academia, industry and the NHS). We jointly run the EPSRC/MRC Oxford Nottingham Biomedical Imaging Centre for Doctoral Training, and coordinate the HiMR Marie Curie Initial Training Network. We are a part of the MEGUK partnership which currently trains 8 PhD students. We run taught postgraduate courses which will increase awareness of the potential of medical imaging in stratified and experimental medicine.
Publications
Jung J
(2016)
Vertex Stimulation as a Control Site for Transcranial Magnetic Stimulation: A Concurrent TMS/fMRI Study.
in Brain stimulation
Cox EF
(2019)
Using MRI to study the alterations in liver blood flow, perfusion, and oxygenation in response to physiological stress challenges: Meal, hyperoxia, and hypercapnia.
in Journal of magnetic resonance imaging : JMRI
Shah S
(2018)
The z-spectrum from human blood at 7T
in NeuroImage
Seedat ZA
(2020)
The role of transient spectral 'bursts' in functional connectivity: A magnetoencephalography study.
in NeuroImage
Jackson SR
(2020)
The role of the insula in the generation of motor tics and the experience of the premonitory urge-to-tic in Tourette syndrome.
in Cortex; a journal devoted to the study of the nervous system and behavior
Hunt BA
(2016)
Relationships between cortical myeloarchitecture and electrophysiological networks.
in Proceedings of the National Academy of Sciences of the United States of America
Rathnaiah M
(2020)
Quantifying the Core Deficit in Classical Schizophrenia.
in Schizophrenia bulletin open
Cronin MJ
(2018)
Quantifying MRI frequency shifts due to structures with anisotropic magnetic susceptibility using pyrolytic graphite sheet.
in Scientific reports
Rathnaiah M
(2021)
Quantfying the disorganization and the core deficit in classical schizophrenia
in BJPsych Open
Mahbub Z
(2017)
Presence of time-dependent diffusion in the brachial plexus
in Magnetic Resonance in Medicine
Draper A
(2016)
Premonitory urges are associated with decreased grey matter thickness within the insula and sensorimotor cortex in young people with Tourette syndrome.
in Journal of neuropsychology
Tewarie P
(2016)
Predicting haemodynamic networks using electrophysiology: The role of non-linear and cross-frequency interactions.
in NeuroImage
Boto E
(2016)
On the Potential of a New Generation of Magnetometers for MEG: A Beamformer Simulation Study.
in PloS one
Eckerbom P
(2019)
Multiparametric assessment of renal physiology in healthy volunteers using noninvasive magnetic resonance imaging.
in American journal of physiology. Renal physiology
Bradley CR
(2018)
Multi-organ assessment of compensated cirrhosis patients using quantitative magnetic resonance imaging.
in Journal of hepatology
Gascoyne LE
(2021)
Motor-related oscillatory activity in schizophrenia according to phase of illness and clinical symptom severity.
in NeuroImage. Clinical
Fry A
(2016)
Modulation of post-movement beta rebound by contraction force and rate of force development.
in Human brain mapping
O'Neill GC
(2017)
Measurement of dynamic task related functional networks using MEG.
in NeuroImage
Fernandes CC
(2020)
Measurement of brain lactate during visual stimulation using a long TE semi-LASER sequence at 7 T.
in NMR in biomedicine
Barratt EL
(2018)
Mapping the topological organisation of beta oscillations in motor cortex using MEG.
in NeuroImage
Sanchez Panchuelo RM
(2016)
Mapping quantal touch using 7 Tesla functional magnetic resonance imaging and single-unit intraneural microstimulation.
in eLife
Besle J
(2019)
Is Human Auditory Cortex Organization Compatible With the Monkey Model? Contrary Evidence From Ultra-High-Field Functional and Structural MRI.
in Cerebral cortex (New York, N.Y. : 1991)
Fernandes CC
(2021)
Investigating the regional effect of the chemical shift displacement artefact on the J-modulated lactate signal at ultra high-field.
in NMR in biomedicine
Bawden SJ
(2016)
Investigating the effects of an oral fructose challenge on hepatic ATP reserves in healthy volunteers: A (31)P MRS study.
in Clinical nutrition (Edinburgh, Scotland)
Tewarie P
(2016)
Integrating cross-frequency and within band functional networks in resting-state MEG: A multi-layer network approach
in NeuroImage
Bawden S
(2017)
Increased liver fat and glycogen stores after consumption of high versus low glycaemic index food: A randomized crossover study.
in Diabetes, obesity & metabolism
Skinner JG
(2020)
High Xe density, high photon flux, stopped-flow spin-exchange optical pumping: Simulations versus experiments.
in Journal of magnetic resonance (San Diego, Calif. : 1997)
Kumar J
(2020)
Glutathione and glutamate in schizophrenia: a 7T MRS study.
in Molecular psychiatry
Tendler B
(2018)
Frequency difference mapping applied to the corpus callosum at 7T
in Magnetic Resonance in Medicine
Daniel AJ
(2019)
Exploring the relative efficacy of motion artefact correction techniques for EEG data acquired during simultaneous fMRI.
in Human brain mapping
Spencer GS
(2018)
Exploring the origins of EEG motion artefacts during simultaneous fMRI acquisition: Implications for motion artefact correction.
in NeuroImage
Briley PM
(2018)
Development of human electrophysiological brain networks.
in Journal of neurophysiology
Wesolowski R
(2019)
Coupling between cerebral blood flow and cerebral blood volume: Contributions of different vascular compartments.
in NMR in biomedicine
Brookes MJ
(2015)
Complexity measures in magnetoencephalography: measuring "disorder" in schizophrenia.
in PloS one
Mandke K
(2018)
Comparing multilayer brain networks between groups: Introducing graph metrics and recommendations.
in NeuroImage
Tierney TM
(2018)
Cognitive neuroscience using wearable magnetometer arrays: Non-invasive assessment of language function.
in NeuroImage
Gascoyne LE
(2018)
Changes in electrophysiological markers of cognitive control after administration of galantamine.
in NeuroImage. Clinical
Hunt BAE
(2019)
Attenuated Post-Movement Beta Rebound Associated With Schizotypal Features in Healthy People.
in Schizophrenia bulletin
Odudu A
(2018)
Arterial spin labelling MRI to measure renal perfusion: a systematic review and statement paper
in Nephrology Dialysis Transplantation
Brookes MJ
(2018)
Altered temporal stability in dynamic neural networks underlies connectivity changes in neurodevelopment.
in NeuroImage
Sigurdsson HP
(2018)
Alterations in the microstructure of white matter in children and adolescents with Tourette syndrome measured using tract-based spatial statistics and probabilistic tractography.
in Cortex; a journal devoted to the study of the nervous system and behavior
Sigurdsson HP
(2020)
Alterations in cerebellar grey matter structure and covariance networks in young people with Tourette syndrome.
in Cortex; a journal devoted to the study of the nervous system and behavior
Carradus A
(2020)
Age-related differences in myeloarchitecture measured at 7 T
in Neurobiology of Aging
Chen C
(2017)
Activation induced changes in GABA: Functional MRS at 7T with MEGA-sLASER.
in NeuroImage
Barratt EL
(2017)
Abnormal task driven neural oscillations in multiple sclerosis: A visuomotor MEG study.
in Human brain mapping
Liddle EB
(2016)
Abnormal salience signaling in schizophrenia: The role of integrative beta oscillations.
in Human brain mapping
Boto E
(2017)
A new generation of magnetoencephalography: Room temperature measurements using optically-pumped magnetometers.
in NeuroImage
Brookes MJ
(2016)
A multi-layer network approach to MEG connectivity analysis.
in NeuroImage
Description | Discovery Grant |
Amount | £672,000 (GBP) |
Funding ID | PC 15074 |
Organisation | Medical Research Council (MRC) |
Sector | Public |
Country | United Kingdom |
Start | 07/2016 |
End | 12/2017 |
Description | Discovery Grant |
Amount | £1,050,149 (GBP) |
Organisation | Medical Research Council (MRC) |
Sector | Public |
Country | United Kingdom |
Start | 06/2016 |
End | 05/2018 |
Description | Network Grant |
Amount | £1,050,149 (GBP) |
Organisation | Medical Research Council (MRC) |
Sector | Public |
Country | United Kingdom |
Start | 01/2016 |
End | 12/2019 |
Description | Compressed sensing |
Organisation | University of Newcastle |
Country | Australia |
Sector | Academic/University |
PI Contribution | Application of sense MRI techniques at ultra-high field |
Collaborator Contribution | Development of compressed sensing methods |
Impact | Application for funding under consideration by the Wellcome Trust |
Start Year | 2015 |