Your search keyword '"Hart, Michael G."' showing total 11 results

1. Transcriptomic and connectomic correlates of differential spatial patterning among gliomas Supplementary Material

Author

Romero García, Rafael, Mandal, Ayan, Bethlehem, Richard A. I., Crespo-Facorro, Benedicto, Hart, Michael G., Suckling, John, Romero García, Rafael, Mandal, Ayan, Bethlehem, Richard A. I., Crespo-Facorro, Benedicto, Hart, Michael G., and Suckling, John

Published

2023

2. Transcriptomic and connectomic correlates of differential spatial patterning among gliomas

Author

Junta de Andalucía, Cancer Research UK, Universidad de Sevilla, Romero Garcia, Rafael [0000-0002-5199-4573], Mandal, Ayan [0000-0002-0780-3864], Romero García, Rafael, Mandal, Ayan, Bethlehem, Richard A. I., Crespo-Facorro, Benedicto, Hart, Michael G., Suckling, John, Junta de Andalucía, Cancer Research UK, Universidad de Sevilla, Romero Garcia, Rafael [0000-0002-5199-4573], Mandal, Ayan [0000-0002-0780-3864], Romero García, Rafael, Mandal, Ayan, Bethlehem, Richard A. I., Crespo-Facorro, Benedicto, Hart, Michael G., and Suckling, John

Abstract

Unravelling the complex events driving grade-specific spatial distribution of brain tumour occurrence requires rich datasets from both healthy individuals and patients. Here, we combined open-access data from The Cancer Genome Atlas, the UK Biobank and the Allen Brain Human Atlas to disentangle how the different spatial occurrences of glioblastoma multiforme and low-grade gliomas are linked to brain network features and the normative transcriptional profiles of brain regions. From MRI of brain tumour patients, we first constructed a grade-related frequency map of the regional occurrence of low-grade gliomas and the more aggressive glioblastoma multiforme. Using associated mRNA transcription data, we derived a set of differential gene expressions from glioblastoma multiforme and low-grade gliomas tissues of the same patients. By combining the resulting values with normative gene expressions from post-mortem brain tissue, we constructed a grade-related expression map indicating which brain regions express genes dysregulated in aggressive gliomas. Additionally, we derived an expression map of genes previously associated with tumour subtypes in a genome-wide association study (tumour-related genes). There were significant associations between grade-related frequency, grade-related expression and tumour-related expression maps, as well as functional brain network features (specifically, nodal strength and participation coefficient) that are implicated in neurological and psychiatric disorders. These findings identify brain network dynamics and transcriptomic signatures as key factors in regional vulnerability for glioblastoma multiforme and low-grade glioma occurrence, placing primary brain tumours within a well established framework of neurological and psychiatric cortical alterations.

Published

2023

3. Transcriptomic and connectomic correlates of differential spatial patterning among gliomas

Author

Universidad de Sevilla. Departamento de Fisiología Médica y Biofísica, Universidad de Sevilla. Departamento de Psiquiatría, Cancer Research UK Cambridge Centre, Programa EMERGIA. Junta de Andalucía, Universidad de Sevilla, Romero García, Rafael, Mandal, Ayan, Bethlehem, Richard A. I., Crespo Facorro, Benedicto, Hart, Michael G., Suckling, John, Universidad de Sevilla. Departamento de Fisiología Médica y Biofísica, Universidad de Sevilla. Departamento de Psiquiatría, Cancer Research UK Cambridge Centre, Programa EMERGIA. Junta de Andalucía, Universidad de Sevilla, Romero García, Rafael, Mandal, Ayan, Bethlehem, Richard A. I., Crespo Facorro, Benedicto, Hart, Michael G., and Suckling, John

Abstract

Unravelling the complex events driving grade-specific spatial distribution of brain tumour occurrence requires rich datasets from both healthy individuals and patients. Here, we combined open-access data from The Cancer Genome Atlas, the UK Biobank and the Allen Brain Human Atlas to disentangle how the different spatial occurrences of glioblastoma multiforme and low-grade gliomas are linked to brain network features and the normative transcriptional profiles of brain regions. From MRI of brain tumour patients, we first constructed a grade-related frequency map of the regional occurrence of low-grade gliomas and the more aggressive glioblastoma multiforme. Using associated mRNA transcription data, we derived a set of differential gene expressions from glioblastoma multiforme and low-grade gliomas tissues of the same patients. By combining the resulting values with normative gene expressions from post-mortem brain tissue, we constructed a grade-related expression map indicating which brain regions express genes dysregulated in aggressive gliomas. Additionally, we derived an expression map of genes previously associated with tumour subtypes in a genome-wide association study (tumour-related genes). There were significant associations between grade-related frequency, grade-related expression and tumour-related expression maps, as well as functional brain network features (specifically, nodal strength and participation coefficient) that are implicated in neurological and psychiatric disorders. These findings identify brain network dynamics and transcriptomic signatures as key factors in regional vulnerability for glioblastoma multiforme and low-grade glioma occurrence, placing primary brain tumours within a well established framework of neurological and psychiatric cortical alterations.

Published

2022

4. Lesion covariance networks reveal proposed origins and pathways of diffuse gliomas

Author

Universidad de Sevilla. Departamento de Fisiología Médica y Biofísica, Mandal, Ayan, Romero García, Rafael, Seidlitz, Jakob, Hart, Michael G., Alexander-Bloch, Aaron F., Suckling, John, Universidad de Sevilla. Departamento de Fisiología Médica y Biofísica, Mandal, Ayan, Romero García, Rafael, Seidlitz, Jakob, Hart, Michael G., Alexander-Bloch, Aaron F., and Suckling, John

Abstract

Diffuse gliomas have been hypothesized to originate from neural stem cells in the subventricular zone and develop along previously healthy brain networks. Here, we evaluated these hypotheses by mapping independent sources of glioma localization and determining their relationships with neurogenic niches, genetic markers and large-scale connectivity networks. By applying independent component analysis to lesion data from 242 adult patients with high- and low-grade glioma, we identified three lesion covariance networks, which reflect clusters of frequent glioma localization. Replicability of the lesion covariance networks was assessed in an independent sample of 168 glioma patients. We related the lesion covariance networks to important clinical variables, including tumour grade and patient survival, as well as genomic information such as molecular genetic subtype and bulk transcriptomic profiles. Finally, we systematically cross-correlated the lesion covariance networks with structural and functional connectivity networks derived from neuroimaging data of over 4000 healthy UK BioBank participants to uncover intrinsic brain networks that may that underlie tumour development. The three lesion covariance networks overlapped with the anterior, posterior and inferior horns of the lateral ventricles respectively, extending into the frontal, parietal and temporal cortices. These locations were independently replicated. The first lesion covariance network, which overlapped with the anterior horn, was associated with low-grade, isocitrate dehydrogenase -mutated/1p19q-codeleted tumours, as well as a neural transcriptomic signature and improved overall survival. Each lesion covariance network significantly coincided with multiple structural and functional connectivity networks, with the first bearing an especially strong relationship with brain connectivity, consistent with its neural transcriptomic profile. Finally, we identified subcortical, periventricular structures with fun

Published

2021

5. Genetic, cellular, and connectomic characterization of the brain regions commonly plagued by glioma

Author

Universidad de Sevilla. Departamento de Fisiología Médica y Biofísica, Universidad de Sevilla. CTS1086: Psiquiatría Traslacional, Mandal, Ayan, Romero García, Rafael, Hart, Michael G., Suckling, John, Universidad de Sevilla. Departamento de Fisiología Médica y Biofísica, Universidad de Sevilla. CTS1086: Psiquiatría Traslacional, Mandal, Ayan, Romero García, Rafael, Hart, Michael G., and Suckling, John

Abstract

For decades, it has been known that gliomas follow a non-random spatial distribution, appearing more often in some brain regions (e.g. the insula) compared to others (e.g. the occipital lobe). A better understanding of the localization patterns of gliomas could provide clues to the origins of these types of tumours, and consequently inform treatment targets. Following hypotheses derived from prior research into neuropsychiatric disease and cancer, gliomas may be expected to localize to brain regions characterized by functional hubness, stem-like cells, and transcription of genetic drivers of gliomagenesis. We combined neuroimaging data from 335 adult patients with high- and low-grade glioma to form a replicable tumour frequency map. Using this map, we demonstrated that glioma frequency is elevated in association cortex and correlated with multiple graph-theoretical metrics of high functional connectedness. Brain regions populated with putative cells of origin for glioma, neural stem cells and oligodendrocyte precursor cells, exhibited a high glioma frequency. Leveraging a human brain atlas of post-mortem gene expression, we found that gliomas were localized to brain regions enriched with expression of genes associated with chromatin organization and synaptic signalling. A set of glioma proto-oncogenes was enriched among the transcriptomic correlates of glioma distribution. Finally, a regression model incorporating connectomic, cellular, and genetic factors explained 58% of the variance in glioma frequency. These results add to previous literature reporting the vulnerability of hub regions to neurological disease, as well as provide support for cancer stem cell theories of glioma. Our findings illustrate how factors of diverse scale, from genetic to connectomic, can independently in fluence the anatomic localization of brain dysfunction.

Published

2020

6. Cortico-thalamic tremor circuits and their associations with deep brain stimulation effects in essential tremor.

Author

He S, West TO, Plazas FR, Wehmeyer L, Pogosyan A, Deli A, Wiest C, Herz DM, Simpson T, Andrade P, Baig F, Hart MG, Morgante F, FitzGerald JJ, Barbe MT, Visser-Vandewalle V, Green AL, Pereira EA, Cagnan H, and Tan H

Abstract

Essential tremor (ET) is one of the most common movement disorders in adults. Deep brain stimulation (DBS) of the ventralis intermediate nucleus (VIM) of the thalamus and/or the posterior subthalamic area (PSA) has been shown to provide significant tremor suppression in patients with ET, but with significant inter-patient variability and habituation to the stimulation. Several non-invasive neuromodulation techniques targeting other parts of the central nervous system, including cerebellar, motor cortex, or peripheral nerves, have also been developed for treating ET, but the clinical outcomes remain inconsistent. Existing studies suggest that pathology in ET may emerge from multiple cortical and subcortical areas, but its exact mechanisms remain unclear. By simultaneously capturing neural activities from motor cortices and thalami, and hand tremor signals recorded via accelerometers in fifteen human subjects who have undergone lead implantations for DBS, we systematically characterized the efferent and afferent cortico-thalamic tremor networks. Through the comparisons of these network characteristics and tremor amplitude between DBS OFF and ON conditions, we further investigated the associations between different tremor network characteristics and the magnitude of DBS effect. Our findings implicate the thalamus, specifically the contralateral hemisphere, as the primary generator of tremor in ET, with a significant contribution of the ipsilateral hemisphere as well. Although there is no direct correlation between the cortico-tremor connectivity and tremor power or reduced tremor by DBS, the strength of connectivity from the motor cortex to the thalamus and vice versa at tremor frequency predicts baseline tremor power and effect of DBS. Interestingly, there is no correlation between these two connectivity pathways themselves, suggesting that, independent of the subcortical pathway, the motor cortex appears to play a relatively distinct role, possibly mediated through an afferent/feedback loop in the propagation of tremor. DBS has a greater clinical effect in those with stronger cortico-thalamo-tremor connectivity involving the contralateral thalamus, which is also associated with bigger and more stable tremor measured with an accelerometer. Interestingly, stronger cross-hemisphere coupling between left and right thalami is associated with more unstable tremor. Together this study provides important insights into a better understanding of the cortico-thalamic tremor generating network and its implication for the development of patient-specific therapeutic approaches for ET., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2024

7. Beta-triggered adaptive deep brain stimulation during reaching movement in Parkinson's disease.

Author

He S, Baig F, Merla A, Torrecillos F, Perera A, Wiest C, Debarros J, Benjaber M, Hart MG, Ricciardi L, Morgante F, Hasegawa H, Samuel M, Edwards M, Denison T, Pogosyan A, Ashkan K, Pereira E, and Tan H

Subjects

Humans, Tremor therapy, Movement physiology, Parkinson Disease therapy, Deep Brain Stimulation methods, Subthalamic Nucleus physiology

Abstract

Subthalamic nucleus (STN) beta-triggered adaptive deep brain stimulation (ADBS) has been shown to provide clinical improvement comparable to conventional continuous DBS (CDBS) with less energy delivered to the brain and less stimulation induced side effects. However, several questions remain unanswered. First, there is a normal physiological reduction of STN beta band power just prior to and during voluntary movement. ADBS systems will therefore reduce or cease stimulation during movement in people with Parkinson's disease and could therefore compromise motor performance compared to CDBS. Second, beta power was smoothed and estimated over a time period of 400 ms in most previous ADBS studies, but a shorter smoothing period could have the advantage of being more sensitive to changes in beta power, which could enhance motor performance. In this study, we addressed these two questions by evaluating the effectiveness of STN beta-triggered ADBS using a standard 400 ms and a shorter 200 ms smoothing window during reaching movements. Results from 13 people with Parkinson's disease showed that reducing the smoothing window for quantifying beta did lead to shortened beta burst durations by increasing the number of beta bursts shorter than 200 ms and more frequent switching on/off of the stimulator but had no behavioural effects. Both ADBS and CDBS improved motor performance to an equivalent extent compared to no DBS. Secondary analysis revealed that there were independent effects of a decrease in beta power and an increase in gamma power in predicting faster movement speed, while a decrease in beta event related desynchronization (ERD) predicted quicker movement initiation. CDBS suppressed both beta and gamma more than ADBS, whereas beta ERD was reduced to a similar level during CDBS and ADBS compared with no DBS, which together explained the achieved similar performance improvement in reaching movements during CDBS and ADBS. In addition, ADBS significantly improved tremor compared with no DBS but was not as effective as CDBS. These results suggest that STN beta-triggered ADBS is effective in improving motor performance during reaching movements in people with Parkinson's disease, and that shortening of the smoothing window does not result in any additional behavioural benefit. When developing ADBS systems for Parkinson's disease, it might not be necessary to track very fast beta dynamics; combining beta, gamma, and information from motor decoding might be more beneficial with additional biomarkers needed for optimal treatment of tremor., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2023

8. Radiofrequency thalamotomy for tremor produces focused and predictable lesions shown on magnetic resonance images.

Author

Ishihara BK, Hart MG, Barrick TR, Howe FA, Morgante F, and Pereira EA

Abstract

Radiofrequency thalamotomy is a neurosurgical management option for medically-refractory tremor. In this observational study, we evaluate the MRI features of the resultant lesion, their temporal dynamics, and how they vary depending on surgical factors. We report on lesion characteristics including size and location, as well as how these vary over time and across different MRI sequences. Data from 12 patients (2 essential tremor, 10 Parkinson's disease) who underwent unilateral radiofrequency thalamotomy for tremor were analysed. Lesion characteristics were compared across five structural sequences. Volumetric analysis of lesion features was performed at early (<5 weeks) and late (>5 months) timepoints by manual segmentation. Lesion location was determined after registration of lesions to standard space. All patients showed tremor improvement (clinical global impressions scale) postoperatively. Chronic side-effects included balance disturbances ( n = 4) and worsening mobility due to parkinsonism progression ( n = 1). Early lesion features including a necrotic core, cytotoxic oedema and perilesional oedema were best demarcated on T 2 -weighted sequences. Multiple lesions were associated with greater cytotoxic oedema compared with single lesions (T 2 -weighted mean volume: 537 ± 112 mm³ versus 302 ± 146 mm³, P = 0.028). Total lesion volume reduced on average by 90% between the early and late scans (T 2 -weighted mean volume: 918 ± 517 versus 75 ± 50 mm³, t = 3.592, P = 0.023, n = 5), with comparable volumes demonstrated at ∼6 months after surgery. Lesion volumes on susceptibility-weighted images were larger than those of T 2 -weighted images at later timepoints. Radiofrequency thalamotomy produces focused and predictable lesion imaging characteristics over time. T 2 -weighted scans distinguish between the early lesion core and oedema characteristics, while lesions may remain more visible on susceptibility-weighted images in the months following surgery. Scanning patients in the immediate postoperative period and then at 6 months is clinically meaningful for understanding the anatomical basis of the transient and permanent effects of thalamotomy., Competing Interests: F.M.: speaking honoraria from Abbvie, Medtronic, Bial and Merz; travel grants from the International Parkinson’s disease and Movement Disorder Society; advisory board fees from Merz and Boston Scientific; consultancy fees from Merz, Boston Scientific and Bial; research support from NIHR, UKRI, Boston Scientific, Merz and Global Kynetic; royalties from Springer for the book ‘Disorders of Movement’; member of the editorial board of Movement Disorders, Movement Disorders Clinical Practice, European Journal of Neurology and Journal of Neurology. E.A.P.: chief investigator of RAPID-CNS., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2023

9. Transcriptomic and connectomic correlates of differential spatial patterning among gliomas.

Author

Romero-Garcia R, Mandal AS, Bethlehem RAI, Crespo-Facorro B, Hart MG, and Suckling J

Subjects

Humans, Transcriptome, Genome-Wide Association Study, Glioblastoma genetics, Connectome, Glioma genetics, Brain Neoplasms metabolism

Abstract

Unravelling the complex events driving grade-specific spatial distribution of brain tumour occurrence requires rich datasets from both healthy individuals and patients. Here, we combined open-access data from The Cancer Genome Atlas, the UK Biobank and the Allen Brain Human Atlas to disentangle how the different spatial occurrences of glioblastoma multiforme and low-grade gliomas are linked to brain network features and the normative transcriptional profiles of brain regions. From MRI of brain tumour patients, we first constructed a grade-related frequency map of the regional occurrence of low-grade gliomas and the more aggressive glioblastoma multiforme. Using associated mRNA transcription data, we derived a set of differential gene expressions from glioblastoma multiforme and low-grade gliomas tissues of the same patients. By combining the resulting values with normative gene expressions from post-mortem brain tissue, we constructed a grade-related expression map indicating which brain regions express genes dysregulated in aggressive gliomas. Additionally, we derived an expression map of genes previously associated with tumour subtypes in a genome-wide association study (tumour-related genes). There were significant associations between grade-related frequency, grade-related expression and tumour-related expression maps, as well as functional brain network features (specifically, nodal strength and participation coefficient) that are implicated in neurological and psychiatric disorders. These findings identify brain network dynamics and transcriptomic signatures as key factors in regional vulnerability for glioblastoma multiforme and low-grade glioma occurrence, placing primary brain tumours within a well established framework of neurological and psychiatric cortical alterations., (© The Author(s) 2022. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2023

10. Lesion covariance networks reveal proposed origins and pathways of diffuse gliomas.

Author

Mandal AS, Romero-Garcia R, Seidlitz J, Hart MG, Alexander-Bloch AF, and Suckling J

Abstract

Diffuse gliomas have been hypothesized to originate from neural stem cells in the subventricular zone and develop along previously healthy brain networks. Here, we evaluated these hypotheses by mapping independent sources of glioma localization and determining their relationships with neurogenic niches, genetic markers and large-scale connectivity networks. By applying independent component analysis to lesion data from 242 adult patients with high- and low-grade glioma, we identified three lesion covariance networks, which reflect clusters of frequent glioma localization. Replicability of the lesion covariance networks was assessed in an independent sample of 168 glioma patients. We related the lesion covariance networks to important clinical variables, including tumour grade and patient survival, as well as genomic information such as molecular genetic subtype and bulk transcriptomic profiles. Finally, we systematically cross-correlated the lesion covariance networks with structural and functional connectivity networks derived from neuroimaging data of over 4000 healthy UK BioBank participants to uncover intrinsic brain networks that may that underlie tumour development. The three lesion covariance networks overlapped with the anterior, posterior and inferior horns of the lateral ventricles respectively, extending into the frontal, parietal and temporal cortices. These locations were independently replicated. The first lesion covariance network, which overlapped with the anterior horn, was associated with low-grade, isocitrate dehydrogenase -mutated/1p19q-codeleted tumours, as well as a neural transcriptomic signature and improved overall survival. Each lesion covariance network significantly coincided with multiple structural and functional connectivity networks, with the first bearing an especially strong relationship with brain connectivity, consistent with its neural transcriptomic profile. Finally, we identified subcortical, periventricular structures with functional connectivity patterns to the cortex that significantly matched each lesion covariance network. In conclusion, we demonstrated replicable patterns of glioma localization with clinical relevance and spatial correspondence with large-scale functional and structural connectivity networks. These results are consistent with prior reports of glioma growth along white matter pathways, as well as evidence for the coordination of glioma stem cell proliferation by neuronal activity. Our findings describe how the locations of gliomas relate to their proposed subventricular origins, suggesting a model wherein periventricular brain connectivity guides tumour development., (© The Author(s) (2021). Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2021

11. Genetic, cellular, and connectomic characterization of the brain regions commonly plagued by glioma.

Author

Mandal AS, Romero-Garcia R, Hart MG, and Suckling J

Subjects

Algorithms, Atlases as Topic, Brain Mapping, Brain Neoplasms epidemiology, Cerebral Cortex pathology, Chromatin genetics, Gene Expression Regulation, Neoplastic genetics, Glioma epidemiology, Humans, Neoplastic Stem Cells pathology, Neural Stem Cells pathology, Neuroimaging, Oligodendrocyte Precursor Cells pathology, Postmortem Changes, Synapses pathology, Brain pathology, Brain Neoplasms genetics, Brain Neoplasms pathology, Connectome, Glioma genetics, Glioma pathology

Abstract

For decades, it has been known that gliomas follow a non-random spatial distribution, appearing more often in some brain regions (e.g. the insula) compared to others (e.g. the occipital lobe). A better understanding of the localization patterns of gliomas could provide clues to the origins of these types of tumours, and consequently inform treatment targets. Following hypotheses derived from prior research into neuropsychiatric disease and cancer, gliomas may be expected to localize to brain regions characterized by functional hubness, stem-like cells, and transcription of genetic drivers of gliomagenesis. We combined neuroimaging data from 335 adult patients with high- and low-grade glioma to form a replicable tumour frequency map. Using this map, we demonstrated that glioma frequency is elevated in association cortex and correlated with multiple graph-theoretical metrics of high functional connectedness. Brain regions populated with putative cells of origin for glioma, neural stem cells and oligodendrocyte precursor cells, exhibited a high glioma frequency. Leveraging a human brain atlas of post-mortem gene expression, we found that gliomas were localized to brain regions enriched with expression of genes associated with chromatin organization and synaptic signalling. A set of glioma proto-oncogenes was enriched among the transcriptomic correlates of glioma distribution. Finally, a regression model incorporating connectomic, cellular, and genetic factors explained 58% of the variance in glioma frequency. These results add to previous literature reporting the vulnerability of hub regions to neurological disease, as well as provide support for cancer stem cell theories of glioma. Our findings illustrate how factors of diverse scale, from genetic to connectomic, can independently influence the anatomic localization of brain dysfunction., (© The Author(s) (2020). Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published

2020