Your search keyword '"Bright, Molly G."' showing total 20 results

1. Simultaneous cortical, subcortical, and brainstem mapping of sensory activation.

Author

Reddy NA, Clements RG, Brooks JCW, and Bright MG

Subjects

Humans, Female, Male, Adult, Young Adult, Cerebral Cortex physiology, Cerebral Cortex diagnostic imaging, Touch Perception physiology, Physical Stimulation, Hand physiology, Brain Stem physiology, Brain Stem diagnostic imaging, Magnetic Resonance Imaging methods, Brain Mapping methods

Abstract

Nonpainful tactile sensory stimuli are processed in the cortex, subcortex, and brainstem. Recent functional magnetic resonance imaging studies have highlighted the value of whole-brain, systems-level investigation for examining sensory processing. However, whole-brain functional magnetic resonance imaging studies are uncommon, in part due to challenges with signal to noise when studying the brainstem. Furthermore, differentiation of small sensory brainstem structures such as the cuneate and gracile nuclei necessitates high-resolution imaging. To address this gap in systems-level sensory investigation, we employed a whole-brain, multi-echo functional magnetic resonance imaging acquisition at 3T with multi-echo independent component analysis denoising and brainstem-specific modeling to enable detection of activation across the entire sensory system. In healthy participants, we examined patterns of activity in response to nonpainful brushing of the right hand, left hand, and right foot (n = 10 per location), and found the expected lateralization, with distinct cortical and subcortical responses for upper and lower limb stimulation. At the brainstem level, we differentiated the adjacent cuneate and gracile nuclei, corresponding to hand and foot stimulation respectively. Our findings demonstrate that simultaneous cortical, subcortical, and brainstem mapping at 3T could be a key tool to understand the sensory system in both healthy individuals and clinical cohorts with sensory deficits., (© The Author(s) 2024. Published by Oxford University Press.)

Published

2024

2. Hemodynamic timing in resting-state and breathing-task BOLD fMRI.

Author

Gong J, Stickland RC, and Bright MG

Subjects

Adult, Humans, Hemodynamics, Brain Mapping methods, Respiration, Cerebrovascular Circulation physiology, Magnetic Resonance Imaging methods, Brain physiology

Abstract

The blood flow response to a vasoactive stimulus demonstrates regional heterogeneity across both the healthy brain and in cerebrovascular pathology. The timing of a regional hemodynamic response is emerging as an important biomarker of cerebrovascular dysfunction, as well as a confound within fMRI analyses. Previous research demonstrated that hemodynamic timing is more robustly characterized when a larger systemic vascular response is evoked by a breathing challenge, compared to when only spontaneous fluctuations in vascular physiology are present (i.e., in resting-state data). However, it is not clear whether hemodynamic delays in these two conditions are physiologically interchangeable, and how methodological signal-to-noise factors may limit their agreement. To address this, we generated whole-brain maps of hemodynamic delays in nine healthy adults. We assessed the agreement of voxel-wise gray matter (GM) hemodynamic delays between two conditions: resting-state and breath-holding. We found that delay values demonstrated poor agreement when considering all GM voxels, but increasingly greater agreement when limiting analyses to voxels showing strong correlation with the GM mean time-series. Voxels showing the strongest agreement with the GM mean time-series were primarily located near large venous vessels, however these voxels explain some, but not all, of the observed agreement in timing. Increasing the degree of spatial smoothing of the fMRI data enhanced the correlation between individual voxel time-series and the GM mean time-series. These results suggest that signal-to-noise factors may be limiting the accuracy of voxel-wise timing estimates and hence their agreement between the two data segments. In conclusion, caution must be taken when using voxel-wise delay estimates from resting-state and breathing-task data interchangeably, and additional work is needed to evaluate their relative sensitivity and specificity to aspects of vascular physiology and pathology., Competing Interests: Declaration of Competing Interest The authors declare no competing financial interests., (Copyright © 2023. Published by Elsevier Inc.)

Published

2023

3. Comparing end-tidal CO 2 , respiration volume per time (RVT), and average gray matter signal for mapping cerebrovascular reactivity amplitude and delay with breath-hold task BOLD fMRI.

Author

Zvolanek KM, Moia S, Dean JN, Stickland RC, Caballero-Gaudes C, and Bright MG

Subjects

Adult, Child, Humans, Carbon Dioxide, Gray Matter diagnostic imaging, Retrospective Studies, Prospective Studies, Breath Holding, Cerebrovascular Circulation physiology, Brain Mapping methods, Magnetic Resonance Imaging methods, Brain physiology

Abstract

Cerebrovascular reactivity (CVR), defined as the cerebral blood flow response to a vasoactive stimulus, is an imaging biomarker with demonstrated utility in a range of diseases and in typical development and aging processes. A robust and widely implemented method to map CVR involves using a breath-hold task during a BOLD fMRI scan. Recording end-tidal CO 2 (P ET CO 2 ) changes during the breath-hold task is recommended to be used as a reference signal for modeling CVR amplitude in standard units (%BOLD/mmHg) and CVR delay in seconds. However, obtaining reliable P ET CO 2 recordings requires equipment and task compliance that may not be achievable in all settings. To address this challenge, we investigated two alternative reference signals to map CVR amplitude and delay in a lagged general linear model (lagged-GLM) framework: respiration volume per time (RVT) and average gray matter BOLD response (GM-BOLD). In 8 healthy adults with multiple scan sessions, we compare spatial agreement of CVR maps from RVT and GM-BOLD to those generated with P ET CO 2 . We define a threshold to determine whether a P ET CO 2 recording has "sufficient" quality for CVR mapping and perform these comparisons in 16 datasets with sufficient P ET CO 2 and 6 datasets with insufficient P ET CO 2 . When P ET CO 2 quality is sufficient, both RVT and GM-BOLD produce CVR amplitude maps that are nearly identical to those from P ET CO 2 (after accounting for differences in scale), with the caveat they are not in standard units to facilitate between-group comparisons. CVR delays are comparable to P ET CO 2 with an RVT regressor but may be underestimated with the average GM-BOLD regressor. Importantly, when P ET CO 2 quality is insufficient, RVT and GM-BOLD CVR recover reasonable CVR amplitude and delay maps, provided the participant attempted the breath-hold task. Therefore, our framework offers a solution for achieving high quality CVR maps in both retrospective and prospective studies where sufficient P ET CO 2 recordings are not available and especially in populations where obtaining reliable measurements is a known challenge (e.g., children). Our results have the potential to improve the accessibility of CVR mapping and to increase the prevalence of this promising metric of vascular health., Competing Interests: Declaration of Competing Interest The authors declare no competing financial interests., (Copyright © 2023. Published by Elsevier Inc.)

Published

2023

4. A practical modification to a resting state fMRI protocol for improved characterization of cerebrovascular function.

Author

Stickland RC, Zvolanek KM, Moia S, Ayyagari A, Caballero-Gaudes C, and Bright MG

Subjects

Adult, Breath Holding, Carbon Dioxide blood, Cerebral Palsy diagnostic imaging, Cerebral Palsy physiopathology, Datasets as Topic, Female, Humans, Incidental Findings, Male, Moyamoya Disease diagnostic imaging, Moyamoya Disease physiopathology, Oxygen blood, Respiration, Young Adult, Cerebrovascular Circulation physiology, Magnetic Resonance Imaging methods, Rest physiology

Abstract

Cerebrovascular reactivity (CVR), defined here as the Blood Oxygenation Level Dependent (BOLD) response to a CO 2 pressure change, is a useful metric of cerebrovascular function. Both the amplitude and the timing (hemodynamic lag) of the CVR response can bring insight into the nature of a cerebrovascular pathology and aid in understanding noise confounds when using functional Magnetic Resonance Imaging (fMRI) to study neural activity. This research assessed a practical modification to a typical resting-state fMRI protocol, to improve the characterization of cerebrovascular function. In 9 healthy subjects, we modelled CVR and lag in three resting-state data segments, and in data segments which added a 2-3 minute breathing task to the start of a resting-state segment. Two different breathing tasks were used to induce fluctuations in arterial CO 2 pressure: a breath-hold task to induce hypercapnia (CO 2 increase) and a cued deep breathing task to induce hypocapnia (CO 2 decrease). Our analysis produced voxel-wise estimates of the amplitude (CVR) and timing (lag) of the BOLD-fMRI response to CO 2 by systematically shifting the CO 2 regressor in time to optimize the model fit. This optimization inherently increases gray matter CVR values and fit statistics. The inclusion of a simple breathing task, compared to a resting-state scan only, increases the number of voxels in the brain that have a significant relationship between CO 2 and BOLD-fMRI signals, and improves our confidence in the plausibility of voxel-wise CVR and hemodynamic lag estimates. We demonstrate the clinical utility and feasibility of this protocol in an incidental finding of Moyamoya disease, and explore the possibilities and challenges of using this protocol in younger populations. This hybrid protocol has direct applications for CVR mapping in both research and clinical settings and wider applications for fMRI denoising and interpretation., Competing Interests: Declaration of Competing Interest The authors declare no competing financial interests., (Copyright © 2021. Published by Elsevier Inc.)

Published

2021

5. ICA-based denoising strategies in breath-hold induced cerebrovascular reactivity mapping with multi echo BOLD fMRI.

Author

Moia S, Termenon M, Uruñuela E, Chen G, Stickland RC, Bright MG, and Caballero-Gaudes C

Subjects

Adult, Aged, Aged, 80 and over, Blood Flow Velocity physiology, Brain blood supply, Cerebral Arteries diagnostic imaging, Cohort Studies, Female, Humans, Male, Middle Aged, Prospective Studies, Brain diagnostic imaging, Breath Holding, Cerebrovascular Circulation physiology, Magnetic Resonance Imaging methods, Oxygen Consumption physiology, Spin Labels

Abstract

Performing a BOLD functional MRI (fMRI) acquisition during breath-hold (BH) tasks is a non-invasive, robust method to estimate cerebrovascular reactivity (CVR). However, movement and breathing-related artefacts caused by the BH can substantially hinder CVR estimates due to their high temporal collinearity with the effect of interest, and attention has to be paid when choosing which analysis model should be applied to the data. In this study, we evaluate the performance of multiple analysis strategies based on lagged general linear models applied on multi-echo BOLD fMRI data, acquired in ten subjects performing a BH task during ten sessions, to obtain subject-specific CVR and haemodynamic lag estimates. The evaluated approaches range from conventional regression models, i.e. including drifts and motion timecourses as nuisance regressors, applied on single-echo or optimally-combined data, to more complex models including regressors obtained from multi-echo independent component analysis with different grades of orthogonalization in order to preserve the effect of interest, i.e. the CVR. We compare these models in terms of their ability to make signal intensity changes independent from motion, as well as the reliability as measured by voxelwise intraclass correlation coefficients of both CVR and lag maps over time. Our results reveal that a conservative independent component analysis model applied on the optimally-combined multi-echo fMRI signal offers the largest reduction of motion-related effects in the signal, while yielding reliable CVR amplitude and lag estimates, although a conventional regression model applied on the optimally-combined data results in similar estimates. This work demonstrates the usefulness of multi-echo based fMRI acquisitions and independent component analysis denoising for precision mapping of CVR in single subjects based on BH paradigms, fostering its potential as a clinically-viable neuroimaging tool for individual patients. It also proves that the way in which data-driven regressors should be incorporated in the analysis model is not straight-forward due to their complex interaction with the BH-induced BOLD response., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

6. Voxelwise optimization of hemodynamic lags to improve regional CVR estimates in breath-hold fMRI.

Author

Moia S, Stickland RC, Ayyagari A, Termenon M, Caballero-Gaudes C, and Bright MG

Subjects

Brain diagnostic imaging, Hemodynamics, Oxygen, Cerebrovascular Circulation, Magnetic Resonance Imaging

Abstract

Cerebrovascular Reactivity (CVR), the responsiveness of blood vessels to a vasodilatory stimulus, is an important indicator of cerebrovascular health. Assessing CVR with fMRI, we can measure the change in the Blood Oxygen Level Dependent (BOLD) response induced by a change in CO2 pressure (%BOLD/mmHg). However, there exists a temporal offset between the recorded CO2 pressure and the local BOLD response, due to both measurement and physiological delays. If this offset is not corrected for, voxel-wise CVR values will not be accurate. In this paper, we propose a framework for mapping hemodynamic lag in breath-hold fMRI data. As breath-hold tasks drive task-correlated head motion artifacts in BOLD fMRI data, our framework for lag estimation fits a model that includes polynomial terms and head motion parameters, as well as a shifted variant of the CO2 regressor (±9 s in 0.3 s increments), and the hemodynamic lag at each voxel is the shift producing the maximum total model R2 within physiological constraints. This approach is evaluated in 8 subjects with multi-echo fMRI data, resulting in robust maps of hemodynamic delay that show consistent regional variation across subjects, and improved contrast-to-noise compared to methods where motion regression is ignored or performed earlier in preprocessing.Clinical Relevance- We map hemodynamic lag using breathhold fMRI, providing insight into vascular transit times and improving the regional accuracy of cerebrovascular reactivity measurements.

Published

2020

7. Ultra-high-field arterial spin labelling MRI for non-contrast assessment of cortical lesion perfusion in multiple sclerosis.

Author

Dury RJ, Falah Y, Gowland PA, Evangelou N, Bright MG, and Francis ST

Subjects

Adult, Cerebral Arteries physiopathology, Female, Humans, Male, Middle Aged, Multiple Sclerosis physiopathology, Spin Labels, Cerebral Arteries diagnostic imaging, Cerebrovascular Circulation physiology, Gray Matter diagnostic imaging, Magnetic Resonance Imaging methods, Multiple Sclerosis diagnosis, Regional Blood Flow physiology

Abstract

Objectives: To assess the feasibility of using an optimised ultra-high-field high-spatial-resolution low-distortion arterial spin labelling (ASL) MRI acquisition to measure focal haemodynamic pathology in cortical lesions (CLs) in multiple sclerosis (MS)., Methods: Twelve MS patients (eight female, mean age 50 years; range 35-64 years) gave informed consent and were scanned on a 7 Tesla Philips Achieva scanner. Perfusion data were collected at multiple post-labelling delay times using a single-slice flow-sensitive alternating inversion recovery ASL protocol with a balanced steady-state free precession readout scheme. CLs were identified using a high-resolution Phase-Sensitive Inversion Recovery (PSIR) scan. Significant differences in perfusion within CLs compared to immediately surrounding normal appearing grey matter (NAGM local ) and total cortical normal appearing grey matter (NAGM cortical ) were assessed using paired t-tests., Results: Forty CLs were identified in PSIR scans that overlapped with the ASL acquisition coverage. After excluding lesions due to small size or intravascular contamination, 27 lesions were eligible for analysis. Mean perfusion was 40 ± 25 ml/100 g/min in CLs, 53 ± 12 ml/100 g/min in NAGM local , and 53 ± 8 ml/100 g/min in NAGM cortical . CL perfusion was significantly reduced by 23 ± 9% (mean ± SE, p = 0.013) and 26 ± 9% (p = 0.006) relative to NAGM local and NAGM cortical perfusion, respectively., Conclusion: This is the first ASL MRI study quantifying CL perfusion in MS at 7 Tesla, demonstrating that an optimised ASL acquisition is sensitive to focal haemodynamic pathology previously observed using dynamic susceptibility contrast MRI. ASL requires no exogenous contrast agent, making it a more appropriate tool to monitor longitudinal perfusion changes in MS, providing a new window to study lesion development., Key Points: • Perfusion can be quantified within cortical lesions in multiple sclerosis using an optimised high spatial resolution arterial spin Labelling MRI acquisition at ultra-high-field. • The majority of cortical lesions assessed using arterial spin labelling are hypo-perfused compared to normal appearing grey matter, in agreement with dynamic susceptibility contrast MRI literature. • Arterial spin labelling MRI, which does not involve the injection of a contrast agent, is a safe and appropriate technique for repeat scanning of an individual patient.

Published

2019

8. Multiparametric measurement of cerebral physiology using calibrated fMRI.

Author

Bright MG, Croal PL, Blockley NP, and Bulte DP

Subjects

Alzheimer Disease diagnostic imaging, Alzheimer Disease physiopathology, Animals, Calibration, Cerebral Blood Volume, Cerebral Cortex blood supply, Cerebrovascular Circulation, Humans, Image Processing, Computer-Assisted methods, Oxygen metabolism, Oxygen Consumption, Brain Mapping methods, Cerebral Cortex diagnostic imaging, Cerebral Cortex physiology, Magnetic Resonance Imaging methods

Abstract

The ultimate goal of calibrated fMRI is the quantitative imaging of oxygen metabolism (CMRO 2 ), and this has been the focus of numerous methods and approaches. However, one underappreciated aspect of this quest is that in the drive to measure CMRO 2 , many other physiological parameters of interest are often acquired along the way. This can significantly increase the value of the dataset, providing greater information that is clinically relevant, or detail that can disambiguate the cause of signal variations. This can also be somewhat of a double-edged sword: calibrated fMRI experiments combine multiple parameters into a physiological model that requires multiple steps, thereby providing more opportunity for error propagation and increasing the noise and error of the final derived values. As with all measurements, there is a trade-off between imaging time, spatial resolution, coverage, and accuracy. In this review, we provide a brief overview of the benefits and pitfalls of extracting multiparametric measurements of cerebral physiology through calibrated fMRI experiments., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2019

9. Changes in arterial cerebral blood volume during lower body negative pressure measured with MRI.

Author

Whittaker JR, Bright MG, Driver ID, Babic A, Khot S, and Murphy K

Subjects

Cerebral Cortex physiology, Homeostasis, Humans, Image Processing, Computer-Assisted, Male, Spin Labels, Arteries physiology, Cerebral Blood Volume, Cerebral Cortex blood supply, Cerebral Cortex diagnostic imaging, Cerebrovascular Circulation, Lower Body Negative Pressure, Magnetic Resonance Imaging methods

Abstract

Cerebral Autoregulation (CA), defined as the ability of the cerebral vasculature to maintain stable levels of blood flow despite changes in systemic blood pressure, is a critical factor in neurophysiological health. Magnetic resonance imaging (MRI) is a powerful technique for investigating cerebrovascular function, offering high spatial resolution and wide fields of view (FOV), yet it is relatively underutilized as a tool for assessment of CA. The aim of this study was to demonstrate the potential of using MRI to measure changes in cerebrovascular resistance in response to lower body negative pressure (LBNP). A Pulsed Arterial Spin Labeling (PASL) approach with short inversion times (TI) was used to estimate cerebral arterial blood volume (CBV a ) in eight healthy subjects at baseline and -40mmHg LBNP. We estimated group mean CBV a values of 3.13 ± 1.00 and 2.70 ± 0.38 for baseline and lbnp respectively, which were the result of a differential change in CBV a during -40mmHg LBNP that was dependent on baseline CBV a . These data suggest that the PASL CBV a estimates are sensitive to the complex cerebrovascular response that occurs during the moderate orthostatic challenge delivered by LBNP, which we speculatively propose may involve differential changes in vascular tone within different segments of the arterial vasculature. These novel data provide invaluable insight into the mechanisms that regulate perfusion of the brain, and establishes the use of MRI as a tool for studying CA in more detail., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2019

10. Potential pitfalls when denoising resting state fMRI data using nuisance regression.

Author

Bright MG, Tench CR, and Murphy K

Subjects

Adult, Female, Humans, Male, Young Adult, Functional Neuroimaging methods, Image Processing, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

In resting state fMRI, it is necessary to remove signal variance associated with noise sources, leaving cleaned fMRI time-series that more accurately reflect the underlying intrinsic brain fluctuations of interest. This is commonly achieved through nuisance regression, in which the fit is calculated of a noise model of head motion and physiological processes to the fMRI data in a General Linear Model, and the "cleaned" residuals of this fit are used in further analysis. We examine the statistical assumptions and requirements of the General Linear Model, and whether these are met during nuisance regression of resting state fMRI data. Using toy examples and real data we show how pre-whitening, temporal filtering and temporal shifting of regressors impact model fit. Based on our own observations, existing literature, and statistical theory, we make the following recommendations when employing nuisance regression: pre-whitening should be applied to achieve valid statistical inference of the noise model fit parameters; temporal filtering should be incorporated into the noise model to best account for changes in degrees of freedom; temporal shifting of regressors, although merited, should be achieved via optimisation and validation of a single temporal shift. We encourage all readers to make simple, practical changes to their fMRI denoising pipeline, and to regularly assess the appropriateness of the noise model used. By negotiating the potential pitfalls described in this paper, and by clearly reporting the details of nuisance regression in future manuscripts, we hope that the field will achieve more accurate and precise noise models for cleaning the resting state fMRI time-series., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2017

11. Cleaning up the fMRI time series: Mitigating noise with advanced acquisition and correction strategies.

Author

Bright MG and Murphy K

Subjects

Brain Mapping methods, Humans, Signal-To-Noise Ratio, Artifacts, Brain physiology, Magnetic Resonance Imaging, Neuroimaging methods

Published

2017

12. Arterial CO2 Fluctuations Modulate Neuronal Rhythmicity: Implications for MEG and fMRI Studies of Resting-State Networks.

Author

Driver ID, Whittaker JR, Bright MG, Muthukumaraswamy SD, and Murphy K

Subjects

Adult, Biological Clocks physiology, Carbon Dioxide administration & dosage, Female, Humans, Hypercapnia blood, Hypercapnia pathology, Hypercapnia physiopathology, Image Processing, Computer-Assisted, Linear Models, Male, Neurons metabolism, Oxygen blood, Brain diagnostic imaging, Brain Mapping, Carbon Dioxide blood, Magnetic Resonance Imaging, Magnetoencephalography, Nerve Net diagnostic imaging, Rest

Abstract

Unlabelled: A fast emerging technique for studying human resting state networks (RSNs) is based on spontaneous temporal fluctuations in neuronal oscillatory power, as measured by magnetoencephalography. However, it has been demonstrated recently that this power is sensitive to modulations in arterial CO2 concentration. Arterial CO2 can be modulated by natural fluctuations in breathing pattern, as might typically occur during the acquisition of an RSN experiment. Here, we demonstrate for the first time the fine-scale dependence of neuronal oscillatory power on arterial CO2 concentration, showing that reductions in alpha, beta, and gamma power are observed with even very mild levels of hypercapnia (increased arterial CO2). We use a graded hypercapnia paradigm and participant feedback to rule out a sensory cause, suggesting a predominantly physiological origin. Furthermore, we demonstrate that natural fluctuations in arterial CO2, without administration of inspired CO2, are of a sufficient level to influence neuronal oscillatory power significantly in the delta-, alpha-, beta-, and gamma-frequency bands. A more thorough understanding of the relationship between physiological factors and cortical rhythmicity is required. In light of these findings, existing results, paradigms, and analysis techniques for the study of resting-state brain data should be revisited., Significance Statement: In this study, we show for the first time that neuronal oscillatory power is intimately linked to arterial CO2 concentration down to the fine-scale modulations that occur during spontaneous breathing. We extend these results to demonstrate a correlation between neuronal oscillatory power and spontaneous arterial CO2 fluctuations in awake humans at rest. This work identifies a need for studies investigating resting-state networks in the human brain to measure and account for the impact of spontaneous changes in arterial CO2 on the neuronal signals of interest. Changes in breathing pattern that are time locked to task performance could also lead to confounding effects on neuronal oscillatory power when considering the electrophysiological response to functional stimulation., Competing Interests: The authors declare no competing financial interests., (Copyright © 2016 Driver et al.)

Published

2016

13. Is fMRI "noise" really noise? Resting state nuisance regressors remove variance with network structure.

Author

Bright MG and Murphy K

Subjects

Adult, Female, Humans, Male, Regression Analysis, Artifacts, Brain physiology, Brain Mapping methods, Magnetic Resonance Imaging methods, Nerve Net physiology

Abstract

Noise correction is a critical step towards accurate mapping of resting state BOLD fMRI connectivity. Noise sources related to head motion or physiology are typically modelled by nuisance regressors, and a generalised linear model is applied to regress out the associated signal variance. In this study, we use independent component analysis (ICA) to characterise the data variance typically discarded in this pre-processing stage in a cohort of 12 healthy volunteers. The signal variance removed by 24, 12, 6, or only 3 head motion parameters demonstrated network structure typically associated with functional connectivity, and certain networks were discernable in the variance extracted by as few as 2 physiologic regressors. Simulated nuisance regressors, unrelated to the true data noise, also removed variance with network structure, indicating that any group of regressors that randomly sample variance may remove highly structured "signal" as well as "noise." Furthermore, to support this we demonstrate that random sampling of the original data variance continues to exhibit robust network structure, even when as few as 10% of the original volumes are considered. Finally, we examine the diminishing returns of increasing the number of nuisance regressors used in pre-processing, showing that excessive use of motion regressors may do little better than chance in removing variance within a functional network. It remains an open challenge to understand the balance between the benefits and confounds of noise correction using nuisance regressors., (Copyright © 2015. Published by Elsevier Inc.)

Published

2015

14. Early anti-correlated BOLD signal changes of physiologic origin.

Author

Bright MG, Bianciardi M, de Zwart JA, Murphy K, and Duyn JH

Subjects

Adult, Female, Humans, Hypocapnia physiopathology, Image Processing, Computer-Assisted, Male, Middle Aged, Oxygen blood, Respiration, Young Adult, Brain blood supply, Brain Mapping, Hemodynamics physiology, Magnetic Resonance Imaging methods

Abstract

Negative BOLD signals that are synchronous with resting state fluctuations have been observed in large vessels in the cortical sulci and surrounding the ventricles. In this study, we investigated the origin of these negative BOLD signals by applying a Cued Deep Breathing (CDB) task to create transient hypocapnia and a resultant global fMRI signal decrease. We hypothesized that a global stimulus would amplify the effect in large vessels and that using a global negative (vasoconstrictive) stimulus would test whether these voxels exhibit either inherently negative or simply anti-correlated BOLD responses. Significantly anti-correlated, but positive, BOLD signal changes during respiratory challenges were identified in voxels primarily located near edges of brain spaces containing CSF. These positive BOLD responses occurred earlier than the negative CDB response across most of gray matter voxels. These findings confirm earlier suggestions that in some brain regions, local, fractional changes in CSF volume may overwhelm BOLD-related signal changes, leading to signal anti-correlation. We show that regions with CDB anti-correlated signals coincide with most, but not all, of the regions with negative BOLD signal changes observed during a visual and motor stimulus task. Thus, the addition of a physiological challenge to fMRI experiments can help identify which negative BOLD signals are passive physiological anti-correlations and which may have a putative neuronal origin., (Published by Elsevier Inc.)

Published

2014

15. Reliable quantification of BOLD fMRI cerebrovascular reactivity despite poor breath-hold performance.

Author

Bright MG and Murphy K

Subjects

Adult, Carbon Dioxide blood, Female, Humans, Image Processing, Computer-Assisted, Male, Reproducibility of Results, Brain blood supply, Brain Mapping methods, Breath Holding, Cerebrovascular Circulation physiology, Magnetic Resonance Imaging

Abstract

Cerebrovascular reactivity (CVR) can be mapped using BOLD fMRI to provide a clinical insight into vascular health that can be used to diagnose cerebrovascular disease. Breath-holds are a readily accessible method for producing the required arterial CO2 increases but their implementation into clinical studies is limited by concerns that patients will demonstrate highly variable performance of breath-hold challenges. This study assesses the repeatability of CVR measurements despite poor task performance, to determine if and how robust results could be achieved with breath-holds in patients. Twelve healthy volunteers were scanned at 3 T. Six functional scans were acquired, each consisting of 6 breath-hold challenges (10, 15, or 20 s duration) interleaved with periods of paced breathing. These scans simulated the varying breath-hold consistency and ability levels that may occur in patient data. Uniform ramps, time-scaled ramps, and end-tidal CO2 data were used as regressors in a general linear model in order to measure CVR at the grey matter, regional, and voxelwise level. The intraclass correlation coefficient (ICC) quantified the repeatability of the CVR measurement for each breath-hold regressor type and scale of interest across the variable task performances. The ramp regressors did not fully account for variability in breath-hold performance and did not achieve acceptable repeatability (ICC<0.4) in several regions analysed. In contrast, the end-tidal CO2 regressors resulted in "excellent" repeatability (ICC=0.82) in the average grey matter data, and resulted in acceptable repeatability in all smaller regions tested (ICC>0.4). Further analysis of intra-subject CVR variability across the brain (ICCspatial and voxelwise correlation) supported the use of end-tidal CO2 data to extract robust whole-brain CVR maps, despite variability in breath-hold performance. We conclude that the incorporation of end-tidal CO2 monitoring into scanning enables robust, repeatable measurement of CVR that makes breath-hold challenges suitable for routine clinical practice., (© 2013.)

Published

2013

16. Removing motion and physiological artifacts from intrinsic BOLD fluctuations using short echo data.

Author

Bright MG and Murphy K

Subjects

Algorithms, Female, Humans, Male, Motion, Movement, Reproducibility of Results, Sensitivity and Specificity, Artifacts, Brain physiology, Brain Mapping methods, Evoked Potentials, Visual physiology, Image Enhancement methods, Image Interpretation, Computer-Assisted methods, Magnetic Resonance Imaging methods

Abstract

Differing noise variance across study populations has been shown to cause artifactual group differences in functional connectivity measures. In this study, we investigate the use of short echo time functional MRI data to correct for these noise sources in blood oxygenation level dependent (BOLD)-weighted time series. A dual-echo sequence was used to simultaneously acquire data at both a short (TE=3.3 ms) and a BOLD-weighted (TE=35 ms) echo time. This approach is effectively "free," using dead-time in the pulse sequence to collect an additional echo without affecting overall scan time or temporal resolution. The proposed correction method uses voxelwise regression of the short TE data from the BOLD-weighted data to remove noise variance. In addition to a typical resting state scan, non-compliant behavior associated with patient groups was simulated via increased head motion or physiological fluctuations in 10 subjects. Short TE data showed significant correlations with the traditional motion-related and physiological noise regressors used in current connectivity analyses. Following traditional preprocessing, the extent of significant additional variance explained by the short TE data regressors was significantly correlated with the average head motion across the scan in the resting data (r(2)=0.93, p<0.0001). The reduction in data variance following the inclusion of short TE regressors was also correlated with scan head motion (r(2)=0.48, p=0.027). Task-related data were used to demonstrate the effects of the short TE correction on BOLD activation time series with known temporal structure; the size and strength of the activation were significantly decreased, but it is not clear whether this reflects BOLD contamination in the short TE data or correlated changes in blood volume. Finally, functional connectivity maps of the default mode network were constructed using a seed correlation approach. The effects of short TE correction and low-pass filtering on the resulting correlations maps were compared. Results suggest that short TE correction more accurately differentiates artifactual correlations from the correlations of interest in conditions of amplified noise., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2013

17. Editorial: Imaging Cerebrovascular Reactivity: Physiology, Physics and Therapy

Author

Duffin, James, Bright, Molly G., and Blockley, Nicholas P.

Subjects

Editorial, Physiology, cerebral blood flow, carbon dioxide, magnetic resonance imaging, cerebrovascular reactivity, blood oxygenation level dependent signal

Published

2021

18. Machine Learning-Based Prediction of MRI-Induced Power Absorption in the Tissue in Patients With Simplified Deep Brain Stimulation Lead Models.

Author

Vu, Jasmine, Nguyen, Bach T., Bhusal, Bhumi, Baraboo, Justin, Rosenow, Joshua, Bagci, Ulas, Bright, Molly G., and Golestanirad, Laleh

Subjects

BRAIN stimulation, DEEP brain stimulation, MAGNETIC resonance imaging, ELECTRONIC equipment, ABSORPTION, ALGORITHMS, PREDICTION models

Abstract

Interaction of an active electronic implant such as a deep brain stimulation (DBS) system and magnetic resonance imaging (MRI) radiofrequency (RF) fields can induce excessive tissue heating, limiting MRI accessibility. Efforts to quantify RF heating mostly rely on electromagnetic (EM) simulations to assess individualized specific absorption rate (SAR), but such simulations require extensive computational resources. Here, we investigate if a predictive model using machine learning (ML) can predict the local SAR in the tissue around tips of implanted leads from the distribution of the tangential component of the MRI incident electric field, Etan. A dataset of 260 unique patient-derived and artificial DBS lead trajectories was constructed, and the 1 g-averaged SAR, 1 g SARmax, at the lead-tip during 1.5 T MRI was determined by EM simulations. Etan values along each lead's trajectory and the simulated SAR values were used to train and test the ML algorithm. The resulting predictions of the ML algorithm indicated that the distribution of Etan could effectively predict 1 g SARmax at the DBS lead-tip (R = 0.82). Our results indicate that ML has the potential to provide a fast method for predicting MR-induced power absorption in the tissue around tips of implanted leads such as those in active electronic medical devices. [ABSTRACT FROM AUTHOR]

Published

2021

19. Changes in arterial cerebral blood volume during lower body negative pressure measured with MRI

Author

Whittaker, Joseph R., Bright, Molly G., Driver, Ian D., Babic, Adele, Khot, Sharmila, and Murphy, Kevin

Subjects

Cerebral Cortex, Lower Body Negative Pressure, Male, Arterial spin labeling, Cerebral blood volume, Arteries, Magnetic Resonance Imaging, Article, Cerebral autoregulation, Cerebrovascular Circulation, Image Processing, Computer-Assisted, Homeostasis, Humans, Spin Labels

Abstract

Cerebral Autoregulation (CA), defined as the ability of the cerebral vasculature to maintain stable levels of blood flow despite changes in systemic blood pressure, is a critical factor in neurophysiological health. Magnetic resonance imaging (MRI) is a powerful technique for investigating cerebrovascular function, offering high spatial resolution and wide fields of view (FOV), yet it is relatively underutilized as a tool for assessment of CA. The aim of this study was to demonstrate the potential of using MRI to measure changes in cerebrovascular resistance in response to lower body negative pressure (LBNP). A Pulsed Arterial Spin Labeling (PASL) approach with short inversion times (TI) was used to estimate cerebral arterial blood volume (CBVa) in eight healthy subjects at baseline and −40 mmHg LBNP. We estimated group mean CBVa values of 3.13 ± 1.00 and 2.70 ± 0.38 for baseline and lbnp respectively, which were the result of a differential change in CBVa during −40 mmHg LBNP that was dependent on baseline CBVa. These data suggest that the PASL CBVa estimates are sensitive to the complex cerebrovascular response that occurs during the moderate orthostatic challenge delivered by LBNP, which we speculatively propose may involve differential changes in vascular tone within different segments of the arterial vasculature. These novel data provide invaluable insight into the mechanisms that regulate perfusion of the brain, and establishes the use of MRI as a tool for studying CA in more detail.

Published

2019

20. The effect of basal vasodilation on hypercapnic and hypocapnic reactivity measured using magnetic resonance imaging.

Author

Bright, Molly G, Donahue, Manus J, Duyn, Jeff H, Jezzard, Peter, and Bulte, Daniel P

Subjects

*VASODILATION, *HYPERCAPNIA, *MAGNETIC resonance imaging, *HEMODYNAMICS, *CEREBROVASCULAR disease, *OXYGENATORS, *RESPIRATORY therapy

Abstract

Cerebrovascular reactivity to vasodilatory hypercapnic and vasoconstrictive hypocapnic challenges is known to be altered in several hemodynamic disorders, which is often attributable to changes in smooth muscle-mediated vascular compliance. Recently, attenuated reactivity to hypercapnia but enhanced reactivity to hypocapnia was observed in patients with chronic stroke. We hypothesize that the latter observation could be explained by a change in the basal vascular tone. In particular, reduced cerebral perfusion pressure, as is prevalent in these patients, may cause vasodilation through autoregulatory mechanisms, and this compensatory baseline condition may alter reactivity to vasoconstrictive hypocapnic challenges. To test this hypothesis, a predilated vascular condition was created in young, healthy subjects (n=11; age=23 to 36 years) using inhalation of 4% CO2. Using blood oxygenation level-dependent functional magnetic resonance imaging at 3 T, breath holding and cued deep breathing respiratory challenges were administered to assess hypercapnia and hypocapnia reactivity, respectively. During the predilated condition, vasoconstrictive reactivity to hypocapnia was significantly (21.1%, P=0.016) enhanced throughout the gray matter, whereas there was no significant change (6.4%, P=0.459) in hypercapnic vasodilatory reactivity. This suggests that baseline vasodilation may explain the enhanced hypocapnia reactivity observed in some stroke patients, and that hypocapnia challenges may help identify the level of vascular compliance in patients with reduced cerebral perfusion pressure. [ABSTRACT FROM AUTHOR]

Published

2011