@article{wiesman_spatially_2022,
	title = {Spatially resolved neural slowing predicts impairment and amyloid burden in {Alzheimer}'s disease.},
	volume = {145},
	copyright = {© The Author(s) (2022). Published by Oxford University Press on behalf of the Guarantors of Brain.},
	issn = {1460-2156 0006-8950},
	doi = {10.1093/brain/awab430},
	abstract = {An extensive electrophysiological literature has proposed a pathological 'slowing' of neuronal activity in patients on the Alzheimer's disease spectrum.  Supported by numerous studies reporting increases in low-frequency and decreases  in high-frequency neural oscillations, this pattern has been suggested as a  stable biomarker with potential clinical utility. However, no spatially resolved  metric of such slowing exists, stymieing efforts to understand its relation to  proteinopathy and clinical outcomes. Further, the assumption that this slowing is  occurring in spatially overlapping populations of neurons has not been  empirically validated. In the current study, we collected cross-sectional resting  state measures of neuronal activity using magnetoencephalography from 38  biomarker-confirmed patients on the Alzheimer's disease spectrum and 20  cognitively normal biomarker-negative older adults. From these data, we compute  and validate a new metric of spatially resolved oscillatory deviations from  healthy ageing for each patient on the Alzheimer's disease spectrum. Using this  Pathological Oscillatory Slowing Index, we show that patients on the Alzheimer's  disease spectrum exhibit robust neuronal slowing across a network of temporal,  parietal, cerebellar and prefrontal cortices. This slowing effect is shown to be  directly relevant to clinical outcomes, as oscillatory slowing in temporal and  parietal cortices significantly predicted both general (i.e. Montreal Cognitive  Assessment scores) and domain-specific (i.e. attention, language and processing  speed) cognitive function. Further, regional amyloid-β accumulation, as measured  by quantitative 18F florbetapir PET, robustly predicted the magnitude of this  pathological neural slowing effect, and the strength of this relationship between  amyloid-β burden and neural slowing also predicted attentional impairments across  patients. These findings provide empirical support for a spatially overlapping  effect of oscillatory neural slowing in biomarker-confirmed patients on the  Alzheimer's disease spectrum, and link this effect to both regional proteinopathy  and cognitive outcomes in a spatially resolved manner. The Pathological  Oscillatory Slowing Index also represents a novel metric that is of potentially  high utility across a number of clinical neuroimaging applications, as  oscillatory slowing has also been extensively documented in other patient  populations, most notably Parkinson's disease, with divergent spectral and  spatial features.},
	language = {eng},
	number = {6},
	journal = {Brain : a journal of neurology},
	author = {Wiesman, Alex I. and Murman, Daniel L. and Losh, Rebecca A. and Schantell, Mikki and Christopher-Hayes, Nicholas J. and Johnson, Hallie J. and Willett, Madelyn P. and Wolfson, Sara L. and Losh, Kathryn L. and Johnson, Craig M. and May, Pamela E. and Wilson, Tony W.},
	month = jun,
	year = {2022},
	pmid = {35088842},
	pmcid = {PMC9246709},
	note = {Place: England},
	keywords = {*Alzheimer Disease/pathology, *Amyloidosis/pathology, *Cognitive Dysfunction, Aged, Amyloid beta-Peptides/metabolism, Amyloid/metabolism, Biomarkers, Brain/pathology, Cross-Sectional Studies, Humans, Positron-Emission Tomography, magnetoencephalography, mild cognitive impairment, neural oscillations, spontaneous activity, tau Proteins/metabolism},
	pages = {2177--2189},
}

{"_id":"KomHySEGpy5yjHud2","bibbaseid":"wiesman-murman-losh-schantell-christopherhayes-johnson-willett-wolfson-etal-spatiallyresolvedneuralslowingpredictsimpairmentandamyloidburdeninalzheimersdisease-2022","author_short":["Wiesman, A. I.","Murman, D. L.","Losh, R. A.","Schantell, M.","Christopher-Hayes, N. J.","Johnson, H. J.","Willett, M. P.","Wolfson, S. L.","Losh, K. L.","Johnson, C. M.","May, P. E.","Wilson, T. W."],"bibdata":{"bibtype":"article","type":"article","title":"Spatially resolved neural slowing predicts impairment and amyloid burden in Alzheimer's disease.","volume":"145","copyright":"© The Author(s) (2022). Published by Oxford University Press on behalf of the Guarantors of Brain.","issn":"1460-2156 0006-8950","doi":"10.1093/brain/awab430","abstract":"An extensive electrophysiological literature has proposed a pathological 'slowing' of neuronal activity in patients on the Alzheimer's disease spectrum. Supported by numerous studies reporting increases in low-frequency and decreases in high-frequency neural oscillations, this pattern has been suggested as a stable biomarker with potential clinical utility. However, no spatially resolved metric of such slowing exists, stymieing efforts to understand its relation to proteinopathy and clinical outcomes. Further, the assumption that this slowing is occurring in spatially overlapping populations of neurons has not been empirically validated. In the current study, we collected cross-sectional resting state measures of neuronal activity using magnetoencephalography from 38 biomarker-confirmed patients on the Alzheimer's disease spectrum and 20 cognitively normal biomarker-negative older adults. From these data, we compute and validate a new metric of spatially resolved oscillatory deviations from healthy ageing for each patient on the Alzheimer's disease spectrum. Using this Pathological Oscillatory Slowing Index, we show that patients on the Alzheimer's disease spectrum exhibit robust neuronal slowing across a network of temporal, parietal, cerebellar and prefrontal cortices. This slowing effect is shown to be directly relevant to clinical outcomes, as oscillatory slowing in temporal and parietal cortices significantly predicted both general (i.e. Montreal Cognitive Assessment scores) and domain-specific (i.e. attention, language and processing speed) cognitive function. Further, regional amyloid-β accumulation, as measured by quantitative 18F florbetapir PET, robustly predicted the magnitude of this pathological neural slowing effect, and the strength of this relationship between amyloid-β burden and neural slowing also predicted attentional impairments across patients. These findings provide empirical support for a spatially overlapping effect of oscillatory neural slowing in biomarker-confirmed patients on the Alzheimer's disease spectrum, and link this effect to both regional proteinopathy and cognitive outcomes in a spatially resolved manner. The Pathological Oscillatory Slowing Index also represents a novel metric that is of potentially high utility across a number of clinical neuroimaging applications, as oscillatory slowing has also been extensively documented in other patient populations, most notably Parkinson's disease, with divergent spectral and spatial features.","language":"eng","number":"6","journal":"Brain : a journal of neurology","author":[{"propositions":[],"lastnames":["Wiesman"],"firstnames":["Alex","I."],"suffixes":[]},{"propositions":[],"lastnames":["Murman"],"firstnames":["Daniel","L."],"suffixes":[]},{"propositions":[],"lastnames":["Losh"],"firstnames":["Rebecca","A."],"suffixes":[]},{"propositions":[],"lastnames":["Schantell"],"firstnames":["Mikki"],"suffixes":[]},{"propositions":[],"lastnames":["Christopher-Hayes"],"firstnames":["Nicholas","J."],"suffixes":[]},{"propositions":[],"lastnames":["Johnson"],"firstnames":["Hallie","J."],"suffixes":[]},{"propositions":[],"lastnames":["Willett"],"firstnames":["Madelyn","P."],"suffixes":[]},{"propositions":[],"lastnames":["Wolfson"],"firstnames":["Sara","L."],"suffixes":[]},{"propositions":[],"lastnames":["Losh"],"firstnames":["Kathryn","L."],"suffixes":[]},{"propositions":[],"lastnames":["Johnson"],"firstnames":["Craig","M."],"suffixes":[]},{"propositions":[],"lastnames":["May"],"firstnames":["Pamela","E."],"suffixes":[]},{"propositions":[],"lastnames":["Wilson"],"firstnames":["Tony","W."],"suffixes":[]}],"month":"June","year":"2022","pmid":"35088842","pmcid":"PMC9246709","note":"Place: England","keywords":"*Alzheimer Disease/pathology, *Amyloidosis/pathology, *Cognitive Dysfunction, Aged, Amyloid beta-Peptides/metabolism, Amyloid/metabolism, Biomarkers, Brain/pathology, Cross-Sectional Studies, Humans, Positron-Emission Tomography, magnetoencephalography, mild cognitive impairment, neural oscillations, spontaneous activity, tau Proteins/metabolism","pages":"2177–2189","bibtex":"@article{wiesman_spatially_2022,\n\ttitle = {Spatially resolved neural slowing predicts impairment and amyloid burden in {Alzheimer}'s disease.},\n\tvolume = {145},\n\tcopyright = {© The Author(s) (2022). Published by Oxford University Press on behalf of the Guarantors of Brain.},\n\tissn = {1460-2156 0006-8950},\n\tdoi = {10.1093/brain/awab430},\n\tabstract = {An extensive electrophysiological literature has proposed a pathological 'slowing' of neuronal activity in patients on the Alzheimer's disease spectrum. Supported by numerous studies reporting increases in low-frequency and decreases in high-frequency neural oscillations, this pattern has been suggested as a stable biomarker with potential clinical utility. However, no spatially resolved metric of such slowing exists, stymieing efforts to understand its relation to proteinopathy and clinical outcomes. Further, the assumption that this slowing is occurring in spatially overlapping populations of neurons has not been empirically validated. In the current study, we collected cross-sectional resting state measures of neuronal activity using magnetoencephalography from 38 biomarker-confirmed patients on the Alzheimer's disease spectrum and 20 cognitively normal biomarker-negative older adults. From these data, we compute and validate a new metric of spatially resolved oscillatory deviations from healthy ageing for each patient on the Alzheimer's disease spectrum. Using this Pathological Oscillatory Slowing Index, we show that patients on the Alzheimer's disease spectrum exhibit robust neuronal slowing across a network of temporal, parietal, cerebellar and prefrontal cortices. This slowing effect is shown to be directly relevant to clinical outcomes, as oscillatory slowing in temporal and parietal cortices significantly predicted both general (i.e. Montreal Cognitive Assessment scores) and domain-specific (i.e. attention, language and processing speed) cognitive function. Further, regional amyloid-β accumulation, as measured by quantitative 18F florbetapir PET, robustly predicted the magnitude of this pathological neural slowing effect, and the strength of this relationship between amyloid-β burden and neural slowing also predicted attentional impairments across patients. These findings provide empirical support for a spatially overlapping effect of oscillatory neural slowing in biomarker-confirmed patients on the Alzheimer's disease spectrum, and link this effect to both regional proteinopathy and cognitive outcomes in a spatially resolved manner. The Pathological Oscillatory Slowing Index also represents a novel metric that is of potentially high utility across a number of clinical neuroimaging applications, as oscillatory slowing has also been extensively documented in other patient populations, most notably Parkinson's disease, with divergent spectral and spatial features.},\n\tlanguage = {eng},\n\tnumber = {6},\n\tjournal = {Brain : a journal of neurology},\n\tauthor = {Wiesman, Alex I. and Murman, Daniel L. and Losh, Rebecca A. and Schantell, Mikki and Christopher-Hayes, Nicholas J. and Johnson, Hallie J. and Willett, Madelyn P. and Wolfson, Sara L. and Losh, Kathryn L. and Johnson, Craig M. and May, Pamela E. and Wilson, Tony W.},\n\tmonth = jun,\n\tyear = {2022},\n\tpmid = {35088842},\n\tpmcid = {PMC9246709},\n\tnote = {Place: England},\n\tkeywords = {*Alzheimer Disease/pathology, *Amyloidosis/pathology, *Cognitive Dysfunction, Aged, Amyloid beta-Peptides/metabolism, Amyloid/metabolism, Biomarkers, Brain/pathology, Cross-Sectional Studies, Humans, Positron-Emission Tomography, magnetoencephalography, mild cognitive impairment, neural oscillations, spontaneous activity, tau Proteins/metabolism},\n\tpages = {2177--2189},\n}\n\n","author_short":["Wiesman, A. 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