Converging metabolic and functional networks for tremor expression and deep brain stimulation-mediated control

dc.contributor.authorWeigl, Benedikt
dc.contributor.authorPistorius, Regina
dc.contributor.authorBrumberg, Joachim
dc.contributor.authorPozzi, Nicoló G.
dc.contributor.authorBuck, Andreas
dc.contributor.authorMuthuraman, Muthuraman
dc.contributor.authorIsaias, Ioannis U.
dc.contributor.authorVolkmann, Jens
dc.contributor.authorJoutsa, Juho
dc.contributor.authorReich, Martin M.
dc.contributor.organizationfi=tyks, vsshp|en=tyks, varha|
dc.contributor.organizationfi=kliiniset neurotieteet|en=Clinical Neurosciences|
dc.contributor.organization-code1.2.246.10.2458963.20.74845969893
dc.converis.publication-id526593767
dc.converis.urlhttps://research.utu.fi/converis/portal/Publication/526593767
dc.date.accessioned2026-06-18T20:11:44Z
dc.description.abstract<p>Emerging evidence indicates that movement disorders arise from symptom-specific rather than disease-specific brain network dysfunctions that can be influenced through targeted neuromodulation. Such networks are widely mapped using normative connectome analyses from lesion and stimulation sites. Here, we used [<sup>18</sup>F]-fluorodeoxyglucose (FDG)-PET in 14 essential tremor patients undergoing thalamic deep brain stimulation (DBS) to identify stimulation-induced and tremor related regional metabolic changes in a within-subject design and combined this with normative connectome results. Stimulation increased metabolism in motor cortical and cerebellar regions - key hubs of the previously proposed tremor treatment network as derived from normative functional connectivity. Importantly, individual alignment with this network predicted clinical tremor improvement (<em>R<sup>2</sup></em> = 0.593, p = 0.007). These same regions showed higher metabolism during tremor expression in the untreated condition, suggesting overlap between the circuits involved in symptom generation and therapeutic response. These findings support indirect connectome-based models by linking them to brain glucose metabolism changes and suggest that DBS relieves tremor by modulating the same circuit that underlies symptom expression.</p>
dc.identifier.eissn2373-8057
dc.identifier.urihttps://www.utupub.fi/handle/11111/62171
dc.identifier.urlhttps://www.nature.com/articles/s41531-026-01388-7
dc.identifier.urnURN:NBN:fi-fe20260618100517
dc.language.isoen
dc.okm.affiliatedauthorJoutsa, Juho
dc.okm.affiliatedauthorDataimport, tyks, vsshp
dc.okm.discipline3112 Neurosciencesen_GB
dc.okm.discipline3112 Neurotieteetfi_FI
dc.okm.internationalcopublicationinternational co-publication
dc.okm.internationalityInternational publication
dc.okm.typeA1 ScientificArticle
dc.publisherSpringer Nature
dc.publisher.countryUnited Statesen_GB
dc.publisher.countryYhdysvallat (USA)fi_FI
dc.publisher.country-codeUS
dc.relation.articlenumber119
dc.relation.doi10.1038/s41531-026-01388-7
dc.relation.ispartofjournalNPJ Parkinson's disease
dc.relation.issue1
dc.relation.volume12
dc.titleConverging metabolic and functional networks for tremor expression and deep brain stimulation-mediated control
dc.year.issued2026

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