Circuit-Specific Plasticity of Callosal Inputs Underlies Cortical Takeover

Petrus, Emily; Dembling, Sarah; Usdin, Ted B.; Isaac, John T.R.; Koretsky, Alan P.

doi:10.1523/jneurosci.1056-20.2020

Cited by 18 publications

(13 citation statements)

References 86 publications

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“…In one model of information exchange across hemispheres, excitatory information from one hemisphere conveyed by the corpus callosum activates inhibitory cells in the opposite hemisphere, thus inhibiting activity ( Palmer et al, 2012 ; Petrus et al, 2019 ). This inhibition between the left and right hemispheres may be important for bilateral dexterity in upper and lower limb movements, and is required for integrating bilateral sensory and motor signals ( Shuler et al, 2002 ; Petrus et al, 2020 ). Unilateral injury (e.g.…”

Section: Discussionmentioning

confidence: 99%

Homotopic contralesional excitation suppresses spontaneous circuit repair and global network reconnections following ischemic stroke

Bice

Xiao

Kong

et al. 2022

eLife

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Understanding circuit-level manipulations that affect the brain's capacity for plasticity will inform the design of targeted interventions that enhance recovery after stroke. Following stroke, increased contralesional activity (e.g. use of the unaffected limb) can negatively influence recovery, but it is unknown which specific neural connections exert this influence, and to what extent increased contralesional activity affects systems- and molecular-level biomarkers of recovery. Here, we combine optogenetic photostimulation with optical intrinsic signal imaging (OISI) to examine how contralesional excitatory activity affects cortical remodeling after stroke in mice. Following photothrombosis of left primary somatosensory forepaw (S1FP) cortex, mice either recovered spontaneously or received chronic optogenetic excitation of right S1FP over the course of 4 weeks. Contralesional excitation suppressed perilesional S1FP remapping and was associated with abnormal patterns of stimulus-evoked activity in the unaffected limb. This maneuver also prevented the restoration of resting-state functional connectivity (RSFC) within the S1FP network, RSFC in several networks functionally-distinct from somatomotor regions, and resulted in persistent limb-use asymmetry. In stimulated mice, perilesional tissue exhibited transcriptional changes in several genes relevant for recovery. Our results suggest that contralesional excitation impedes local and global circuit reconnection through suppression of cortical activity and several neuroplasticity-related genes after stroke, and highlight the importance of site selection for therapeutic intervention after focal ischemia.

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Section: Discussionmentioning

confidence: 99%

Homotopic contralesional excitation suppresses spontaneous circuit repair and global network reconnections following ischemic stroke

Bice

Xiao

Kong

et al. 2022

eLife

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show abstract

“…Spontaneous outputs from these disinhibited pyramidal cells can lead to downstream plasticity related changes in neuronal activity, as observed in peripheral sensory deprivation models. 73 , 76 …”

Section: Discussionmentioning

confidence: 99%

Compensatory functional connectome changes in a rat model of traumatic brain injury

Yang

Zhu

Pompilus

et al. 2021

Brain Communications

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Penetrating cortical impact injuries alter neuronal communication beyond the injury epicenter, across regions involved in affective, sensorimotor, and cognitive processing. Understanding how traumatic brain injury reorganizes local and brain wide nodal interactions may provide valuable quantitative parameters for monitoring pathological progression and recovery. To this end, we investigated spontaneous fluctuations in the functional MRI signal obtained at 11.1 Tesla in rats sustaining controlled cortical impact and imaged at 2- and 30-days post-injury. Graph theory-based calculations were applied to weighted undirected matrices constructed from 12,879 pairwise correlations between functional MRI signals from 162 regions. Our data indicate that on days 2 and 30 post-controlled cortical impact there is a significant increase in connectivity strength in nodes located in contralesional cortical, thalamic, and basal forebrain areas. Rats imaged on day 2 post-injury had significantly greater network modularity than controls, with influential nodes (with high eigenvector centrality) contained within the contralesional module and participating less in cross-modular interactions. By day 30, modularity and cross-modular interactions recover, although a cluster of nodes with low strength and low eigenvector centrality remain in the ipsilateral cortex. Our results suggest that changes in node strength, modularity, eigenvector centrality, and participation coefficient track early and late traumatic brain injury effects on brain functional connectivity. We propose that the observed compensatory functional connectivity reorganization in response to controlled cortical impact may be unfavorable to brain wide communication in the early post-injury period.

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“…This could partly explain the observed compensatory increases in functional connectivity and reorganization of hub nodes. Spontaneous outputs from these disinhibited pyramidal cells can lead to downstream plasticity related changes in neuronal activity, as observed in peripheral sensory deprivation models (Pluto et al ., 2005; Petrus et al ., 2020).…”

Section: Discussionmentioning

confidence: 99%

Compensatory functional connectome changes in a rat model of traumatic brain injury

Yang

Zhu

Pompilus

et al. 2021

Preprint

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Penetrating cortical impact injuries alter neuronal communication beyond the injury epicenter, across regions involved in affective, sensorimotor, and cognitive processing. Understanding how traumatic brain injury (TBI) reorganizes local and brain wide nodal functional interactions may provide valuable quantitative parameters for monitoring pathological progression and functional recovery. To this end, we investigated spontaneous fluctuations in the functional magnetic resonance imaging (fMRI) signal obtained at 11.1 Tesla in rats sustaining controlled cortical impact (CCI) and imaged at 2- and 30-days post-injury. Graph theory-based calculations were applied to weighted undirected matrices constructed from 12,879 pairwise correlations between fMRI signals from 162 regions. Our data indicate that on days 2 and 30 post-CCI there is a significant increase in connectivity strength in nodes located in contralesional cortical, thalamic, and basal forebrain areas. Rats imaged on day 2 post-injury had significantly greater network modularity than controls, with influential nodes (with high eigenvector centrality) contained within the contralesional module and participating less in cross-modular interactions. By day 30, modularity and cross-modular interactions recover, although a cluster of nodes with low strength and low eigenvector centrality remain in the ipsilateral cortex. Our results suggest that changes in node strength, modularity, eigenvector centrality, and participation coefficient track early and late TBI effects on brain functional connectivity. We propose that the observed compensatory functional connectivity reorganization in response to CCI may be unfavorable to brain wide communication in the early post-injury period.

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Circuit-Specific Plasticity of Callosal Inputs Underlies Cortical Takeover

Cited by 18 publications

References 86 publications

Homotopic contralesional excitation suppresses spontaneous circuit repair and global network reconnections following ischemic stroke

Homotopic contralesional excitation suppresses spontaneous circuit repair and global network reconnections following ischemic stroke

Compensatory functional connectome changes in a rat model of traumatic brain injury

Compensatory functional connectome changes in a rat model of traumatic brain injury

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