Assessing the Stability of the Motor Networks Recruited During the Bimanual String-Pulling Task Throughout Stroke Recovery

Ladouceur, Mikaël

11 January 2023

In the absence of treatment following strokes, both humans and model organisms demonstrate partial improvements in motor function. Several endogenous mechanisms, such as cortical reorganization, are hypothesized to cause this spontaneous biological recovery. Reorganization of the motor cortex occurs within a time sensitive period and involves both proximal and distal sites of the intact brain. Despite these advancements, whether the same or different cells are used in the reorganized cortex after stroke remains unknown. In order to identify the motor networks involved in recovery, our lab has begun using the inducible Arc-CreERᵀ²:Rosa-YFPᶠᐟᶠ mice. In conjunction with the bimanual string-pulling task, this inducible model allows for the labelling of active cells throughout stroke recovery; either pre, 2 days post-stroke (dps) and 2 weeks post-stroke (wps). Behavioural deficits on the string-pull task were observed at 2 dps and accompanied by a decrease in active cells in the ipsilesional secondary motor (M2) cortex of stroke mice. By 2 wps, stroke mice had partial recovery of motor function with no differences in active cells in the ipsilesional M2. Interestingly, ~40% of cell in the motor cortex of sham and stroke mice were activated more than once while performing the string-pull task until 2 wps. Deeplabcut kinematic analysis of the string-pull task was also unable to identify differences in motor performance between stroke and sham mice. In addition, irrelevant of stroke injuries, only 60% of cells co-expressed the pan-neuronal marker NeuN after surgeries. Together these findings suggest that 40% of cells are reactivated up to 2 weeks post-stroke during the performance of a motor task, despite the acute decreases in active cells in the ipsilesional M2 of stroke mice. DeepLabCut kinematic results also highlight the need to redefine kinematic outcomes to better assess the full spectrum of stroke deficits.

Cortical reorganization

Bimanual string-pull task

Stroke

Investigating Cortical Reorganization Following Motor Cortex Photothrombotic Stroke in Mice

Eckert, Zachary

13 February 2024

Following a stroke, normal usage of the impaired limb guides spontaneous recovery across many months or even years; however, recovery is rarely complete. Pre-clinical tools are needed to investigate stroke-induced cortical reorganization over long periods. This thesis aims to characterize stroke impairment and spontaneous recovery in parallel with a battery of behaviour tasks in a mouse model of focal stroke. Young adult Thy1-ChR2 mice were implanted with a transcranial window over the intact skull permitting cortex visualization and enabling longitudinal assessments with light-based motor mapping and intrinsic signal optical imaging. Furthermore, mice were tested on sensorimotor behavioural tasks in parallel to the mapping experiments. These experiments allowed for the quantification of impairments in the sensorimotor cortex and forelimb function while identifying regions within the sensorimotor cortex that show re-mapping associated with behavioural recovery. Following primary motor cortex-stroke induction, both sensory and motor map impairments occurred. Sensory map transient impairments recovered within the same atlas-defined regions two weeks after a primary motor cortex stroke as identified by intrinsic signal optical imaging. In contrast, motor forelimb recovery was observed four weeks after the stroke in the peri-infarct region, the supplemental motor cortex, and the contralesional motor cortex. This recovery was identified through a combination of analyses, including changes in the mapped area and the amplitude of evoked forelimb movements using light-based motor mapping. Behavioural recovery occurred four to six weeks post-stroke, depending on the sensitivity of the task in forelimb impairment. Additionally, the contralesional hemisphere and forelimb did not show impairment acutely but evoked forelimb amplitude was significantly increased by post-stroke week four for both forelimbs. As the first study to conduct within-animal longitudinal spontaneous recovery sensory and motor map experiments using bilateral forelimb and hemispheric representations, we show that 1) photothrombotic stroke impacts both forelimb representations pertained within the ipsilesional hemisphere in LBMM experiments, 2) recovery of the impaired forelimb occurs ipsilesionally and contralesionally and, 3) impairments from stroke observed through motor mapping are functionally relevant and precede behavioural recovery ranging from zero to two or more weeks depending on the motor cortex's involvement in the behavioural task.

Stroke

Spontaneous Recovery

Non-invasive Stimulation

Optogenetics

Rodent Model

Light-Based Motor Mapping

Motor Mapping

Intrinsic Signal Optical Imaging

Sensory Mapping

String-Pull Task

Grid Walking Task

Cylinder Task

Post-Stroke Recovery

Motor Cortex

Sensory Cortex

Neural Reorganization