Comparative Effectiveness of Ipsilesional High-frequency rTMS, Contralesional Continuous Burst Theta rTMS, and Sham rTMS, Each Combined With Physiotherapy, in Subacute Ischemic Stroke Upper Limb Recovery : Clinical, Neurophysiological and Radiological

Overview

To compare the efficacy of lesional high-frequency rTMS, contralesional cTBS, and sham stimulation in improving motor and cognitive recovery in post-stroke patients undergoing physiotherapy.

Globally, stroke is the second leading cause of both death and disability. In 2020, the global prevalence of all stroke subtypes was 89.13 million cases, with acute ischemic stroke (AIS) comprising 76.47% of these, equating to 68.16 million cases . AIS presents a major global public health concern, given the wide range of disabilities it causes, including cognitive impairments. Survivors of stroke bear a significant burden due to the persistent disability they experience over time . Immediately following a stroke, motor impairments are accompanied by significant alterations in the affected primary motor cortex (M1) - detected by transcranial magnetic stimulation (TMS)- resulting in reduced cortical excitability. This can be evidenced by the absence of recordable motor evoked potentials (MEPs), diminished MEP amplitudes, and increased resting motor threshold (rMT). Additionally, stroke can alter brain connectivity, particularly in terms of functional connectivity, which has implications for recovery. Neuroplasticity plays a crucial role in recovery after stroke, allowing the brain to reorganize and compensate for lost functions. Physiotherapy is a cornerstone of post-stroke rehabilitation, particularly for upper limb recovery and cognitive improvement, with early intervention associated with better outcomes. Repetitive transcranial magnetic stimulation (rTMS) has shown promise in the early stages post-stroke, enhancing motor and cognitive recovery, particularly when applied within two weeks of stroke onset. MEPs can be used to monitor changes in cortical excitability and have been linked to both cognitive and motor recovery. Combining rTMS with diffusion tensor imaging (DTI) allows for the assessment of both functional and structural brain changes, providing a deeper understanding of rTMS's therapeutic effects. DTI, through fractional anisotropy (FA), helps to evaluate white matter integrity, and studies have shown that increased FA correlates with motor recovery, making it a valuable tool in examining the structural changes induced by rTMS in stroke recovery. While high frequency rTMS targeting the ipsilesional motor cortex (M1) has demonstrated efficacy in enhancing motor recovery, contralesional continuous theta-burst stimulation (cTBS) has shown promising results offering an alternative by modulating interhemispheric inhibition. However, no studies have directly compared the efficacy of these two paradigms against each other and sham stimulation in subacute stroke recovery. This study seeks to address this gap by comparing the outcomes of lesional high frequency rTMS, contralesional cTBS, and sham stimulation in combination with physiotherapy.