Abstract
Transcranial electrical stimulated motor-evoked potentials (tcMEPs) are widely used to evaluate motor function in humans, and even in animal studies, tcMEPs are used to evaluate neurological dysfunction. However, there is a dearth of reports on extended tcMEP recordings in both animal models and humans. Therefore, this study examined a new technique for stably recording tcMEPs over several weeks in six healthy female Sprague–Dawley rats. We thinned the skull bone using the skull base and spinal surgery technique to reduce electrical resistance for electrical stimulation. tcMEPs were recorded on days 1, 7, 14, 21, and 28 after surgery. The onset latency and amplitude of tcMEPs from the hindlimbs were recorded and evaluated, and histological analysis was performed. Stable amplitude and onset latency could be recorded over several weeks, and histological analysis indicated no complications attributable to the procedure. Thus, our novel technique allows for less invasive, safer, easier, and more stable extended tcMEP recordings than previously reported techniques. The presently reported technique may be applied to the study of various nerve injury models in rats: specifically, to evaluate the degree of nerve dysfunction and recovery in spinal cord injury, cerebral infarction, and brain contusion models.
Highlights
Transcranial electrical stimulated motor-evoked potentials are widely used to evaluate motor function in humans, and even in animal studies, Transcranial electrical stimulation Motor-evoked potentials (MEPs) (tcMEP) are used to evaluate neurological dysfunction
This study examined a new technique for stably recording tcMEPs via transcranial electrical stimulation in rats over several weeks that addressed the increased thickness of the rat skull
The results of our study indicate that the bone-thinning technique enables the successful recording of tcMEPs of the hindlimbs in healthy rats over a month
Summary
Transcranial electrical stimulated motor-evoked potentials (tcMEPs) are widely used to evaluate motor function in humans, and even in animal studies, tcMEPs are used to evaluate neurological dysfunction. This study examined a new technique for stably recording tcMEPs over several weeks in six healthy female Sprague–Dawley rats. The presently reported technique may be applied to the study of various nerve injury models in rats: to evaluate the degree of nerve dysfunction and recovery in spinal cord injury, cerebral infarction, and brain contusion models. This study examined a new technique for stably recording tcMEPs via transcranial electrical stimulation in rats over several weeks that addressed the increased thickness of the rat skull. We expect that the establishment of such an improved method could help improve the evaluation of the degree of nerve dysfunction and recovery in spinal cord injury, cerebral infarction, and brain contusion models
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