Abstract
BackgroundRapid compensatory arm reactions represent important response strategies following an unexpected loss of balance. While it has been assumed that early corrective actions arise largely from sub-cortical networks, recent findings have prompted speculation about the potential role of cortical involvement. To test the idea that cortical motor regions are involved in early compensatory arm reactions, we used continuous theta burst stimulation (cTBS) to temporarily suppress the hand area of primary motor cortex (M1) in participants prior to evoking upper limb balance reactions in response to whole body perturbation. We hypothesized that following cTBS to the M1 hand area evoked EMG responses in the stimulated hand would be diminished. To isolate balance reactions to the upper limb participants were seated in an elevated tilt-chair while holding a stable handle with both hands. The chair was held vertical by a magnet and was triggered to fall backward unpredictably. To regain balance, participants used the handle to restore upright stability as quickly as possible with both hands. Muscle activity was recorded from proximal and distal muscles of both upper limbs.ResultsOur results revealed an impact of cTBS on the amplitude of the EMG responses in the stimulated hand muscles often manifest as inhibition in the stimulated hand. The change in EMG amplitude was specific to the target hand muscles and occasionally their homologous pairs on the non-stimulated hand with no consistent effects on the remaining more proximal arm muscles.ConclusionsPresent findings offer support for cortical contributions to the control of early compensatory arm reactions following whole-body perturbation.
Highlights
Rapid compensatory arm reactions represent important response strategies following an unexpected loss of balance
The sequence of muscle activity following perturbation revealed that wrist flexor (WF) was the fastest responder for both the right (150.3 ± 5.8 ms) and left (149.6 ± 4.2 ms) limbs with the remaining muscles (first dorsal interosseous (FDI), abductor pollicis brevis (APB), and biceps brachii (BIC)) engaged approximately 20 ms later (FDIR: 169.4 ± 4.4 ms; APBR: 173.4 ± 5.2 ms; BICR: 168.1 ± 5.1 ms; FDIL: 164.2 ± 5. ms; APBL: 166.8 ± 3.3 ms; BICL: 170.6 ± 5.5 ms)
Our results showed a significant drop of 23% (SE ± 9%) in motor evoked potential (MEP) amplitude in FDI following continuous theta burst stimulation (cTBS) in the 9 subjects where MEPs were collected (t8 = 2.56, p = 0.035)
Summary
Rapid compensatory arm reactions represent important response strategies following an unexpected loss of balance. Focal suppression of rapid compensatory hand muscle activity indicated that M1 contributed to producing or at least scaling of the initial response This same pattern of suppression was noted when reaching in response to an auditory cue suggesting that both perturbation-evoked and auditory-cued arm actions were mediated through a similar cortical network. These results extend upon previous work by Gage and colleagues which revealed a preservation of spatialtemporal reach patterns during volitional and compensatory reaching [17]. One proposed explanation for this phenomenon is that heightened arousal drives the same cortical networks involved in producing a cortically mediated reach at a much faster rate [18,19]
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