Eden T. Delahunty, Leanne M. Bisset, Justin J. Kavanagh
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Measurements were obtained from electromyography (EMG) of the first dorsal interosseous (FDI) at baseline, during cold-water immersion, and during recovery from cold-water immersion. The intervention caused unconditioned MEPs to increase during exposure to the cold stimulus (<i>P</i> = 0.008) which then returned to baseline levels once the hand was removed from the cold water. MEP responses were decoupled from SAI responses, where SAI was reduced during exposure to the cold stimulus (<i>P</i> = 0.005) and remained reduced compared to baseline when the hand was removed from the cold water (<i>P</i> = 0.002). The intervention had no effect on LAI. The uncoupling of SAI from MEPs during the recovery period suggests that the mechanisms underlying the modulation of corticospinal excitability by sensory input may be distinct from those affecting intracortical inhibitory circuits.</p>\n </section>\n \n <section>\n \n <h3> Highlights</h3>\n \n <div>\n <ul>\n \n <li>\n <p><b>What is the central question of this study?</b></p>\n \n <p>Does immersion of a limb in very cold water influence corticospinal excitability and the level of afferent inhibition exerted on motor cortical circuits?</p>\n </li>\n \n <li>\n <p><b>What is the main finding and its importance?</b></p>\n \n <p>In additional to perception of temperature, immersion in 6°C water also induced perceptions of pain. Motor evoked potential (MEP) amplitude increased during immersion, and short-latency afferent inhibition (SAI) of the motor cortex was reduced during immersion; however, these responses differed after the limb was removed from the cold stimulus, as MEPs returned to normal levels while SAI remained suppressed.</p>\n </li>\n </ul>\n </div>\n </section>\n </div>","PeriodicalId":12092,"journal":{"name":"Experimental Physiology","volume":"109 11","pages":"1817-1825"},"PeriodicalIF":2.6000,"publicationDate":"2024-08-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1113/EP091896","citationCount":"0","resultStr":"{\"title\":\"Short-latency afferent inhibition is reduced with cold-water immersion of a limb and remains reduced after removal from the cold stimulus\",\"authors\":\"Eden T. Delahunty, Leanne M. Bisset, Justin J. 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Measurements were obtained from electromyography (EMG) of the first dorsal interosseous (FDI) at baseline, during cold-water immersion, and during recovery from cold-water immersion. The intervention caused unconditioned MEPs to increase during exposure to the cold stimulus (<i>P</i> = 0.008) which then returned to baseline levels once the hand was removed from the cold water. MEP responses were decoupled from SAI responses, where SAI was reduced during exposure to the cold stimulus (<i>P</i> = 0.005) and remained reduced compared to baseline when the hand was removed from the cold water (<i>P</i> = 0.002). The intervention had no effect on LAI. 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引用次数: 0
摘要
极冷温度引起的疼痛体验会对运动皮层电路产生调节作用。众所周知,将单肢浸泡在极冷的水中可提高皮质运动神经的兴奋性,但传入皮质的输入如何影响兴奋和抑制过程尚不清楚。因此,本研究的目的是检测单手浸入冷水后的运动诱发电位(MEP)、短时传入抑制(SAI)和长时传入抑制(LAI)。经颅磁刺激(TMS)用于评估 MEPs,正中神经的周围神经刺激与 TMS 搭配使用,用于测量同侧半球运动回路中的 SAI 和 LAI。在基线、冷水浸泡期间和冷水浸泡后恢复期间,通过第一背侧骨间肌电图(FDI)进行测量。在暴露于冷刺激时,干预会导致非条件性 MEPs 增加(P = 0.008),一旦将手从冷水中移开,MEPs 就会恢复到基线水平。MEP 反应与 SAI 反应分离,SAI 在接触冷刺激时降低(P = 0.005),当手从冷水中移开时,SAI 与基线相比仍然降低(P = 0.002)。干预对 LAI 没有影响。恢复期间 SAI 与 MEPs 的解耦表明,感觉输入对皮质脊髓兴奋性的调节机制可能不同于影响皮质内抑制回路的机制。重点:本研究的核心问题是什么?将肢体浸泡在极冷的水中是否会影响皮质脊髓的兴奋性以及传入对运动皮质回路的抑制水平?主要发现及其重要性是什么?除了对温度的感知外,浸泡在 6°C 的水中还能引起对疼痛的感知。浸泡期间,运动诱发电位(MEP)振幅增大,运动皮层的短时传入抑制(SAI)降低;然而,这些反应在肢体脱离冷刺激后有所不同,MEP恢复到正常水平,而SAI仍然受到抑制。
Short-latency afferent inhibition is reduced with cold-water immersion of a limb and remains reduced after removal from the cold stimulus
The experience of pain that is induced by extremely cold temperatures can exert a modulatory effect on motor cortex circuitry. Although it is known that immersion of a single limb in very cold water can increase corticomotor excitability it is unknown how afferent input to the cortex shapes excitatory and inhibitory processes. Therefore, the purpose of this study was to examine motor-evoked potentials (MEP), short-latency afferent inhibition (SAI) and long-latency afferent inhibition (LAI) in response to immersion of a single hand in cold water. Transcranial magnetic stimulation (TMS) was used to assess MEPs, and peripheral nerve stimulation of the median nerve paired with TMS was used to measure SAI and LAI in motor circuits of the ipsilateral hemisphere. Measurements were obtained from electromyography (EMG) of the first dorsal interosseous (FDI) at baseline, during cold-water immersion, and during recovery from cold-water immersion. The intervention caused unconditioned MEPs to increase during exposure to the cold stimulus (P = 0.008) which then returned to baseline levels once the hand was removed from the cold water. MEP responses were decoupled from SAI responses, where SAI was reduced during exposure to the cold stimulus (P = 0.005) and remained reduced compared to baseline when the hand was removed from the cold water (P = 0.002). The intervention had no effect on LAI. The uncoupling of SAI from MEPs during the recovery period suggests that the mechanisms underlying the modulation of corticospinal excitability by sensory input may be distinct from those affecting intracortical inhibitory circuits.
Highlights
What is the central question of this study?
Does immersion of a limb in very cold water influence corticospinal excitability and the level of afferent inhibition exerted on motor cortical circuits?
What is the main finding and its importance?
In additional to perception of temperature, immersion in 6°C water also induced perceptions of pain. Motor evoked potential (MEP) amplitude increased during immersion, and short-latency afferent inhibition (SAI) of the motor cortex was reduced during immersion; however, these responses differed after the limb was removed from the cold stimulus, as MEPs returned to normal levels while SAI remained suppressed.
期刊介绍:
Experimental Physiology publishes research papers that report novel insights into homeostatic and adaptive responses in health, as well as those that further our understanding of pathophysiological mechanisms in disease. We encourage papers that embrace the journal’s orientation of translation and integration, including studies of the adaptive responses to exercise, acute and chronic environmental stressors, growth and aging, and diseases where integrative homeostatic mechanisms play a key role in the response to and evolution of the disease process. Examples of such diseases include hypertension, heart failure, hypoxic lung disease, endocrine and neurological disorders. We are also keen to publish research that has a translational aspect or clinical application. Comparative physiology work that can be applied to aid the understanding human physiology is also encouraged.
Manuscripts that report the use of bioinformatic, genomic, molecular, proteomic and cellular techniques to provide novel insights into integrative physiological and pathophysiological mechanisms are welcomed.