正常猫和去大脑猫的节段性反射活动

Segmental reflex action in normal and decerebrate cats.

作者信息

Hoffer J A, Leonard T R, Cleland C L, Sinkjaer T

机构信息

Department of Clinical Neurosciences, University of Calgary, Faculty of Medicine, Alberta, Canada.

出版信息

J Neurophysiol. 1990 Nov;64(5):1611-24. doi: 10.1152/jn.1990.64.5.1611.

DOI:10.1152/jn.1990.64.5.1611

PMID:2283543

Abstract

The objective of this study was to evaluate the action of the stretch reflex on the ankle extensor muscles of normal and decerebrate cats. 2. Experiments were performed on nine freely standing, unrestrained cats and repeated after decerebration at the premammillary level. The length, force, and electromyograph (EMG) of the soleus (SOL) and lateral gastrocnemius (LG) muscles were recorded with the use of implanted transducers and electrodes. 3. The left ankle joint was unexpectedly and reproducibly dorsiflexed by briefly stimulating the common peroneal (CP) nerve with electrodes within an implanted nerve cuff. The ensuing twitch contractions of the ankle dorsiflexor muscles stretched the ankle extensor muscles by 0.3-2.0 mm. Lidocaine was infused into another nerve cuff proximal to the stimulation site, to reversibly block the central propagation of evoked volleys in the CP nerve. 4. Reflex action before and after decerebration was measured from the responses to perturbations of similar amplitude and duration delivered at approximately matched background values of muscle length and force. In most cats the temperature of the hindlimb was monitored with an implanted thermistor and was restored to normal values with radiant heat after decerebration. 5. A stretch imposed on the tonically active ankle extensor muscles immediately caused a considerable rise in the force recorded from the triceps tendon. Within 30-40 ms the triceps force peaked, reaching a value 10-20 N greater than background, and then rapidly declined while the extensor muscles were still lengthening. The initial rise in force preceded any change in triceps EMG. It was attributed to the intrinsic viscoelasticity of the stretched muscles and tendons. After decerebration the magnitude and timing of the initial force peak did not change. 6. A short-latency reflex EMG burst was typically recorded from both the SOL and LG muscles, starting 11-17 ms after stimulus onset. After decerebration the area of the reflex EMG burst increased in all nine cats, typically by a factor of 2 or 3. 7. After decerebration a second, smaller increase in force was typically observed starting 60-80 ms after onset of stretch. This later force rise, interpreted to be of reflex origin, was rarely apparent in normal cats. 8. Decerebration introduced consistent modifications in postural behavior that were revealed by pushing down on the back of quietly standing cats. In normal cats, after brief pushes that stretched the ankle extensor muscles by 1-2 mm, the EMG, force, and length quickly stabilized near their initial values.(ABSTRACT TRUNCATED AT 400 WORDS)

摘要

本研究的目的是评估牵张反射对正常猫和去大脑猫踝关节伸肌的作用。2. 对9只自由站立、未受束缚的猫进行实验，并在乳头前水平去大脑后重复实验。使用植入式换能器和电极记录比目鱼肌（SOL）和外侧腓肠肌（LG）的长度、力量和肌电图（EMG）。3. 通过在植入的神经袖套内用电极短暂刺激腓总神经（CP），意外且可重复地使左踝关节背屈。随后踝关节背屈肌的抽搐收缩使踝关节伸肌伸展0.3 - 2.0毫米。将利多卡因注入刺激部位近端的另一个神经袖套内，以可逆地阻断CP神经中诱发冲动的中枢传播。4. 根据在肌肉长度和力量的大致匹配背景值下施加的类似幅度和持续时间的扰动反应，测量去大脑前后的反射作用。在大多数猫中，用植入的热敏电阻监测后肢温度，并在去大脑后用辐射热将其恢复到正常值。5. 对持续活跃的踝关节伸肌施加牵张立即导致肱三头肌腱记录的力量显著增加。在30 - 40毫秒内，肱三头肌力量达到峰值，比背景值高10 - 20牛，然后在伸肌仍在延长时迅速下降。力量的初始增加先于肱三头肌EMG的任何变化。这归因于被拉伸的肌肉和肌腱的内在粘弹性。去大脑后，初始力量峰值的大小和时间没有变化。6. 通常在刺激开始后11 - 17毫秒从SOL和LG肌肉记录到短潜伏期反射EMG爆发。去大脑后，所有9只猫的反射EMG爆发面积都增加了，通常增加2或3倍。7. 去大脑后，通常在牵张开始后60 - 80毫秒观察到力量的第二次较小增加。这种后来的力量增加被解释为反射起源，在正常猫中很少明显。8. 去大脑引起姿势行为的一致改变，这在轻轻按压安静站立的猫的背部时表现出来。在正常猫中，在短暂按压使踝关节伸肌伸展1 - 2毫米后，EMG、力量和长度很快稳定在其初始值附近。（摘要截取自400字）

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正常猫和去大脑猫的节段性反射活动

Segmental reflex action in normal and decerebrate cats.

作者信息

Hoffer J A, Leonard T R, Cleland C L, Sinkjaer T

机构信息

Department of Clinical Neurosciences, University of Calgary, Faculty of Medicine, Alberta, Canada.

出版信息

J Neurophysiol. 1990 Nov;64(5):1611-24. doi: 10.1152/jn.1990.64.5.1611.

DOI:10.1152/jn.1990.64.5.1611

PMID:2283543

Abstract

The objective of this study was to evaluate the action of the stretch reflex on the ankle extensor muscles of normal and decerebrate cats. 2. Experiments were performed on nine freely standing, unrestrained cats and repeated after decerebration at the premammillary level. The length, force, and electromyograph (EMG) of the soleus (SOL) and lateral gastrocnemius (LG) muscles were recorded with the use of implanted transducers and electrodes. 3. The left ankle joint was unexpectedly and reproducibly dorsiflexed by briefly stimulating the common peroneal (CP) nerve with electrodes within an implanted nerve cuff. The ensuing twitch contractions of the ankle dorsiflexor muscles stretched the ankle extensor muscles by 0.3-2.0 mm. Lidocaine was infused into another nerve cuff proximal to the stimulation site, to reversibly block the central propagation of evoked volleys in the CP nerve. 4. Reflex action before and after decerebration was measured from the responses to perturbations of similar amplitude and duration delivered at approximately matched background values of muscle length and force. In most cats the temperature of the hindlimb was monitored with an implanted thermistor and was restored to normal values with radiant heat after decerebration. 5. A stretch imposed on the tonically active ankle extensor muscles immediately caused a considerable rise in the force recorded from the triceps tendon. Within 30-40 ms the triceps force peaked, reaching a value 10-20 N greater than background, and then rapidly declined while the extensor muscles were still lengthening. The initial rise in force preceded any change in triceps EMG. It was attributed to the intrinsic viscoelasticity of the stretched muscles and tendons. After decerebration the magnitude and timing of the initial force peak did not change. 6. A short-latency reflex EMG burst was typically recorded from both the SOL and LG muscles, starting 11-17 ms after stimulus onset. After decerebration the area of the reflex EMG burst increased in all nine cats, typically by a factor of 2 or 3. 7. After decerebration a second, smaller increase in force was typically observed starting 60-80 ms after onset of stretch. This later force rise, interpreted to be of reflex origin, was rarely apparent in normal cats. 8. Decerebration introduced consistent modifications in postural behavior that were revealed by pushing down on the back of quietly standing cats. In normal cats, after brief pushes that stretched the ankle extensor muscles by 1-2 mm, the EMG, force, and length quickly stabilized near their initial values.(ABSTRACT TRUNCATED AT 400 WORDS)

摘要

本研究的目的是评估牵张反射对正常猫和去大脑猫踝关节伸肌的作用。2. 对9只自由站立、未受束缚的猫进行实验，并在乳头前水平去大脑后重复实验。使用植入式换能器和电极记录比目鱼肌（SOL）和外侧腓肠肌（LG）的长度、力量和肌电图（EMG）。3. 通过在植入的神经袖套内用电极短暂刺激腓总神经（CP），意外且可重复地使左踝关节背屈。随后踝关节背屈肌的抽搐收缩使踝关节伸肌伸展0.3 - 2.0毫米。将利多卡因注入刺激部位近端的另一个神经袖套内，以可逆地阻断CP神经中诱发冲动的中枢传播。4. 根据在肌肉长度和力量的大致匹配背景值下施加的类似幅度和持续时间的扰动反应，测量去大脑前后的反射作用。在大多数猫中，用植入的热敏电阻监测后肢温度，并在去大脑后用辐射热将其恢复到正常值。5. 对持续活跃的踝关节伸肌施加牵张立即导致肱三头肌腱记录的力量显著增加。在30 - 40毫秒内，肱三头肌力量达到峰值，比背景值高10 - 20牛，然后在伸肌仍在延长时迅速下降。力量的初始增加先于肱三头肌EMG的任何变化。这归因于被拉伸的肌肉和肌腱的内在粘弹性。去大脑后，初始力量峰值的大小和时间没有变化。6. 通常在刺激开始后11 - 17毫秒从SOL和LG肌肉记录到短潜伏期反射EMG爆发。去大脑后，所有9只猫的反射EMG爆发面积都增加了，通常增加2或3倍。7. 去大脑后，通常在牵张开始后60 - 80毫秒观察到力量的第二次较小增加。这种后来的力量增加被解释为反射起源，在正常猫中很少明显。8. 去大脑引起姿势行为的一致改变，这在轻轻按压安静站立的猫的背部时表现出来。在正常猫中，在短暂按压使踝关节伸肌伸展1 - 2毫米后，EMG、力量和长度很快稳定在其初始值附近。（摘要截取自400字）

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正常猫和去大脑猫的节段性反射活动

Segmental reflex action in normal and decerebrate cats.

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机构信息

出版信息

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引用本文的文献

正常猫和去大脑猫的节段性反射活动

Segmental reflex action in normal and decerebrate cats.

作者信息

机构信息

出版信息

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