支配猴皮肤的伤害性初级传入神经中两种不同热转导机制的证据。
Evidence for two different heat transduction mechanisms in nociceptive primary afferents innervating monkey skin.
作者信息
Treede R D, Meyer R A, Raja S N, Campbell J N
机构信息
Department of Neurosurgery, School of Medicine, Johns Hopkins University, Baltimore, MD 21205, USA.
出版信息
J Physiol. 1995 Mar 15;483 ( Pt 3)(Pt 3):747-58. doi: 10.1113/jphysiol.1995.sp020619.
Abstract
- Mechano- and heat-sensitive A fibre nociceptors (AMHs) and C fibre nociceptors (CMHs) in hairy skin (forty-six AMHs and twenty-one CMHs) and in glabrous skin (fifty-nine AMHs and ten CMHs) of anaesthetized monkeys were tested with a 30 s, 53 degrees C heat stimulus, delivered by a laser thermal stimulator (0.1 s rise time, 7.5 mm diameter). 2. Two types of heat response were observed in hairy skin AMHs. Type I AMHs had a peak discharge towards the end of the stimulus, response latencies to heat of up to several seconds, a median heat threshold greater than 53 degrees C, and a mean conduction velocity of 25 m s-1 (n = 33). Type II AMHs had a peak discharge within 1-3 s, a mean response latency of 120 ms, a median heat threshold of 46 degrees C, and a mean conduction velocity of 15 m s-1 (n = 13). Type I AMH fibres were sensitized to heat, whereas heat responses of type II AMHs were suppressed following the intense heat stimulus. 3. In glabrous skin, only type I AMHs were found. The absence of type II AMHs is consistent with the absence of first pain to heat in glabrous skin. 4. C fibre nociceptors in hairy skin had a peak discharge near stimulus onset, a mean response latency of 100 ms and a median heat threshold of 41 degrees C. Heat responses of CMHs in glabrous skin were not significantly different from those in hairy skin. 5. Only type II AMHs had response latencies that were short enough to explain first pain to heat. Heat thresholds of type II AMHs were significantly higher than those of CMHs. 6. These results suggest two different heat transduction mechanisms in nociceptive afferents. For one, heat energy is quickly transduced into action potentials, and the peak discharge is reached soon after stimulus onset. For the other, the transduction of heat is distinctly slower, and the peak discharge occurs near the end of the stimulus. Chemically mediated sensitization may be involved in the second transduction mechanism.
摘要
- 用激光热刺激器(上升时间0.1秒,直径7.5毫米)施加30秒、53摄氏度的热刺激,对麻醉猴的有毛皮肤(46个A纤维伤害感受器和21个C纤维伤害感受器)和无毛皮肤(59个A纤维伤害感受器和10个C纤维伤害感受器)中的机械和热敏感A纤维伤害感受器(AMH)和C纤维伤害感受器(CMH)进行测试。2. 在有毛皮肤AMH中观察到两种热反应类型。I型AMH在刺激结束时放电达到峰值,对热的反应潜伏期长达数秒,热阈值中位数大于53摄氏度,平均传导速度为25米/秒(n = 33)。II型AMH在1 - 3秒内放电达到峰值,平均反应潜伏期为120毫秒,热阈值中位数为46摄氏度,平均传导速度为15米/秒(n = 13)。I型AMH纤维对热敏感,而在强烈热刺激后II型AMH的热反应受到抑制。3. 在无毛皮肤中,仅发现I型AMH。II型AMH的缺失与无毛皮肤中对热的第一痛觉缺失一致。4. 有毛皮肤中的C纤维伤害感受器在刺激开始时附近放电达到峰值,平均反应潜伏期为100毫秒,热阈值中位数为41摄氏度。无毛皮肤中CMH的热反应与有毛皮肤中的无显著差异。5. 只有II型AMH的反应潜伏期短到足以解释对热的第一痛觉。II型AMH的热阈值显著高于CMH的热阈值。6. 这些结果表明伤害性传入纤维中存在两种不同的热转导机制。一种是热能迅速转化为动作电位,刺激开始后不久放电达到峰值。另一种是热转导明显较慢,放电峰值出现在刺激结束时。化学介导的敏化作用可能参与了第二种转导机制。
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