流体静压力对青蛙神经肌肉接头处递质自发释放的影响。
The effects of hydrostatic pressure on the spontaneous release of transmitter at the frog neuromuscular junction.
作者信息
Ashford M L, MacDonald A G, Wann K T
出版信息
J Physiol. 1982 Dec;333:531-43. doi: 10.1113/jphysiol.1982.sp014467.
Abstract
- The effects of hydrostatic pressure (0.1-15.55 MPa) on the spontaneous release of transmitter at the frog neuromuscular junction were investigated. 2. The major effect of high pressure is on the release mechanism, pressure (0.1-10.40 MPa) producing an exponential decrease in frequency of the miniature end-plate currents in normal Ringer solution. The frequency decreases to 0.52 and 0.24 of the control value at 5.25 and 10.40 MPa respectively. This effect is reversible on decompression. 3. The sensitivity of the release process to high pressure is unaltered in 10 mM-K+, 6 mM- and 10 mM-Ca2+ and hypertonic (165 mM-NaCl) Ringer solution, although the high Ca2+ media shift the threshold for the pressure effect to higher pressures. 4. Higher pressure (10.40-15.55 MPa) produces a small increase in the time constant of decay (tau D) of m.e.p.c.s with no effect on the growth phase. A pressure of 15.55 MPa increases tau D to 1.35 of the control value. 5. The possible actions of high pressure on both the pre- and post-synaptic processes are briefly discussed.
摘要
- 研究了静水压力(0.1 - 15.55兆帕)对青蛙神经肌肉接头处递质自发释放的影响。2. 高压的主要作用在于释放机制,在正常任氏液中,压力(0.1 - 10.40兆帕)使微小终板电流频率呈指数下降。在5.25兆帕和10.40兆帕时,频率分别降至对照值的0.52和0.24。减压后此效应可逆。3. 在10毫摩/升钾离子、6毫摩/升和10毫摩/升钙离子以及高渗(165毫摩/升氯化钠)任氏液中,释放过程对高压的敏感性未改变,尽管高钙介质使压力效应的阈值向更高压力偏移。4. 更高压力(10.40 - 15.55兆帕)使微小终板电流的衰减时间常数(τD)略有增加,对增长期无影响。15.55兆帕的压力使τD增至对照值的1.35。5. 简要讨论了高压对突触前和突触后过程可能的作用。
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