Segundo J P, Diez Martínez O, Quijano H
Biol Cybern. 1987;55(6):355-66. doi: 10.1007/BF00318370.
The experimentally observed influence of regularly arriving tugs upon the AP discharge of the slowly-adapting stretch receptor organ (SAO) of crayfish was compared to a model of pacemaker excitatory synaptic interactions (Segundo and Kohn 1981). Criteria for compliance referred to facets as A) the excitation, B) the postulates, and C) the behavior. A) Excitation was implied primarily by the tug initially increasing the AP rate (it subsequently decreased it). B) The pacemaker AP discharges, and with more reason the electronically driven tugs, were considered acceptably regular sequence (postulate i). Tugs advanced the next AP (postulate ii); the "delay function" plots of delays vs. phases, i.e. interval shortenings vs. the time from the last AP to the tug, were close to the V of postulate iii, even though the shortest phases tended to postpone the next AP and the longest ones did not trigger immediately but with an around 5 ms latency. These effects were displayed also as "old phase vs. new phase" plots. The interval following that with the tug tended to be lengthened, but the pre-tug timing was not recovered. C) Behavior during a train of excitatory events, both in model and experiments, went through very similar initial settlings and eventual steady-states. The latter were characterized in the model by 1. an average excitatory vs. excited rate display formed by an endless number of segments with all positive rational slopes separated by negative-going discontinuities, 2. locking in the sense of preferential phases, and 3. periodic repetition of the same phases and inter-AP intervals. Experimental results were compatible with this. Such behavior was absent when the tug sequence was highly irregular. The initial settling, in the SAO as in the model, depended jointly on the first phase phi 1 and the intertug interval E. If the former was under lambda, it went through one or two monotonic phase-decreasing stages (one smaller, the other larger, than lambda), or through a single increasing one, depending on E being smaller or greater than, respectively, an estimated but never actually observed E leading to unstable lockings. If the initial phase was greater than lambda, settling with E's under rN + lambda involved jumps between larger than and smaller than lambda phases; with E's over rn + lambda, it involved an intermediate stable locking with phi = E-rN.(ABSTRACT TRUNCATED AT 400 WORDS)
将实验观察到的定期到达的拖力对小龙虾慢适应性牵张感受器器官(SAO)动作电位发放的影响,与起搏器兴奋性突触相互作用模型(Segundo和Kohn,1981年)进行了比较。符合标准涉及以下几个方面:A)兴奋,B)假设,以及C)行为。A)兴奋主要表现为拖力最初使动作电位发放率增加(随后降低)。B)起搏器动作电位发放,更确切地说电子驱动的拖力,被认为是可接受的规则序列(假设i)。拖力使下一个动作电位提前(假设ii);延迟与相位的“延迟函数”图,即间隔缩短与从上一个动作电位到拖力的时间的关系图,即使最短相位倾向于推迟下一个动作电位,最长相位不会立即触发而是有大约5毫秒的潜伏期,但仍接近假设iii的V形。这些效应也以“旧相位与新相位”图呈现。拖力后的间隔往往会延长,但拖力前的时间并未恢复。C)在一系列兴奋性事件期间,模型和实验中的行为都经历了非常相似的初始稳定阶段和最终稳态。在模型中,后者的特征为:1. 由无数具有所有正有理斜率且由负向不连续分隔的段形成的平均兴奋与被兴奋发放率显示;2. 优先相位意义上的锁定;3. 相同相位和动作电位间期的周期性重复。实验结果与此相符。当拖力序列高度不规则时,这种行为不存在。在SAO中,如同在模型中一样,初始稳定阶段共同取决于第一个相位φ1和拖力间隔E。如果前者小于λ,它会经历一个或两个单调相位减小阶段(一个小于λ,另一个大于λ),或者经历一个单一的增加阶段,这取决于E分别小于或大于一个估计但从未实际观察到的导致不稳定锁定的E。如果初始相位大于λ,当E小于rN + λ时,稳定阶段涉及大于和小于λ相位之间的跳跃;当E大于rn + λ时,它涉及一个中间稳定锁定,其中φ = E - rN。(摘要截于400字)
