Lecarpentier Y, Martin J L, Claes V, Chambaret J P, Migus A, Antonetti A, Hatt P Y
Circ Res. 1985 Mar;56(3):331-9. doi: 10.1161/01.res.56.3.331.
Kinetics of sarcomere movement were studied in real-time by laser diffraction. Instantaneous sarcomere shortening was measured during afterloaded twitches simultaneously with instantaneous shortening and tension of the whole trabecula excised from rat right ventricle. Resting sarcomere length at optimal length was 2.20 +/- 0.02 micron (mean +/- SEM). Maximum amplitude of sarcomere shortening was 0.30 +/- 0.01 and 0.16 +/- 0.01 micron, respectively, in twitches loaded with preload only, and in "isometric" twitches. When the isotonic load (expressed as a percentage of maximum isometric force TF) increased, the maximum velocity of sarcomere relaxation max Vr (micron/sec) decreased: max Vr = -4 exp (-2.5 X 10(-2) % TF); r = 0.95. The time course of sarcomere relaxation appeared to be progressively delayed when the total load increased from preload only up to "isometric" load. Sarcomere relaxation occurred in two successive exponential phases, a rapid phase [time constant (msec): tau 1] followed by a slower one (time constant: tau 2). When the total load increased, tau 1 increased and tau 2 decreased according to the linear relations: % TF = 0.2 tau 1 + 4.8 (r = 0.83) and % TF = -0.1 tau 2 + 157 (r = 0.95). The relative predominance of both the time course and the amplitude of these two phases depended upon the level of total load. The rapid process predominated at low load, the slow one at high load. The role of load and/or shortening in the time course of these two phases is discussed.
通过激光衍射实时研究肌节运动的动力学。在大鼠右心室切除的整个小梁的瞬时缩短和张力的同时,测量后负荷收缩期的瞬时肌节缩短。最佳长度下的静息肌节长度为2.20±0.02微米(平均值±标准误)。仅加载前负荷的收缩期和“等长”收缩期肌节缩短的最大幅度分别为0.30±0.01和0.16±0.01微米。当等张负荷(表示为最大等长力TF的百分比)增加时,肌节舒张的最大速度max Vr(微米/秒)降低:max Vr = -4 exp(-2.5×10^(-2) % TF);r = 0.95。当总负荷从仅前负荷增加到“等长”负荷时,肌节舒张的时间进程似乎逐渐延迟。肌节舒张发生在两个连续的指数阶段,一个快速阶段[时间常数(毫秒):tau 1],随后是一个较慢的阶段(时间常数:tau 2)。当总负荷增加时,tau 1根据线性关系增加,tau 2根据线性关系降低:% TF = 0.2 tau 1 + 4.8(r = 0.83)和% TF = -0.1 tau 2 + 157(r = 0.95)。这两个阶段的时间进程和幅度的相对优势取决于总负荷水平。快速过程在低负荷时占主导,缓慢过程在高负荷时占主导。讨论了负荷和/或缩短在这两个阶段时间进程中的作用。
