豚鼠心脏光学动作电位和钙瞬变的同步图谱:一致性交替变化的潜在机制。
Simultaneous maps of optical action potentials and calcium transients in guinea-pig hearts: mechanisms underlying concordant alternans.
作者信息
Choi B R, Salama G
机构信息
Department of Cell Biology and Physiology, University of Pittsburgh, School of Medicine, Pittsburgh, PA 15261, USA.
出版信息
J Physiol. 2000 Nov 15;529 Pt 1(Pt 1):171-88. doi: 10.1111/j.1469-7793.2000.00171.x.
Abstract
- The mechanisms underlying electro-mechanical alternans caused by faster heart rates were investigated in perfused guinea-pig hearts stained with RH237 and Rhod-2 AM to simultaneously map optical action potentials (APs) and intracellular free Ca2+ (Ca2+i). 2. Fluorescence images of the heart were focused on two 16 x 16 photodiode arrays to map Ca2+i (emission wavelength (lamdda;em) = 585 +/- 20 nm) and APs (lamdda;em > 715 nm) from 252 sites. Spatial resolution was 0.8 mm x 0.8 mm per diode and temporal resolution 4000 frames s-1. 3. The mean time-to-peak for APs and [Ca2+]i was spatially homogeneous (8.8 +/- 0.5 and 25.6 +/- 5.0 ms, respectively; n = 6). The durations of APs (APDs) and Ca2+i transients were shorter at the apex and progressively longer towards the base, indicating a gradient of ventricular relaxation. 4. Restitution kinetics revealed increasingly longer delays between AP and Ca2+i upstrokes (9.5 +/- 0.4 to 11.3 +/- 0.4 ms) with increasingly shorter S1-S2 intervals, particularly at the base, despite nearly normal peak [Ca2+]i. 5. Alternans of APs and Ca2+i transients were induced by a decrease++ in cycle length (CL), if the shorter CL captured at the pacing site and was shorter than refractory periods (RPs) near the base, creating heterogeneities of conduction velocity. 6. Rate-induced alternans in normoxic hearts were concordant (long APD with large [Ca2+]i) across the epicardium, with a magnitude (difference between odd-even signals) that varied with the local RP. Alternans were initiated by gradients of RP, producing alternans of conduction that terminated spontaneously without progressing to fibrillation.
摘要
- 在灌注的豚鼠心脏中,用RH237和Rhod-2 AM染色,以同时绘制光学动作电位(APs)和细胞内游离钙(Ca2+i),研究了心率加快引起的机电交替的潜在机制。2. 心脏的荧光图像聚焦在两个16×16光电二极管阵列上,以绘制来自252个位点的Ca2+i(发射波长(λem)= 585±20 nm)和APs(λem > 715 nm)。每个二极管的空间分辨率为0.8 mm×0.8 mm,时间分辨率为4000帧/秒。3. APs和[Ca2+]i的平均峰值时间在空间上是均匀的(分别为8.8±0.5和25.6±5.0毫秒;n = 6)。动作电位时程(APDs)和Ca2+i瞬变在 apex处较短,向基部逐渐变长,表明心室松弛存在梯度。4. 恢复动力学显示,随着S1-S2间隔越来越短,AP和Ca2+i上升之间的延迟越来越长(9.5±0.4至11.3±0.4毫秒),特别是在基部,尽管峰值[Ca2+]i几乎正常。5. 如果起搏部位捕获的较短周期长度(CL)短于基部附近的不应期(RPs),则通过缩短CL诱导APs和Ca2+i瞬变的交替,从而产生传导速度的异质性。6. 常氧心脏中速率诱导的交替在整个心外膜是一致的(长APD与大[Ca2+]i),其幅度(奇偶信号之间的差异)随局部RP而变化。交替由RP梯度引发,产生传导交替,自发终止而不发展为颤动。
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