豚鼠单个心室肌细胞与离体心室肌细胞内pH瞬变的比较。
Comparison of intracellular pH transients in single ventricular myocytes and isolated ventricular muscle of guinea-pig.
作者信息
Bountra C, Powell T, Vaughan-Jones R D
机构信息
University Laboratory of Physiology, Oxford.
出版信息
J Physiol. 1990 May;424:343-65. doi: 10.1113/jphysiol.1990.sp018071.
Abstract
- Intracellular pH was recorded (double-barrelled pH-selective microelectrodes) in single ventricular myocytes and whole papillary muscles isolated from guinea-pig heart. Both preparations were acid-loaded by various manoeuvres (addition and removal of external NH4Cl or CO2) in order that a comparison could be made of the size and speed of intracellular pH changes and hence of the apparent intracellular buffering power (beta). 2. For the same acid-loading procedure, the size of intracellular pH (pHi) changes was about threefold larger in the isolated myocyte than in whole papillary muscle. The rate of initial acid loading as well as the subsequent rate of pHi recovery (caused by acid extrusion from the cell) were also threefold faster in the myocyte. Estimates of apparent intrinsic (non-CO2) buffering power, based upon the size of pHi changes during acid loading, were 15-20 mmol l-1 for the myocyte and about 70 mmol l-1 for whole muscle. This latter value is similar to previous estimates of beta in heart. 3. When acid extrusion was reduced by applying a high dose of amiloride (1 mmol l-1), then the size of the pHi change during acid loading increased greatly in papillary muscle but changed much less in the myocyte; beta now appeared to be about 30 mmol l-1 in whole muscle but remained essentially unchanged in the myocyte. 4. We conclude that previous values for beta in cardiac muscle have been greatly overestimated because of the presence of sarcolemmal acid extrusion. Paradoxically, this error in estimating beta is far less evident in the isolated myocyte. We suggest that this is because a much more rapid acid loading is achievable in the myocyte so that acid loading will be blunted less by acid extrusion than in whole muscle. We present a simple mathematical model that demonstrates this phenomenon. We conclude that beta in ventricular muscle is likely to resemble that measured in the isolated myocyte, i.e. 15-20 mmol l-1. 5. Slow acid loading in whole ventricular muscle will also affect the kinetics of pHi changes. The model indicates that the rate of pHi recovery from an acid load in papillary muscle does not reflect the pHi dependence of acid extrusion. Instead, it is heavily influenced by the slow rate of acid loading. This emphasises that great care should be taken when interpreting the kinetics of pHi changes in multicellular ventricular preparations.
摘要
- 使用双管pH选择性微电极记录从豚鼠心脏分离出的单个心室肌细胞和完整乳头肌的细胞内pH值。通过各种操作(添加和去除细胞外氯化铵或二氧化碳)使两种标本进行酸负荷处理,以便比较细胞内pH变化的大小和速度,从而比较表观细胞内缓冲能力(β)。2. 对于相同的酸负荷程序,分离的肌细胞内pH(pHi)变化的大小比完整乳头肌大约大三倍。肌细胞中初始酸负荷的速率以及随后pHi恢复的速率(由细胞内酸排出引起)也快三倍。根据酸负荷期间pHi变化的大小估算的表观固有(非二氧化碳)缓冲能力,肌细胞为15 - 20 mmol·l⁻¹,全肌肉约为70 mmol·l⁻¹。后一个值与先前对心脏中β的估计值相似。3. 当通过应用高剂量的氨氯地平(1 mmol·l⁻¹)降低酸排出时,乳头肌中酸负荷期间pHi变化的大小大幅增加,而肌细胞中的变化则小得多;此时全肌肉中的β似乎约为30 mmol·l⁻¹,而肌细胞中的β基本保持不变。4. 我们得出结论,由于肌膜酸排出的存在,先前对心肌中β的估计值被大大高估了。矛盾的是,这种在估计β时的误差在分离的肌细胞中远不那么明显。我们认为这是因为在肌细胞中可以实现更快的酸负荷,因此与全肌肉相比,酸负荷受酸排出的影响较小。我们提出了一个简单的数学模型来证明这一现象。我们得出结论,心室肌中的β可能类似于在分离的肌细胞中测得的值,即15 - 20 mmol·l⁻¹。5. 全心室肌中的缓慢酸负荷也会影响pHi变化的动力学。该模型表明,乳头肌中酸负荷后pHi恢复的速率并不反映酸排出对pHi的依赖性。相反,它受到酸负荷缓慢速率的严重影响。这强调了在解释多细胞心室标本中pHi变化的动力学时应格外小心。
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