Lochner A, Pentz A, Williams K, Tromp E, Harper I S
Experimental Biology Programme, South African Medical Research Council,Tygerberg, Republic of South Africa.
Basic Res Cardiol. 1996 Jan-Feb;91(1):64-78. doi: 10.1007/BF00788867.
Based on the hypothesis that provision of glucose is good and fatty acids are bad for the ischaemic myocardium, the aims of this study were to determine i) the effects of different substrates on sarcolemmal permeability during normoxia, low-flow hypoxia (HLF) and reperfusion, ii) whether increased membrane permeability is associated with ultrastructural damage and increased influx of Ca2+ into cells and iii) whether changes in membrane permeability correlate with myocardial function and high energy phosphate metabolism.
The isolated rat heart subjected to HLF was used as model of global ischaemia, and sarcolemmal permeability assessed by release of LDH from and influx of lanthanum and Ca2+ into myocardial tissue. Myocyte structural injury was also evaluated quantitatively, and mechanical activity was monitored throughout the experimental protocol.
Regardless of the substrate used, HLF caused a 80-90% and 20-40% reduction in myocardial oxygen uptake and coronary flow rate, respectively. Palmitate (0.5 mM conjugated to 0.1 mM albumin) or substrate-free perfusion caused ultrastructural damage and loss of normal sarcolemmal integrity during both normoxia and HLF. Although reperfusion reversed injury in some cells, in general, myocytes exhibited myofibrillar contracture, while membrane integrity recovered to some extent, as indicated by reduced lanthanum influx. Intracellular Ca2+ increased significantly upon reperfusion. Mechanical function as well as tissue high energy phosphates were significantly depressed during both HLF and reperfusion. Glucose, on the other hand, protected against ischaemia-induced structural damage and loss of sarcolemmal integrity. Reperfusion in these experiments resulted in almost complete recovery of normal morphology, ultrastructure and sarcolemmal integrity, while intracellular Ca2+ remained unchanged. Mechanical function and tissue high energy phosphates were significantly higher in glucose-perfused hearts than in palmitate-perfused or substrate-free hearts. Glucose was also able to attenuate the harmful effects of palmitate on myocardial ultrastructure, membrane integrity, mechanical function, energy metabolism and prevented Ca2+ overloading during reperfusion.
The results provide new evidence for the protective role of glucose during myocardial ischaemia and reperfusion. Although the exact mechanism of the beneficial actions of glucose remains to be established, the results suggest that glycolytic flux and thus glycolytically derived ATP protect against ischaemic damage via preservation of membrane integrity.
基于葡萄糖对缺血心肌有益而脂肪酸有害的假设,本研究的目的是确定:i)在常氧、低流量缺氧(HLF)和再灌注期间不同底物对肌膜通透性的影响;ii)膜通透性增加是否与超微结构损伤及Ca2+流入细胞增加有关;iii)膜通透性变化是否与心肌功能和高能磷酸代谢相关。
将经历HLF的离体大鼠心脏用作全心缺血模型,通过心肌组织中乳酸脱氢酶(LDH)的释放以及镧和Ca2+的流入来评估肌膜通透性。还对心肌细胞结构损伤进行了定量评估,并在整个实验过程中监测机械活性。
无论使用何种底物,HLF均导致心肌摄氧量和冠状动脉血流量分别降低80 - 90%和20 - 40%。棕榈酸(0.5 mM与0.1 mM白蛋白结合)或无底物灌注在常氧和HLF期间均导致超微结构损伤和正常肌膜完整性丧失。尽管再灌注使一些细胞的损伤得到逆转,但总体而言,心肌细胞出现肌原纤维挛缩,而膜完整性在一定程度上得以恢复,这表现为镧流入减少。再灌注时细胞内Ca2+显著增加。在HLF和再灌注期间,机械功能以及组织高能磷酸盐均显著降低。另一方面,葡萄糖可防止缺血诱导的结构损伤和肌膜完整性丧失。在这些实验中,再灌注导致正常形态、超微结构和肌膜完整性几乎完全恢复,而细胞内Ca2+保持不变。葡萄糖灌注心脏的机械功能和组织高能磷酸盐显著高于棕榈酸灌注或无底物灌注的心脏。葡萄糖还能够减轻棕榈酸对心肌超微结构、膜完整性、机械功能、能量代谢的有害影响,并防止再灌注期间Ca2+超载。
这些结果为葡萄糖在心肌缺血和再灌注期间的保护作用提供了新证据。尽管葡萄糖有益作用的确切机制仍有待确定,但结果表明糖酵解通量以及由此产生 的糖酵解衍生ATP通过维持膜完整性来防止缺血损伤。
