缺血心肌的收缩后期缩短：主动收缩还是被动回弹？

Postsystolic shortening in ischemic myocardium: active contraction or passive recoil?

作者信息

Skulstad Helge, Edvardsen Thor, Urheim Stig, Rabben Stein Inge, Stugaard Marie, Lyseggen Erik, Ihlen Halfdan, Smiseth Otto A

机构信息

Institute for Surgical Research and Department of Cardiology, Rikshospitalet University Hospital, Oslo, Norway.

出版信息

Circulation. 2002 Aug 6;106(6):718-24. doi: 10.1161/01.cir.0000024102.55150.b6.

DOI:10.1161/01.cir.0000024102.55150.b6

PMID:12163433

Abstract

BACKGROUND

Postsystolic shortening in ischemic myocardium has been proposed as a marker of tissue viability. Our objectives were to determine if postsystolic shortening represents active fiber shortening or passive recoil and if postsystolic shortening may be quantified by strain Doppler echocardiography (SDE).

METHODS AND RESULTS

In 15 anesthetized dogs, we measured left ventricular (LV) pressure, myocardial long-axis strains by SDE, and segment lengths by sonomicrometry before and during LAD stenosis and occlusion. Active contraction was defined as elevated LVP and stress during postsystolic shortening when compared with the fully relaxed ventricle at similar segment lengths. LAD stenosis decreased systolic shortening from 10.4+/-1.2% to 5.9+/-0.9% (P<0.05), whereas postsystolic shortening increased from 1.1+/-0.3% to 4.2+/-0.7% (P<0.05). In hypokinetic and akinetic segments, LV pressure-segment length and LV stress-segment length loop analysis indicated that postsystolic shortening was active. LAD occlusion resulted in dyskinesis, and postsystolic shortening increased additionally to 8.2+/-1.0% (P<0.05). After 3 to 5 minutes with LAD occlusion, the dyskinetic segment generated no active stress, and the postsystolic shortening was attributable to passive recoil. Elevation of afterload caused hypokinetic segments to become dyskinetic, and postsystolic shortening remained partly active. Postsystolic shortening by SDE correlated well with sonomicrometry (r=0.83, P<0.01).

CONCLUSIONS

Postsystolic shortening is a relatively nonspecific feature of ischemic myocardium and may occur in dyskinetic segments by an entirely passive mechanism. However, in segments with systolic hypokinesis or akinesis, postsystolic shortening is a marker of actively contracting myocardium. SDE was able to quantify postsystolic shortening and might represent a clinical method for identifying actively contracting and hence viable myocardium.

摘要

背景

收缩期后缩短被认为是缺血心肌组织存活的一个标志物。我们的目的是确定收缩期后缩短是代表主动纤维缩短还是被动回弹，以及收缩期后缩短是否可以通过应变多普勒超声心动图（SDE）进行量化。

方法与结果

在15只麻醉犬中，我们在左前降支（LAD）狭窄和闭塞前及过程中测量了左心室（LV）压力、通过SDE测量的心肌长轴应变以及通过声测法测量的节段长度。主动收缩被定义为与相似节段长度下完全松弛的心室相比，收缩期后缩短期间左心室压力（LVP）和应力升高。LAD狭窄使收缩期缩短从10.4±1.2%降至5.9±0.9%（P<0.05），而收缩期后缩短从1.1±0.3%增至4.2±0.7%（P<0.05）。在运动减弱和运动消失节段，左心室压力-节段长度和左心室应力-节段长度环分析表明收缩期后缩短是主动的。LAD闭塞导致运动障碍，收缩期后缩短进一步增至8.2±1.0%（P<0.05）。LAD闭塞3至5分钟后，运动障碍节段不再产生主动应力，收缩期后缩短归因于被动回弹。后负荷升高使运动减弱节段变为运动障碍节段，收缩期后缩短仍部分为主动的。SDE测量的收缩期后缩短与声测法相关性良好（r=0.83，P<0.01）。

结论

收缩期后缩短是缺血心肌的一个相对非特异性特征，可能通过完全被动机制出现在运动障碍节段。然而，在收缩期运动减弱或运动消失节段，收缩期后缩短是心肌主动收缩的一个标志物。SDE能够量化收缩期后缩短，可能代表一种识别心肌主动收缩从而存活心肌的临床方法。

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缺血心肌的收缩后期缩短：主动收缩还是被动回弹？

Postsystolic shortening in ischemic myocardium: active contraction or passive recoil?

作者信息

机构信息

出版信息

BACKGROUND

METHODS AND RESULTS

CONCLUSIONS

背景

方法与结果

结论

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