Okada K, Yamashita C, Okada M, Okada M
Department of Surgery, Kobe University School of Medicine, Japan.
J Heart Lung Transplant. 1996 May;15(5):475-84.
The University of Wisconsin solution has been proven to be effective for prolonged heart preservation. However, 24-hour heart preservation by simple cold immersion in University of Wisconsin solution has been disappointing. We have performed hypothermic low-pressure continuous coronary perfusion with oxygenated University of Wisconsin solution for experimental prolonged heart preservation. However, the high potassium concentration of University of Wisconsin solution combined with prolonged ischemia has detrimental effects on endothelial function, which increases coronary tone during preservation and after reperfusion. The severe vasoconstriction and tissue edema result in damage to the coronary microcirculation. The purpose of this study was to determine whether hypothermic low-pressure continuous coronary perfusion technique with oxygenated University of Wisconsin solution containing a selective endothelin-A receptor antagonist (FR139317) would increase the effectiveness of the perfusion technique and improve postischemic cardiac function, both minimizing tissue edema and suppressing vasoconstriction.
Preischemic and postischemic cardiac function of isolated rabbit hearts was evaluated with a Langendorff apparatus. The hearts were divided into three groups (n = 7 each): group I (hypothermic low-pressure continuous coronary perfusion with University of Wisconsin solution), group II (hypothermic low-pressure continuous coronary perfusion with oxygenated University of Wisconsin solution), and group III (hypothermic low-pressure continuous coronary perfusion with oxygenated University of Wisconsin solution containing 10 mg/L of FR139317). Preservation was performed for 24 hours. The initial perfusion pressure for continuous coronary perfusion was set at 5 mm Hg. Measurement of percentage of tissue water content and ultrastructural examination of the myocardium was then performed. In groups I, II, and III, the perfusion pressures at the end of the 24-hour preservation period increased from 5 mm Hg to 12.2 +/- 2.5, 8.1 +/- 1.3, and 5.4 +/- 0.8 mm Hg (p < 0.05), respectively. Percent recovery rate of cardiac output was 56.6 +/- 2.8, 82.3 +/- 8.2, and 93.3 +/- 6.0 (p < 0.05), respectively. And percent recovery rate of coronary flow was 55.5 +/- 8.1, 80.0 +/- 8.0, and 94.3 +/- 9.4 (p < 0.05), respectively. A significant inverse correlation was found between continuous coronary perfusion pressure at the end of preservation and the recovery rate of cardiac output (r = 0.85, p < 0.05). Tissue water content was significantly higher in group I than in groups II and III. These effects were inhibited by oxygenation of the University of Wisconsin solution (group II) and by the addition of the selective endothelin-A receptor antagonist (FR139317) (group III). Damage to coronary circulation was reduced by oxygenation and the addition of endothelin-A receptor antagonist during prolonged heart preservation.
We concluded that hypothermic low-pressure continuous coronary perfusion technique with oxygenated UW solution containing endothelin-A receptor antagonist (FR139317) maintained coronary circulation by suppressing tissue edema and vasoconstriction during preservation, which improved postischemic functional recovery.
威斯康星大学溶液已被证明对延长心脏保存有效。然而,单纯将心脏在威斯康星大学溶液中冷浸保存24小时的效果并不理想。我们进行了用氧合威斯康星大学溶液进行低温低压连续冠状动脉灌注以进行实验性延长心脏保存。然而,威斯康星大学溶液的高钾浓度与长时间缺血相结合对内皮功能有不利影响,这会在保存期间和再灌注后增加冠状动脉张力。严重的血管收缩和组织水肿会导致冠状动脉微循环受损。本研究的目的是确定用含有选择性内皮素-A受体拮抗剂(FR139317)的氧合威斯康星大学溶液进行低温低压连续冠状动脉灌注技术是否会提高灌注技术的有效性并改善缺血后心脏功能,同时最小化组织水肿并抑制血管收缩。
用Langendorff装置评估离体兔心脏缺血前和缺血后的心脏功能状态。心脏被分为三组(每组n = 7):第一组(用威斯康星大学溶液进行低温低压连续冠状动脉灌注),第二组(用氧合威斯康星大学溶液进行低温低压连续冠状动脉灌注),第三组(用含有10 mg/L FR139317的氧合威斯康星大学溶液进行低温低压连续冠状动脉灌注)。保存24小时。连续冠状动脉灌注的初始灌注压力设定为5 mmHg。然后进行组织含水量百分比的测量和心肌的超微结构检查。在第一组、第二组和第三组中,24小时保存期结束时的灌注压力分别从5 mmHg增加到12.2±2.5、8.1±1.3和5.4±0.8 mmHg(p < 0.05)。心输出量的恢复率百分比分别为56.6±2.8、82.3±8.2和93.3±6.0(p < 0.05)。冠状动脉血流的恢复率百分比分别为55.5±8.1、80.0±8.0和94.3±9.4(p < 0.05)。在保存结束时连续冠状动脉灌注压力与心输出量恢复率之间发现显著的负相关(r = 0.85,p < 0.05)。第一组的组织含水量明显高于第二组和第三组。这些影响通过威斯康星大学溶液的氧合作用(第二组)和添加选择性内皮素-A受体拮抗剂(FR139317)(第三组)得到抑制。在延长心脏保存期间,通过氧合作用和添加内皮素-A受体拮抗剂减少了冠状动脉循环的损伤。
我们得出结论,用含有内皮素-A受体拮抗剂(FR139317)的氧合UW溶液进行低温低压连续冠状动脉灌注技术通过在保存期间抑制组织水肿和血管收缩来维持冠状动脉循环,从而改善缺血后功能恢复。
