在动脉血流条件下，通过纤溶药物对壁血小板沉积物溶解情况的实时测量。

Graham D A, Huang T C, Keyt B A, Alevriadou B R

Department of Biomedical Engineering, Vascular Bioengineering Laboratory, The Johns Hopkins School of Medicine, Baltimore, MD 21205, USA.

Ann Biomed Eng. 1998 Jul-Aug;26(4):712-24. doi: 10.1114/1.46.

An in vitro whole blood reperfusion model was employed to quantify: (a) initial rates of lysis of mural platelet deposits from flowing blood onto fibrin-coated surfaces and (b) plasmin-mediated consumption of plasma plasminogen and fibrinogen, by recombinant tissue-type plasminogen activator (rt-PA) and two t-PA variants, KHRR 296-299 AAAA (K-tPA) and T103N, N117Q, KHRR 296-299 AAAA (TNK-tPA), at wall shear rates of either 500 or 1000 s(-1). K- and TNK-tPA are more fibrin-specific than rt-PA, and are also resistant to inactivation by plasminogen activator inhibitor-1 (PAI-1). At 500 s(-1), no agent showed significant lysis of mural platelet deposits on fibrin, even at concentrations as high as 10 microg/ml of blood. At 1000 s(-1), each agent demonstrated a dose-dependent lysis of mural platelet deposits, due to plasmin-mediated lysis of the fibrin substrate (fibrinolysis). The local concentration of thrombolytic agents close to the fibrin-coated surface is probably higher than the concentration of released PAI-1 from the adherent and activated platelets. Hence, the initial rates of lysis achieved by K- and TNK-tPA were not significantly different from that by rt-PA, when each agent was tested at either 1 or 10 microg/ml of blood. However, TNK-tPA, at 1 microg/ml, caused the most extensive lysis at the end of the 50 min reperfusion period (50% vs 29% and 17% by rt-PA and K-tPA, respectively). K- and TNK-tPA, at concentrations as high as 10 microg/ml of blood, caused plasminogen activation that was controlled by the natural plasmin inhibitors, and, thus, no proteolytic degradation of plasma fibrinogen (fibrinogenolysis). On the contrary, rt-PA at 1 microg/ml revealed slight fibrinogenolysis that became extensive at 10 microg/ml. This study demonstrates the potential use of an in vitro model, that mimics the in vivo hemodynamic environment, in evaluating the performance of thrombolytic agents. The data suggest that: (a) adequate flow must accompany fibrinolysis for successful embolization, and (b) the TNK variant may lyse annular thrombi after recanalization, at least as efficiently as rt-PA does, while causing lesser defect of systemic hemostasis.

采用体外全血再灌注模型来量化

(a) 流动血液中壁面血小板沉积物在纤维蛋白包被表面上的初始溶解速率，以及 (b) 重组组织型纤溶酶原激活剂 (rt-PA) 和两种 t-PA 变体 KHRR 296 - 299 AAAA (K-tPA) 和 T103N、N117Q、KHRR 296 - 299 AAAA (TNK-tPA) 在壁面剪切速率为 500 或 1000 s(-1) 时，纤溶酶介导的血浆纤溶酶原和纤维蛋白原的消耗。K-tPA 和 TNK-tPA 比 rt-PA 对纤维蛋白更具特异性，并且对纤溶酶原激活剂抑制剂 -1 (PAI-1) 的失活具有抗性。在 500 s(-1) 时，即使在血液浓度高达 10 μg/ml 的情况下，没有一种药物能使纤维蛋白上的壁面血小板沉积物发生显著溶解。在 1000 s(-1) 时，由于纤溶酶介导的纤维蛋白底物溶解（纤维蛋白溶解），每种药物都表现出壁面血小板沉积物的剂量依赖性溶解。靠近纤维蛋白包被表面的溶栓剂局部浓度可能高于黏附并活化的血小板释放的 PAI-1 浓度。因此，当每种药物在血液浓度为 1 μg/ml 或 10 μg/ml 下进行测试时，K-tPA 和 TNK-tPA 实现的初始溶解速率与 rt-PA 的初始溶解速率没有显著差异。然而，在 50 分钟再灌注期结束时，1 μg/ml 的 TNK-tPA 引起的溶解最为广泛（rt-PA 和 K-tPA 分别为 29% 和 17%，而 TNK-tPA 为 50%）。在血液浓度高达 10 μg/ml 的情况下，K-tPA 和 TNK-tPA 引起的纤溶酶原激活由天然纤溶酶抑制剂控制，因此，血浆纤维蛋白原没有蛋白水解降解（纤维蛋白原溶解）。相反，1 μg/ml 的 rt-PA 显示出轻微的纤维蛋白原溶解，在 10 μg/ml 时变得广泛。本研究证明了一种体外模型在评估溶栓剂性能方面的潜在用途，该模型模拟了体内血液动力学环境。数据表明：(a) 成功的血栓溶解必须伴随足够的血流进行纤维蛋白溶解，以及 (b) TNK 变体在再通后可能溶解环形血栓，至少与 rt-PA 一样有效，同时引起的全身止血缺陷较小。