Bäck Jennie, Lang Markus Huber, Elgue Graciela, Kalbitz Miriam, Sanchez Javier, Ekdahl Kristina Nilsson, Nilsson Bo
Department of Oncology, Radiology, and Clinical Immunology, Division of Clinical Immunology, Rudbeck Laboratory C5, Uppsala University, SE-751 85 Uppsala, Sweden.
Biomaterials. 2009 Dec;30(34):6573-80. doi: 10.1016/j.biomaterials.2009.07.052. Epub 2009 Sep 24.
Activated human plate lets trigger FXII-mediated contact activation, which leads to the generation of FXIIa-antithrombin (AT) and FXIa-AT complexes. This suggests that contact activation takes place at different sites, on activated platelets and material surfaces, during therapeutic procedures involving biomaterials in contact with blood and is differentially regulated. Here we show that activation in platelet-poor plasma, platelet-rich plasma (PRP), and whole blood induced by glass, kaolin, and polyphosphate elicited high levels of FXIIa-C1-inhibitor (C1INH), low levels of FXIa-C1INH and KK-C1INH, and almost no AT complexes. Platelet activation, in both PRP and blood, led to the formation of FXIIa-AT, FXIa-AT, and kallikrein (KK)-AT but almost no C1INH complexes. In severe trauma patients, FXIIa-AT and FXIa-AT were correlated with the release of thrombospondin-1 (TSP-1) from activated platelets. In contrast, FXIIa-C1INH complexes were detected when the FXIIa-AT levels were low. No correlations were found between FXIIa-C1INH and FXIIa-AT or TSP-1. Inhibition of FXIIa on material surfaces was also shown to affect the function of aggregating platelets. In conclusion, formation of FXIIa-AT and FXIIa-C1INH complexes can help to distinguish between contact activation triggered by biomaterial surfaces and by activated platelets. Platelet aggregation studies also demonstrated that platelet function is influenced by material surface-mediated contact activation and that generation of FXIIa-AT complexes may serve as a new biomarker for thrombotic reactions during therapeutic procedures employing biomaterial devices.
活化的人血小板可触发FXII介导的接触激活,进而导致生成FXIIa-抗凝血酶(AT)和FXIa-AT复合物。这表明在涉及生物材料与血液接触的治疗过程中,接触激活发生在不同部位,即活化的血小板和材料表面,且受到不同的调节。在此我们表明,玻璃、高岭土和多聚磷酸盐在乏血小板血浆、富血小板血浆(PRP)和全血中诱导的激活引发了高水平的FXIIa-C1抑制剂(C1INH)、低水平的FXIa-C1INH和激肽释放酶(KK)-C1INH,且几乎没有AT复合物。PRP和血液中的血小板活化均导致FXIIa-AT、FXIa-AT和激肽释放酶(KK)-AT的形成,但几乎没有C1INH复合物。在严重创伤患者中,FXIIa-AT和FXIa-AT与活化血小板中血小板反应蛋白-1(TSP-1)的释放相关。相比之下,当FXIIa-AT水平较低时可检测到FXIIa-C1INH复合物。未发现FXIIa-C1INH与FXIIa-AT或TSP-1之间存在相关性。还表明对材料表面上FXIIa的抑制会影响聚集血小板的功能。总之,FXIIa-AT和FXIIa-C1INH复合物的形成有助于区分生物材料表面和活化血小板引发的接触激活。血小板聚集研究还表明,血小板功能受材料表面介导的接触激活影响,并且FXIIa-AT复合物的生成可能作为使用生物材料装置的治疗过程中血栓形成反应的新生物标志物。
