Plaza V, Prat J, Rosellò J, Ballester E, Ramis I, Mullol J, Gelpí E, Vives-Corrons J L, Picado C
Servei de Pneumologia, Hospital Clinic, Departament de Medicina, Facultat de Medicina, Barcelona, Spain.
Thorax. 1995 May;50(5):490-6. doi: 10.1136/thx.50.5.490.
An abnormal platelet release of oxygen-free radicals has been described in acetylsalicylic acid (aspirin)-induced asthma, a finding which might suggest the existence of an intrinsic, specific platelet abnormality of arachidonic acid metabolism in these patients. The objective of this study was to evaluate platelet arachidonic acid metabolism in asthmatic patients with or without intolerance to aspirin.
Thirty subjects distributed into three groups were studied: group 1, 10 healthy subjects; group 2, 10 asthmatic patients with aspirin tolerance; and group 3, 10 aspirin-intolerant asthmatics. Platelets were isolated from blood, preincubated with 3H-arachidonic acid for 30 minutes and then incubated for 10 minutes with platelet activating factor (PAF) and aspirin. Cyclo-oxygenase (thromboxane, PGE2, PGF2 alpha, and HHT) and lipoxygenase (12-HETE) arachidonic acid metabolites were measured by high pressure liquid chromatography. Release of oxygen free radicals after incubation with PAF and aspirin was measured by chemiluminescence. Platelet levels of glutathione peroxidase (GSH-Px) were also measured using spectrophotometry.
Platelets from aspirin-intolerant asthmatic patients produced higher quantities of arachidonic acid metabolites than the control group at baseline conditions. This increase was significant only for lipoxygenase products. No differences were found amongst the three groups in the response of arachidonic acid metabolism to PAF and aspirin. Incubation with aspirin but not with PAF caused an increase in oxygen-free radical production in aspirin-intolerant patients whereas in aspirin-tolerant patients PAF, rather than aspirin, was the more potent stimulus for oxygen-free radical production. No differences in GSH-Px levels were found amongst the three groups.
These results suggest that the platelet lipoxygenase pathway is activated in aspirin-intolerant patients and that the production of oxygen-free radicals may differentiate aspirin-tolerant from aspirin-intolerant asthmatic subjects. Our study, however, does not support the hypothesis that an increase in lipoxygenase products may be responsible for oxygen-free radical production. Moreover, a lowered platelet GSH-Px activity does not seem to be involved in this phenomenon.
在阿司匹林诱发的哮喘中已发现血小板释放氧自由基异常,这一发现可能提示这些患者存在花生四烯酸代谢内在的、特异性的血小板异常。本研究的目的是评估有或无阿司匹林不耐受的哮喘患者的血小板花生四烯酸代谢情况。
研究对象分为三组,共30名受试者:第1组,10名健康受试者;第2组,10名对阿司匹林耐受的哮喘患者;第3组,10名阿司匹林不耐受的哮喘患者。从血液中分离血小板,先与3H-花生四烯酸预孵育30分钟,然后与血小板活化因子(PAF)和阿司匹林孵育10分钟。通过高压液相色谱法测定环氧化酶(血栓素、PGE2、PGF2α和HHT)和脂氧化酶(12-HETE)的花生四烯酸代谢产物。通过化学发光法测定与PAF和阿司匹林孵育后氧自由基的释放。还使用分光光度法测定血小板谷胱甘肽过氧化物酶(GSH-Px)水平。
在基线条件下,阿司匹林不耐受的哮喘患者的血小板产生的花生四烯酸代谢产物比对照组多。这种增加仅在脂氧化酶产物方面有统计学意义。三组之间花生四烯酸代谢对PAF和阿司匹林的反应未发现差异。与阿司匹林孵育而非与PAF孵育会导致阿司匹林不耐受患者的氧自由基产生增加,而在阿司匹林耐受患者中,PAF而非阿司匹林是氧自由基产生的更强刺激因素。三组之间GSH-Px水平未发现差异。
这些结果表明,阿司匹林不耐受患者的血小板脂氧化酶途径被激活,氧自由基的产生可能使阿司匹林耐受和不耐受的哮喘患者有所区别。然而,我们的研究不支持脂氧化酶产物增加可能是氧自由基产生原因的假设。此外,血小板GSH-Px活性降低似乎与这一现象无关。
