IK1上调在人类心房颤动相关动作电位缩短中的作用。
Role of up-regulation of IK1 in action potential shortening associated with atrial fibrillation in humans.
作者信息
Zhang Henggui, Garratt Clifford J, Zhu Jiujiang, Holden Arun V
机构信息
Biological Physics Group, School of Physics and Astronomy, The University of Manchester, UK.
出版信息
Cardiovasc Res. 2005 Jun 1;66(3):493-502. doi: 10.1016/j.cardiores.2005.01.020. Epub 2005 Feb 24.
OBJECTIVES
Although previous studies in dogs have indicated a minimal role for changes in I(K1) in the shortening of action potential duration (APD) associated with atrial fibrillation (AF), in humans, there is evidence for significant AF-induced up-regulation of this current. In this computer model study, we investigated the relative contributions of the remodeling of I(K1), L-type calcium current, and other remodeled ionic channel currents to AF-induced APD reduction in human atrium.
METHODS
Two computer models of electrical activity of human atrial cell were modified by incorporating experimental data of AF-induced changes in human atrial ionic channel conductance and kinetics reported by Bosch et al. (I(CaL), I(to), I(K1), and I(Na)) (AF-1) and Workman et al. (I(CaL), I(to), and I(K1)) (AF-2). The roles and relative importance of individually remodeled ion channels in the APD reduction in human atrium were evaluated by the removal and exclusive methods, in which remodeling of specific currents was omitted, or considered in isolation, in the two models.
RESULTS
When tested together, previously reported AF-induced changes in sarcolemmal ion currents result in marked shortening of atrial APD(90). With the AF-1 remodeled parameters, there is a 62% reduction in APD(90) for the Nygren et al. model, and a 68% reduction for the Courtemanche et al. model, which are comparable to experimental results of 60% reduction seen in humans. When tested individually, AF-1-induced changes in I(CaL), I(K1), or I(to) alone result in APD(90) reduction of 20%, 64%, and -10%, respectively, for the Nygren et al. model, and 27%, 40%, and 11.6%, respectively, for the Courtemanche et al. model. With the AF-2 remodeled parameters, there is a 47% reduction in APD(90) for the Nygren et al. model and a 49% reduction for the Courtemanche et al. model, which are also comparable to experimental results of 45% reduction. When tested individually, AF-2-induced changes in I(CaL) or I(K1) alone result in APD(90) reduction of 20% and 40%, respectively, for the Nygren et al. model, and 14% and 21%, respectively, for the Courtemanche et al. model.
CONCLUSION
Previously reported changes in L-type Ca(2+) current are insufficient to account for the observed reduction in atrial APD associated with persistent AF. Up-regulation of I(K1) has a greater influence on atrial APD in the human model.
目的
尽管之前在犬类中的研究表明,内向整流钾电流(I(K1))的变化在与心房颤动(AF)相关的动作电位时程(APD)缩短中作用极小,但在人类中,有证据表明AF可导致该电流显著上调。在这项计算机模型研究中,我们调查了I(K1)重塑、L型钙电流以及其他重塑离子通道电流对AF诱导的人类心房APD缩短的相对贡献。
方法
通过纳入Bosch等人(I(CaL)、I(to)、I(K1)和I(Na))(AF - 1)以及Workman等人(I(CaL)、I(to)和I(K1))(AF - 2)报道的AF诱导的人类心房离子通道电导和动力学变化的实验数据,对两个人类心房细胞电活动的计算机模型进行了修改。通过去除和单独考虑的方法评估了各个重塑离子通道在人类心房APD缩短中的作用和相对重要性,即在两个模型中分别省略特定电流的重塑或单独考虑特定电流的重塑。
结果
当一起测试时,先前报道的AF诱导的肌膜离子电流变化导致心房APD(90)显著缩短。对于Nygren等人的模型,采用AF - 1重塑参数时,APD(90)降低62%;对于Courtemanche等人的模型,降低68%,这与人类实验中60%的降低结果相当。单独测试时,对于Nygren等人的模型,AF - 1诱导的I(CaL)、I(K1)或I(to)单独变化分别导致APD(90)降低20%、64%和 - 10%;对于Courtemanche等人的模型,分别降低27%、40%和11.6%。对于Nygren等人的模型,采用AF - 2重塑参数时,APD(90)降低47%;对于Courtemanche等人的模型,降低49%,这也与45%的实验降低结果相当。单独测试时,对于Nygren等人的模型,AF - 2诱导的I(CaL)或I(K1)单独变化分别导致APD(90)降低20%和40%;对于Courtemanche等人的模型,分别降低14%和21%。
结论
先前报道的L型Ca(2+)电流变化不足以解释与持续性AF相关的观察到的心房APD降低。I(K1)的上调对人类模型中的心房APD有更大影响。
Zotero 插件