Mintun M A, Lundstrom B N, Snyder A Z, Vlassenko A G, Shulman G L, Raichle M E
Mallinckrodt Institute of Radiology, Washington University School of Medicine, St. Louis, MO 63110, USA.
Proc Natl Acad Sci U S A. 2001 Jun 5;98(12):6859-64. doi: 10.1073/pnas.111164398. Epub 2001 May 29.
Coupling of cerebral blood flow (CBF) and cerebral metabolic rate for oxygen (CMRO(2)) in physiologically activated brain states remains the subject of debates. Recently it was suggested that CBF is tightly coupled to oxidative metabolism in a nonlinear fashion. As part of this hypothesis, mathematical models of oxygen delivery to the brain have been described in which disproportionately large increases in CBF are necessary to sustain even small increases in CMRO(2) during activation. We have explored the coupling of CBF and oxygen delivery by using two complementary methods. First, a more complex mathematical model was tested that differs from those recently described in that no assumptions were made regarding tissue oxygen level. Second, [(15)O] water CBF positron emission tomography (PET) studies in nine healthy subjects were conducted during states of visual activation and hypoxia to examine the relationship of CBF and oxygen delivery. In contrast to previous reports, our model showed adequate tissue levels of oxygen could be maintained without the need for increased CBF or oxygen delivery. Similarly, the PET studies demonstrated that the regional increase in CBF during visual activation was not affected by hypoxia. These findings strongly indicate that the increase in CBF associated with physiological activation is regulated by factors other than local requirements in oxygen.
在生理激活的脑状态下,脑血流量(CBF)与脑氧代谢率(CMRO₂)之间的耦合关系仍是一个有争议的话题。最近有人提出,CBF与氧化代谢以非线性方式紧密耦合。作为这一假设的一部分,已经描述了向大脑输送氧气的数学模型,其中在激活过程中,即使CMRO₂有很小的增加,也需要CBF有不成比例的大幅增加才能维持。我们使用两种互补的方法探讨了CBF与氧气输送之间的耦合关系。首先,测试了一个更复杂的数学模型,该模型与最近描述的模型不同,因为它没有对组织氧水平做出任何假设。其次,在9名健康受试者处于视觉激活和缺氧状态期间,进行了[¹⁵O]水CBF正电子发射断层扫描(PET)研究,以检查CBF与氧气输送之间的关系。与之前的报告相反,我们的模型表明,无需增加CBF或氧气输送就能维持足够的组织氧水平。同样,PET研究表明,视觉激活期间CBF的区域增加不受缺氧影响。这些发现有力地表明,与生理激活相关的CBF增加是由局部氧需求以外的因素调节的。