Schaffartzik W, Barton E D, Poole D C, Tsukimoto K, Hogan M C, Bebout D E, Wagner P D
Department of Medicine, University of California, San Diego, La Jolla 92093-0623.
J Appl Physiol (1985). 1993 Aug;75(2):491-8; discussion 489-90. doi: 10.1152/jappl.1993.75.2.491.
Maximum oxygen uptake (VO2max) is affected by hemoglobin concentration ([Hb]). Whether this is simply due to altered convection of O2 into the muscle microcirculation or also to [Hb]-dependent diffusive transport of O2 out of the muscle capillary is unknown in humans. To examine this, seven healthy volunteers performed four maximal cycle exercise bouts at sea level immediately after 8 wk at altitude (3,801 m, barometric pressure 485 Torr), a sojourn designed to increase [Hb]. The first two bouts were at ambient [Hb] of 15.9 +/- 0.7 g/100 ml breathing 21 or 12% O2 in random order. [Hb] was then decreased to a prealtitude level of 13.8 +/- 0.6 g/100 ml by venesection and isovolemic replacement with 5% albumin in 0.9% saline, and the exercise bouts were repeated. At whole body VO2max, PO2, PCO2, pH, and O2 saturation were measured in radial arterial and femoral venous blood. Femoral venous thermodilution blood flow was determined for calculation of leg VO2. Mean muscle capillary PO2 and muscle diffusing capacity (DO2) were computed by Bohr integration between measured arterial and femoral venous PO2. Averaged over both fractional concentrations of inspired O2, leg VO2 at maximum decreased by 17.7 +/- 4.3% as [Hb] was lowered while leg O2 delivery decreased by 17.5 +/- 2.6% and DO2 decreased by 10.7 +/- 2.7% (all P < 0.05). The relative contributions of decreases in leg O2 delivery and DO2 to the decrease in VO2max were computed to be 64 and 36%, respectively. These findings suggest that [Hb] is an important determinant of O2 diffusion rates into working muscle in humans. Possible mechanisms include 1) dependence of DO2 on intracapillary red blood cell spacing, 2) changes in the total rate of dissociation of O2 from [Hb], and 3) increased red blood cell flow heterogeneity as [Hb] is reduced.
最大摄氧量(VO2max)受血红蛋白浓度([Hb])影响。在人类中,这仅仅是由于进入肌肉微循环的氧气对流改变,还是也由于依赖[Hb]的氧气从肌肉毛细血管扩散运输,目前尚不清楚。为了研究这一问题,7名健康志愿者在海拔(3801米,气压485托)停留8周后立即在海平面进行了4次最大强度的自行车运动试验,此次停留旨在提高[Hb]。前两次试验在环境[Hb]为15.9±0.7克/100毫升的情况下,随机呼吸21%或12%的氧气。然后通过静脉放血和用0.9%盐水中的5%白蛋白进行等容置换,将[Hb]降至海拔前水平13.8±0.6克/100毫升,并重复运动试验。在全身VO2max时,测量桡动脉和股静脉血中的PO2、PCO2、pH和O2饱和度。测定股静脉热稀释血流量以计算腿部VO2。通过测量的动脉和股静脉PO2之间的玻尔积分计算平均肌肉毛细血管PO2和肌肉扩散能力(DO2)。在两种吸入氧气分数浓度下平均,随着[Hb]降低,最大时腿部VO2下降17.7±4.3%,而腿部氧气输送下降17.5±2.6%,DO2下降10.7±2.7%(所有P<0.05)。计算得出腿部氧气输送和DO2下降对VO2max下降的相对贡献分别为64%和36%。这些发现表明[Hb]是人类工作肌肉中氧气扩散速率的重要决定因素。可能的机制包括:1)DO2对毛细血管内红细胞间距的依赖性;2)氧气从[Hb]解离的总速率变化;3)随着[Hb]降低,红细胞血流异质性增加。
