Suzuki M, Sudoh M, Matsubara S, Kawakami K, Shiota M, Ikawa S
Department of Laboratory Medicine, Jikei University School of Medicine, Tokyo, Japan.
Eur J Appl Physiol Occup Physiol. 1996;74(1-2):1-7. doi: 10.1007/BF00376487.
We measured renal blood flow (RBF) repeatedly in six male volunteers following exhausting cycling exercise using radionuclide angiography (RA) with technetium 99 m phytate (99 mTc-phytate), which is a nondiffusible radio-active tracer for kidney imaging and which is taken up quickly by the liver after injection into the circulation. The relationships between changes in RBF and creatinine clearance (Ccr), urine volume (UV) and plasma hormone involved in the regulation of renal function were also investigated. A bolus of 99 mTc-phytate (92.5 MBq.ml-1) was injected into the brachial vein via a catheter, while each subject was maintained in a supine position with his back to a scinticamera, which was connected to a computer for data processing. The pool transit time (PTT) was calculated from the time-concentration flow curve in the left kidney following injection of the bolus. The PTT normalized by the PTT of the heart (PTTn: kidney PTT/heart PTT), and the change in the reciprocal of PTTn (1/PTTn) were used as indices of the change in RBF. The resting RBF was also measured simultaneously by both RA and the para-aminohippuric acid (PAH) clearance method (CPAH). Post-exercise RBF was measured only by RA within 60 s of exercise, then again within 30 and 60 min of exercise on different days, since RBF can be measured successively only three times even with the use of 99 mTc-phytate. The resting value of 1/PTTn was converted to the value of CPAH corrected for haematocrit, and post-exercise change of 1/PTTn (RBF) was represented as a change in the value of CPAH in order to express a definite numerical change, rather than a percentage change, from resting RBF. The RBF decreased by 53.4% immediately after exercise, and remained decreased by 17.5% 30 min after and by 21.1% 60 min after exercise in comparison with the resting value. The RBF was found to be correlated with changes in Ccr (r = 0.773, P < 0.001), UV (r = 0.598, P < 0.001), and the concentrations of plasma angiotensin II (r = -0.686, P < 0.001) and noradrenaline (r = 0.652, P < 0.001) after exercise. However, there were no significant correlations between the changes in plasma aldosterone ([Ald]) and plasma noradrenaline, or in [Ald]p1 and plasma angiotensin II concentrations. The change in [Ald]p1 did not coincide with the variation in reabsorption of Na+ in the renal tubules. Results of the present study showed that change in Ccr after exhausting exercise depended mainly on change in RBF and that changes in UV and osmolality after exhausting exercise were induced not only by change in RBF, but also by changes in reabsorption of water and solutes in the renal tubules. It is suggested that changes in reabsorption of water and solutes might be influenced by metabolites induced by exercise and an increased release of hormones, other than aldosterone, involved in the regulation of renal function.
我们使用锝99m植酸盐(99mTc - 植酸盐)通过放射性核素血管造影术(RA)对6名男性志愿者在进行力竭性自行车运动后反复测量肾血流量(RBF)。99mTc - 植酸盐是一种用于肾脏成像的非扩散性放射性示踪剂,注入循环后会迅速被肝脏摄取。我们还研究了RBF变化与肌酐清除率(Ccr)、尿量(UV)以及参与肾功能调节的血浆激素之间的关系。通过导管将一剂99mTc - 植酸盐(92.5 MBq·ml-1)注入肱静脉,同时让每个受试者保持仰卧位,背部朝向与计算机相连用于数据处理的闪烁相机。根据注入造影剂后左肾的时间 - 浓度流量曲线计算血池通过时间(PTT)。将PTT通过心脏的PTT进行归一化处理(PTTn:肾脏PTT/心脏PTT),并将PTTn的倒数变化(1/PTTn)用作RBF变化的指标。静息RBF还同时通过RA和对氨基马尿酸(PAH)清除率法(CPAH)进行测量。运动后RBF仅在运动后60秒内通过RA测量,然后在不同日期的运动后30分钟和60分钟再次测量,因为即使使用99mTc - 植酸盐,RBF也只能连续测量三次。将静息时的1/PTTn值转换为校正血细胞比容后的CPAH值,运动后1/PTTn(RBF)的变化表示为CPAH值的变化,以便从静息RBF表达明确的数值变化,而非百分比变化。与静息值相比,运动后RBF立即下降53.4%,运动后30分钟仍下降17.5%,运动后60分钟下降21.1%。发现运动后RBF与Ccr变化(r = 0.773,P < 0.001)、UV变化(r = 0.598,P < 0.001)以及血浆血管紧张素II浓度(r = -0.686,P < 0.001)和去甲肾上腺素浓度(r = 0.652,P < 0.001)相关。然而,血浆醛固酮([Ald])与血浆去甲肾上腺素的变化之间,或[Ald]p1与血浆血管紧张素II浓度之间无显著相关性。[Ald]p1的变化与肾小管中Na+重吸收的变化不一致。本研究结果表明,力竭运动后Ccr的变化主要取决于RBF的变化,力竭运动后UV和渗透压的变化不仅由RBF的变化引起,还由肾小管中水和溶质重吸收的变化引起。提示水和溶质重吸收的变化可能受运动诱导的代谢产物以及参与肾功能调节的除醛固酮外的激素释放增加的影响。
