体外培养的大鼠颈动脉体中缺氧诱导儿茶酚胺释放的发育变化。
Developmental changes in hypoxia-induced catecholamine release from rat carotid body, in vitro.
作者信息
Donnelly D F, Doyle T P
机构信息
Department of Pediatrics, Yale University School of Medicine, New Haven, CT 06510.
出版信息
J Physiol. 1994 Mar 1;475(2):267-75. doi: 10.1113/jphysiol.1994.sp020067.
Abstract
- Developmental changes in free tissue catecholamine levels were studied using Nafion-coated, carbon fibre electrodes placed in rat carotid bodies, in vitro. Simultaneously, single fibre chemoreceptor afferent activity was recorded from the sinus nerve. Five age groups were examined: 1, 2, 6, 10 and 20-30 days of age. 2. Using fast-scan voltammetry, similar current peaks were observed during exposure to exogenous dopamine and during superfusion with hypoxic saline. This suggests that changes in carbon fibre electrode current are due to an increase in free tissue catecholamines. 3. Baseline catecholamine levels were significantly less in the 1-6 day age groups compared to 10 day and 20-30 day rats. 4. During 1 min of hypoxia the peak concentration of tissue catecholamine was significantly less in the 1 day compared to the 2 day age groups, and these were less than in 10 day and 20-30 day rats. 5. Peak nerve response during hypoxia increased with age from 4.5 +/- 0.6 Hz in the 1 day to 10.5 +/- 1.6 Hz in the 6 day and to 15.5 +/- 2.2 Hz in the 20-30 day rats. 6. We conclude that (1) resting free tissue catecholamine levels increase with age in the newborn period, (2) hypoxia causes enhanced catecholamine release, and (3) the magnitude of the release increases in the postnatal period as does the nerve activity.
摘要
- 使用置于大鼠颈动脉体的涂有萘磺化钠的碳纤维电极,在体外研究了游离组织儿茶酚胺水平的发育变化。同时,记录了来自窦神经的单纤维化学感受器传入活动。检查了五个年龄组:1、2、6、10和20 - 30日龄。2. 使用快速扫描伏安法,在暴露于外源性多巴胺期间以及用低氧盐水灌注期间观察到类似的电流峰值。这表明碳纤维电极电流的变化是由于游离组织儿茶酚胺增加所致。3. 与10日龄和20 - 30日龄的大鼠相比,1 - 6日龄组的基线儿茶酚胺水平显著较低。4. 在1分钟的低氧期间,1日龄组的组织儿茶酚胺峰值浓度显著低于2日龄组,且低于10日龄和20 - 30日龄的大鼠。5. 低氧期间的神经反应峰值随年龄增加,从1日龄时的4.5±0.6 Hz增加到6日龄时的10.5±1.6 Hz,再到20 - 30日龄大鼠的15.5±2.2 Hz。6. 我们得出结论:(1) 在新生儿期,静息游离组织儿茶酚胺水平随年龄增加;(2) 低氧导致儿茶酚胺释放增强;(3) 出生后释放量的增加与神经活动的增加一样。
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