大鼠肺原位液体吸收:肺泡上皮细胞腔面膜中钠进入的途径。
Fluid absorption by rat lung in situ: pathways for sodium entry in the luminal membrane of alveolar epithelium.
作者信息
Basset G, Crone C, Saumon G
机构信息
Département de Physiologie, Université Paris, France.
出版信息
J Physiol. 1987 Mar;384:325-45. doi: 10.1113/jphysiol.1987.sp016457.
Abstract
- The purpose of the investigation was to characterize the luminal membrane and the paracellular pathway of rat lung alveolar epithelium. Experiments were performed on lungs in situ instilled with isotonic, buffered Ringer solution and perfused with blood from a donor rat using cross-circulation technique. 2. The rate of active Na+ transport was 4.4 pmol/(cm2s). The fluid absorption was 156 nl/s, and was unaffected by the presence of protein in the instillate (166 nl/s). In the absence of Na+, fluid absorption was zero. Amiloride (10(-3) M) reduced fluid absorption by 60%. Amiloride, combined with absence of D-glucose, arrested fluid absorption completely. Phloridzin at the luminal side reduced fluid absorption whilst phloretin had no effect. Amiloride together with phloridzin (10(-3) M) also arrested absorption. Thus, there are two entry systems for Na+ in the luminal membrane: Na+ channels and a Na+-D-glucose symport. These results show that alveolar fluid absorption is due to cellular activity. 3. Substitution of Cl- with gluconate not only stopped fluid absorption, but led to slight reversal of net fluid movement. 4. Passive unidirectional flux of Na+, determined with 22Na+, was 9.9 pmol/(cm2s) and that of Cl-, determined with 36Cl-, was 12.4 pmol/(cm2s). These fluxes were based on an assumed alveolar surface area of 5000 cm2. Transference numbers calculated from these figures are close to those in free solution, suggesting a neutral or weakly charged intercellular junctional pathway. The D-mannitol permeability in the paracellular pathway was 1.7 X 10(-8) cm/s. 5. It is a consequence of the proposed mechanism for fluid absorption that it becomes inoperative if the normally high reflexion coefficients for Na+ and Cl- are lowered in pathological states. In such conditions pulmonary oedema may develop depending on the net balance of passive mechanical and colloid-osmotic forces. 6. An explanation of the reversal of fluid transport at the time of birth is presented.
摘要
- 本研究的目的是对大鼠肺泡上皮的管腔膜和细胞旁途径进行表征。实验在原位肺上进行,向肺内注入等渗、缓冲的林格氏溶液,并使用交叉循环技术用供体大鼠的血液进行灌注。2. 钠主动转运速率为4.4皮摩尔/(平方厘米·秒)。液体吸收量为156纳升/秒,且不受注入液中蛋白质存在的影响(166纳升/秒)。在无钠的情况下,液体吸收量为零。氨氯地平(10⁻³摩尔)使液体吸收量降低60%。氨氯地平与右旋葡萄糖缺失共同作用时,完全阻止了液体吸收。管腔侧的根皮苷降低了液体吸收,而根皮素则没有作用。氨氯地平与根皮苷(10⁻³摩尔)共同作用也阻止了吸收。因此,管腔膜中存在两种钠进入系统:钠通道和钠 - 右旋葡萄糖共转运体。这些结果表明肺泡液体吸收是由于细胞活动。3. 用葡萄糖酸盐替代氯离子不仅停止了液体吸收,还导致净液体移动略有逆转。4. 用²²Na⁺测定的钠被动单向通量为9.9皮摩尔/(平方厘米·秒),用³⁶Cl⁻测定的氯被动单向通量为12.4皮摩尔/(平方厘米·秒)。这些通量基于假定的5000平方厘米的肺泡表面积。根据这些数据计算出的迁移数与自由溶液中的迁移数接近,表明细胞间连接途径呈中性或弱带电。细胞旁途径中D - 甘露醇的渗透率为1.7×10⁻⁸厘米/秒。5. 所提出的液体吸收机制的一个结果是,如果在病理状态下钠和氯通常较高的反射系数降低,该机制将失效。在这种情况下,根据被动机械力和胶体渗透力的净平衡,可能会发生肺水肿。6. 本文提出了对出生时液体转运逆转的一种解释。
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