Fredberg J J, Bunk D, Ingenito E, Shore S A
Harvard School of Public Health, Boston, Massachusetts 02115.
J Appl Physiol (1985). 1993 Mar;74(3):1387-97. doi: 10.1152/jappl.1993.74.3.1387.
When challenged with a contractile agonist in increasing graded concentrations, lung parenchymal tissue assumes a sequence of mechanical states. That sequence is mapped here. Isolated lung parenchymal strips from male Hartley guinea pigs were mounted in a bath containing Krebs solution at 37 degrees C, aerated with 95% O2-5% CO2. One end was attached to a force transducer and the other to a servo-controlled lever arm. After stress adaptation, sinusoidal length oscillations (1% strain at 0.31 Hz) yielded force-length loops from which we computed induced changes in active tension (F), tissue stiffness (E), and hysteresivity (eta) (J. J. Fredberg and D. Stamenović. J. Appl. Physiol. 67:2408-2419, 1989). Changes of tissue resistance (R) were, by definition, governed by those of eta and E. Histamine (10(-6) -10(-3) M), prostaglandin D2 (10(-5) -10(-4) M), and prostaglandin F2 alpha (10(-5) -10(-4) M) caused dose-related increases of F, eta, and E. Plotting induced changes of E vs. those of F revealed a unique relationship that was identical for these as well as a wider panel of contractile agonists; changes of E and F were closely associated. However, plotting induced changes of E vs. those of eta revealed relationships that differed distinctly between agonists; changes of eta were dissociated from those of F and E. This latter observation demonstrated the existence of distinct mechanical states that differed according to the specific agonist by which the tissue was stimulated. In producing agonist-induced changes in R, changes of E were of equal or greater importance compared with those of eta. We conclude that guinea pig lung parenchyma, viewed as an integrated physiological tissue system, exhibits different kinds as well as varying intensities of mechanical response according to the specific agonist present in the cellular microenvironment. These differences in contractile state reveal themselves principally in the hysteretic nature of the tissue.
当用浓度递增的收缩性激动剂进行刺激时,肺实质组织会呈现出一系列机械状态。在此描绘了该序列。从雄性哈特利豚鼠分离出的肺实质条带置于盛有37℃ Krebs溶液的浴槽中,用95% O₂ - 5% CO₂ 通气。一端连接到力传感器,另一端连接到伺服控制的杠杆臂。在应力适应后,正弦长度振荡(0.31 Hz时1%应变)产生力 - 长度环,从中我们计算出主动张力(F)、组织硬度(E)和滞后性(η)的诱导变化(J. J. Fredberg和D. Stamenović。《应用生理学杂志》67:2408 - 2419, 1989)。根据定义,组织阻力(R)的变化受η和E变化的支配。组胺(10⁻⁶ - 10⁻³ M)、前列腺素D₂(10⁻⁵ - 10⁻⁴ M)和前列腺素F₂α(10⁻⁵ - 10⁻⁴ M)引起F、η和E的剂量相关增加。绘制E的诱导变化与F的诱导变化的关系图,揭示了一种独特的关系,对于这些以及更广泛的收缩性激动剂面板来说都是相同的;E和F的变化密切相关。然而,绘制E的诱导变化与η的诱导变化的关系图,揭示了激动剂之间明显不同的关系;η的变化与F和E的变化相分离。后一观察结果表明存在根据刺激组织的特定激动剂而不同的独特机械状态。在产生激动剂诱导的R变化时,与η的变化相比,E的变化具有同等或更大的重要性。我们得出结论,豚鼠肺实质作为一个整合的生理组织系统,根据细胞微环境中存在的特定激动剂,表现出不同类型以及不同强度的机械反应。这些收缩状态的差异主要体现在组织的滞后性质上。
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