Jung H
Radiat Res. 1986 Apr;106(1):56-72.
Based on the analysis of many survival curves obtained after hyperthermic treatments of CHO cells at various temperatures, or after consecutive exposure to two different temperatures, a generalized concept has been developed for the action of heat on cell survival. The basic idea of this concept is that cellular inactivation by heat is a two step process. In the first step, heating produces nonlethal lesions. In the second step, the nonlethal lesions are converted into lethal events upon further heating. The conversion of one of the nonlethal lesions in a cell leads to cell death. Based on the assumption that both production and conversion of nonlethal lesions occur at random and depend only on temperature, a mathematical model has been worked out that quantitatively describes cell killing by single heating as well as by step-down or step-up heating. After the cells are heated at a certain temperature for a time t, the surviving fraction is given by the equation S(t) = exp [(p/c) X [1 - c X t - exp(-c X t)]) where p is the rate constant for the production of nonlethal lesions per cell and per unit of time, and c is the rate constant for the conversion of one nonlethal lesion into a lethal event per unit of time. When heating is performed consecutively at two different temperatures; i.e., when a pretreatment at the temperature T1 for the time t1 is followed by a graded exposure to the temperature T for the time t, the surviving fraction is given by the equation S(t1,t) = exp [(p1/c1) X exp(-c X t) X [1 - c1 X t1 X exp (c X t) - exp(-c1 X t1) + (p/c) X [1 - c X t - exp(-c X t)]) where p1 and c1 are the production rate and the conversion rate at the temperature T1 of the pretreatment, and p and c are the corresponding values at the temperature of the second treatment. By fitting the equations given above to the experimental data of many heat survival curves, the values of p and c were determined for the temperature range 39 to 45 degrees C. In this range, the conversion rate c increases exponentially with temperature; the slope corresponds to an activation energy of Ea = 86 +/- 6 kcal/mol. The Arrhenius plot of the production rate p shows an inflection point at 42.5 degrees C. Above that temperature, the activation energy is 185 +/- 14 kcal/mol; below, Ea = 370 +/- 30 kcal/mol was obtained.(ABSTRACT TRUNCATED AT 400 WORDS)
基于对CHO细胞在不同温度下进行热疗后或连续暴露于两种不同温度后获得的多条存活曲线的分析,已形成了一个关于热对细胞存活作用的广义概念。该概念的基本思想是,热导致细胞失活是一个两步过程。第一步,加热产生非致死性损伤。第二步,进一步加热时,非致死性损伤转化为致死性事件。细胞中一个非致死性损伤的转化会导致细胞死亡。基于非致死性损伤的产生和转化均随机发生且仅取决于温度这一假设,已建立了一个数学模型,该模型定量描述了单次加热以及逐步降温或升温加热导致的细胞杀伤情况。细胞在某一温度下加热时间t后,存活分数由方程S(t) = exp [(p/c) × [1 - c × t - exp(-c × t)]]给出,其中p是每个细胞每单位时间产生非致死性损伤的速率常数,c是每单位时间将一个非致死性损伤转化为致死性事件的速率常数。当在两个不同温度下连续加热时;即,在温度T1下预处理时间t1后,再在温度T下分级暴露时间t,存活分数由方程S(t1,t) = exp [(p1/c1) × exp(-c × t) × [1 - c1 × t1 × exp (c × t) - exp(-c1 × t1) + (p/c) × [1 - c × t - exp(-c × t)]]给出,其中p1和c1是预处理温度T1下的产生速率和转化速率,p和c是第二次处理温度下的相应值。通过将上述方程与多条热存活曲线的实验数据拟合,确定了39至45摄氏度温度范围内的p和c值。在此范围内,转化速率c随温度呈指数增加;斜率对应于活化能Ea = 在86 +/- 6千卡/摩尔。产生速率p的阿累尼乌斯图在42.5摄氏度处有一个拐点。高于该温度,活化能为185 +/- 14千卡/摩尔;低于该温度,得到的Ea = 370 +/- 30千卡/摩尔。(摘要截取自400字)
