Several mathematical descriptions of heat transport in perfused tissues have been proposed but have not been thoroughly tested under conditions of time-varying temperatures. Data was obtained by measuring the response of brain temperature to step changes in temperature of chronically implanted thermodes in conscious baboons. These responses were compared to numerical solutions of an equation expressing heat transport in terms of conduction in the tissue and convection due to capillary blood flow. Good agreement between experimental and theoretical curves was obtained for values of k (thermal diffusivity) of 0.0017-0.0021 cm2/sec and ø (blood flow per unit volume of tissue) of 0.3-0.7 cm3/cm3-min. The predicted temperature response at a given tissue location was not greatly affected either by changes in k and ø over the physiological range, or by small errors in describing experimental geometry. However, inaccuracies in describing boundary locations or failing to account for the relatively avascular scar tissue around the thermode changed the value of ø needed to fit the data by as much as 50%. Thus, we conclude that the model described in this paper can be used for a description of thermal gradients surrounding a thermode but extreme caution should be exercised if such a model is used to quantitatively evaluate blood flow.
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机译:已经提出了几种在灌注组织中热传递的数学描述,但是在时变温度条件下尚未进行彻底的测试。通过测量大脑温度对有意识的狒狒中长期植入的温度计的温度变化的响应获得数据。将这些响应与方程式的数值解进行比较,该方程式根据组织中的传导和由于毛细血管血流的对流来表达热传输。 k(热扩散率)为0.0017-0.0021 cm 2 / sec和ø(单位体积组织血流量)为0.3-0.7 cm 3 / cm 3 -min。在给定组织位置的预测温度响应不受在生理范围内k和ø的变化或描述实验几何形状的小误差的影响很大。但是,描述边界位置的不准确或无法解释热熔体周围相对无血管的疤痕组织,使拟合数据所需的ø值改变了多达50%。因此,我们得出的结论是,本文中描述的模型可用于描述热电极周围的温度梯度,但是如果使用这种模型定量评估血流,则应格外小心。
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