Rendell M S, Kelly S T, Bamisedun O, Luu T, Finney D A, Knox S
Creighton Diabetes Center, Omaha, NE 68131.
Clin Physiol. 1993 May;13(3):235-45. doi: 10.1111/j.1475-097x.1993.tb00323.x.
Using laser Doppler techniques in nine healthy volunteers, we contrasted the effect of increasing local skin temperature at the elbow, a skin site with nutritive microvasculature, and the finger pulp, with predominantly arteriovenous anastomic (AVA) perfusion). We also assessed flow at the finger dorsum, with contributions of both types of microvasculature. In parallel with the laser Doppler studies, we determined the effect of increasing temperature on the red cell deformability of our subjects, using the new technique of Cell Transit Time Analysis (CTTA). Thermal stimulation produced very large increases in skin blood flow at all three sites tested. However, the magnitude and the pattern of increase were different at the three sites. At the finger pulp, there was a linear approximately threefold increase in flow as temperature increased from the basal level to 44 degrees C. At the elbow, basal flow was considerably lower than at the finger pulp and increased very slowly until skin temperature reached 38 degrees C. From that point, flow increased sharply, reaching tenfold the basal level at 44 degrees C. The thermally induced increase at the finger dorsum was intermediate between the other two sites, with a pattern resembling the elbow more than the finger pulp. These differences among the sites were attributable to substantially different patterns of change in the two components of flow, microvascular volume and velocity. At the finger pulp, there was very little increase in microvascular volume with increasing temperature. The curve was practically flat from basal temperature to 44 degrees C. In contrast, there was a linear increase in red blood cell velocity of about 300%. At the elbow, both microvascular volume and red blood cell velocity exhibited a parallel curvilinear pattern of equivalent increase, on the order of 300% for each. There was only a small increase in both parameters until the temperature reached 38 degrees, at which point there was a sharp increase in both. At the finger dorsum, the situation was intermediate, again resembling the elbow more than the finger pulp. Cell Transit Time Analysis revealed a progressive decrease in red cell transit time (TT), from 3.28 ms at 28 degrees C to 2.48 m at 44 degrees C, an overall change of 24%. The decrease in TT was accompanied by an increase in transit frequency, measured as counts s-1 (C s-1), from 3.1 to 5.3, an overall change of 71%. The changes in both TT and C/S were essentially linear.(ABSTRACT TRUNCATED AT 400 WORDS)
在9名健康志愿者身上使用激光多普勒技术,我们对比了提高肘部(一个具有营养性微脉管系统的皮肤部位)和指尖(主要是动静脉吻合支灌注)局部皮肤温度的效果。我们还评估了手指背部的血流情况,该部位两种类型的微脉管系统都有贡献。在进行激光多普勒研究的同时,我们使用细胞通过时间分析(CTTA)新技术,测定了温度升高对受试者红细胞变形能力的影响。热刺激使所有三个测试部位的皮肤血流量大幅增加。然而,三个部位血流量增加的幅度和模式有所不同。在指尖,随着温度从基础水平升高到44摄氏度,血流量呈线性增加,约为原来的三倍。在肘部,基础血流量远低于指尖,在皮肤温度达到38摄氏度之前增加非常缓慢。从那时起,血流量急剧增加,在44摄氏度时达到基础水平的十倍。手指背部热诱导的血流量增加介于其他两个部位之间,其模式更类似于肘部而非指尖。这些部位之间的差异归因于血流量的两个组成部分(微血管容积和速度)截然不同的变化模式。在指尖,随着温度升高,微血管容积几乎没有增加。从基础温度到44摄氏度,曲线几乎是平的。相比之下,红细胞速度呈线性增加,约为300%。在肘部,微血管容积和红细胞速度都呈现出平行的曲线模式,且增加幅度相当,各自约为300%。在温度达到38摄氏度之前,这两个参数只有小幅增加,此后两者都急剧增加。在手指背部,情况介于两者之间,同样更类似于肘部而非指尖。细胞通过时间分析显示红细胞通过时间(TT)逐渐减少,从28摄氏度时的3.28毫秒降至44摄氏度时的2.48毫秒,总体变化为24%。TT的减少伴随着通过频率(以每秒计数(C s-1)衡量)从3.1增加到5.3,总体变化为71%。TT和C/S的变化基本呈线性。(摘要截选至400字)
