Kurz A, Xiong J, Sessler D I, Dechert M, Noyes K, Belani K
Department of Anesthesia, University of California, San Francisco, USA.
Anesthesiology. 1995 Dec;83(6):1212-9. doi: 10.1097/00000542-199512000-00012.
Thermoregulatory responses, such as arteriovenous shunt vasoconstriction, provide substantial protection against core hypothermia. A response can be characterized by its threshold (core temperature triggering response), gain (rate at which response intensity increases, once triggered), and maximum response intensity. Reduced gain decreases the efficacy of a thermoregulatory response at a given threshold because response intensity will increase more slowly than usual. The effects of general anesthesia on the gain of arteriovenous shunt vasoconstriction have not been reported. Accordingly, we tested the hypothesis that desflurane decreases the gain of centrally mediated vasoconstriction.
We studied seven healthy male volunteers. Each was studied twice: (1) desflurane (end-tidal concentration 0.4 minimum alveolar concentration); and (2) control (no anesthesia). Mean skin and fingertip temperatures were controlled at 35.5 degrees C throughout the study. Core temperature was reduced at a rate of 1.5 degrees C/h by central venous infusion of cold fluid. Fingertip arteriovenous shunt flow was measured using venous occlusion volume plethysmography at 1-min intervals. Flow was also evaluated using the perfusion index and laser Doppler flowmetry. Vasoconstriction thresholds were calculated as the core temperatures triggering fingertip flows of 1.0 ml/min (beginning of vasoconstriction) and 0.25 ml/min (intense vasoconstriction). The gain of vasoconstriction was considered to be the slope of the fingertip flow versus core temperature regression within the linear range from 1.0 ml/min to 0.15 ml/min. The minimum observed flow was considered maximum vasoconstriction intensity. Data are presented as means +/- SD; P < 0.01 was considered statistically significant.
The vasoconstriction threshold (when defined using a flow of 1.0 ml/min) was reduced from 36.8 +/- 0.3 degrees C to 35.6 +/- 0.3 degrees C by desflurane anesthesia (P < 0.01). Desflurane reduced the gain of vasoconstriction by a factor of three, from 2.4 to 0.8 ml.min-1.degrees C-1 (P < 0.01). Gains, as determined by the perfusion index and laser Doppler flowmetry, were likewise reduced (P < 0.01). The threshold on the control day was only 0.2 +/- 0.1 degrees C less when significant vasoconstriction was defined as a flow of 0.25 ml/min rather than 1.0 ml/min. Because gain was reduced, however, the threshold during desflurane administration was 0.8 +/- 0.2 degrees C less when significant vasoconstriction was defined by a flow of 0.25 ml/min. Minimum flows were comparable and near zero with and without anesthesia.
The threshold reduction (1.2 degrees C/0.4 minimum alveolar concentration) was similar to that observed previously during isoflurane anesthesia. Similarly, it is established already that maximum vasoconstriction intensity is comparable with and without isoflurane anesthesia. However, the data also indicate that even relatively low desflurane concentrations markedly reduce the gain of vasoconstriction. It is likely that reduced gain (i.e., slow onset of vasoconstriction) contributes to core hypothermia in some surgical patients.
体温调节反应,如动静脉分流血管收缩,可提供对核心体温过低的实质性保护。一种反应可通过其阈值(触发反应的核心温度)、增益(一旦触发,反应强度增加的速率)和最大反应强度来表征。增益降低会降低在给定阈值下体温调节反应的功效,因为反应强度的增加将比正常情况更缓慢。尚未有关于全身麻醉对动静脉分流血管收缩增益影响的报道。因此,我们检验了地氟烷会降低中枢介导的血管收缩增益这一假设。
我们研究了7名健康男性志愿者。每人进行两次研究:(1)地氟烷(呼气末浓度为0.4最低肺泡浓度);(2)对照(无麻醉)。在整个研究过程中,平均皮肤温度和指尖温度控制在35.5摄氏度。通过中心静脉输注冷液体,以每小时1.5摄氏度的速率降低核心温度。每隔1分钟使用静脉阻断容积描记法测量指尖动静脉分流血流量。还使用灌注指数和激光多普勒血流仪评估血流量。血管收缩阈值计算为触发指尖血流量为1.0毫升/分钟(血管收缩开始)和0.25毫升/分钟(强烈血管收缩)时的核心温度。血管收缩增益被认为是在1.0毫升/分钟至0.15毫升/分钟的线性范围内指尖血流量与核心温度回归的斜率。观察到的最小血流量被视为最大血管收缩强度。数据以平均值±标准差表示;P<0.01被认为具有统计学意义。
地氟烷麻醉使血管收缩阈值(以1.0毫升/分钟的血流量定义时)从36.8±0.3摄氏度降至35.6±0.3摄氏度(P<0.01)。地氟烷使血管收缩增益降低了三倍,从2.4降至0.8毫升·分钟-1·摄氏度-1(P<0.01)。通过灌注指数和激光多普勒血流仪确定得到的增益同样降低(P<0.01)。当将显著血管收缩定义为血流量为0.25毫升/分钟而非1.0毫升/分钟时,对照日的阈值仅低0.2±0.1摄氏度。然而,由于增益降低,在地氟烷给药期间,当将显著血管收缩定义为血流量为0.25毫升/分钟时,阈值低0.8±0.2摄氏度。有无麻醉时的最小血流量相当且接近零。
阈值降低(1.2摄氏度/0.4最低肺泡浓度)与先前在异氟烷麻醉期间观察到的相似。同样,已经确定异氟烷麻醉与否时最大血管收缩强度相当。然而,数据还表明,即使是相对较低的地氟烷浓度也会显著降低血管收缩增益。增益降低(即血管收缩起效缓慢)可能在一些手术患者中导致核心体温过低。
