Scheer P, Hložková J, Brhelová E, Aksu A, Goliášová S, Doležalová J, Tlučhořová L, Mikulík R
Stroke Group, St. Anne's University Hospital, Brno, Czech Republic.
Physiol Res. 2025 Jul 23;74(3):393-401. doi: 10.33549/physiolres.935413.
The successful development and testing of new thrombolytics in animal models requires monitoring of hemodynamic changes in cerebral circulation before and after stroke. The purpose of the present study was to document that percutaneous transcranial Doppler (TCD) monitoring is able to differentiate two hemodynamic situations induced with two anesthetic protocols. Twelve adult rats divided into two groups underwent general anesthesia (60 min) using combination: 1) ketamine-xylazine-diazepam (KXD); and 2) ketamine-xylazine-urethane-alpha-chloralose (URACH). The TCD was performed with the skin and skull intact. The heart rate, peak systolic velocity, pulsatility index, and resistance index were recorded in a branch of the posterior cerebral artery. Flow detection and measurement was possible in all rat brains bilaterally. The mean heart rate was lower in the KXD 243+/-4 (range: 238 to 249) than in the URACH group 265+/-12 (range: 250 to 279), the difference between means: 22; 95 % CI [8 to 34], p=0.005) only for the first 20 min of monitoring. Peak systolic velocity was lower in the KXD 73.4+/-3.3 mm/s (range 70.3 to 76.5) vs. URACH group 93.7+/-4.0 mm/s (range: 90.0 to 97.4) during the entire observation period (difference between means: 20; 95 % CI [16 to 25], p<0.001). Same difference was observed for pulsatility and resistance indexes. TCD was able to differentiate hemodynamic changes in the rat brains, making the TCD suitable for monitoring of hemodynamic changes and explores, e.g. how such changes contribute to hemorrhagic transformation after thrombolysis. Also, TCD holds promise as a tool for monitoring of recanalization induced by thrombolytics. Key words Non-invasive monitoring " Brain flow velocity " Anesthesia " Animal model.
在动物模型中成功研发和测试新型溶栓剂需要监测中风前后脑循环中的血流动力学变化。本研究的目的是证明经皮经颅多普勒(TCD)监测能够区分两种麻醉方案所诱发的两种血流动力学情况。将12只成年大鼠分为两组,分别使用以下组合进行全身麻醉(60分钟):1)氯胺酮-赛拉嗪-地西泮(KXD);2)氯胺酮-赛拉嗪-乌拉坦-α-氯醛糖(URACH)。在皮肤和颅骨完整的情况下进行TCD检查。记录大脑后动脉一个分支中的心率、收缩期峰值速度、搏动指数和阻力指数。在所有大鼠双侧大脑中均能进行血流检测和测量。仅在监测的前20分钟内,KXD组的平均心率243±4(范围:238至249)低于URACH组265±12(范围:250至279),均值差异为22;95%置信区间[8至34],p = 0.005)。在整个观察期内,KXD组的收缩期峰值速度为73.4±3.3毫米/秒(范围70.3至76.5),低于URACH组93.7±4.0毫米/秒(范围:90.0至97.4)(均值差异为20;95%置信区间[16至25],p<0.001)。搏动指数和阻力指数也观察到相同差异。TCD能够区分大鼠大脑中的血流动力学变化,这使得TCD适用于监测血流动力学变化,并探索例如这些变化如何导致溶栓后出血转化。此外,TCD有望作为监测溶栓剂诱导再通的工具。关键词 无创监测 “脑血流速度” “麻醉” “动物模型”
