Scheinin H, Aantaa R, Anttila M, Hakola P, Helminen A, Karhuvaara S
Department of Anesthesiology, Turku University Hospital, Finland.
Anesthesiology. 1998 Sep;89(3):574-84. doi: 10.1097/00000542-199809000-00005.
Specific and selective alpha2-adrenergic drugs are widely exploited in veterinary anesthesiology. Because alpha2-agonists are also being introduced to human practice, the authors studied reversal of a clinically relevant dexmedetomidine dose with atipamezole, an alpha2-antagonist, in healthy persons.
The study consisted of two parts. In an open dose-finding study (part 1), the intravenous dose of atipamezole to reverse the sedative effects of 2.5 microg/kg of dexmedetomidine given intramuscularly was determined (n = 6). Part 2 was a placebo-controlled, double-blinded, randomized cross-over study in which three doses of atipamezole (15, 50, and 150 microg/kg given intravenously in 2 min) or saline were administered 1 h after dexmedetomidine at 1-week intervals (n = 8). Subjective vigilance and anxiety, psychomotor performance, hemodynamics, and saliva secretion were determined, and plasma catecholamines and serum drug concentrations were measured for 7 h.
The mean +/- SD atipamezole dose needed in part 1 was 104+/-44 microg/kg. In part 2, dexmedetomidine induced clear impairments of vigilance and psychomotor performance that were dose dependently reversed by atipamezole (P < 0.001). Complete resolution of sedation was evident after the highest (150 microg/kg) dose, and the degree of vigilance remained high for 7 h. Atipamezole dose dependently reversed the reductions in blood pressure (P < 0.001) and heart rate (P = 0.009). Changes in saliva secretion and plasma catecholamines were similarly biphasic (i.e., they decreased after dexmedetomidine followed by dose-dependent restoration after atipamezole). Plasma norepinephrine levels were, however, increased considerably after the 150 microg/kg dose of atipamezole. The pharmacokinetics of atipamezole were linear, and elimination half-lives for both drugs were approximately 2 h. Atipamezole did not affect the disposition of dexmedetomidine. One person had symptomatic sinus arrest, and another had transient bradycardia approximately 3 h after receiving dexmedetomidine.
The sedative and sympatholytic effects of intramuscular dexmedetomidine were dose dependently antagonized by intravenous atipamezole. The applied infusion rate (75 microg x kg(-1) x min(-1)) for the highest atipamezole dose was, however, too fast, as evident by transient sympathoactivation. Similar elimination half-lives of these two drugs are a clear advantage considering the possible clinical applications.
特异性和选择性α2-肾上腺素能药物在兽医麻醉学中得到广泛应用。由于α2-激动剂也开始应用于人类医疗实践,作者研究了α2-拮抗剂阿替美唑对健康受试者临床相关剂量右美托咪定的逆转作用。
本研究包括两个部分。在开放剂量探索性研究(第1部分)中,确定静脉注射阿替美唑以逆转肌肉注射2.5μg/kg右美托咪定的镇静作用所需的剂量(n = 6)。第2部分是安慰剂对照、双盲、随机交叉研究,在右美托咪定给药1小时后,每隔1周静脉注射三种剂量的阿替美唑(15、50和150μg/kg,2分钟内注射完毕)或生理盐水(n = 8)。测定主观警觉性和焦虑、精神运动表现、血流动力学及唾液分泌情况,并在7小时内检测血浆儿茶酚胺和血清药物浓度。
第1部分所需阿替美唑的平均±标准差剂量为104±44μg/kg。在第2部分中,右美托咪定导致警觉性和精神运动表现明显受损,阿替美唑可剂量依赖性地逆转这种损害(P < 0.001)。最高剂量(150μg/kg)后镇静作用完全消除,警觉程度在7小时内保持较高水平。阿替美唑剂量依赖性地逆转了血压降低(P < 0.001)和心率降低(P = 0.009)。唾液分泌和血浆儿茶酚胺的变化同样呈双相性(即右美托咪定给药后降低,阿替美唑给药后剂量依赖性恢复)。然而,150μg/kg剂量的阿替美唑给药后血浆去甲肾上腺素水平显著升高。阿替美唑的药代动力学呈线性,两种药物的消除半衰期均约为2小时。阿替美唑不影响右美托咪定的处置。一名受试者出现症状性窦性停搏,另一名受试者在接受右美托咪定约3小时后出现短暂性心动过缓。
静脉注射阿替美唑可剂量依赖性地拮抗肌肉注射右美托咪定的镇静和抗交感神经作用。然而,最高剂量阿替美唑的输注速率(75μg·kg-1·min-1)过快,表现为短暂的交感神经激活。考虑到可能的临床应用,这两种药物相似的消除半衰期是一个明显的优势。
