From the Department of Anesthesiology and Perioperative Medicine, People's Hospital of Zhengzhou University, Zhengzhou, Henan, China.
Department of Anesthesiology, University of Florida College of Medicine, Gainesville, Florida.
Anesth Analg. 2022 Oct 1;135(4):877-887. doi: 10.1213/ANE.0000000000006125. Epub 2022 Jun 21.
Sevoflurane (SEVO) increases neuronal excitation in neonatal rodent brains through alteration of gamma aminobutyric acid (GABA)(A) receptor signaling and increases corticosterone release. These actions may contribute to mechanisms that initiate the anesthetic's long-term neuroendocrine and neurobehavioral effects. Dexmedetomidine (DEX), a non-GABAergic α2-adrenergic receptor agonist, is likely to counteract SEVO-induced neuronal excitation. We investigated how DEX pretreatment may alter the neurodevelopmental effects induced by SEVO in neonatal rats.
Postnatal day (P) 5 Sprague-Dawley male rats received DEX (25 µg/kg, intraperitoneal) or vehicle before exposure to 2.1% SEVO for 6 hours (the DEX + SEVO and SEVO groups, respectively). Rats in the DEX-only group received DEX without exposure to SEVO. A subcohort of P5 rats was used for electroencephalographic and serum corticosterone measurements. The remaining rats were sequentially evaluated in the elevated plus maze on P80, prepulse inhibition of the acoustic startle response on P90, Morris water maze (MWM) starting on P100, and for corticosterone responses to physical restraint for 30 minutes on P120, followed by assessment of epigenomic DNA methylation patterns in the hippocampus.
Acutely, DEX depressed SEVO-induced electroencephalogram-detectable seizure-like activity (mean ± SEM, SEVO versus DEX + SEVO, 33.1 ± 5.3 vs 3.9 ± 5.3 seconds, P < .001), but it exacerbated corticosterone release (SEVO versus DEX + SEVO, 169.935 ± 20.995 versus 280.853 ± 40.963 ng/mL, P = .043). DEX diminished, but did not fully abolish, SEVO-induced corticosterone responses to restraint (control: 11625.230 ± 877.513, SEVO: 19363.555 ± 751.325, DEX + SEVO: 15012.216 ± 901.706, DEX-only: 12497.051 ± 999.816; F[3,31] = 16.878, P < .001) and behavioral deficiencies (time spent in the target quadrant of the MWM: control: 31.283% ± 1.722%, SEVO: 21.888% ± 2.187%, DEX + SEVO: 28.617% ± 1.501%, DEX-only: 31.339% ± 3.087%; F[3,67] = 3.944, P = .012) in adulthood. Of the 391 differentially methylated genes in the SEVO group, 303 genes in the DEX + SEVO group had DNA methylation patterns that were not different from those in the control group (ie, they were normal). DEX alone did not cause acute or long-term functional abnormalities.
This study suggests that the ability of DEX to depress SEVO-induced neuronal excitation, despite increasing corticosterone release, is sufficient to weaken mechanisms leading to long-term neuroendocrine/neurobehavioral abnormalities. DEX may prevent changes in DNA methylation in the majority of genes affected by SEVO, epigenetic modifications that could predict abnormalities in a wide range of functions.
七氟醚(SEVO)通过改变γ-氨基丁酸(GABA)(A)受体信号和增加皮质酮释放来增加新生啮齿动物大脑中的神经元兴奋。这些作用可能有助于启动麻醉剂长期神经内分泌和神经行为影响的机制。右美托咪定(DEX),一种非 GABA 能 α2-肾上腺素能受体激动剂,可能会抵消 SEVO 引起的神经元兴奋。我们研究了 DEX 预处理如何改变 SEVO 在新生大鼠中诱导的神经发育效应。
出生后第 5 天(P)的雄性 Sprague-Dawley 大鼠在暴露于 2.1% SEVO 6 小时前接受 DEX(25 µg/kg,腹腔内)或载体(分别为 DEX + SEVO 和 SEVO 组)。DEX 组的大鼠接受 DEX 但不暴露于 SEVO。P5 大鼠的一个亚组用于脑电图和血清皮质酮测量。其余大鼠在 P80 时进行高架十字迷宫评估,在 P90 时进行声刺激起始反应的前脉冲抑制评估,在 P100 时开始进行 Morris 水迷宫(MWM)评估,在 P120 时进行 30 分钟的身体束缚后评估皮质酮反应,随后评估海马体的表观遗传 DNA 甲基化模式。
急性时,DEX 抑制 SEVO 诱导的脑电图可检测到的惊厥样活动(均值±SEM,SEVO 与 DEX + SEVO,33.1±5.3 与 3.9±5.3 秒,P<.001),但加剧了皮质酮释放(SEVO 与 DEX + SEVO,169.935±20.995 与 280.853±40.963ng/mL,P=.043)。DEX 减弱但不能完全消除 SEVO 引起的束缚皮质酮反应(对照:11625.230±877.513,SEVO:19363.555±751.325,DEX+SEVO:15012.216±901.706,DEX 单药:12497.051±999.816;F[3,31]=16.878,P<.001)和行为缺陷(MWM 中目标象限的时间:对照:31.283%±1.722%,SEVO:21.888%±2.187%,DEX+SEVO:28.617%±1.501%,DEX 单药:31.339%±3.087%;F[3,67]=3.944,P=.012)在成年期。在 SEVO 组的 391 个差异甲基化基因中,DEX+SEVO 组的 303 个基因的 DNA 甲基化模式与对照组不同(即正常)。DEX 单独使用不会引起急性或长期功能异常。
本研究表明,DEX 抑制 SEVO 诱导的神经元兴奋的能力,尽管增加皮质酮释放,足以削弱导致长期神经内分泌/神经行为异常的机制。DEX 可能会防止 SEVO 影响的大多数基因的 DNA 甲基化发生变化,这些表观遗传修饰可能预测广泛功能的异常。
