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通过抑制犬尿氨酸羟化酶来修饰犬尿氨酸途径可减轻雄性大鼠手术性脑损伤并发症。

Modification of kynurenine pathway via inhibition of kynurenine hydroxylase attenuates surgical brain injury complications in a male rat model.

机构信息

Department of Physiology and Pharmacology, Loma Linda University, Loma Linda, California.

Department of Neurosurgery, Loma Linda University, Loma Linda, California.

出版信息

J Neurosci Res. 2020 Jan;98(1):155-167. doi: 10.1002/jnr.24489. Epub 2019 Jun 30.

DOI:10.1002/jnr.24489
PMID:31257634
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6854312/
Abstract

Neurosurgical procedures result in surgically induced brain injury (SBI) that causes postoperative complications including brain edema and neuronal apoptosis in the surrounding brain tissue. SBI leads to the release of cytokines that indirectly cause the stimulation of kynurenine 3-monooxygenase (KMO) and the release of neurotoxic quinolinic acid (QUIN). This study tested a KMO inhibitor, RO 61-8048, to prevent postoperative brain edema and consequent neuronal apoptosis in an in vivo model of SBI. A rodent model of SBI was utilized which involves partial resection of the right frontal lobe. A total of 127 Sprague-Dawley male rats (weight 275-325 g) were randomly divided into the following groups: Sham surgical group, SBI, SBI + DMSO, SBI + RO 61-8048 (10 mg/kg), SBI + RO 61-8048 (40 mg/kg), and SBI + RO 61-8048 (40 mg/kg) + KAT II inhibitor PF-04859989 (5 mg/kg). RO 61-8048 was administered by intraperitoneal injection after SBI. Postoperative assessment at different time points included brain water content (brain edema), neurological scoring, and western blot. SBI increased brain water content (ipsilateral frontal lobe), decreased neurological function, and increased apoptotic markers compared with sham animals. Treatment with RO 61-8048 (40 mg/kg) reduced brain water content and improved long-term neurological function after SBI. RO 61-8048 increased the expression of kynurenic acid while reducing QUIN and apoptotic markers in the surrounding brain tissue after SBI. These neuroprotective effects were reversed by PF-04859989. This study suggests KMO inhibition via RO 61-8048 as a potential postoperative therapy following neurosurgical procedures.

摘要

神经外科手术会导致手术引起的脑损伤(SBI),从而导致术后并发症,包括脑水肿和周围脑组织中的神经元凋亡。SBI 导致细胞因子的释放,这些细胞因子间接刺激犬尿氨酸 3-单加氧酶(KMO)的释放,并释放出神经毒性喹啉酸(QUIN)。本研究在 SBI 的体内模型中测试了一种 KMO 抑制剂 RO 61-8048,以防止术后脑水肿和随之而来的神经元凋亡。使用 SBI 的啮齿动物模型,涉及右额叶的部分切除。总共 127 只 Sprague-Dawley 雄性大鼠(体重 275-325 克)被随机分为以下几组:假手术组、SBI 组、SBI+DMSO 组、SBI+RO 61-8048(10mg/kg)组、SBI+RO 61-8048(40mg/kg)组和 SBI+RO 61-8048(40mg/kg)+KAT II 抑制剂 PF-04859989(5mg/kg)组。RO 61-8048 在 SBI 后通过腹腔注射给药。不同时间点的术后评估包括脑水含量(脑水肿)、神经评分和 Western blot。与假手术动物相比,SBI 增加了脑水含量(同侧额叶)、降低了神经功能并增加了凋亡标志物。RO 61-8048(40mg/kg)治疗可减少 SBI 后的脑水含量并改善长期神经功能。RO 61-8048 增加了犬尿氨酸的表达,同时减少了 SBI 后周围脑组织中的 QUIN 和凋亡标志物。这些神经保护作用被 PF-04859989 逆转。本研究表明,通过 RO 61-8048 抑制 KMO 可能是神经外科手术后的一种潜在术后治疗方法。

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