Post-traumatic regeneration, neurogenesis and neuronal migration in the adult mammalian brain.

Virginia medical quarterly : VMQ Pub Date : 1997-01-01
D E Scott, S L Hansen
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Abstract

Unlike the peripheral nervous system (PNS), the mammalian central nervous system (CNS) clearly lacks the robust regenerative characteristics and capacity of the former. Despite this fact, two unique regions of the adult mammalian CNS possess such regenerative potential and are capable of active regeneration following injury or structural compromise. These unique areas are the olfactory system and the neurohypophyseal system of the endocrine hypothalamus. Furthermore, it has been clearly demonstrated that primordial neuroblasts regarded as stem cells emerge from the subependymal parenchyma of the walls and floor of the third cerebral ventricle, migrate to the ventricular surface and undergo compensatory synaptogenesis within one week following hypophysectomy. In situ hybridization studies have unequivocally demonstrated that the up-regulation of nitric oxide synthase (NOS) is essential for neural (axonal) regeneration and neuronal (stem cell) migration to occur. Moreover, neuronal migration is reliably inhibited following the administration of the NO antagonist, nitroarginine. The current investigation serves to confirm a remarkable degree of plasticity and regeneration in the adult mammalian neurohypophyseal system coupled with the emergence of primordial neuroblasts that undergo apparent differentiation, migration and compensatory synaptogenesis in response to the up-regulation of NO that occurs following the trauma of hypophysectomy. Evidence from the current investigation appears to confirm that specialized glia of the neurohypophyseal system, the so-called pituicyte, proliferate following hypophysectomy and may serve as a growth matrix or structural template that may target and direct regenerating Supraoptic (SON) and Paraventricular (PVN) axons toward endothelial primordia in the regenerating neural stem and lobe.

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成年哺乳动物脑外伤后再生、神经发生和神经元迁移。
与外周神经系统(PNS)不同,哺乳动物中枢神经系统(CNS)显然缺乏外周神经系统强大的再生特性和能力。尽管如此,成年哺乳动物中枢神经系统的两个独特区域具有这种再生潜力,并且能够在损伤或结构受损后进行主动再生。这些独特的区域是嗅觉系统和下丘脑内分泌的神经垂体系统。此外,研究清楚地表明,被视为干细胞的原始神经母细胞从第三脑室壁和脑室底的室管膜下实质中出现,在脑室表面迁移,并在垂体切除术后一周内进行代偿性突触发生。原位杂交研究明确表明,一氧化氮合酶(NOS)的上调对于神经(轴突)再生和神经元(干细胞)迁移的发生至关重要。此外,在给予NO拮抗剂硝基精氨酸后,神经元迁移被可靠地抑制。目前的研究证实,成年哺乳动物神经垂体系统具有显著程度的可塑性和再生能力,伴随着原始神经母细胞的出现,这些原始神经母细胞经历了明显的分化、迁移和代偿性突触发生,以响应垂体切除创伤后NO的上调。来自当前研究的证据似乎证实,神经垂体系统的特化胶质细胞,即所谓的垂体细胞,在垂体切除术后增殖,并可能作为生长基质或结构模板,靶向并引导再生的视上(SON)和室旁(PVN)轴突向再生的神经干和叶的内皮原基。
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