锂诱导的神经可塑性

R. Mukhopadhyaya, M. Rajadhyaksha
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引用次数: 0

摘要

神经可塑性指的是大脑建立新细胞连接的能力。诱导神经可塑性的药物具有重要的基础和临床意义。锂,一种已经在使用的药物,已经被证明具有神经保护作用,并且可能会得到更广泛的应用。可以用锂治疗的一系列疾病表明,可能有一种共同的细胞机制在起作用,比如神经可塑性。我们回顾了锂对主要细胞过程的影响,包括神经可塑性的改变,在体外和体内,在神经突,轴突和突触形成。已知锂支持细胞质生长的延伸。锂改变了轴突修饰的模式,包括它们的延伸或收缩以及新分支的萌发。然而,很少有研究直接证明锂对突触形成的作用。锂离子作用的分子基础是复杂的,串扰涉及多种途径。在这些多种途径中,我们重点关注锂诱导的糖原合成酶激酶-3β的抑制,肌醇磷酸途径的阻断和神经营养因子的上调,因为有直接证据表明这些参与了锂诱导的神经可塑性。这篇综述提供了一个鸟瞰图的研究,可以提供洞察锂作用的特殊方面,可塑性的诱导,这对治疗各种神经系统疾病具有重要意义
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Lithium induced neural plasticity
Neural plasticity refers to the brain’s ability to make new cellular connections. Drugs that can induce neural plasticity are of basic as well as clinical interest. Lithium, a drug already in use, has been demonstrated to be neuroprotective and is likely to find wider use. The spectrum of diseases that can be potentially treated with lithium suggests that there could be a common cellular mechanism, such as neural plasticity, in operation. We review effects of lithium on major cellular processes that comprise neuroplasticity – alterations, in vitro and in vivo, in neurites, axons and synapse formation. Lithium is known to support extension of cytoplasmic outgrowths. Lithium alters patterns of axonal modifications including their extensions or retractions and sprouting of new branches. However, there are few studies directly demonstrating lithium action of synapse formation. The molecular basis of lithium action is complex with various pathways involved in cross talk. Of these multiple pathways, we have focused on lithium induced inhibition of glycogen synthase kinase-3β, block of inositol phosphate pathway and up regulation of neurotrophins as there are direct evidences of involvement of these in lithium induced neuroplasticity. This review provides a bird’s eye view of studies that could provide insight into special aspect of lithium action, induction of plasticity, which have implication for treating a wide variety of neurological conditions
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