Unravelling the neurochemical maze: neurotransmitters, neuropeptides and novel drug modes of action based on epilepsy pathophysiology

M. Dhall, R. Kadian, P. Sharma, A. Hooda, P. Kumar, P. Mudgal, K. Singh, A. Arya, N. Rani
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Abstract

The brain is extremely complicated three dimensional structures made up of interconnected neurons and neuroglia cells. It entails all type of functions of our body whether we are healthy or in disease conditions. Brain is accountable for our connectivity with the surroundings; all this is performed by an organized and systemic electrical activity of neurons by which they communicate messages to and from the brain. The abnormal electrical activity leading to the intense outburst of impulses, results in the development of epilepsy. Epilepsy is typified by recurrent, unprovoked seizures as a result excessive, hypersynchronous discharge of neurons occurs in the brain. Nearly 1% of the population throughout the worldwide is suffering from epilepsy and almost 75% begins at childhood. The patients almost one third are resistant to current available antiepileptic drugs. We don’t have the deep knowledge of the pathophysiology of the disease which can prove useful in further research for drugs with new mechanisms of action for diseases. This paper covers the role various neurotransmitters and neuropeptides in the pathophysiology of epilepsy. Our objective is to introduce the scientists with that aspect of the disease which may prove useful for further development of new drugs of epilepsy to overcome the resistance shown by the patientsorithm.
解开神经化学迷宫:基于癫痫病理生理学的神经递质、神经肽和新型药物作用模式
大脑是极其复杂的三维结构,由相互连接的神经元和神经胶质细胞组成。它包含了我们身体的所有功能,无论我们是健康的还是生病的。大脑负责我们与周围环境的联系;所有这些都是通过神经元有组织的、系统的电活动来完成的,神经元通过这种电活动与大脑交流信息。异常的电活动导致强烈的脉冲爆发,导致癫痫的发展。癫痫的典型特征是由于大脑中出现过多的、超同步的神经元放电而引起的反复的、无端的癫痫发作。全世界近1%的人口患有癫痫,近75%的人在儿童时期发病。近三分之一的患者对目前可用的抗癫痫药物有耐药性。我们对疾病的病理生理学没有深入的了解,这对进一步研究具有新的疾病作用机制的药物是有用的。本文介绍了各种神经递质和神经肽在癫痫病理生理中的作用。我们的目标是向科学家介绍这种疾病的这一方面,这可能对进一步开发新的癫痫药物有用,以克服患者算法所显示的耐药性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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