{"title":"21 Neurogenesis and Hippocampal Memory System","authors":"D. Abrous, J. Wojtowicz","doi":"10.1101/087969784.52.445","DOIUrl":null,"url":null,"abstract":"When discussing a brain function such as memory, one should relate it to brain plasticity. One definition of plasticity is an alternative way of performing the same function. Anecdotal evidence suggests that the human brain can perform amazing memory feats in unexpected, alternative ways. For example, the established ability of savants (individuals with partial brain damage) to memorize events, sequences of numbers, letters, or musical notes, and to perform arithmetical calculations, suggests that compensatory rewiring of brain circuits after injury can affect learning. Which particular form of brain plasticity could be responsible for such astounding learning abilities as those seen in Kim Peek (“Rain Man”) and Daniel Tammet (“Brainman”), two individuals diagnosed as autistic savants (www.savantsyndrome.com)? In this chapter, we describe a radical form of plasticity, adult neurogenesis, in hippocampal formation (HF). The discovery of adult neurogenesis (production of new neurons in adult brain) has radically changed our ideas of how the brain can adapt to physiological and environmental challenges. The process of neuronal production is highly regulated and is involved in hippocampal functions under physiological conditions. In some cases, neurogenesis can respond to hippocampus-related pathologies such as epilepsy, ischemia, mood disorders, and addiction. Understanding neurogenesis, along with other forms of brain plasticity, may help us to understand normal memory and perhaps the enhanced memory such as that seen in individuals with the Savant Syndrome (Treffert and Christensen 2005). LESIONS OF THE NEUROGENIC REGION The HF is part of an integrated network involved in learning and memory (Eichenbaum 2000, 2001;...","PeriodicalId":10493,"journal":{"name":"Cold Spring Harbor Monograph Archive","volume":"23 1","pages":"445-461"},"PeriodicalIF":0.0000,"publicationDate":"2008-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"17","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Cold Spring Harbor Monograph Archive","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1101/087969784.52.445","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 17
Abstract
When discussing a brain function such as memory, one should relate it to brain plasticity. One definition of plasticity is an alternative way of performing the same function. Anecdotal evidence suggests that the human brain can perform amazing memory feats in unexpected, alternative ways. For example, the established ability of savants (individuals with partial brain damage) to memorize events, sequences of numbers, letters, or musical notes, and to perform arithmetical calculations, suggests that compensatory rewiring of brain circuits after injury can affect learning. Which particular form of brain plasticity could be responsible for such astounding learning abilities as those seen in Kim Peek (“Rain Man”) and Daniel Tammet (“Brainman”), two individuals diagnosed as autistic savants (www.savantsyndrome.com)? In this chapter, we describe a radical form of plasticity, adult neurogenesis, in hippocampal formation (HF). The discovery of adult neurogenesis (production of new neurons in adult brain) has radically changed our ideas of how the brain can adapt to physiological and environmental challenges. The process of neuronal production is highly regulated and is involved in hippocampal functions under physiological conditions. In some cases, neurogenesis can respond to hippocampus-related pathologies such as epilepsy, ischemia, mood disorders, and addiction. Understanding neurogenesis, along with other forms of brain plasticity, may help us to understand normal memory and perhaps the enhanced memory such as that seen in individuals with the Savant Syndrome (Treffert and Christensen 2005). LESIONS OF THE NEUROGENIC REGION The HF is part of an integrated network involved in learning and memory (Eichenbaum 2000, 2001;...
在讨论诸如记忆之类的大脑功能时,我们应该将其与大脑的可塑性联系起来。可塑性的一个定义是执行相同功能的另一种方式。轶事证据表明,人类大脑可以以意想不到的、不同的方式表现出惊人的记忆壮举。例如,学者(部分脑损伤的个体)记忆事件、数字序列、字母或音符以及进行算术计算的能力表明,损伤后大脑回路的补偿性重新布线会影响学习。哪一种特殊的大脑可塑性会导致金·皮克(“雨人”)和丹尼尔·塔米特(“聪明人”)如此惊人的学习能力,这两个被诊断为自闭症的学者(www.savantsyndrome.com)?在本章中,我们描述了一种根本性的可塑性形式,即海马形成(HF)中的成人神经发生。成人神经发生(在成人大脑中产生新的神经元)的发现从根本上改变了我们对大脑如何适应生理和环境挑战的看法。在生理条件下,神经元的产生过程受到高度调控,并参与海马的功能。在某些情况下,神经发生可以对海马体相关的病理,如癫痫、缺血、情绪障碍和成瘾作出反应。了解神经发生,以及其他形式的大脑可塑性,可能有助于我们理解正常记忆,也许还能帮助我们理解像学者综合症患者那样的增强记忆(Treffert and Christensen 2005)。HF是学习和记忆相关的综合网络的一部分(Eichenbaum 2000,2001;…