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22 似乎环境的丰富也可能有更微妙的影响。无论给予的物体是令人厌恶的、奖励性的还是中性的,生活在环境贫乏笼子里的水貂花更多时间与新颖的物体交往。也就是新近有了这些特权的水貂比之前就在丰富环境笼子里待着的水貂更快与这些物体建立关系。从这项观察研究中得出的结论是,在贫乏环境中长大的动物明显更“无聊”。我们确实需要小心,不要过度解释这些结果,不然会听到这样的警告:每当我们使用最适合人类行为方式的术语时,谨慎的做法是不要过于随便地使用这个术语。水貂不是人类,我们也不能在没有根据的情况下,把诸如无聊这样复杂的心理状态强加给它们。可以说,丰富环境本身就是一种全新的体验,它让单个成分的“新颖性”相形见绌,而且与之前的生活方式相比,经常接触新事物的动物也体现出了更大的差异性。然而,浅尝一下丰富的感觉可能还不如完全没有丰富的环境。由于无法参与积极的行为,有些被关在笼子里的动物表现出刻板行为:某种重复而毫无目的的动作,通常代表压力很大。对这些动物来说,丰富能够减少这些动作,但是当它们被安置在一个丰富的环境中时,比那些一直放在贫乏环境中的动物表现出更严重的刻板行为。Meagher, R.K.&Mason, G.J.‘Environmental enrichment reduces signs of boredom in caged mink’.PLoS One,7,e49180(2012).另请参阅 Latham, N.&Mason, G.‘Frustration and perseveration in stereotypic captive animals:is a taste of enrichment worse than none at all?’Behavioural Brain Research ,211,96-104(2010).
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23 Mora, F.,Segovia, G.&del Arco, A.‘Aging, plasticity and environmental enrichment:structural changes and neurotransmitter dynamics in several areas of the brain’.Brain Research Review ,55,78-88(2007). Kozorovitskiy, Y.et al.‘Ex
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perience induces structural and biochemical changes in the adult primate brain’.Proceedings of the National Academy of Sciences of the United States of America ,102,17478-82(2005).
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24 Kolb, B. Brain,Plasticity and Behaviour ,ch 1.Laurence Erlbaum Assoc(1995).
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25 Greenfield, S. A.Mind Change:How Digital Technologies are Leaving Teeir Mark on Our Brains .(Random House,2014).
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26 另外,在妊娠第28周和70周(即婴儿出生后第30周)之间,突触密度增加,并在8个月大时达到峰值,为6亿个,在10岁时趋于稳定,达到3亿个。Huttenlocher, P.et al.‘Synaptogenesis in human visual cortex-evidence for synapse elimination during normal development’.Neuroscience Letters ,33,247-52(1982).
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27 Gogtay, N. et al.‘Dynamic mapping of human cortical development during childhood through early adulthood’.Proceedings of the National Academy of Sciences of the United States of America ,101,8174-9(2004).
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28 同时,在“交汇关联”区域的细胞(那些皮层区域主要不是参与感觉或运动加工),例如前额叶皮层,会比诸如感觉皮层经历更长期的衰退。在感觉皮层,成长和衰退阶段的敏锐性被认为是感觉模式“关键时期”的基础,该术语表明,时间框架对于建立正确的通路是至关重要的。有趣的是,“白质”(也就是连接纤维)的体积在研究的整个过程中不断增加,这是由于髓鞘化(myelination)的增加——这种绝缘能改善神经传导,并解释多发性硬化症(一种破坏性的疾病)恶化时所造成的损害。
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29 Maguire, E. A.et al.‘Navigation-related structural change in the hippocampi of taxi drivers’.Proceedings of the National Academy of Sciences of the United States of America ,97,4398-403(2000).
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30 Gaser, C.&Schlaug, G.‘Brain structures differ between musicians and non-musicians’.Journal of Neuroscience ,23,9240-5(2003).
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31 Bengtsson, S. L.et al.‘Extensive piano practising has regionally specifc effects on white matter development’.Nature Neuroscience ,8,1148-50(2005).
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32 Jäncke, L.et al.‘The architecture of the golfer’s brain’.PLoS One ,4,e4785(2009).
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33 Park, I. S.et al.‘Experience-dependent plasticity of cerebellar vermis in basket-ball players’.Cerebellum ,8,334-9(2009).
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34 Mechelli, A. et al.‘Neurolinguistics:structural plasticity in the bilingual brain’.Nature ,431,757(2004);另请参阅Stein, M.et al.‘Structural plasticity in the language system related to increased second-language profciency’.Cortex ,48,458-65(2012).
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35 Draganski, B. et al.‘Neuroplasticity:changes in grey matter induced by training’.Nature,427,311-12(2004);另请参阅Driemeyer, J.et al.‘Changes in gray matter induced by learning-revisited’.PLoS One ,3,e2669(2008).
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36 Pascual-Leone, A. et al.‘Modulation of muscle responses evoked by transcranial magnetic stimulation during the acquisition of new fine motor skills’.Journal of Neurophysiology ,74,1037-45(1995).
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37 Bailey, C. H.&Kandel, E.R.‘Synaptic remodeling, synaptic growth and the storage of long-term memory in Aplysia’.Progress in Brain Research ,169,179-98(2008).
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38 Ridley, M.Nature via Nurture:Genes, Experience and What Makes Us Human .(Harper Perennial,2004).
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39 Greenfield,2014;另请参阅 Greenfield, S.A.You and Me:Tee Neuroscience of Identity .(Notting Hill Editions,2011).
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40 Pittenger, C.&Kandel, E. R.‘In search of general mechanisms for long-lasting plasticity:Aplysia and the hippocampus’.Philosophical Transactions of the Royal Society of London B:Biological Sciences ,358,757-63(2003);对于长时程增强效应(LTP)和长时程抑制(LTD)的基本解释见S.A.Greenfield,Tee Human Brain:A Guided Tour (Orion,1997);更加全面且更技术化的描述见D.Purves,Neuroscience (Sinauer Press,2011,5th edn).
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41 Deidda, G.,Bozarth, I. F.&Cancedda, L.‘Modulation of GABAergic transmission in development and neurodevelopmental disorders:investigating physiology and pathology to gain therapeutic perspectives’.Frontiers in Cellular Neuroscience ,8,119(2014).
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42 Storer, K. P.&Reeke, G.N.‘γ-Aminobutyric acid receptor type A receptor potentiation reduces firing of neuronal assemblies in a computational cortical model’.Anesthesiology ,117,780-90(2012).
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43 Olds, J.&Milner, P.‘Positive reinforcement produced by electrical stimulation of septal area and other regions of rat brain’.Journal of Comparative Physiological Psychology ,47,419-27(1954).
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44 多巴胺对前额叶皮层有抑制作用。请参阅Ferron, A.et al.‘Inhibitory infuence of the mesocortical dopaminergic system on spontaneous activity or excitatory response induced from the thalamic mediodorsal nucleus in the rat medial prefrontal cortex’.Brain Research ,302,257-65(1984).Gao, W.-J.,Wang, Y.&Goldman-Rakic, P.S.‘Dopamine modulation of perisomatic and peridendritic inhibition in prefrontal cortex’.Journal of Neuroscience ,23,1622-30(2003).Cole, M.W.&Schneider, W.‘The cognitive control network:integrated cortical regions with dissociable functions’.Neuroimage ,37,343-60(2007).Cole, M.W.,Pathak, S.&Schneider, W.‘Identifying the brain’s most globally connected regions’.NeuroImage ,49,3132-48(2010).Cools, R.&d’Esposito, M.‘Inverted-U-shaped dopamine actions on human working memory and cognitive control’.Biological Psychiatry ,69,e113-25(2011).多亏了这一抑制作用,多巴胺能够在三个不同水平上限制神经元集合的大小。第一,在单个神经元水平上,通过一种直接的调节作用,在特定的大脑区域即前额叶皮层上,对神经元产生有效的抑制。第二,通过全脑间接解剖系统:前额叶皮层所连接的脑区比其他任何区域都要多。因此,如果多巴胺抑制这一关键的脑区,尤其以人类大脑为例,那么大脑的整体组织功能将变得碎片化,因此大脑会不太可能形成任何超越正常解剖划分的神经元集合。第三,也是最后一点,在间接的行为水平上,多巴胺可能会使神经元集合的大小减小。众所周知,释放脑内多巴胺的苯丙胺类药物,对大脑整体具有刺激和兴奋的作用,导致过度亢奋。在这种状态下,当多巴胺水平很高时,有一种可能性会增加,过于活跃兴奋的人有更多机会即刻直接感知到周围的环境,而不会对某物或某人有长期沉思的“认知”过程。在前一个石头还没来得及激起全部的水波纹时,就寻求一种新的刺激,把一块新石头扔进水潭。正如我们所见,这将是一个高速竞争的世界,由于周转率高,因而神经元集合的大小会减小。
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45 与多巴胺类似效果的讨论请参阅Susanta Bandyopadhyay and John J.Hablitz(2007),‘Dopaminergic Modulation of Local Network Activity in Rat Prefrontal Cortex’,Journal of Neurophysiology :4120-28.
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