“大规模脑网络”的版本间的差异
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| + | |keywords=脑网络,复杂网络,神经网络 | ||
| + | |description=在对基于血氧水平依赖效应BOLD的功能性磁共振成像信号 | ||
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| − | + | '''大规模脑网络 Large-scale brain networks'''(也称为'''内在大脑网络 Intrinsic brain networks''')是在对基于'''血氧水平依赖效应BOLD'''的功能性磁共振成像 Functional magnetic resonance imaging(fMRI)信号<ref name=Riedl>{{cite journal|last1=Riedl|first1=Valentin|last2=Utz|first2=Lukas|last3=Castrillón|first3=Gabriel|last4=Grimmer|first4=Timo|last5=Rauschecker|first5=Josef P.|last6=Ploner|first6=Markus|last7=Friston|first7=Karl J.|last8=Drzezga|first8=Alexander|last9=Sorg|first9=Christian|title=Metabolic connectivity mapping reveals effective connectivity in the resting human brain|journal=PNAS|date=January 12, 2016|volume=113|issue=2|pages=428–433|doi=10.1073/pnas.1513752113|pmid=26712010|pmc=4720331|bibcode=2016PNAS..113..428R|doi-access=free}}</ref>的统计分析或其他记录方法(如'''脑电图 Electroencephalography(EEG)<ref name=":1">{{Cite journal|last1=Foster|first1=Brett L.|last2=Parvizi|first2=Josef|date=2012-03-01|title=Resting oscillations and cross-frequency coupling in the human posteromedial cortex|journal=NeuroImage|volume=60|issue=1|pages=384–391|doi=10.1016/j.neuroimage.2011.12.019|pmid=22227048|issn=1053-8119|pmc=3596417}}</ref>'''、'''正电子发射断层扫描技术 Positron emission tomography(PET)<ref name=":2">{{Cite journal|last1=Buckner|first1=Randy L.|last2=Andrews‐Hanna|first2=Jessica R.|last3=Schacter|first3=Daniel L.|date=2008|title=The Brain's Default Network|journal=Annals of the New York Academy of Sciences|language=en|volume=1124|issue=1|pages=1–38|doi=10.1196/annals.1440.011|pmid=18400922|issn=1749-6632|bibcode=2008NYASA1124....1B|s2cid=3167595}}</ref>'''和'''脑磁图 Magnetoencephalography(MEG)<ref name=":3">{{Cite journal|last1=Morris|first1=Peter G.|last2=Smith|first2=Stephen M.|last3=Barnes|first3=Gareth R.|last4=Stephenson|first4=Mary C.|last5=Hale|first5=Joanne R.|last6=Price|first6=Darren|last7=Luckhoo|first7=Henry|last8=Woolrich|first8=Mark|last9=Brookes|first9=Matthew J.|date=2011-10-04|title=Investigating the electrophysiological basis of resting state networks using magnetoencephalography|journal=Proceedings of the National Academy of Sciences|language=en|volume=108|issue=40|pages=16783–16788|doi=10.1073/pnas.1112685108|issn=0027-8424|pmid=21930901|pmc=3189080|bibcode=2011PNAS..10816783B|doi-access=free}}</ref>''')中,表现出'''功能连接 Functional connectivity'''的'''脑区 Brain regions'''的集合。根据神经科学中一个新出现的范式,认知任务不是由单个脑区独立执行的,而是由几个互不相连的脑区“功能连接”组成的网络执行的。功能连接网络可以通过'''数据聚类Cluster analysis'''、空间'''独立元素分析ICA'''、种子点方法等算法来发现。<ref name="Petersen">{{cite journal|last1=Petersen|first1=Steven|last2=Sporns|first2=Olaf|title=Brain Networks and Cognitive Architectures|journal=Neuron|date=October 2015|volume=88|issue=1|pages=207–219|doi=10.1016/j.neuron.2015.09.027|pmid=26447582|pmc=4598639 }}</ref>同步的脑区也可以用脑电图、脑磁图或其他动态脑信号的远程同步来识别。.<ref name=Bressler>{{cite journal|last1=Bressler|first1=Steven L.|last2=Menon|first2=Vinod|s2cid=5967761|title=Large scale brain networks in cognition: emerging methods and principles|journal=Trends in Cognitive Sciences|date=June 2010|volume=14|issue=6|pages=233–290|doi=10.1016/j.tics.2010.04.004|url=http://www.cell.com/trends/cognitive-sciences/issue?pii=S1364-6613(10)X0005-5|accessdate=24 January 2016|pmid=20493761}}</ref> | |
| − | '''Large-scale brain networks''' ( | ||
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| − | + | 大规模脑网络中,连接在一起的脑区集合因认知功能的不同而不同。<ref name="Bressler2">{{cite journal|last1=Bressler|first1=Steven L.|title=Neurocognitive networks|journal=Scholarpedia|volume=3|issue=2|pages=1567|doi=10.4249/scholarpedia.1567|year=2008|bibcode=2008SchpJ...3.1567B|doi-access=free}}</ref>当认知状态不明确(即主体处于“静止”状态)时,大规模脑网络是一个'''静息状态Resting state'''网络(RSN)。作为一个具有图形特征的物理系统,<ref name="Bressler" />大规模脑网络既有节点又有边,不能简单地通过脑区的共同激活来识别。近几十年来,成像技术不断进步,同时[[图论]]、[[动力学系统]]领域出现了新的技术手段,这使得脑网络分析变得可行。 | |
| − | + | 大规模脑网络是通过其功能来进行识别的。通过研究大规模脑网络建立神经模型,对不同脑区组合所形成的自组织联合体如何实现不同的'''认知Cognition'''功能进行解释,就能够为认知理解提供一个连贯的框架。识别算法和参数的不同会导致所识别出的上述联合体的数量和组成有所不同。<ref name="Yeo" /><ref name=":4">{{cite journal|last1=Abou Elseoud|first1=Ahmed|last2=Littow|first2=Harri|last3=Remes|first3=Jukka|last4=Starck|first4=Tuomo|last5=Nikkinen|first5=Juha|last6=Nissilä|first6=Juuso|last7=Timonen|first7=Markku|last8=Tervonen|first8=Osmo|last9=Kiviniemi1|first9=Vesa|title=Group-ICA Model Order Highlights Patterns of Functional Brain Connectivity|journal= Frontiers in Systems Neuroscience|date=2011-06-03|volume=5|pages=37|doi=10.3389/fnsys.2011.00037|pmid=21687724|pmc=3109774 |doi-access=free}}</ref>一个模型理论认为,符合上述条件的神经模型只包含'''默认模式网络Default mode network'''和'''任务激活网络Task-positive network''',但目前'''<font color="#32CD32">大多数分析理论都包括从几个到17个不等的网络</font>。<ref name="Yeo" />'''下面列举了最常见且稳定的网络。'''<font color="#32CD32"> 人脑'''可以动态地重新配置参与功能网络的脑区</font>。<ref name="Petersen" /><ref name="Bassett">{{cite journal|last1=Bassett|first1=Daniella|last2=Bertolero|first2=Max|title=How Matter Becomes Mind|journal=Scientific American|date=July 2019|volume=321|issue=1|page=32|url=https://www.scientificamerican.com/|accessdate=23 June 2019 }}</ref> | |
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| + | 脑网络活动的中断与诸多神经精神疾病密切相关,如抑郁症、老年痴呆症、自闭症谱系障碍、精神分裂症、多动症<ref name=":5">{{cite journal |last1=Griffiths |first1=Kristi R. |last2=Braund |first2=Taylor A. |last3=Kohn |first3=Michael R. |last4=Clarke |first4=Simon |last5=Williams |first5=Leanne M. |last6=Korgaonkar |first6=Mayuresh S. |title=Structural brain network topology underpinning ADHD and response to methylphenidate treatment |journal=Translational Psychiatry |date=2 March 2021 |volume=11 |issue=1 |pages=1–9 |doi=10.1038/s41398-021-01278-x | pmc=7925571 |pmid=33654073 |url=https://www.nature.com/articles/s41398-021-01278-x#citeas |access-date=16 November 2021}}</ref>'''和'''躁郁症Bipolar disorder<ref name=":6">{{Cite journal|url=https://www.researchgate.net/publication/51639686|title=Large-scale brain networks and psychopathology: A unifying triple network model|last=Menon|first=Vinod|s2cid=26653572|journal=Trends in Cognitive Sciences|date=2011-09-09|volume=15|issue=10|pages=483–506|doi=10.1016/j.tics.2011.08.003|pmid=21908230}}</ref>'''。 | ||
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==核心网络== | ==核心网络== | ||
| − | + | [[File:Heine2012x3010.png|thumb|这是一个通过独立元素分析方法从静息状态脑功能性磁共振成像信号中分辨出10个大规模脑网络的例子。<ref name="Heine" />]] | |
| + | 因为脑网络可以在不同分辨率条件下、使用不同的神经生物学特性来识别,所以没有能够适用于所有情况的通用脑网络图谱。<ref name=":7">{{cite journal|last1=Eickhoff|first1=SB|last2=Yeo|first2=BTT|last3=Genon|first3=S|title=Imaging-based parcellations of the human brain.|journal=Nature Reviews. Neuroscience|date=November 2018|volume=19|issue=11|pages=672–686|doi=10.1038/s41583-018-0071-7|pmid=30305712|s2cid=52954265|url=http://juser.fz-juelich.de/record/856633/files/Eickhoff_Yeo_Genon_NRN_MainManuscriptInclFigures.pdf}}</ref>在承认这个问题的同时,Uddin,Yeo,和Spreng在2019年提出<ref name="Uddin2019">{{cite journal|last1=Uddin|first1=LQ|last2=Yeo|first2=BTT|last3=Spreng|first3=RN|title=Towards a Universal Taxonomy of Macro-scale Functional Human Brain Networks.|journal=Brain Topography|date=November 2019|volume=32|issue=6|pages=926–942|doi=10.1007/s10548-019-00744-6|pmid=31707621|pmc=7325607}}</ref>,综合考虑来自多个研究的证据<ref name=":8">{{cite journal|last1=Doucet|first1=GE|last2=Lee|first2=WH|last3=Frangou|first3=S|title=Evaluation of the spatial variability in the major resting-state networks across human brain functional atlases.|journal=Human Brain Mapping|date=2019-10-15|volume=40|issue=15|pages=4577–4587|doi=10.1002/hbm.24722|pmid=31322303|pmc=6771873}}</ref><ref name="Yeo" /><ref name=":9">{{cite journal|last1=Smith|first1=SM|last2=Fox|first2=PT|last3=Miller|first3=KL|last4=Glahn|first4=DC|last5=Fox|first5=PM|last6=Mackay|first6=CE|last7=Filippini|first7=N|last8=Watkins|first8=KE|last9=Toro|first9=R|last10=Laird|first10=AR|last11=Beckmann|first11=CF|title=Correspondence of the brain's functional architecture during activation and rest.|journal=Proceedings of the National Academy of Sciences of the United States of America|date=2009-08-04|volume=106|issue=31|pages=13040–5|doi=10.1073/pnas.0905267106|pmid=19620724|pmc=2722273|bibcode=2009PNAS..10613040S|doi-access=free}}</ref>,以下六个网络应该被定义为核心网络,以促进研究人员之间的交流。 | ||
| − | + | ===默认模式网络(内侧额顶骨)=== | |
| − | + | *默认模式网络在个体清醒和休息时都处于活跃状态。当个体专注于内部导向任务,比如做白日梦、展望未来、提取回忆和'''心智理论Theory of mind'''任务时,默认模式网络会被优先激活。它与专注于外部视觉信号的大脑系统成负相关。对默认模式网络的研究目前是所谓网络之中最为广泛的。<ref name="Bressler" /><ref name="Bassett" /><ref name=":10">{{Cite journal|date=2012-08-15|title=The serendipitous discovery of the brain's default network|journal=NeuroImage|language=en|volume=62|issue=2|pages=1137–1145|doi=10.1016/j.neuroimage.2011.10.035|pmid=22037421|issn=1053-8119|last1=Buckner|first1=Randy L.|s2cid=9880586}}</ref><ref name="Riedl" /><ref name="Yuan"> | |
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{{cite journal|last1=Yuan|first1=Rui|last2=Di|first2=Xin|last3=Taylor|first3=Paul A.|last4=Gohel|first4=Suril|last5=Tsai|first5=Yuan-Hsiung|last6=Biswal|first6=Bharat B.|title=Functional topography of the thalamocortical system in human|journal=Brain Structure and Function|date=30 April 2015|doi=10.1007/s00429-015-1018-7|pmid=25924563|pmc=6363530|volume=221|issue=4|pages=1971–1984}}</ref><ref name="Bell">{{cite journal|last1=Bell|first1=Peter T.|last2=Shine|first2=James M.|title=Estimating Large-Scale Network Convergence in the Human Functional Connectome|journal=Brain Connectivity|date=2015-11-09|volume=5|issue=9|doi=10.1089/brain.2015.0348|pmid=26005099|pages=565–74}}</ref><ref name="Heine">{{cite journal|last1=Heine|first1=Lizette|last2=Soddu|first2=Andrea|last3=Gomez|first3=Francisco|last4=Vanhaudenhuyse|first4=Audrey|last5=Tshibanda|first5=Luaba|last6=Thonnard|first6=Marie|last7=Charland-Verville|first7=Vanessa|last8=Kirsch|first8=Murielle|last9=Laureys|first9=Steven|last10=Demertzi|first10=Athena|title=Resting state networks and consciousness. Alterations of multiple resting state network connectivity in physiological, pharmacological and pathological consciousness states.|journal=Frontiers in Psychology|date=2012|volume=3|pages=295|doi=10.3389/fpsyg.2012.00295|pmid=22969735|pmc=3427917|doi-access=free}}</ref><ref name="Yeo">{{cite journal|last1=Yeo|first1=B. T. Thomas|last2=Krienen|first2=Fenna M.|last3=Sepulcre|first3=Jorge|last4=Sabuncu|first4=Mert R.|last5=Lashkari|first5=Danial|last6=Hollinshead|first6=Marisa|last7=Roffman|first7=Joshua L.|last8=Smoller|first8=Jordan W.|last9=Zöllei|first9=Lilla|last10=Polimeni|first10=Jonathan R.|last11=Fischl|first11=Bruce|last12=Liu|first12=Hesheng|last13=Buckner|first13=Randy L.|title=The organization of the human cerebral cortex estimated by intrinsic functional connectivity|journal=Journal of Neurophysiology|date=2011-09-01|volume=106|issue=3|pages=1125–1165|doi=10.1152/jn.00338.2011|pmid=21653723|pmc=3174820|bibcode=2011NatSD...2E0031H }}</ref><ref name="Shafiei">{{cite journal|last1=Shafiei|first1=Golia|last2=Zeighami|first2=Yashar|last3=Clark|first3=Crystal A.|last4=Coull|first4=Jennifer T.|last5=Nagano-Saito|first5=Atsuko|last6=Leyton|first6=Marco|last7=Dagher|first7=Alain|last8=Mišić|first8=Bratislav|title=Dopamine Signaling Modulates the Stability and Integration of Intrinsic Brain Networks|journal=Cerebral Cortex|date=2018-10-01|volume=29|issue=1|pages=397–409|doi=10.1093/cercor/bhy264|pmid=30357316|pmc=6294404 }}</ref><ref name="Bailey">{{cite journal|last1=Bailey|first1=Stephen K.|last2=Aboud|first2=Katherine S.|last3=Nguyen|first3=Tin Q.|last4=Cutting|first4=Laurie E.|title=Applying a network framework to the neurobiology of reading and dyslexia|journal=Journal of Neurodevelopmental Disorders|date=13 December 2018|volume=10|issue=1|page=37|doi=10.1186/s11689-018-9251-z|pmid=30541433|pmc=6291929 }}</ref> | {{cite journal|last1=Yuan|first1=Rui|last2=Di|first2=Xin|last3=Taylor|first3=Paul A.|last4=Gohel|first4=Suril|last5=Tsai|first5=Yuan-Hsiung|last6=Biswal|first6=Bharat B.|title=Functional topography of the thalamocortical system in human|journal=Brain Structure and Function|date=30 April 2015|doi=10.1007/s00429-015-1018-7|pmid=25924563|pmc=6363530|volume=221|issue=4|pages=1971–1984}}</ref><ref name="Bell">{{cite journal|last1=Bell|first1=Peter T.|last2=Shine|first2=James M.|title=Estimating Large-Scale Network Convergence in the Human Functional Connectome|journal=Brain Connectivity|date=2015-11-09|volume=5|issue=9|doi=10.1089/brain.2015.0348|pmid=26005099|pages=565–74}}</ref><ref name="Heine">{{cite journal|last1=Heine|first1=Lizette|last2=Soddu|first2=Andrea|last3=Gomez|first3=Francisco|last4=Vanhaudenhuyse|first4=Audrey|last5=Tshibanda|first5=Luaba|last6=Thonnard|first6=Marie|last7=Charland-Verville|first7=Vanessa|last8=Kirsch|first8=Murielle|last9=Laureys|first9=Steven|last10=Demertzi|first10=Athena|title=Resting state networks and consciousness. Alterations of multiple resting state network connectivity in physiological, pharmacological and pathological consciousness states.|journal=Frontiers in Psychology|date=2012|volume=3|pages=295|doi=10.3389/fpsyg.2012.00295|pmid=22969735|pmc=3427917|doi-access=free}}</ref><ref name="Yeo">{{cite journal|last1=Yeo|first1=B. T. Thomas|last2=Krienen|first2=Fenna M.|last3=Sepulcre|first3=Jorge|last4=Sabuncu|first4=Mert R.|last5=Lashkari|first5=Danial|last6=Hollinshead|first6=Marisa|last7=Roffman|first7=Joshua L.|last8=Smoller|first8=Jordan W.|last9=Zöllei|first9=Lilla|last10=Polimeni|first10=Jonathan R.|last11=Fischl|first11=Bruce|last12=Liu|first12=Hesheng|last13=Buckner|first13=Randy L.|title=The organization of the human cerebral cortex estimated by intrinsic functional connectivity|journal=Journal of Neurophysiology|date=2011-09-01|volume=106|issue=3|pages=1125–1165|doi=10.1152/jn.00338.2011|pmid=21653723|pmc=3174820|bibcode=2011NatSD...2E0031H }}</ref><ref name="Shafiei">{{cite journal|last1=Shafiei|first1=Golia|last2=Zeighami|first2=Yashar|last3=Clark|first3=Crystal A.|last4=Coull|first4=Jennifer T.|last5=Nagano-Saito|first5=Atsuko|last6=Leyton|first6=Marco|last7=Dagher|first7=Alain|last8=Mišić|first8=Bratislav|title=Dopamine Signaling Modulates the Stability and Integration of Intrinsic Brain Networks|journal=Cerebral Cortex|date=2018-10-01|volume=29|issue=1|pages=397–409|doi=10.1093/cercor/bhy264|pmid=30357316|pmc=6294404 }}</ref><ref name="Bailey">{{cite journal|last1=Bailey|first1=Stephen K.|last2=Aboud|first2=Katherine S.|last3=Nguyen|first3=Tin Q.|last4=Cutting|first4=Laurie E.|title=Applying a network framework to the neurobiology of reading and dyslexia|journal=Journal of Neurodevelopmental Disorders|date=13 December 2018|volume=10|issue=1|page=37|doi=10.1186/s11689-018-9251-z|pmid=30541433|pmc=6291929 }}</ref> | ||
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===突显网络(扣带回-岛叶)=== | ===突显网络(扣带回-岛叶)=== | ||
| − | *突显网络由'''<font color="#32CD32"> 前(双)岛、前扣带回皮层和三个皮层下结构(腹侧纹状体、黑质/腹侧被盖区)</font>'''组成,<ref name=":11" /><ref name=":0" />它在监测外部输入和内部脑活动的''' | + | *突显网络由'''<font color="#32CD32"> 前(双)岛、前扣带回皮层和三个皮层下结构(腹侧纹状体、黑质/腹侧被盖区) the anterior (bilateral) insula, dorsal anterior cingulate cortex, and three subcortical structures</font>'''组成,<ref name=":11">{{Cite journal|last1=Steimke|first1=Rosa|last2=Nomi|first2=Jason S.|last3=Calhoun|first3=Vince D.|last4=Stelzel|first4=Christine|last5=Paschke|first5=Lena M.|last6=Gaschler|first6=Robert|last7=Goschke|first7=Thomas|last8=Walter|first8=Henrik|last9=Uddin|first9=Lucina Q.|date=2017-12-01|title=Salience network dynamics underlying successful resistance of temptation|journal=Social Cognitive and Affective Neuroscience|language=en|volume=12|issue=12|pages=1928–1939|doi=10.1093/scan/nsx123|pmid=29048582|pmc=5716209|issn=1749-5016|doi-access=free}}</ref><ref name=":0">{{Citation|last=Menon|first=V.|title=Brain Mapping|chapter=Salience Network|date=2015-01-01|chapter-url=http://www.sciencedirect.com/science/article/pii/B978012397025100052X|pages=597–611|editor-last=Toga|editor-first=Arthur W.|publisher=Academic Press|isbn=978-0-12-397316-0|access-date=2019-12-08|doi=10.1016/B978-0-12-397025-1.00052-X}}</ref>它在监测外部输入和内部脑活动的'''凸显程度Salience'''中发挥着关键作用。<ref name="Riedl" /><ref name="Bressler" /><ref name="Bassett" /><ref name="Yuan" /><ref name="Heine" /><ref name="Yeo" /><ref name="Shafiei" />具体来说,突显网络通过识别重要的生理、认知活动来帮助引导注意力。<ref name=":0" /><ref name="Bailey" /> |
| − | *突显网络包括主要由右半球的''' | + | *突显网络包括主要由右半球的'''颞顶联合区Temporoparietal junction'''和腹侧'''额叶Frontal cortex'''皮层组成的腹侧注意网络。<ref name="Uddin2019" /><ref name="Vossel" />当行为相关的刺激意外发生时,这些区域会对此做出反应。在自上而下加工注意焦点的过程中(例如使用视觉搜索某件物品时),腹侧注意网络会受到抑制。这种抑制反应可以防止目标驱动的注意力被不相关的刺激分散。当找到目标或相关信息时,突显网络会被再次激活。<ref name="Vossel" /><ref name=":12">{{Cite journal|last1=Shulman|first1=Gordon L.|last2=McAvoy|first2=Mark P.|last3=Cowan|first3=Melanie C.|last4=Astafiev|first4=Serguei V.|last5=Tansy|first5=Aaron P.|last6=d'Avossa|first6=Giovanni|last7=Corbetta|first7=Maurizio|date=2003-11-01|title=Quantitative Analysis of Attention and Detection Signals During Visual Search|journal=Journal of Neurophysiology|volume=90|issue=5|pages=3384–3397|doi=10.1152/jn.00343.2003|pmid=12917383|issn=0022-3077}}</ref> |
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===注意网络(背侧额顶骨)=== | ===注意网络(背侧额顶骨)=== | ||
| − | *这个网络参与了自发的、自上而下的注意力分配。<ref name="Riedl" /><ref name="Yuan" /><ref name="Bell" /><ref name="Yeo" /><ref name="Shafiei" /><ref name="Vossel" | + | *这个网络参与了自发的、自上而下的注意力分配。<ref name="Riedl" /><ref name="Yuan" /><ref name="Bell" /><ref name="Yeo" /><ref name="Shafiei" /><ref name="Vossel">{{cite journal|last1=Vossel|first1=Simone|last2=Geng|first2=Joy J.|last3=Fink|first3=Gereon R.|title=Dorsal and Ventral Attention Systems: Distinct Neural Circuits but Collaborative Roles|journal=The Neuroscientist|date=2014|volume=20|issue=2|pages=150–159|doi=10.1177/1073858413494269|pmid=23835449|pmc=4107817}}</ref><ref name="Hutton">{{cite journal|last1=Hutton|first1=John S.|last2=Dudley|first2=Jonathan|last3=Horowitz-Kraus|first3=Tzipi|last4=DeWitt|first4=Tom|last5=Holland|first5=Scott K.|title=Functional Connectivity of Attention, Visual, and Language Networks During Audio, Illustrated, and Animated Stories in Preschool-Age Children|journal=Brain Connectivity|date=1 September 2019|volume=9|issue=7|pages=580–592|doi=10.1089/brain.2019.0679|pmid=31144523|pmc=6775495|ref=Hutton}}</ref>在背侧注意网络中,顶内沟和额眼影响着大脑的视觉区域。这些影响因素决定了注意力的方向。<ref name=":13">{{Cite journal|last1=Fox|first1=Michael D.|last2=Corbetta|first2=Maurizio|last3=Snyder|first3=Abraham Z.|last4=Vincent|first4=Justin L.|last5=Raichle|first5=Marcus E.|date=2006-06-27|title=Spontaneous neuronal activity distinguishes human dorsal and ventral attention systems|journal=Proceedings of the National Academy of Sciences|language=en|volume=103|issue=26|pages=10046–10051|doi=10.1073/pnas.0604187103|issn=0027-8424|pmid=16788060|pmc=1480402|bibcode=2006PNAS..10310046F|doi-access=free}}</ref><ref name="Vossel" /><ref name="Bailey" /> |
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===控制网络(侧额顶骨)=== | ===控制网络(侧额顶骨)=== | ||
| − | *这个网络参与了认知控制的启动与调节,它包括了大脑的18个亚区。<ref name=":14" />额顶网络与其他网络的参与程度和流体智力之间存在着有很强的相关性。<ref name=":15" /> | + | *这个网络参与了认知控制的启动与调节,它包括了大脑的18个亚区。<ref name=":14">{{Cite journal|last1=Scolari|first1=Miranda|last2=Seidl-Rathkopf|first2=Katharina N|last3=Kastner|first3=Sabine|date=2015-02-01|title=Functions of the human frontoparietal attention network: Evidence from neuroimaging|journal=Current Opinion in Behavioral Sciences|series=Cognitive control|volume=1|pages=32–39|doi=10.1016/j.cobeha.2014.08.003|issn=2352-1546|pmid=27398396|pmc=4936532}}</ref>额顶网络与其他网络的参与程度和流体智力之间存在着有很强的相关性。<ref name=":15">{{Cite journal|last1=Marek|first1=Scott|last2=Dosenbach|first2=Nico U. F.|date=June 2018|title=The frontoparietal network: function, electrophysiology, and importance of individual precision mapping|journal=Dialogues in Clinical Neuroscience|volume=20|issue=2|pages=133–140|doi=10.31887/DCNS.2018.20.2/smarek|issn=1294-8322|pmc=6136121|pmid=30250390}}</ref> |
*在其它版本中,这种网络也被称为中央执行(或执行控制)网络和认知控制网络。<ref name="Uddin2019" /> | *在其它版本中,这种网络也被称为中央执行(或执行控制)网络和认知控制网络。<ref name="Uddin2019" /> | ||
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===感觉运动网络(中央区域) === | ===感觉运动网络(中央区域) === | ||
| − | *这个网络参与了躯体感觉信息的加工和运动的协调。<ref name="Heine" /><ref name="Yeo" /><ref name="Shafiei" /><ref name="Bassett" /><ref name="Yuan" />''' | + | *这个网络参与了躯体感觉信息的加工和运动的协调。<ref name="Heine" /><ref name="Yeo" /><ref name="Shafiei" /><ref name="Bassett" /><ref name="Yuan" />'''听觉皮层 Auditory cortex'''可能也包括在内。<ref name="Uddin2019" /><ref name="Yeo" /> |
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===视觉网络(枕部)=== | ===视觉网络(枕部)=== | ||
| − | *这个网络处理视觉信息。<ref name="Yang" /> | + | *这个网络处理视觉信息。<ref name="Yang">{{cite journal|last1=Yang|first1=Yan-li|last2=Deng|first2=Hong-xia|last3=Xing|first3=Gui-yang|last4=Xia|first4=Xiao-luan|last5=Li|first5=Hai-fang|title=Brain functional network connectivity based on a visual task: visual information processing-related brain regions are significantly activated in the task state|journal=Neural Regeneration Research|date=2015|volume=10|issue=2|pages=298–307|doi=10.4103/1673-5374.152386|pmid=25883631|pmc=4392680 }}</ref> |
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==其他网络== | ==其他网络== | ||
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*视知觉/图像网络<ref name="Hutton" /> | *视知觉/图像网络<ref name="Hutton" /> | ||
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| − | == | + | ==另见== |
*[[复杂网络]] | *[[复杂网络]] | ||
*[[神经网络]] | *[[神经网络]] | ||
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| − | + | ---- | |
| + | 本中文词条由Shenky20翻译,[[用户:薄荷|薄荷]]编辑,如有问题,欢迎在讨论页面留言。 | ||
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| − | [[Category: | + | '''本词条内容源自wikipedia及公开资料,遵守 CC3.0协议。''' |
| + | [[Category:神经科学]] | ||
| + | [[Category:神经编码]] | ||
| + | [[Category:神经回路]] | ||
| + | [[Category:神经生理学]] | ||
2022年4月10日 (日) 15:51的版本
大规模脑网络 Large-scale brain networks(也称为内在大脑网络 Intrinsic brain networks)是在对基于血氧水平依赖效应BOLD的功能性磁共振成像 Functional magnetic resonance imaging(fMRI)信号[1]的统计分析或其他记录方法(如脑电图 Electroencephalography(EEG)[2]、正电子发射断层扫描技术 Positron emission tomography(PET)[3]和脑磁图 Magnetoencephalography(MEG)[4])中,表现出功能连接 Functional connectivity的脑区 Brain regions的集合。根据神经科学中一个新出现的范式,认知任务不是由单个脑区独立执行的,而是由几个互不相连的脑区“功能连接”组成的网络执行的。功能连接网络可以通过数据聚类Cluster analysis、空间独立元素分析ICA、种子点方法等算法来发现。[5]同步的脑区也可以用脑电图、脑磁图或其他动态脑信号的远程同步来识别。.[6]
大规模脑网络中,连接在一起的脑区集合因认知功能的不同而不同。[7]当认知状态不明确(即主体处于“静止”状态)时,大规模脑网络是一个静息状态Resting state网络(RSN)。作为一个具有图形特征的物理系统,[6]大规模脑网络既有节点又有边,不能简单地通过脑区的共同激活来识别。近几十年来,成像技术不断进步,同时图论、动力学系统领域出现了新的技术手段,这使得脑网络分析变得可行。
大规模脑网络是通过其功能来进行识别的。通过研究大规模脑网络建立神经模型,对不同脑区组合所形成的自组织联合体如何实现不同的认知Cognition功能进行解释,就能够为认知理解提供一个连贯的框架。识别算法和参数的不同会导致所识别出的上述联合体的数量和组成有所不同。[8][9]一个模型理论认为,符合上述条件的神经模型只包含默认模式网络Default mode network和任务激活网络Task-positive network,但目前大多数分析理论都包括从几个到17个不等的网络。[8]下面列举了最常见且稳定的网络。 人脑可以动态地重新配置参与功能网络的脑区。[5][10]
脑网络活动的中断与诸多神经精神疾病密切相关,如抑郁症、老年痴呆症、自闭症谱系障碍、精神分裂症、多动症[11]和躁郁症Bipolar disorder[12]。
核心网络
这是一个通过独立元素分析方法从静息状态脑功能性磁共振成像信号中分辨出10个大规模脑网络的例子。[13]
因为脑网络可以在不同分辨率条件下、使用不同的神经生物学特性来识别,所以没有能够适用于所有情况的通用脑网络图谱。[14]在承认这个问题的同时,Uddin,Yeo,和Spreng在2019年提出[15],综合考虑来自多个研究的证据[16][8][17],以下六个网络应该被定义为核心网络,以促进研究人员之间的交流。
默认模式网络(内侧额顶骨)
- 默认模式网络在个体清醒和休息时都处于活跃状态。当个体专注于内部导向任务,比如做白日梦、展望未来、提取回忆和心智理论Theory of mind任务时,默认模式网络会被优先激活。它与专注于外部视觉信号的大脑系统成负相关。对默认模式网络的研究目前是所谓网络之中最为广泛的。[6][10][18][1][19][20][13][8][21][22]
突显网络(扣带回-岛叶)
- 突显网络由 前(双)岛、前扣带回皮层和三个皮层下结构(腹侧纹状体、黑质/腹侧被盖区) the anterior (bilateral) insula, dorsal anterior cingulate cortex, and three subcortical structures组成,[23][24]它在监测外部输入和内部脑活动的凸显程度Salience中发挥着关键作用。[1][6][10][19][13][8][21]具体来说,突显网络通过识别重要的生理、认知活动来帮助引导注意力。[24][22]
- 突显网络包括主要由右半球的颞顶联合区Temporoparietal junction和腹侧额叶Frontal cortex皮层组成的腹侧注意网络。[15][25]当行为相关的刺激意外发生时,这些区域会对此做出反应。在自上而下加工注意焦点的过程中(例如使用视觉搜索某件物品时),腹侧注意网络会受到抑制。这种抑制反应可以防止目标驱动的注意力被不相关的刺激分散。当找到目标或相关信息时,突显网络会被再次激活。[25][26]
注意网络(背侧额顶骨)
- 这个网络参与了自发的、自上而下的注意力分配。[1][19][20][8][21][25][27]在背侧注意网络中,顶内沟和额眼影响着大脑的视觉区域。这些影响因素决定了注意力的方向。[28][25][22]
控制网络(侧额顶骨)
- 这个网络参与了认知控制的启动与调节,它包括了大脑的18个亚区。[29]额顶网络与其他网络的参与程度和流体智力之间存在着有很强的相关性。[30]
- 在其它版本中,这种网络也被称为中央执行(或执行控制)网络和认知控制网络。[15]
感觉运动网络(中央区域)
视觉网络(枕部)
- 这个网络处理视觉信息。[31]
其他网络
不同的方法和数据已经能够确定上述核心网络以外的几个大脑网络,其中许多网络之间存在极大的重叠,部分网络实际上是核心网络更具特点的子集。[15]
- 边缘网络[10][8][22]
- 听觉网络[19][13]
- 右/左执行网络[19][13]
- 小脑网络[20][13]
- 空间注意网络[1][6]
- 语言网络[6][27]
- 外侧视觉网络[19][20][13]
- 颞骨网络[8][21]
- 视知觉/图像网络[27]
另见
参考文献
- ↑ 1.0 1.1 1.2 1.3 1.4 Riedl, Valentin; Utz, Lukas; Castrillón, Gabriel; Grimmer, Timo; Rauschecker, Josef P.; Ploner, Markus; Friston, Karl J.; Drzezga, Alexander; Sorg, Christian (January 12, 2016). "Metabolic connectivity mapping reveals effective connectivity in the resting human brain". PNAS. 113 (2): 428–433. Bibcode:2016PNAS..113..428R. doi:10.1073/pnas.1513752113. PMC 4720331. PMID 26712010.
- ↑ Foster, Brett L.; Parvizi, Josef (2012-03-01). "Resting oscillations and cross-frequency coupling in the human posteromedial cortex". NeuroImage. 60 (1): 384–391. doi:10.1016/j.neuroimage.2011.12.019. ISSN 1053-8119. PMC 3596417. PMID 22227048.
- ↑ Buckner, Randy L.; Andrews‐Hanna, Jessica R.; Schacter, Daniel L. (2008). "The Brain's Default Network". Annals of the New York Academy of Sciences (in English). 1124 (1): 1–38. Bibcode:2008NYASA1124....1B. doi:10.1196/annals.1440.011. ISSN 1749-6632. PMID 18400922. S2CID 3167595.
- ↑ Morris, Peter G.; Smith, Stephen M.; Barnes, Gareth R.; Stephenson, Mary C.; Hale, Joanne R.; Price, Darren; Luckhoo, Henry; Woolrich, Mark; Brookes, Matthew J. (2011-10-04). "Investigating the electrophysiological basis of resting state networks using magnetoencephalography". Proceedings of the National Academy of Sciences (in English). 108 (40): 16783–16788. Bibcode:2011PNAS..10816783B. doi:10.1073/pnas.1112685108. ISSN 0027-8424. PMC 3189080. PMID 21930901.
- ↑ 5.0 5.1 Petersen, Steven; Sporns, Olaf (October 2015). "Brain Networks and Cognitive Architectures". Neuron. 88 (1): 207–219. doi:10.1016/j.neuron.2015.09.027. PMC 4598639. PMID 26447582.
- ↑ 6.0 6.1 6.2 6.3 6.4 6.5 Bressler, Steven L.; Menon, Vinod (June 2010). "Large scale brain networks in cognition: emerging methods and principles". Trends in Cognitive Sciences. 14 (6): 233–290. doi:10.1016/j.tics.2010.04.004. PMID 20493761. S2CID 5967761. Retrieved 24 January 2016.
- ↑ Bressler, Steven L. (2008). "Neurocognitive networks". Scholarpedia. 3 (2): 1567. Bibcode:2008SchpJ...3.1567B. doi:10.4249/scholarpedia.1567.
- ↑ 8.0 8.1 8.2 8.3 8.4 8.5 8.6 8.7 8.8 8.9 Yeo, B. T. Thomas; Krienen, Fenna M.; Sepulcre, Jorge; Sabuncu, Mert R.; Lashkari, Danial; Hollinshead, Marisa; Roffman, Joshua L.; Smoller, Jordan W.; Zöllei, Lilla; Polimeni, Jonathan R.; Fischl, Bruce; Liu, Hesheng; Buckner, Randy L. (2011-09-01). "The organization of the human cerebral cortex estimated by intrinsic functional connectivity". Journal of Neurophysiology. 106 (3): 1125–1165. Bibcode:2011NatSD...2E0031H. doi:10.1152/jn.00338.2011. PMC 3174820. PMID 21653723.
- ↑ Abou Elseoud, Ahmed; Littow, Harri; Remes, Jukka; Starck, Tuomo; Nikkinen, Juha; Nissilä, Juuso; Timonen, Markku; Tervonen, Osmo; Kiviniemi1, Vesa (2011-06-03). "Group-ICA Model Order Highlights Patterns of Functional Brain Connectivity". Frontiers in Systems Neuroscience. 5: 37. doi:10.3389/fnsys.2011.00037. PMC 3109774. PMID 21687724.
- ↑ 10.0 10.1 10.2 10.3 10.4 Bassett, Daniella; Bertolero, Max (July 2019). "How Matter Becomes Mind". Scientific American. 321 (1): 32. Retrieved 23 June 2019.
- ↑ Griffiths, Kristi R.; Braund, Taylor A.; Kohn, Michael R.; Clarke, Simon; Williams, Leanne M.; Korgaonkar, Mayuresh S. (2 March 2021). "Structural brain network topology underpinning ADHD and response to methylphenidate treatment". Translational Psychiatry. 11 (1): 1–9. doi:10.1038/s41398-021-01278-x. PMC 7925571. PMID 33654073. Retrieved 16 November 2021.
- ↑ Menon, Vinod (2011-09-09). "Large-scale brain networks and psychopathology: A unifying triple network model". Trends in Cognitive Sciences. 15 (10): 483–506. doi:10.1016/j.tics.2011.08.003. PMID 21908230. S2CID 26653572.
- ↑ 13.0 13.1 13.2 13.3 13.4 13.5 13.6 13.7 Heine, Lizette; Soddu, Andrea; Gomez, Francisco; Vanhaudenhuyse, Audrey; Tshibanda, Luaba; Thonnard, Marie; Charland-Verville, Vanessa; Kirsch, Murielle; Laureys, Steven; Demertzi, Athena (2012). "Resting state networks and consciousness. Alterations of multiple resting state network connectivity in physiological, pharmacological and pathological consciousness states". Frontiers in Psychology. 3: 295. doi:10.3389/fpsyg.2012.00295. PMC 3427917. PMID 22969735.
- ↑ Eickhoff, SB; Yeo, BTT; Genon, S (November 2018). "Imaging-based parcellations of the human brain" (PDF). Nature Reviews. Neuroscience. 19 (11): 672–686. doi:10.1038/s41583-018-0071-7. PMID 30305712. S2CID 52954265.
- ↑ 15.0 15.1 15.2 15.3 15.4 Uddin, LQ; Yeo, BTT; Spreng, RN (November 2019). "Towards a Universal Taxonomy of Macro-scale Functional Human Brain Networks". Brain Topography. 32 (6): 926–942. doi:10.1007/s10548-019-00744-6. PMC 7325607. PMID 31707621.
- ↑ Doucet, GE; Lee, WH; Frangou, S (2019-10-15). "Evaluation of the spatial variability in the major resting-state networks across human brain functional atlases". Human Brain Mapping. 40 (15): 4577–4587. doi:10.1002/hbm.24722. PMC 6771873. PMID 31322303.
- ↑ Smith, SM; Fox, PT; Miller, KL; Glahn, DC; Fox, PM; Mackay, CE; Filippini, N; Watkins, KE; Toro, R; Laird, AR; Beckmann, CF (2009-08-04). "Correspondence of the brain's functional architecture during activation and rest". Proceedings of the National Academy of Sciences of the United States of America. 106 (31): 13040–5. Bibcode:2009PNAS..10613040S. doi:10.1073/pnas.0905267106. PMC 2722273. PMID 19620724.
- ↑ Buckner, Randy L. (2012-08-15). "The serendipitous discovery of the brain's default network". NeuroImage (in English). 62 (2): 1137–1145. doi:10.1016/j.neuroimage.2011.10.035. ISSN 1053-8119. PMID 22037421. S2CID 9880586.
- ↑ 19.0 19.1 19.2 19.3 19.4 19.5 19.6 Yuan, Rui; Di, Xin; Taylor, Paul A.; Gohel, Suril; Tsai, Yuan-Hsiung; Biswal, Bharat B. (30 April 2015). "Functional topography of the thalamocortical system in human". Brain Structure and Function. 221 (4): 1971–1984. doi:10.1007/s00429-015-1018-7. PMC 6363530. PMID 25924563.
- ↑ 20.0 20.1 20.2 20.3 Bell, Peter T.; Shine, James M. (2015-11-09). "Estimating Large-Scale Network Convergence in the Human Functional Connectome". Brain Connectivity. 5 (9): 565–74. doi:10.1089/brain.2015.0348. PMID 26005099.
- ↑ 21.0 21.1 21.2 21.3 21.4 Shafiei, Golia; Zeighami, Yashar; Clark, Crystal A.; Coull, Jennifer T.; Nagano-Saito, Atsuko; Leyton, Marco; Dagher, Alain; Mišić, Bratislav (2018-10-01). "Dopamine Signaling Modulates the Stability and Integration of Intrinsic Brain Networks". Cerebral Cortex. 29 (1): 397–409. doi:10.1093/cercor/bhy264. PMC 6294404. PMID 30357316.
- ↑ 22.0 22.1 22.2 22.3 Bailey, Stephen K.; Aboud, Katherine S.; Nguyen, Tin Q.; Cutting, Laurie E. (13 December 2018). "Applying a network framework to the neurobiology of reading and dyslexia". Journal of Neurodevelopmental Disorders. 10 (1): 37. doi:10.1186/s11689-018-9251-z. PMC 6291929. PMID 30541433.
- ↑ Steimke, Rosa; Nomi, Jason S.; Calhoun, Vince D.; Stelzel, Christine; Paschke, Lena M.; Gaschler, Robert; Goschke, Thomas; Walter, Henrik; Uddin, Lucina Q. (2017-12-01). "Salience network dynamics underlying successful resistance of temptation". Social Cognitive and Affective Neuroscience (in English). 12 (12): 1928–1939. doi:10.1093/scan/nsx123. ISSN 1749-5016. PMC 5716209. PMID 29048582.
- ↑ 24.0 24.1 Menon, V. (2015-01-01), "Salience Network", in Toga, Arthur W. (ed.), Brain Mapping, Academic Press, pp. 597–611, doi:10.1016/B978-0-12-397025-1.00052-X, ISBN 978-0-12-397316-0, retrieved 2019-12-08
- ↑ 25.0 25.1 25.2 25.3 Vossel, Simone; Geng, Joy J.; Fink, Gereon R. (2014). "Dorsal and Ventral Attention Systems: Distinct Neural Circuits but Collaborative Roles". The Neuroscientist. 20 (2): 150–159. doi:10.1177/1073858413494269. PMC 4107817. PMID 23835449.
- ↑ Shulman, Gordon L.; McAvoy, Mark P.; Cowan, Melanie C.; Astafiev, Serguei V.; Tansy, Aaron P.; d'Avossa, Giovanni; Corbetta, Maurizio (2003-11-01). "Quantitative Analysis of Attention and Detection Signals During Visual Search". Journal of Neurophysiology. 90 (5): 3384–3397. doi:10.1152/jn.00343.2003. ISSN 0022-3077. PMID 12917383.
- ↑ 27.0 27.1 27.2 Hutton, John S.; Dudley, Jonathan; Horowitz-Kraus, Tzipi; DeWitt, Tom; Holland, Scott K. (1 September 2019). "Functional Connectivity of Attention, Visual, and Language Networks During Audio, Illustrated, and Animated Stories in Preschool-Age Children". Brain Connectivity. 9 (7): 580–592. doi:10.1089/brain.2019.0679. PMC 6775495. PMID 31144523.
- ↑ Fox, Michael D.; Corbetta, Maurizio; Snyder, Abraham Z.; Vincent, Justin L.; Raichle, Marcus E. (2006-06-27). "Spontaneous neuronal activity distinguishes human dorsal and ventral attention systems". Proceedings of the National Academy of Sciences (in English). 103 (26): 10046–10051. Bibcode:2006PNAS..10310046F. doi:10.1073/pnas.0604187103. ISSN 0027-8424. PMC 1480402. PMID 16788060.
- ↑ Scolari, Miranda; Seidl-Rathkopf, Katharina N; Kastner, Sabine (2015-02-01). "Functions of the human frontoparietal attention network: Evidence from neuroimaging". Current Opinion in Behavioral Sciences. Cognitive control. 1: 32–39. doi:10.1016/j.cobeha.2014.08.003. ISSN 2352-1546. PMC 4936532. PMID 27398396.
- ↑ Marek, Scott; Dosenbach, Nico U. F. (June 2018). "The frontoparietal network: function, electrophysiology, and importance of individual precision mapping". Dialogues in Clinical Neuroscience. 20 (2): 133–140. doi:10.31887/DCNS.2018.20.2/smarek. ISSN 1294-8322. PMC 6136121. PMID 30250390.
- ↑ Yang, Yan-li; Deng, Hong-xia; Xing, Gui-yang; Xia, Xiao-luan; Li, Hai-fang (2015). "Brain functional network connectivity based on a visual task: visual information processing-related brain regions are significantly activated in the task state". Neural Regeneration Research. 10 (2): 298–307. doi:10.4103/1673-5374.152386. PMC 4392680. PMID 25883631.
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