{ "labelLang" : "hun", "responseDate" : "2024-03-28 12:30", "content" : { "otype" : "JournalArticle", "mtid" : 31279815, "status" : "VALIDATED", "published" : true, "comment" : "Department of Pediatrics, Division of Developmental Behavioral Pediatrics, Greenville Health System, 200 Patewood Drive, Suite A200, Greenville, SC 29615, United States \n University of South Carolina School of Medicine Greenville, 200 Patewood Drive, Greenville, SC 29615, United States \n University of Miami, Miller School of Medicine, Department Miami Project to Cure Paralysis, Miami, FL 33136, United States \n Department of Psychiatry, Faculty of Medicine, University of São Paulo, São Paulo, Brazil \n Department of Neurology, Faculty of Medicine, University of São Paulo, São Paulo, Brazil \n State Key Laboratory of Cognitive Neuroscience and Learning & IDG/McGovern Institute for Brain Research, Beijing Normal University, Beijing, China \n Export Date: 15 April 2020 \n CODEN: PCAMD \n Correspondence Address: Casanova, M.F.; Department of Pediatrics, Division of Developmental Behavioral Pediatrics, Greenville Health System, 200 Patewood Drive, Suite A200, United States; email: Manuel.Casanova@prismahealth.org \n Funding details: National Institutes of Health, NIH, MH86784 \n Funding text 1: This article is based on several studies partially supported by a grant from the National Institutes of Health ( MH86784 ) awarded to M.F. Casanova.\nDepartment of Pediatrics, Division of Developmental Behavioral Pediatrics, Greenville Health System, 200 Patewood Drive, Suite A200, Greenville, SC 29615, United States \n University of South Carolina School of Medicine Greenville, 200 Patewood Drive, Greenville, SC 29615, United States \n University of Miami, Miller School of Medicine, Department Miami Project to Cure Paralysis, Miami, FL 33136, United States \n Department of Psychiatry, Faculty of Medicine, University of São Paulo, São Paulo, Brazil \n Department of Neurology, Faculty of Medicine, University of São Paulo, São Paulo, Brazil \n State Key Laboratory of Cognitive Neuroscience and Learning & IDG/McGovern Institute for Brain Research, Beijing Normal University, Beijing, China \n Export Date: 18 March 2021 \n CODEN: PCAMD \n Correspondence Address: Casanova, M.F.; Department of Pediatrics, 200 Patewood Drive, Suite A200, United States; email: Manuel.Casanova@prismahealth.org \n Chemicals/CAS: parvalbumin, 56094-12-3, 83667-75-8 \n Funding details: National Institutes of Health, NIH, MH86784 \n Funding text 1: This article is based on several studies partially supported by a grant from the National Institutes of Health ( MH86784 ) awarded to M.F. Casanova.", "unhandledTickets" : 0, "deleted" : false, "lastRefresh" : "2021-10-02T10:31:57.084+0000", "lastModified" : "2020-08-25T11:19:34.217+0000", "created" : "2020-04-15T16:47:55.518+0000", "creator" : { "otype" : "Admin", "mtid" : 10065463, "link" : "/api/admin/10065463", "label" : "Turek Márta (KOKI admin 4)", "familyName" : "Turek", "givenName" : "Márta", "published" : true, "snippet" : true }, "lastDuplumSearch" : "2023-04-19T10:14:44.241+0000", "validated" : "2020-08-25T11:19:33.591+0000", "validator" : { "otype" : "Admin", "mtid" : 565, "link" : "/api/admin/565", "label" : "WoS import (admin)", "familyName" : "WoS", "givenName" : "import", "published" : true, "snippet" : true }, "core" : false, "citation" : true, "publicationPending" : true, "type" : { "otype" : "PublicationType", "mtid" : 24, "link" : "/api/publicationtype/24", "label" : "Folyóiratcikk", "code" : 24, "otypeName" : "JournalArticle", "listPosition" : 1, "published" : true, "oldId" : 24, "snippet" : true }, "subType" : { "otype" : "SubType", "mtid" : 1134514, "link" : "/api/subtype/1134514", "label" : "Összefoglaló cikk (Folyóiratcikk)", "name" : "Összefoglaló cikk", "nameEng" : "Survey paper", "docType" : { "otype" : "PublicationType", "mtid" : 24, "link" : "/api/publicationtype/24", "label" : "Folyóiratcikk", "code" : 24, "otypeName" : "JournalArticle", "listPosition" : 1, "published" : true, "oldId" : 24, "snippet" : true }, "listPosition" : 102, "published" : true, "oldId" : 1134514, "snippet" : true }, "category" : { "otype" : "Category", "mtid" : 1, "link" : "/api/category/1", "label" : "Tudományos", "published" : true, "oldId" : 1, "snippet" : true }, "languages" : [ { "otype" : "Language", "mtid" : 10002, "link" : "/api/language/10002", "label" : "Angol", "name" : "Angol", "nameEng" : "English", "published" : true, "oldId" : 2, "snippet" : true } ], "firstAuthor" : "Casanova, M.F.", "authorships" : [ { "otype" : "PersonAuthorship", "mtid" : 91420085, "link" : "/api/authorship/91420085", "label" : "Casanova, M.F. ✉", "listPosition" : 1, "share" : 0.0, "first" : true, "last" : false, "corresponding" : true, "familyName" : "Casanova", "givenName" : "M.F.", "authorTyped" : true, "editorTyped" : false, "otherTyped" : false, "type" : { "otype" : "AuthorshipType", "mtid" : 1, "link" : "/api/authorshiptype/1", "label" : "Szerző", "code" : 0, "published" : true, "oldId" : 0, "snippet" : true }, "published" : false, "snippet" : true }, { "otype" : "PersonAuthorship", "mtid" : 91420086, "link" : "/api/authorship/91420086", "label" : "Sokhadze, E.M.", "listPosition" : 2, "share" : 0.0, "first" : false, "last" : false, "corresponding" : false, "familyName" : "Sokhadze", "givenName" : "E.M.", "authorTyped" : true, "editorTyped" : false, "otherTyped" : false, "type" : { "otype" : "AuthorshipType", "mtid" : 1, "link" : "/api/authorshiptype/1", "label" : "Szerző", "code" : 0, "published" : true, "oldId" : 0, "snippet" : true }, "published" : false, "snippet" : true }, { "otype" : "PersonAuthorship", "mtid" : 91420087, "link" : "/api/authorship/91420087", "label" : "Casanova, E.L.", "listPosition" : 3, "share" : 0.0, "first" : false, "last" : false, "corresponding" : false, "familyName" : "Casanova", "givenName" : "E.L.", "authorTyped" : true, "editorTyped" : false, "otherTyped" : false, "type" : { "otype" : "AuthorshipType", "mtid" : 1, "link" : "/api/authorshiptype/1", "label" : "Szerző", "code" : 0, "published" : true, "oldId" : 0, "snippet" : true }, "published" : false, "snippet" : true }, { "otype" : "PersonAuthorship", "mtid" : 91420088, "link" : "/api/authorship/91420088", "label" : "Opris, I.", "listPosition" : 4, "share" : 0.0, "first" : false, "last" : false, "corresponding" : false, "familyName" : "Opris", "givenName" : "I.", "authorTyped" : true, "editorTyped" : false, "otherTyped" : false, "type" : { "otype" : "AuthorshipType", "mtid" : 1, "link" : "/api/authorshiptype/1", "label" : "Szerző", "code" : 0, "published" : true, "oldId" : 0, "snippet" : true }, "published" : false, "snippet" : true }, { "otype" : "PersonAuthorship", "mtid" : 91420089, "link" : "/api/authorship/91420089", "label" : "Abujadi, C.", "listPosition" : 5, "share" : 0.0, "first" : false, "last" : false, "corresponding" : false, "familyName" : "Abujadi", "givenName" : "C.", "authorTyped" : true, "editorTyped" : false, "otherTyped" : false, "type" : { "otype" : "AuthorshipType", "mtid" : 1, "link" : "/api/authorshiptype/1", "label" : "Szerző", "code" : 0, "published" : true, "oldId" : 0, "snippet" : true }, "published" : false, "snippet" : true }, { "otype" : "PersonAuthorship", "mtid" : 91420090, "link" : "/api/authorship/91420090", "label" : "Marcolin, M.A.", "listPosition" : 6, "share" : 0.0, "first" : false, "last" : false, "corresponding" : false, "familyName" : "Marcolin", "givenName" : "M.A.", "authorTyped" : true, "editorTyped" : false, "otherTyped" : false, "type" : { "otype" : "AuthorshipType", "mtid" : 1, "link" : "/api/authorshiptype/1", "label" : "Szerző", "code" : 0, "published" : true, "oldId" : 0, "snippet" : true }, "published" : false, "snippet" : true }, { "otype" : "PersonAuthorship", "mtid" : 91420091, "link" : "/api/authorship/91420091", "label" : "Li, X.", "listPosition" : 7, "share" : 0.0, "first" : false, "last" : true, "corresponding" : false, "familyName" : "Li", "givenName" : "X.", "authorTyped" : true, "editorTyped" : false, "otherTyped" : false, "type" : { "otype" : "AuthorshipType", "mtid" : 1, "link" : "/api/authorshiptype/1", "label" : "Szerző", "code" : 0, "published" : true, "oldId" : 0, "snippet" : true }, "published" : false, "snippet" : true } ], "title" : "Translational Neuroscience in Autism: From Neuropathology to Transcranial Magnetic Stimulation Therapies", "identifiers" : [ { "otype" : "PublicationIdentifier", "mtid" : 16835625, "link" : "/api/publicationidentifier/16835625", "label" : "DOI: 10.1016/j.psc.2020.02.004", "source" : { "otype" : "PlainSource", "mtid" : 6, "link" : "/api/publicationsource/6", "label" : "DOI", "type" : { "otype" : "PublicationSourceType", "mtid" : 10001, "link" : "/api/publicationsourcetype/10001", "label" : "DOI", "mayHaveOa" : true, "published" : true, "snippet" : true }, "name" : "DOI", "nameEng" : "DOI", "linkPattern" : "https://doi.org/@@@", "publiclyVisible" : true, "published" : true, "oldId" : 6, "snippet" : true }, "validState" : "IDENTICAL", "idValue" : "10.1016/j.psc.2020.02.004", "realUrl" : "https://doi.org/10.1016%2Fj.psc.2020.02.004", "published" : false, "snippet" : true }, { "otype" : "PublicationIdentifier", "mtid" : 17140735, "link" : "/api/publicationidentifier/17140735", "label" : "WoS: 000534683000003", "source" : { "otype" : "PlainSource", "mtid" : 1, "link" : "/api/publicationsource/1", "label" : "WoS", "type" : { "otype" : "PublicationSourceType", "mtid" : 10003, "link" : "/api/publicationsourcetype/10003", "label" : "Indexelő adatbázis", "mayHaveOa" : false, "published" : true, "snippet" : true }, "name" : "WoS", "nameEng" : "WoS", "linkPattern" : "http://gateway.isiknowledge.com/gateway/Gateway.cgi?&GWVersion=2&SrcAuth=CustomerName&SrcApp=CustomerName&DestLinkType=FullRecord&KeyUT=@@@&DestApp=WOS", "publiclyVisible" : true, "published" : true, "oldId" : 1, "snippet" : true }, "validState" : "IDENTICAL", "idValue" : "000534683000003", "realUrl" : "http://gateway.isiknowledge.com/gateway/Gateway.cgi?&GWVersion=2&SrcAuth=CustomerName&SrcApp=CustomerName&DestLinkType=FullRecord&KeyUT=000534683000003&DestApp=WOS", "published" : false, "snippet" : true }, { "otype" : "PublicationIdentifier", "mtid" : 16835624, "link" : "/api/publicationidentifier/16835624", "label" : "Scopus: 85082880154", "source" : { "otype" : "PlainSource", "mtid" : 3, "link" : "/api/publicationsource/3", "label" : "Scopus", "type" : { "otype" : "PublicationSourceType", "mtid" : 10003, "link" : "/api/publicationsourcetype/10003", "label" : "Indexelő adatbázis", "mayHaveOa" : false, "published" : true, "snippet" : true }, "name" : "Scopus", "linkPattern" : "http://www.scopus.com/record/display.url?origin=inward&eid=2-s2.0-@@@", "publiclyVisible" : true, "published" : true, "oldId" : 3, "snippet" : true }, "validState" : "IDENTICAL", "idValue" : "85082880154", "realUrl" : "http://www.scopus.com/record/display.url?origin=inward&eid=2-s2.0-85082880154", "published" : false, "snippet" : true } ], "journal" : { "otype" : "Journal", "mtid" : 5621, "link" : "/api/journal/5621", "label" : "PSYCHIATRIC CLINICS OF NORTH AMERICA 0193-953X", "pIssn" : "0193-953X", "reviewType" : "REVIEWED", "noIF" : false, "sciIndexed" : true, "scopusIndexed" : true, "lang" : "FOREIGN", "hungarian" : false, "published" : true, "oldId" : 5621, "snippet" : true }, "firstPageOrInternalIdForSort" : "", "publishedYear" : 2020, "abstractText" : "The presence of heterotopias, increased regional density of neurons at the gray-white matter junction, and focal cortical dysplasias all suggest an abnormality of neuronal migration in autism spectrum disorder (ASD). The abnormality is borne from a dissonance in timing between radial and tangentially migrating neuroblasts to the developing cortical plate. The uncoupling of excitatory and inhibitory cortical cells disturbs the coordinated interactions of neurons within local networks, thus providing abnormal patterns of brainwave activity in the gamma bandwidth. In ASD, gamma oscillation abnormalities and autonomic markers offer measures of therapeutic progress and help in the identification of subgroups. © 2020 Elsevier Inc.", "keywords" : [ { "otype" : "Keyword", "mtid" : 1042549, "link" : "/api/keyword/1042549", "label" : "transcranial magnetic stimulation", "published" : true, "oldId" : 1042549, "snippet" : true }, { "otype" : "Keyword", "mtid" : 1069651, "link" : "/api/keyword/1069651", "label" : "EXECUTIVE FUNCTION", "published" : true, "oldId" : 1069651, "snippet" : true }, { "otype" : "Keyword", "mtid" : 1496898, "link" : "/api/keyword/1496898", "label" : "Autism Spectrum Disorder", "published" : true, "snippet" : true }, { "otype" : "Keyword", "mtid" : 1514377, "link" : "/api/keyword/1514377", "label" : "GAMMA OSCILLATIONS", "published" : true, "snippet" : true }, { "otype" : "Keyword", "mtid" : 1675051, "link" : "/api/keyword/1675051", "label" : "minicolumns", "published" : true, "snippet" : true } ], "digital" : null, "printed" : null, "sourceYear" : 2020, "foreignEdition" : true, "foreignLanguage" : true, "fullPublication" : true, "conferencePublication" : false, "nationalOrigin" : null, "missingAuthor" : false, "oaType" : "NONE", "oaCheckDate" : "2021-10-02", "oaFree" : false, "citationCount" : 0, "citationCountUnpublished" : 0, "citationCountWoOther" : 0, "independentCitCountWoOther" : 0, "doiCitationCount" : 0, "wosCitationCount" : 0, "scopusCitationCount" : 0, "independentCitationCount" : 0, "unhandledCitationCount" : 0, "citingPubCount" : 0, "independentCitingPubCount" : 0, "unhandledCitingPubCount" : 0, "citedPubCount" : 2, "citedCount" : 2, "ratings" : [ { "otype" : "SjrRating", "mtid" : 10883932, "link" : "/api/sjrrating/10883932", "label" : "sjr:Q2 (2020) Scopus - Psychiatry and Mental Health PSYCHIATRIC CLINICS OF NORTH AMERICA 0193-953X", "listPos" : 150, "rankValue" : 0.49, "type" : "journal", "ratingType" : { "otype" : "RatingType", "mtid" : 10002, "link" : "/api/ratingtype/10002", "label" : "sjr", "code" : "sjr", "published" : true, "snippet" : true }, "subject" : { "otype" : "ClassificationExternal", "mtid" : 2738, "link" : "/api/classificationexternal/2738", "label" : "Scopus - Psychiatry and Mental Health", "published" : true, "oldId" : 2738, "snippet" : true }, "ranking" : "Q2", "calculation" : "DIRECT", "published" : true, "snippet" : true } ], "ratingsForSort" : "Q2", "referenceList" : "Zafeiriou, D.I., Ververi, A., Dafoulis, V., Autism spectrum disorders: the quest for genetic syndromes (2013) Am J Med Genet B Neuropsychiatr Genet, 162B (4), pp. 327-366 ;\n Huttenlocher, P.R., Wollmann, R.L., Cellular neuropathology of tuberous sclerosis (1991) Ann N Y Acad Sci, 615, pp. 140-148 ;\n Kyriakides, T., Hallam, L.A., Hockey, A., Angelman's syndrome: a neuropathological study (1992) Acta Neuropathol, 83 (6), pp. 675-678 ;\n Bailey, A., Luthert, P., Dean, A., A clinicopathological study of autism (1998) Brain, 121, pp. 889-905 ;\n Casanova, M.F., The neuropathology of autism (2007) Brain Pathol, 17 (4), pp. 422-433 ;\n Wegiel, J., Kuchna, I., Nowicki, K., The neuropathology of autism: defects of neurogenesis and neuronal migration, and dysplastic changes (2010) Acta Neuropathol, 11, pp. 755-770 ;\n Casanova, M.F., (2014), pp. 497-531. , The neuropathology of autism. In: Volkmar F, Pelphrey K, Paul R, editors. Handbook of autism and pervasive developmental disorders. 4th edition. [Chapter 21]. New York: Wiley ;\n Hutsler, J.J., Casanova, M.F., Cortical construction in autism spectrum disorder: columns, connectivity and the subplate (2016) Neuropathol Appl Neurobiol, 42 (2), pp. 115-134 ;\n Rakic, P., Kornack, D.R., Neocortical expansion and elaboration during primate evolution: A view from neuroembryology (2001) Evolutionary anatomy of the primate cerebral cortex, pp. 30-56. , D. Falk K.R. Gibson Cambridge University Press New York ;\n Casanova, M.F., El-Baz, A., Vanbogaer, E., Minicolumnar width: Comparison between supragranular and infragranular layers (2009) J Neurosci Methods, 184, pp. 19-24 ;\n Casanova, M.F., Trippe, J., Tillquist, C., Morphometric variability of minicolumns in the striate cortex of Homo sapiens, Macaca mulatta, and Pan troglodytes (2009) J Anat, 214, pp. 226-234 ;\n Casanova, M.F., Trippe, J., Regulatory mechanisms of cortical laminar development (2006) Brain Res Rev, 51, pp. 72-84 ;\n Marin-Padilla, M., The human brain: prenatal development and structure (2011), Springer-Verlag Berlin ;\n Wong, F.K., Bercsenyi, K., Sreenivasan, V., Pyramidal cell regulation of interneuron survival sculpts cortical networks (2018) Nature, 557 (7707), pp. 668-673 ;\n Lorente de Nó, R., Architectonics and structure of the cerebral cortex (1938) Physiology of the nervous system, pp. 291-330. , J.F. Fulton Oxford University Press New York ;\n Mountcastle, V.B., The columnar organization of the neocortex (1997) Brain, 120, pp. 701-722 ;\n Shipp, S., Structure and function of the cerebral cortex (2007) Curr Biol, 17 (12), pp. R443-R449 ;\n Girvan, M., Newman, M.E., Community structure in social and biological networks (2002) Proc Natl Acad Sci U S A, 99 (12), pp. 7821-7826 ;\n Sporns, O., Honey, C.J., Small worlds inside big brains (2006) Proc Natl Acad Sci U S A, 103, pp. 19219-19220 ;\n Meunier, D., Lambiotte, R., Bullmore, E.T., Modular and hierarchical modular organization of brain networks (2010) Front Neurosci, 4, p. 200 ;\n Casanova, M.F., El-Baz, A., Mott, M., Reduced gyral window and corpus callosum size in autism: possible macroscopic correlates of a minicolumnopathy (2009) J Autism Dev Disord, 39 (5), pp. 751-764 ;\n Williams, E.L., El-Baz, A., Nitzeken, M., Spherical harmonic analysis of cortical complexity in autism and dyslexia (2012) Transl Neurosci, 3 (1), pp. 36-40 ;\n Mountcastle, V.B., Perceptual neuroscience: the cerebral cortex (1998), Harvard University Press Cambridge (England) ;\n Szentágothai, J., Arbib, M.A., Conceptual models of neural organization (1975), MIT Press Cambridge (England) ;\n Kéïta, L., Mottron, L., Dawson, M., Atypical lateral connectivity: a neural basis for altered visuospatial processing in autism (2011) Biol Psychiatry, 70 (9), pp. 806-811 ;\n Puts, N.A.J., Wodka, E.L., Tommerdahl, M., Impaired tactile processing in children with autism spectrum disorder (2014) J Neurophysiol, 111 (9), pp. 1803-1811 ;\n Fatemi, S.H., Reutiman, T.J., Folsom, T.D., GABA(A) receptor downregulation in brains of subjects with autism (2009) J Autism Dev Disord, 39, pp. 223-230 ;\n Dickinson, A., Jones, M., Milne, E., Measuring neural excitation and inhibition in autism: different approaches, different findings and different interpretations (2016) Brain Res, 1648, pp. 277-289 ;\n Gaetz, W., Bloy, L., Wang, D.J., GABA estimation in the brains of children on the autism spectrum: measurement precision and regional cortical variation (2014) Neuroimage, 86, pp. 1-9 ;\n Cochran, D.M., Sikoglu, E.M., Hodge, S.M., Relationship among glutamine, γ-aminobutyric acid, and social cognition in autism spectrum disorders (2015) J Child Adolesc Psychopharmacol, 25, pp. 314-322 ;\n Casanova, M.F., El-Baz, A.S., Kamat, S.S., Focal cortical dysplasias in autism spectrum disorders (2013) Acta Neuropathol Commun, 1, p. 67 ;\n Hashemi, E., Ariza, J., Rogers, H., The number of parvalbumin-expressing interneurons is creased in the prefrontal cortex in autism (2017) Cereb Cortex, 27 (3), pp. 1931-1943 ;\n Fairless, R., Williams, S.K., Diem, R., Calcium-binding proteins as determinants of central nervous system neuronal vulnerability to disease (2019) Int J Mol Sci, 20 (9), p. 2146 ;\n Ariza, J., Rogers, H., Hashemi, E., The number of chandelier and basket cells are differentially decreased in prefrontal cortex in autism (2018) Cereb Cortex, 28 (2), pp. 411-420 ;\n Lee, E., Lee, J., Kim, E., Excitation/inhibition imbalance in animal models of autism spectrum disorders (2017) Biol Psychiatry, 81 (10), pp. 838-847 ;\n Filice, F., Schwaller, B., Parvalbumin and autism: different causes, same effect? (2016) Oncotarget, 8 (5), pp. 7222-7223 ;\n Berridge, M.J., Dysregulation of neural calcium signaling in Alzheimer disease, bipolar disorder and schizophrenia (2013) Prion, 7, pp. 2-13 ;\n Ferguson, B.R., Gao, W.J., PV interneurons: critical regulators of E/I balance for prefrontal cortex-dependent behavior and psychiatric disorders (2018) Front Neural Circuits, 12, p. 37 ;\n Saunders, J.A., Tatard-Leitman, V.M., Suh, J., Knockout of NMDA receptors in parvalbumin interneurons recreates autism-like phenotypes (2013) Autism Res, 6 (2), pp. 69-77 ;\n Wöhr, M., Orduz, D., Gregory, P., Lack of parvalbumin in mice leads to behavioral deficits relevant to all human autism core symptoms and related neural morphofunctional abnormalities (2015) Transl Psychiatry, 5 (3), p. e525 ;\n Tamas, G., Buhl, E.H., Lorincz, A., Proximally targeted GABAergic synapses and gap junctions synchronize cortical interneurons (2000) Nat Neurosci, 3 (4), pp. 366-371 ;\n Szabadics, J., Lorincz, A., Tamas, G., Beta and gamma frequency synchronization by dendritic gabaergic synapses and gap junctions in a network of cortical interneurons (2001) J Neurosci, 21 (15), pp. 5824-5831 ;\n Deans, M.R., Gibson, J.R., Sellitto, C., Synchronous activity of inhibitory networks in neocortex requires electrical synapses containing connexin36 (2001) Neuron, 31 (3), pp. 477-485 ;\n Bartos, M., Vida, I., Frotscher, M., Fast synaptic inhibition promotes synchronized gamma oscillations in hippocampal interneuron networks (2002) Proc Natl Acad Sci U S A, 99 (20), pp. 13222-13227 ;\n Traub, R.D., Cunningham, M.O., Gloveli, T., GABA-enhanced collective behavior in neuronal axons underlies persistent gamma-frequency oscillations (2003) Proc Natl Acad Sci U S A, 100 (19), pp. 11047-11052 ;\n Traub, R.D., Bibbig, A., LeBeau, F.E.N., Cellular mechanisms of neuronal population oscillations in the hippocampus in vitro (2004) Annu Rev Neurosci, 27, pp. 247-278 ;\n Traub, R.D., Michelson-Law, H., Bibbig, A.E.J., Gap junctions, fast oscillations and the initiation of seizures (2004) Adv Exp Med Biol, 548, pp. 110-122 ;\n Bartos, M., Vida, I., Jonas, P., Synaptic mechanisms of synchronized gamma oscillations in inhibitory interneuron networks (2007) Nat Rev Neurosci, 8 (1), pp. 45-56 ;\n Rojas, D.C., Wilson, L.B., Gamma-band abnormalities as markers of autism spectrum disorders (2014) Biomark Med, 8 (3), pp. 353-368 ;\n Dienel, S.J., Lewis, D.A., Alterations in cortical interneurons and cognitive function in schizophrenia (2019) Neurobiol Dis, 131, p. 104208 ;\n Curley, A.A., Lewis, D.A., Cortical basket cell dysfunction in schizophrenia (2012) J Physiol, 590 (4), pp. 715-724 ;\n Lewis, D.A., Curley, A.A., Glusier, J.R., Cortical parvalbumin interneurons and cognitive dysfunction in schizophrenia (2012) Trends Neurosci, 35 (1), pp. 57-67 ;\n Gonzalez-Burgos, G., Cho, R.Y., Lewis, D.A., Alterations in cortical network oscillations and parvalbumin neurons in schizophrenia (2015) Biol Psychiatry, 77, pp. 1031-1040 ;\n Tallon-Baudry, C., Bertrand, O., Peronnet, F., Induced γ-band activity during the delay of a visual short-term memory task in humans (1998) J Neurosci, 18 (11), pp. 4244-4254 ;\n Fries, P., Reynolds, J.H., Rorie, A.E., Modulation of oscillatory neuronal synchronization by selective visual attention (2001) Science, 291 (5508), pp. 1560-1563 ;\n Howard, M.W., Rizzuto, D.S., Caplan, J.B., Gamma oscillations correlate with working memory load in humans (2003) Cereb Cortex, 13 (12), pp. 1369-1374 ;\n Spencer, K.M., Nestor, P.G., Niznikiewicz, M.A., Abnormal neural synchrony in schizophrenia (2003) J Neurosci, 23 (19), pp. 7407-7411 ;\n Sohal, V.S., Zhang, F., Yizhar, O., Parvalbumin neurons and gamma rhythms enhance cortical circuit performance (2009) Nature, 459 (7247), pp. 698-702 ;\n Brock, J., Brown, C.C., Boucher, J., The temporal binding deficit hypothesis of autism (2002) Dev Psychopathol, 14, pp. 209-224 ;\n Orekhova, E.V., Stroganova, T.A., Nygren, G., Excess of high frequency electroencephalogram oscillations in boys with autism (2007) Biol Psychiatry, 62 (9), pp. 1022-1029 ;\n Başar, E., Tülay, E., Güntekin, B., Multiple gamma oscillations in the brain: a new strategy to differentiate functional correlates and P300 dynamics (2015) Int J Psychophysiol, 95, pp. 406-420 ;\n Gaona, C.M., Sharma, M., Freudenburg, Z.V., Nonuniform high-gamma (60-500 Hz) power changes dissociate cognitive task and anatomy in human cortex (2011) J Neurosci, 31, pp. 2091-2100 ;\n Rippon, G., Gamma abnormalities in autism spectrum disorders (2017) Autism imaging and devices, pp. 457-496. , M.F. Casanova A. El-Baz J.S. Suri CRC Press, Taylor and Francis Group Boca Raton FL [Chapter: 22] ;\n (1994), Von der Malsburg C. The Correlation Theory of Brain Function. In: Domany E, van Hemmen JL, Schulten K, editors. Models of Neural Networks. Physics of Neural Networks. New York: Springer ;\n ;\n Singer, W., Gray, C.M., Visual feature integration and the temporal correlation hypothesis (1995) Annu Rev Neurosci, 18, pp. 555-586 ;\n Tallon-Baudry, C., Bertrand, O., Oscillatory gamma activity in humans and its role in object representation (1999) Trends Cogn Sci, 3, pp. 151-162 ;\n Casanova, M.F., Baruth, J., El-Baz, A.S., Evoked and induced gamma frequency oscillations in autism (2013) Imaging the brain in autism, pp. 87-106. , M.F. Casanova A.S. El-Baz J.S. Suri Springer New York ;\n Jia, X., Kohn, A., Gamma rhythms in the brain (2011) PLoS Biol, 9, p. e1001045 ;\n Brown, C.C., Gruber, T., Boucher, J., Gamma abnormalities during perception of illusory figures in autism (2005) Cortex, 41, pp. 364-376 ;\n Ogawa, A., Ukai, S., Shinosaki, K., Slow repetitive transcranial magnetic stimulation increases somatosensory high-frequency oscillations in humans (2004) Neurosci Lett, 358, pp. 193-196 ;\n Cole, J.C., Green Bernacki, C., Helmer, A., Efficacy of transcranial magnetic stimulation (TMS) in the treatment of schizophrenia: a review of the literature to date (2015) Innov Clin Neurosci, 12 (7-8), pp. 12-19 ;\n Kaar, S.J., Angelescu, I., Reis Marques, T., Pre-frontal parvalbumin interneurons in schizophrenia: a meta-analysis of postmortem studies (2019) J Neural Transm (Vienna), 126 (12), pp. 1637-1651 ;\n Yanagi, M., Joho, R.H., Southcott, S.A., Kv3.1-containing K+ channels are reduced in untreated schizophrenia and normalized with antipsychotic drugs (2014) Mol Psychiatry, 19, pp. 573-579 ;\n Boddum, K., Hougaard, C., Xiao-Ying Lin, J., Kv3.1/Kv3.2 channel positive modulators enable faster activating kinetics and increase firing frequency in fast-spiking GABAergic interneurons (2017) Neuropharmacology, 118, pp. 102-112 ;\n Brown, M.R., El-Hassar, L., Zhang, Y., Physiological modulators of Kv3.1 channels adjust firing patterns of auditory brain stem neurons (2016) J Neurophysiol, 116, pp. 106-121 ;\n Rosato-Siri, M.D., Zambello, E., Mutinelli, C., A novel modulator of Kv3 potassium channels regulates the firing of parvalbumin-positive cortical interneurons (2015) J Pharmacol Exp Ther, 354, pp. 251-260 ;\n Barr, M., Farzan, F., Arenovich, T., The effect of repetitive transcranial magnetic stimulation on gamma oscillatory activity in schizophrenia (2011) PLoS One, 6 (7), p. e22627 ;\n Farzan, F., Barr, M.S., Wong, W., Suppression of gamma-oscillations in the dorsolateral prefrontal cortex following long interval cortical inhibition: a TMS-EEG study (2009) Neuropsychopharmacology, 34 (6), pp. 1543-1551 ;\n Farzan, F., Barr, M.S., Sun, Y., Transcranial magnetic stimulation on the modulation of gamma oscillations in schizophrenia (2012) Ann N Y Acad Sci, 1265, pp. 25-35 ;\n Rogasch, N.C., Daskalakis, Z.J., Fitzgerald, P.B., Cortical inhibition of distinct mechanisms in the dorsolateral prefrontal cortex is related to working memory performance: a TMS-EEG study (2015) Cortex, 64, pp. 68-77 ;\n Fox, P.T., Narayana, S., Tandon, N., Column-based model of electric field excitation of cerebral cortex (2004) Hum Brain Mapp, 22, pp. 1-16 ;\n Wassermann, E.M., Wedegaertner, F.R., Ziemann, U., Crossed reduction of motor cortex excitability by 1 Hz transcranial magnetic stimulation (1998) Neurosci Lett, 250, pp. 141-144 ;\n Sokhadze, E., El-Baz, A., Baruth, J., Effects of low frequency repetitive transcranial magnetic stimulation (rTMS) on gamma frequency oscillations and event-related potentials during processing of illusory figures in autism (2009) J Autism Dev Disord, 39, pp. 619-634 ;\n Casanova, M.F., Sokhadze, E., Opris, I., Autism spectrum disorders: linking neuropathological findings to treatment with transcranial magnetic stimulation (2015) Acta Paediatr, 104 (4), pp. 346-355 ;\n Oberman, L.M., Enticott, P.G., Casanova, M.F., Transcranial magnetic stimulation in autism spectrum disorder: challenges, promise, and roadmap for future research (2016) Autism Res, 9 (2), pp. 184-203 ;\n Barahona-Corrêa, J.B., Velosa, A., Chainho, A., Repetitive transcranial magnetic stimulation for treatment of autism spectrum disorder: a systematic review and meta-analysis (2018) Front Integr Neurosci, 12, p. 27 ;\n Casanova, M.F., Sokhadze, E.M., Opris, I., Autism, transcranial magnetic stimulation and gamma frequencies (2019) Autism spectrum disorder: neuromodulation, neurofeedback, and sensory integration approaches to research and treatment, pp. 49-65. , E.M. Sokhadze M.F. Casanova FNNR & BMED Press Murfreesboro (TN) ;\n Cole, E.J., Enticott, P.G., Oberman, L.M., The potential of repetitive transcranial magnetic stimulation for autism spectrum disorder: a consensus statement (2019) Biol Psychiatry, 85 (4), pp. e21-e22 ;\n Finisguerra, A., Borgatti, R., Urgesi, C., Non-invasive brain stimulation for the rehabilitation of children and adolescents with neurodevelopmental disorders: a systematic review (2019) Front Psychol, 135, p. 10 ;\n Masuda, F., Nakajima, S., Miyazaki, T., Clinical effectiveness of repetitive transcranial magnetic stimulation treatment in children and adolescents with neurodevelopmental disorders: a systematic review (2019) Autism, , 1362361318822502 ;\n Ni, H.-C., Huang, Y.-Z., Theta burst stimulation in autism (2019) Autism spectrum disorder: neuromodulation, neurofeedback, and sensory integration approaches to research and treatment, pp. 67-87. , E.M. Sokhadze M.F. Casanova FNNR & BMED Press Murfreesboro (TN) ;\n Gómez, L., Vidal, B., Morales, L., Non-invasive brain stimulation in children with autism spectrum disorder (2019) Autism spectrum disorder: neuromodulation, neurofeedback, and sensory integration approaches to research and treatment, pp. 89-114. , E.M. Sokhadze M.F. Casanova FNNR & BMED Press Murfreesboro (TN) ;\n Baruth, J., Casanova, M.F., El-Baz, A., Low-frequency repetitive transcranial magnetic stimulation modulates evoked-gamma frequency oscillations in autism spectrum disorders (2010) J Neurother, 14, pp. 179-194 ;\n Baruth, J.M., Williams, E.L., Sokhade, E.M., Beneficial effects of repetitive transcranial magnetic stimulation (rTMS) on behavioral outcome measures in autism spectrum disorder (2011) Autism Sci Dig, 1, pp. 52-57 ;\n Casanova, M.F., Baruth, J.M., El-Baz, A., Repetitive transcranial magnetic stimulation (rTMS) modulates event-related potential (ERP) indices of attention in autism (2012) Transl Neurosci, 3, pp. 170-180 ;\n Sokhadze, E.M., El-Baz, A.S., Sears, L.L., rTMS neuromodulation improves electrocortical functional measures of information processing and behavioral responses in autism (2014) Front Syst Neurosci, 8, p. 134 ;\n Hensley, M.K., El-Baz, A.S., Sokhadze, E., Effects of 18 session TMS therapy on gamma coherence in autism (2014) Psychophysiology, 51, p. S16. , (Abstract) ;\n Rippon, G., Brock, J., Brown, C., Disordered connectivity in the autistic brain: challenges for the “new psychophysiology (2007) Int J Psychophysiol, 63, pp. 164-172 ;\n Grice, S.J., Spratling, M.W., Karmiloff-Smith, A., Disordered visual processing and oscillatory brain activity in autism and Williams syndrome (2001) Neuroreport, 12, pp. 2697-2700 ;\n De Vries, M., Geurts, H.M., Cognitive flexibility in ASD ;\n task switching with emotional faces (2012) J Autism Dev Disord, 42 (12), pp. 2558-2568 ;\n Craig, F., Margari, F., Legrottaglie, A.R., A review of executive function deficits in autism spectrum disorder and attention-deficit/hyperactivity disorder (2016) Neuropsychiatr Dis Treat, 12, pp. 1191-1202 ;\n Simões-Franklin, C., Hester, R., Shapner, M., Executive function and error detection the effect of motivation on cingulate and ventral striatum activity (2010) Hum Brain Mapp, 31 (3), pp. 458-469 ;\n Sokhadze, E., Baruth, J., El-Baz, A., Impaired error monitoring and correction function in autism (2010) J Neurother, 14 (2), pp. 79-95 ;\n Van Veen, Carter, C.S., The timing of action-monitoring processes in the anterior cingulate cortex (2002) J Cogn Neurosci, 14 (4), pp. 593-602 ;\n Sokhadze, E.M., Baruth, J.M., Sears, L., Prefrontal neuromodulation using rTMS improves error monitoring and correction function in autism (2012) Appl Psychophysiol Biofeedback, 37 (2), pp. 91-102 ;\n Goodman, B., Autonomic dysfunction in autism spectrum disorders (ASD) (2016) Neurology, 86 (16 Supplement), p. p. 5.117 ;\n Casanova, M.F., Hensley, M.K., Sokhadze, E.M., Effects of weekly low-frequency rTMS on autonomic measures in children with autism spectrum disorder (2014) Front Hum Neurosci, 8, p. 851 ;\n Wang, Y., Hensley, M.K., Tasman, A., Heart rate variability and skin conductance during repetitive TMS course in children with autism (2016) Appl Psychophysiol Biofeedback, 41 (1), pp. 47-60 ;\n Sokhadze, G., Casanova, M.F., Kelly, D., Neuromodulation based on rTMS affects behavioral measures and autonomic nervous system activity in children with autism (2017) NeuroRegulation, 4 (2), p. 65 ;\n Sagar-Ouriaghil, I., Lievesley, K., Santosh, P.J., Propranolol for treating emotional, behavioural, autonomic dysregulation in children and adolescents with autism spectrum disorders (2018) J Psychopharmacol, 32 (6), pp. 641-653 ;\n Sokhadze, E.M., El-Baz, A.S., Tasman, A., Neuromodulation integrating rTMS and neurofeedback for the treatment of autism spectrum disorder: an exploratory study (2014) Appl Psychophysiol Biofeedback, 39 (304), pp. 237-257 ;\n Licht, C.M.M., de Geus, E.J.C., Penninx, B.W.J.H., Dysregulation of the autonomic nervous system predicts the development of the metabolic syndrome (2013) J Clin Endocrinol Metab, 98 (6), pp. 2484-2493 ;\n Siebner, H.R., Hartwigsen, G., Kassuba, T., ow does transcranial magnetic stimulation modify neuronal activity in the brain? Implications for studies of cognition (2009) Cortex, 45 (9), pp. 1035-1042 ;\n Abujadi, C., Croarkin, P.E., Bellini, B.B., Intermittent theta-burst transcranial magnetic stimulation for autism spectrum disorder: an open-label pilot study (2018) Braz J Psychiatry, 40 (3), pp. 309-311", "hasCitationDuplums" : false, "userChangeableUntil" : "2020-07-14T16:49:35.448+0000", "directInstitutesForSort" : "", "ownerAuthorCount" : 4, "ownerInstituteCount" : 22, "directInstituteCount" : 0, "authorCount" : 7, "contributorCount" : 0, "hasQualityFactor" : true, "link" : "/api/publication/31279815", "label" : "Casanova M.F. et al. Translational Neuroscience in Autism: From Neuropathology to Transcranial Magnetic Stimulation Therapies. (2020) PSYCHIATRIC CLINICS OF NORTH AMERICA 0193-953X 1558-3147", "template" : "