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Four functionally distinct regions in the left supramarginal gyrus support word processing
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Four Functionally Distinct Regions in the Left Supramarginal Gyrus Support Word Processing
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In: CEREBRAL CORTEX , 26 (11) pp. 4212-4226. (2016) (2016)
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Comparing language outcomes in monolingual and bilingual stroke patients.
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In: Brain , 138 (Pt 4) 1070 - 1083. (2015) (2015)
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A Trade-Off between Somatosensory and Auditory Related Brain Activity during Object Naming But Not Reading.
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In: J Neurosci , 35 (11) 4751 - 4759. (2015) (2015)
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Sensory-to-motor integration during auditory repetition: a combined fMRI and lesion study.
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In: Front Hum Neurosci , 8 , Article 24 . (2014) (2014)
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Inter- and intrahemispheric connectivity differences when reading Japanese Kanji and Hiragana.
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In: Cereb Cortex , 24 (6) pp. 1601-1608. (2014) (2014)
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What makes written words so special to the brain?
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In: Front Hum Neurosci , 8 634 - ?. (2014) (2014)
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The importance of premotor cortex for supporting speech production after left capsular-putaminal damage.
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In: J Neurosci , 34 (43) 14338 - 14348. (2014) (2014)
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Dissecting the functional anatomy of auditory word repetition.
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In: Front Hum Neurosci , 8 , Article 246 . (2014) (2014)
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Functionally distinct contributions of the anterior and posterior putamen during sublexical and lexical reading.
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In: Front Hum Neurosci , 7 , Article 787 . (2013) (2013)
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Predicting outcome and recovery after stroke with lesions extracted from MRI images
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In: NEUROIMAGE-CLINICAL , 2 pp. 424-433. (2013) (2013)
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The angular gyrus: multiple functions and multiple subdivisions.
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In: Neuroscientist , 19 (1) 43 - 61. (2013) (2013)
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Reading without the left ventral occipito-temporal cortex.
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In: Symplectic Elements at Oxford ; Europe PubMed Central ; PubMed (http://www.ncbi.nlm.nih.gov/pubmed/) ; Web of Science (Lite) (http://apps.webofknowledge.com/summary.do) ; Scopus (http://www.scopus.com/home.url) ; CrossRef (2012)
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Where, when and why brain activation differs for bilinguals and monolinguals during picture naming and reading aloud.
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In: Cereb Cortex , 22 (4) 892 - 902. (2012) (2012)
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Where, when and why brain activation differs for bilinguals and monolinguals during picture naming and reading aloud.
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In: Cereb Cortex , 22 (4) 892 - 902. (2012) (2012)
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Multiple Routes from Occipital to Temporal Cortices during Reading
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In: J NEUROSCI , 31 (22) 8239 - 8247. (2011) (2011)
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Predicting Language Outcome and Recovery After Stroke (PLORAS)
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Abstract:
The ability of comprehend and produce speech after stroke depends on whether the areas of the brain that support language have been damaged. Here we review two different ways to predict language outcome after stroke. The first depends on understanding the neural circuits that support language. This model-based approach is a challenging endeavor because language is a complex cognitive function that involves the interaction of many different brain areas. The second approach does not require an understanding of why a lesion impairs language, instead, predictions are made on the basis of how previous patients with the same lesion recovered. This requires a database storing the speech and language abilities of a large population of patients who have, between them, incurred a comprehensive range of focal brain damage. In addition it requires a system that converts an MRI scan from a new patient into a 3D description of the lesion and then compares this lesion to all others on the database. The outputs of this system are the longitudinal language outcomes of corresponding patients in the database. This will provide a new patient, their carers and the clinician team managing them the range of likely recovery patterns over a variety of language measures.
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Keyword:
Article
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URL: https://doi.org/10.1038/nrneurol.2010.15 http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3556582 http://www.ncbi.nlm.nih.gov/pubmed/20212513
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Lesion sites that predict the ability to gesture how an object is used
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In: ARCH ITAL BIOL , 148 (3) 243 - 258. (2010) (2010)
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Predicting language outcome and recovery after stroke: the PLORAS system
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In: NAT REV NEUROL , 6 (4) 202 - 210. (2010) (2010)
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The Role of Functional Magnetic Resonance Imaging in the Study of Brain Development, Injury, and Recovery in the Newborn
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In: SEMIN PERINATOL , 34 (1) 79 - 86. (2010) (2010)
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