Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke. - Wikidata - wikimedia - TriplyDB

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

http://www.wikidata.org/entity/Q49045156

about

Improvement after constraint-induced movement therapy is independent of infarct location in chronic stroke patients Recovery Potential After Acute Stroke Functional MRI using robotic MRI compatible devices for monitoring rehabilitation from chronic stroke in the molecular medicine era (Review)Diffusion tensor imaging in hemorrhagic stroke Action observation as a tool for neurorehabilitation to moderate motor deficits and aphasia following stroke.The future of magnetic resonance-based techniques in neurology.Cannabinoid CB2 receptor (CB2R) stimulation delays rubrospinal mitochondrial-dependent degeneration and improves functional recovery after spinal cord hemisection by ERK1/2 inactivation.Functional neuroimaging in stroke recovery and neurorehabilitation: conceptual issues and perspectives.Brain-mapping techniques for evaluating poststroke recovery and rehabilitation: a review.Arterial spin labelling shows functional depression of non-lesion tissue in chronic Wernicke's aphasia.Lesion load of the corticospinal tract predicts motor impairment in chronic stroke.Motor outcomes of patients with a complete middle cerebral artery territory infarct.Recovery of the corticospinal tracts injured by subfalcine herniation: a diffusion tensor tractography study.Functional imaging correlates of recovery after stroke in humans.Mechanisms underlying human motor system plasticity.Neuroimaging patterns associated with motor control in traumatic brain injury.Response to intensive upper extremity therapy by individuals with ataxia from stroke.Neural function, injury, and stroke subtype predict treatment gains after stroke.Somatotopic arrangement and location of the corticospinal tract in the brainstem of the human brain.A change in injured corticospinal tract originating from the premotor cortex to the primary motor cortex in a patient with intracerebral hemorrhage Long term reshaping of language, sensory, and motor maps after glioma resection: a new parameter to integrate in the surgical strategy.Longitudinal thalamic diffusion changes after middle cerebral artery infarcts Plasticity in the human cerebral cortex: lessons from the normal brain and from stroke.Low-frequency rTMS in patients with subacute ischemic stroke: clinical evaluation of short and long-term outcomes and neurophysiological assessment of cortical excitability.Using ipsilateral motor signals in the unaffected cerebral hemisphere as a signal platform for brain-computer interfaces in hemiplegic stroke survivors.Effects of Electroacupuncture at Head Points on the Function of Cerebral Motor Areas in Stroke Patients: A PET Study Plasticity and reorganization of the brain post stroke.The Right Supramarginal Gyrus Is Important for Proprioception in Healthy and Stroke-Affected Participants: A Functional MRI Study.Imaging motor recovery after stroke.White matter integrity is a stronger predictor of motor function than BOLD response in patients with stroke.Vicarious function of remote cortex following stroke: recent evidence from human and animal studies.The role of noninvasive techniques in stroke therapy Relationships between functional and structural corticospinal tract integrity and walking post stroke.Corticospinal tract compression by hematoma in a patient with intracerebral hemorrhage: a diffusion tensor tractography and functional MRI study.Transcranial magnetic stimulation in cognitive rehabilitation.The "Janus-faced role" of autophagy in neuronal sickness: focus on neurodegeneration.Motor recovery mechanisms in patients with middle cerebral artery infarct: a mini-review.Spasticity after stroke: physiology, assessment and treatment.Role of microglia in ischemic focal stroke and recovery: focus on Toll-like receptors.Investigating structure and function in the healthy human brain: validity of acute versus chronic lesion-symptom mapping.

P2860

Q24652577-0F1DBB09-6D92-4A55-9A27-B0EB9494BC31 Q26776144-2E2F4E9F-C654-47D5-90E7-B731D0926715 Q27007654-F098CFB0-31DC-4973-AE27-2BC70FE76646 Q28087284-BB2A4951-1119-4960-87D4-075020B8CC61 Q30420314-7C545589-A92A-4B43-B072-87A9E30A3520 Q30658699-F9269BED-738B-4232-9C3B-2A1143007634 Q30661637-E9A11CDC-BE82-49D6-BCB9-B720DC1B15CD Q33360425-C08A137B-A145-4762-B8D7-021B1264A2DD Q33384358-D3A5D9F1-3500-4D61-A392-46983163934B Q33825049-7A6DE7EE-012E-4D97-830E-3DA2BDAFDDE7 Q33917527-B26B3246-F3E6-4F70-80CC-E815B7EDA2EB Q34094817-A0254992-A370-482A-8C7A-1AC26BDD3420 Q34096229-74510F3C-8CA0-4386-8BD6-D431C9D93DB2 Q34113423-F978F943-308C-41D7-AA10-DFBF5F62C0ED Q34228649-79CB3A67-EC83-4651-BF73-6F2BBF4299C7 Q34492852-1D60EC1D-EF82-4BF2-B7B6-18353F97C101 Q34799344-A746C1F6-FAF4-4010-BF83-527E909346E9 Q34945284-7B85803E-C209-44A0-87BA-6900EDEF11F0 Q35014813-BE37B383-DAB0-4ECF-A7E6-350B1731C92E Q35123807-15A73DC0-5AC9-4344-83E9-0D6DC79D0579 Q35466662-F61C50D1-14FB-4338-B50C-7AE96EDBA015 Q35486079-FAE43342-BBF4-4889-9D15-F21C988A68D3 Q35740544-8A930449-2C84-4B03-B332-A857AB4D5FA6 Q36017727-A017C0F0-0EA1-42DC-9B44-C5D74149B375 Q36108853-9E01C758-6ED9-4D05-B532-9895ABA28EF5 Q36204042-5D5212CF-A3F5-462F-A4E2-B199E2D0DEC8 Q36234776-1040BDE7-730C-449A-9B4F-1F0EBCEA1432 Q36343068-83113708-E437-4BB1-ABC2-1CCC969E6530 Q36608817-35C5E18E-BB75-424B-8888-2A21248895C0 Q36630385-32AF82C8-7F48-465E-AF4D-02BEA989C67A Q36641843-2CB24090-4474-4BEF-9EA6-11A619B1DC61 Q37084538-5A44C39E-E7EE-43C7-BDF4-60B2D78B9CBD Q37187574-8FBB269D-6702-481E-BF03-9243E8F7CD11 Q37205104-BD598095-7D1E-4DFD-AD18-A5B8030F7CF6 Q37861036-C65B667B-2AB4-4FF9-866D-0580F64A4DFD Q38024715-11226384-9E49-4EE0-A322-7FBF873755D0 Q38046012-A247F7FC-9AA9-4347-8B26-C0EA20689804 Q38124046-1D1D9AFB-7BD2-4521-BF3C-01C12A9FF3D8 Q38889538-0B7417CE-930E-4FE7-9B8C-6CF89986DACD Q39222179-1255B53D-41CE-41F4-A234-05491FEF65EC

P2860

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

http://www.wikidata.org/entity/Q49045156

description

1996 nî lūn-bûn

@nan

1996年の論文

@ja

1996年学术文章

@wuu

1996年学术文章

@zh

1996年学术文章

@zh-cn

1996年学术文章

@zh-hans

1996年学术文章

@zh-my

1996年学术文章

@zh-sg

1996年學術文章

@yue

1996年學術文章

@zh-hant

name

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

@en

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

@nl

type

label

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

@en

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

@nl

prefLabel

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

@en

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

@nl

P1433

Q49045156-5C06865A-280E-41F3-A8C3-2368326E4BC3

P1476

Q49045156-FB7647BD-6E94-47B2-A226-BE1F42464D62

P2093

Q49045156-111EC56C-816A-4552-A2E4-F09A04563937

Q49045156-3A8F0AD2-F4C0-49C6-A389-EA46EF578FAB

Q49045156-602585E6-89E2-440C-A4FA-257EF60860FD

Q49045156-60C67F87-DF70-4A36-A7FF-5A64BBACF7DB

Q49045156-687B36A4-754D-484E-B6FC-D4390DECBF2C

Q49045156-AE4EA1B1-3D86-408B-8699-96B70933ED9F

P2860

Q49045156-01C2F58F-287A-432E-B969-7A9279B7B7BA

Q49045156-152AEA16-74B6-4637-B02F-84BCC3BAB705

Q49045156-1781A029-F792-4A12-9BC9-444D63017DAE

Q49045156-18CBF4AE-9FE9-4D12-B884-C2ADFD7530FE

Q49045156-1FBCAA5C-3EFD-4367-B9F3-6768063AD365

Q49045156-2572099F-0757-4A88-818C-6714B8E7AFCF

Q49045156-26C31B00-BB9A-4261-8949-CD33ADAB87A1

Q49045156-36B0BB11-155E-4A0A-AC75-1BFDE60F55FC

Q49045156-51129349-8BF7-4D9B-9528-9F6EAFB59C76

Q49045156-5439011A-9BF5-44DA-BF25-AB3C54DA5DDC

P304

Q49045156-49D72979-C15F-49B3-8E4B-A13015710DC1

P31

Q49045156-400AA782-7846-49F1-A429-143654CD25B2

P356

Q49045156-03739087-84E6-41D9-ABFC-FB0ED7949677

P433

Q49045156-53BB6AD8-3D2C-4637-812B-6CE5BFE35435

P478

Q49045156-CD4EE189-40CA-4F07-B598-75B9BF762C31

P577

Q49045156-FF887F55-986A-441E-AA6A-30784C567A5B

P698

Q49045156-81DF2DEB-41A5-41FE-A148-8D00A6B2288C

P356

P1433

Annals of Neurology

P1476

Thalamic metbolism and corticospinal tract integrity determine motor recovery in stroke.

@en

P2093

Arnold S

http://www.w3.org/2001/XMLSchema#string

Benecke R

http://www.w3.org/2001/XMLSchema#string

Binkofski F

http://www.w3.org/2001/XMLSchema#string

Classen J

http://www.w3.org/2001/XMLSchema#string

Freund HJ

http://www.w3.org/2001/XMLSchema#string

Seitz RJ

http://www.w3.org/2001/XMLSchema#string

P2860

Infarct topography and hemiparesis profiles with cerebral convexity infarction: the Stroke Data Bank

Transcranial electrical motor evoked potentials as a prognostic indicator for motor recovery in stroke patients.

Contralateral cerebellar hypometabolism: a predictor for stroke outcome?

Lacunar strokes and infarcts: a review.

Differential effects of electrical stimulation of sciatic nerve on metabolic activity in spinal cord and dorsal root ganglion in the rat.

Frequency-dependent activation of glucose utilization in the superior cervical ganglion by electrical stimulation of cervical sympathetic trunk.

Effects on movement of surgical incisions into the human spinal cord.

Thalamic and cortical afferents differentiate anterior from posterior cingulate cortex in the monkey.

Tomographic measurement of local cerebral glucose metabolic rate in humans with (F-18)2-fluoro-2-deoxy-D-glucose: validation of method.

P304

460-470

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1002/ANA.410390408

http://www.w3.org/2001/XMLSchema#string

P433

4

http://www.w3.org/2001/XMLSchema#string

P478

39

http://www.w3.org/2001/XMLSchema#string

P577

1996-04-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

8619524

http://www.w3.org/2001/XMLSchema#string