Rehabilitation
underpinnings of gesture discrimination in patients with limb apraxiam, J Neurosci, 2008;28:3030–41.
9. 10. 11. 12. 13. 14. 15.
Karnath HO, Rorden C, Ticini LF, Damage to white matter fiber tracts in acute spatial neglect, Cereb Cortex, 2009;19:2331–7.
Stoeckel MC, Wittsack HJ, Meisel S, Seitz RJ, Pattern of cortex and white matter involvement in severe middle cerebral artery ischemia, J Neuroimaging, 2007;17:131–40.
Seitz RJ, Sondermann V, Wittsack HJ, Siebler M, Lesion patterns in successful and failed thrombolysis in middle cerebral artery stroke, Neuroradiology, 2009;51:865–71.
Binkofski F, Seitz RJ, Arnold S, et al., Thalamic metabolism and corticospinal tract integrity determine motor recovery in stroke, Ann Neurol, 1996;39:460–70.
Chen CL, Tang FT, Chen HC, et al., Brain lesion size and location, Arch Phys Med Rehabil, 2000;81:447–52.
Zhu LL, Lindenberg R, Alexander MP, Schlaug G, Lesion load of the corticospinal tract predicts motor impairment in chronic stroke, Stroke, 2010;41:910–5.
Fries W, Danek A, Witt TN, Motor responses after transcranial electrical stimulation of cerebral hemispheres with a degenerated pyramidal tract, Ann Neurol, 1991;29: 646–50.
16.
Lang CE, Schieber MH, Reduced muscle selectivity during individuated finger movements in humans after damage to the motor cortex or corticospinal tract, J Neurophysiol, 2004;91:1722–33.
17. 18. 19.
Lindenberg R, Renga V, Zhu LL, et al., Structural integrity of corticospinal motor fibers predicts motor impairment in chronic stroke, Neurology, 2010;74:280–7.
Canedo A, Primary motor cortex influences on the descending and ascending systems, Prog Neurobiol, 1997;51:287–335.
Talelli P, Greenwood RJ, Rothwell JC, Arm function after stroke: neurophysiological correlates and recovery mechanisms assessed by transcranial magnetic stimulation, Clin Neurophysiol, 2006;117:1641–59.
20.
Beaulieu C, The biological basis of diffusion anisotropy. In: Johansen-Berg H, Behrens TE (eds), Diffusion MRI: From quantitative measurement to in vivo neuroanatomy, London: Academic Press, 2009:105–26.
21.
Song SK, Sun SW, Ju WK, et al., Diffusion tensor imaging detects and differentiates axon and myelin degeneration in mouse optic nerve after retinal ischemia, NeuroImage, 2003;20:1714–22.
22.
Sun SW, Liang HF, Cross AH, Song SK, Evolving Wallerian degeneration after transient retinal ischemia in mice characterized by diffusion tensor imaging, NeuroImage, 2008;40:1–10.
23. 24.
Naismith RT, Xu J, Tutlam NT, et al., Disability in optic neuritis correlates with diffusion tensor-derived directional diffusivities, Neurology, 2009;72:589–94.
Sidaros A, Engberg AW, Sidaros K, et al., Diffusion tensor imaging during recovery from severe traumatic brain injury and relation to clinical outcome: a longitudinal study, Brain, 2008;131:559–72.
25.
Acosta-Cabronero J, Williams GB, Pengas G, et al., Absolute diffusivities define the landscape of white matter degeneration in Alzheimer’s disease, Brain, 2010;133(Pt 2):529–39.
26. 27. 28.
Wheeler-Kingshott CA, Cercignani M, About ‘axial‘ and ‘radial’ diffusivities, Magn Reson Med, 2009;61:1255–60.
Kang DW, Chu K, Yoon BW, et al., Diffusion-weighted imaging in Wallerian degeneration, J Neurolog Sci, 2000;178:167–9.
Lindberg PG, Skejo PH, Rounis E, et al., Wallerian degeneration of the corticofugal tracts in chronic stroke: a pilot study relating diffusion tensor imaging, transcranial magnetic stimulation, and hand function, Neurorehab Neural Repair, 2007;21:551–60.
29.
Thomalla G, Glauche V, Koch MA, et al., Diffusion tensor imaging detects early Wallerian degeneration of the pyramidal tract after ischemic stroke, NeuroImage, 2004;22:1767–74.
48. 49. 33. 34. 35. 36. 37. 30.
Werring DJ, Toosy AT, Clark CA, et al., Diffusion tensor imaging can detect and quantify corticospinal tract degeneration after stroke, J Neurol Neurosurg Psych, 2000;69:269–72.
31. 32.
Konishi J, Yamada K, Kizu O, et al., MR tractography for the evaluation of functional recovery from lenticulostriate infarcts, Neurology, 2005;64:108–13. Kunimatsu A, Aoki S, Masutani Y, et al.,
Three-dimensional white matter tractography by diffusion tensor imaging in ischemic stroke involving the corticospinal tract, Neuroradiology, 2003;45:532–5.
Lee JS, Han MK, Kim SH, et al., Fiber tracking by diffusion tensor imaging in corticospinal tract stroke: NeuroImage, 2005;26:771–6.
Nelles M, Gieseke J, Flacke S, et al., Diffusion tensor pyramidal tractography in patients with anterior choroidal artery infarcts, AJNR, 2008;29:488–93.
Yamada K, Ito H, Nakamura H, et al., Stroke patients’ evolving symptoms assessed by tractography, J Magn Reson Imaging, 2004;20:923–9.
Newton JM, Ward NS, Parker GJ, et al., Non-invasive mapping of corticofugal fibers from multiple motor areas – relevance to stroke recovery, Brain, 2006;129:1844–58.
Schaechter JD, Fricker ZP, Perdue KL, et al., Microstructural status of ipsilesional and contralesional corticospinal tract correlates with motor skill in chronic stroke patients, Hum Brain Mapp, 2009;30:3461–74.
38. 39. 40.
Perez MA, Cohen LG, Interhemispheric inhibition between primary motor cortices: what have we learned?, J Physiol, 2009;587:725–6.
Carter AR, Astafiev SV, Lang CE, et al., Resting inter-hemispheric fMRI connectivity predicts performance after stroke, Ann Neurol, 2009;67:365–75.
Grefkes C, Nowak DA, Eickhoff SB, et al., Cortical connectivity after subcortical stroke assessed with functional magnetic resonance imaging, Ann Neurology, 2008;63:236–46.
41. 42. 43. 44.
Schlaug G, Renga V, Nair D, Transcranial direct current stimulation in stroke recovery, Arch Neurol, 2008;65: 1571–6.
Johansen-Berg H, Rushworth MF, Bogdanovic MD, et al., The role of ipsilateral premotor cortex in hand movement after stroke, Proc Nat Acad Sci USA, 2002;99:14518–23.
Werhahn KJ, Conforto AB, Kadom N, et al., Contribution of the ipsilateral motor cortex to recovery after chronic stroke, Annals Neurol, 2003;54:464–72.
Wahl M, Lauterbach-Soon B, Hattingen E, et al., Human motor corpus callosum: topography, somatotopy, and link between microstructure and function, J Neurosci, 2007;27:12132–8.
45. 46.
Lindenberg R, Zhu LL, Rüber T, Schlaug G, Predicting functional motor potential in chronic stroke patients using diffusion tensor imaging, Hum Brain Mapp, 2010; in press.
Rother J, Schellinger PD, Gass A, et al., Effect of intravenous thrombolysis on MRI parameters and functional outcome in acute stroke <6 hours, Stroke, 2002;33:2438–45.
47.
Olivot JM, Mlynash M, Thijs VN, et al., Relationships between infarct growth, clinical outcome, and early recanalization in diffusion and perfusion imaging for understanding stroke evolution (DEFUSE), Stroke, 2008;39:2257–63.
Hillis AE, Gold L, Kannan V, et al., Site of the ischemic penumbra as a predictor of potential for recovery of functions, Neurology, 2008;71:184–9.
De Silva DA, Fink JN, Christensen S, et al., Assessing reperfusion and recanalization as markers of clinical outcomes after intravenous thrombolysis in the echoplanar imaging thrombolytic evaluation trial (EPITHET), Stroke, 2009;40:2872–4.
50. 51.
Taoufik E, Probert L, Ischemic neuronal damage, Curr Pharm Des, 2008;14:3565–73.
Guadagno JV, Jones PS, Aigbirhio FI, et al., Selective neuronal loss in rescued penumbra relates to initial
73. hypoperfusion, Brain, 2008;131:2666–78. 52. 53.
Hummel FC, Steven B, Hoppe J, et al., Deficient intracortical inhibition (SICI) during movement preparation after chronic stroke, Neurology, 2009;72:1766–72.
Butefisch CM, Wessling M, Netz J, et al., Relationship between interhemispheric inhibition and motor cortex excitability in subacute stroke patients, Neurorehab Neural Repair, 2008;22:4–21.
54. 55.
Marshall RS, Zarahn E, Alon L, et al., Early imaging correlates of subsequent motor recovery after stroke, Ann Neurol, 2009;65:596–602.
Askim T, Indredavik B, Vangberg T, Haberg A, Motor network changes associated with successful motor skill relearning after acute ischemic stroke, Neurorehab Neural Repair, 2009;23:295–304.
56. 57. 58. 59.
Saur D, Lange R, Baumgaertner A, et al., Dynamics of language reorganization after stroke, Brain, 2006;129: 1371–84.
Floel A, Nagorsen U, Werhahn KJ, et al., Influence of somatosensory input on motor function in patients with chronic stroke, Ann Neurology, 2004;56:206–12.
Schaechter JD, Moore CI, Connell BD, et al., Structural and functional plasticity in the somatosensory cortex of chronic stroke patients, Brain, 2006;129:2722–33.
Carey LM, Abbott DF, Harvey MR, et al., Touch impairment after subcortical or cortical sensory lesions differentially correlates with brain activation, Neurorehab Neural Repair, 2011; in press.
60. 61. 62.
Staines WR, Black SE, Graham SJ, McIlroy WE, Somatosensory gating and recovery from stroke involving the thalamus, Stroke, 2002;33:2642–51.
Johansen-Berg H, Functional imaging of stroke recovery: what have we learnt and where do we go from here?, Int J Stroke, 2007;2:7–16.
Raos V, Bentivoglio M, Crosstalk between the two sides of the thalamus through the reticular nucleus: a retrograde and anterograde tracing study in the rat, J Comp Neurol, 1993;332:145–54.
63.
Jain N, Qi HX, Collins CE, Kaas JH, Large-scale reorganization in the somatosensory cortex and thalamus after sensory loss in macaque monkeys, J Neurosci, 2008;28: 11042–60.
64. 65. 66.
Kaas JH, Is most of neural plasticity in the thalamus cortical?, Proc Na Academy Sci USA, 1999;96:7622–3.
Krupa DJ, Ghazanfar AA, Nicolelis MA, Immediate thalamic sensory plasticity depends on corticothalamic feedback, Proc Na Academy Sci USA, 1999;96:8200–5.
Hamzei F, Dettmers C, Rijntjes M, Weiller C, The effect of cortico-spinal tract damage on primary sensorimotor cortex activation after rehabilitation therapy, Exp Brain Res, 2008;190:329–36.
67.
Sawaki L, Butler AJ, Leng X, et al., Constraint-induced movement therapy results in increased motor map area in subjects 3 to 9 months after stroke, Neurorehab Neural Repair, 2008;22:505–13.
68.
Gauthier LV, Taub E, Perkins C, et al., Remodeling the brain: plastic structural brain changes produced by different motor therapies after stroke, Stroke, 2008;39: 1520–5.
69.
Dong Y, Winstein CJ, Albistegui-DuBois R, Dobkin BH, Evolution of FMRI activation in the perilesional primary motor cortex and cerebellum with rehabilitation training- related motor gains after stroke: a pilot study, Neurorehab Neural Repair, 2007;21:412–28.
70. 71. 72.
Takahashi CD, Der-Yeghiaian L, Le V, et al., Robot-based hand motor therapy after stroke, Brain, 2008;131:425–37.
Luft AR, Macko RF, Forrester LW, et al., Treadmill exercise activates subcortical neural networks and improves walking after stroke Stroke, 2008;39:3341–50.
Lindberg PG, Schmitz C, Engardt M, et al., Use-dependent up- and down-regulation of sensorimotor brain circuits in stroke patients, Neurorehab Neural Repair, 2007;21:315–26.
Lang CE, DeJong SL, Beebe JA, Recovery of thumb and finger extension and its relation to grasp performance after
110
US NEUROLOGY
Page 1 |
Page 2 |
Page 3 |
Page 4 |
Page 5 |
Page 6 |
Page 7 |
Page 8 |
Page 9 |
Page 10 |
Page 11 |
Page 12 |
Page 13 |
Page 14 |
Page 15 |
Page 16 |
Page 17 |
Page 18 |
Page 19 |
Page 20 |
Page 21 |
Page 22 |
Page 23 |
Page 24 |
Page 25 |
Page 26 |
Page 27 |
Page 28 |
Page 29 |
Page 30 |
Page 31 |
Page 32 |
Page 33 |
Page 34 |
Page 35 |
Page 36 |
Page 37 |
Page 38 |
Page 39 |
Page 40 |
Page 41 |
Page 42 |
Page 43 |
Page 44 |
Page 45 |
Page 46 |
Page 47 |
Page 48 |
Page 49 |
Page 50 |
Page 51 |
Page 52 |
Page 53 |
Page 54 |
Page 55 |
Page 56 |
Page 57 |
Page 58 |
Page 59 |
Page 60 |
Page 61 |
Page 62 |
Page 63 |
Page 64 |
Page 65 |
Page 66 |
Page 67 |
Page 68 |
Page 69 |
Page 70 |
Page 71 |
Page 72 |
Page 73 |
Page 74 |
Page 75 |
Page 76 |
Page 77 |
Page 78 |
Page 79 |
Page 80 |
Page 81 |
Page 82 |
Page 83 |
Page 84 |
Page 85 |
Page 86 |
Page 87 |
Page 88 |
Page 89 |
Page 90 |
Page 91 |
Page 92 |
Page 93 |
Page 94 |
Page 95 |
Page 96 |
Page 97 |
Page 98 |
Page 99 |
Page 100 |
Page 101 |
Page 102 |
Page 103 |
Page 104 |
Page 105 |
Page 106 |
Page 107 |
Page 108 |
Page 109 |
Page 110 |
Page 111 |
Page 112 |
Page 113 |
Page 114 |
Page 115 |
Page 116 |
Page 117 |
Page 118 |
Page 119 |
Page 120 |
Page 121 |
Page 122 |
Page 123 |
Page 124 |
Page 125 |
Page 126 |
Page 127 |
Page 128 |
Page 129 |
Page 130 |
Page 131 |
Page 132