Neuro-Ophthalmology & Visual Neuroscience
ISSN (Print): 2572-7257 ISSN (Online): 2572-7281 Website: Editor-in-chief: Carlo Aleci
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Neuro-Ophthalmology & Visual Neuroscience. 2020, 5(1), 2-3
DOI: 10.12691/novn-5-1-2
Open AccessArticle

Electrify Yourself

Carlo Aleci1,

1University of Turin

Pub. Date: July 01, 2020

Cite this paper:
Carlo Aleci. Electrify Yourself. Neuro-Ophthalmology & Visual Neuroscience. 2020; 5(1):2-3. doi: 10.12691/novn-5-1-2

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit


[1]  Julkunen L, Tenovuo O, Jaaskelainen S, Hamalainen H. (2003). Rehabilitation of chronic post-stroke visual field defect with computer-assisted training: a clinical and neurophysiological study. Restorative Neurology & Neuroscience, 21: 19-28.
[2]  Sabel BA, Kenkel S, Kasten E. (2004). Vision restoration therapy (VRT) efficacy as assessed by comparative perimetric analysis and subjective questionnaires. Restorative Neurology & Neuroscience, 22: 399-420.
[3]  Kasten E, Bunzenthal U, Sabel BA. (2006) Visual field recovery after vision restoration therapy (VRT) is independent of eye movements: an eye tracker study. Behavioral Brain Research, 175: 18-26.
[4]  Poggel DA, Kasten E, Muller-Oehring EM, Bunzenthal U, Sabel BA. (2006). Improving residual vision by attentional cueing in patients with brain lesions. Brain Research, 1097: 142-148.
[5]  Henriksson L, Raninen A, Näsänen R, Hyvärinen L, Vanni S. (2007). Training-induced cortical representation of a hemianopic hemifield. Journal of Neurology, Neurosurgery & Psychiatry, 78: 74-81.
[6]  Mueller I, Gall C, Kasten E, Sabel BA. (2008). Long-term learning of visual functions in patients after brain damage. Behavioral Brain Research, 191: 32-42.
[7]  Mueller I, Mast H, Sabel BA. (2007). Recovery of visual field defects: a large clinical observational study using vision restoration therapy. Restorative Neurology & Neuroscience, 25: 563-572.
[8]  Marshall RS, Ferrera JJ, Barnes A, Xian Zhang, O'Brien KA, Chmayssani M, Hirsch J, Lazar RM. (2008). Brain activity associated with stimulation therapy of the visual borderzone in hemianopic stroke patients. Neurorehabilitation & Neural Repair, 22: 136-144.
[9]  Bechtereva MP, Shandurina AN, Khilko VA, Lyskov EB, Matveev YK, Panin AV, Nikolsky AV. (1985). Clinical and physiological basis for a new method underlying rehabilitation of the damaged visual nerve function by direct electrical stimulation. International Journal of Psychophysiology, 2(4): 257-272.
[10]  Fedorov AB, Chibisova AM, Tchibissova JM. (2005). Impulse modulating therapeutic electrical stimulation (IMTES) increases visual field size in patients with optic nerve lesions. International Congress Series, 1282: 525-529.
[11]  Gall C, Fedorov AB, Ernst L, Borrmann A, Sabel BA. (2010). Repetitive transorbital alternating current stimulation in optic neuropathy. Neurorehabilitation, 27(4): 335-341.
[12]  Gall C, Sgorzaly S, Schmidt S, Brandt S, Ferodov A, Sabel BA. (2011). Noninvasive transorbital alternating current stimulation improves subjective quality of life in optic neuropathy. Brain Stimulation, 4: 175-188.
[13]  Fedorov A, Jobke S, Bersnev V, Chibisova A, Chibisova Y, Gall C, Sabel BA. (2011). Restoration of vision after optic nerve lesions with noninvasive transorbital alternating current stimulation: a clinical observational study. Brain Stimulation. Brain Stimulation, 4(4): 189-201.
[14]  Schmidt S, Bathe-Peters R, Gall C, Fedorov A, Sabel BA, Brandt SA. (2013). Progressive enhancement of alpha activity and visual function in patients with optic neuropathy; a two-week non-invasive alternating current stimulation study. Clinical Neurophysiology, 122: S150-S151.