Anales de la RANM

26 A N A L E S R A N M R E V I S T A F U N D A D A E N 1 8 7 9 NEUROPLASTICIDAD CROSMODAL TÁC TIL Tomás Ortiz Alonso An RANM · Año 2020 · número 137 (01) · páginas 22 a 26 6. Shiosaka, S., Yoshida, S. Synaptic microenviron- ments, structural plasticity, adhesion molecules, proteases and their inhibitors. Neurosci. Res . 2000; 37: 85–89. 7. Ismail FY, Fatemi A, Johnston MV. Cerebral plas- ticity: Windows of opportunity in the developing brain. Eur J Paediatr Neurol. 2017, 21(1):23-48. 8. Henschke JU, Oelschlegel AM, Angenstein F, et al. Early sensory experience influences the develo- pment of multisensorial thalamocortical and in- tracortical connections of primary sensory cor- tices. Brain Struct Funct. 2018;223(3):1165-1190 9. Merabet, LB., Hamilton, R., Schlaug,G., et al. Rapid and reversible recruitment of early visual cortex for touch. PLoS ONE, 2008, 3 (8):e3046. 10. Sathian, K. y Stilla.R. Cross-modal plasticity of tactile perception in blindness. Rest Neurol Neu- rosci, 2010, 28 (2):271–281. 11. Stilla, R., Hanna, R., Hu, X., Mariola, E., Deshpande,G., Sathian, K. Neural processing underlying tactile microspatial discrimination in the blind: A functional magnetic resonance imaging study. J Vision 2008, 8 (10):1–19. 12. Henschke, J.U., Noesselt, T., Scheich, H., Budin- ger, E. Possible anatomical pathways for short- latency multisensory integration processes in primary sensory cortices. Brain Struct Funct 2015;220:955–977. 13. Muller, F., Niso, G., Samiee, S., Ptito, M., Baillet, S., Kupers, R. A thalamocortical pathway for fast rerou- ting of tactile information to occipital cortex in con- genital blindness. Nat Commun 2019;10:1-9 14. Ortiz T., Poch J., Santos J.M., et al. Occipital enduring neuroplasticity induced by long-term repetitive tactile stimulation: a case report, Neurocase 2014;20(3):273-282. 15. Ortiz T., Santos JM., Generación de experiencias vi- suales en ciegos mediante estimulación táctil repeti- tiva, Ciencia Cognitiva 2012;6(1): 9-12. 16. Sadato N,Okada T, Honda M, Yonekura Y. Cri- tical period for cross-modal plasticity in blind humans: A functional MRI study. Neuroimage, 2002; 16 (2):389–400. 17. Sani L, Ricciardi E, Gentili C et al.. Effects of vi- sual experience on the human MTþ functional connectivity networks: An fMRI study of motion perception in sighted and congenitally blind in- dividuals. Front Sys Neurosci 2010;4:159 
 18. Collignon O, Dormal G, Albouy G, et al. Impact of blindness onset on the functional organiza- tion and the connectivity of the occipital cortex. Brain 2013;136:2769–2783 19. Boroojerdi B., Bushara K. O., Corwell B. et al. Enhanced excitability of the human visual cortex induced by short-term light deprivation. Cere- bral Cortex. 2002;10 (5):529–534. 20. Facchini, S. Y Aglioti, SM. Short term light de- privation increases tactile spatial acuity in hu- mans. Neurology, 2003; 60 (12):1998–1999. 21. Burton H., Snyder A.Z., Contouro T.E. et al. Adaptive changes in early and late blind: An fMRI study of Braille reading. J Neurophysiol 2002; 87 (1):589–607. 22. Burton, H. Visual cortex activity in early and late blind people. J Neurosc, 2003; 23 (10):4005–4011. 23. Burton H, Sinclair RJ, McLaren DG. Cortical ac- tivity to vibrotactile stimulation: An fMRI stu- dy in blind and sighted individuals. Hum Brain Mapping, 2004; 23 (4):210–228 24. Burton, H., McLaren, DG, Sinclair, RJ. Reading embossed capital letters: An fMRI study in blind and sighted individuals. Hum Brain Mapping, 2006; 27 (4):325–339. 25. Burton, H., D. G. McLaren. Visual cortex activa- tion in late-onset, Braille naive blind individuals: An fMRI study during semantic and phonolo- gical tasks with heard words. Neurosci Letters, 2006; 392 (1–2):38–42. 26. Leo A, Bernardi G, Handjaras G, et al. Increa- sed BOLD variability in the parietal cortex and enhanced parieto- occipital connectivity during tactile perception in congenitally blind indivi- duals. Neural Plast 2012;2012:720278 27. Voss, P., Gougoux, F., Zatorre,RJ., et al. Differen- tial occipital responses in early- and late-blind individuals during a sound-source discrimina- tion task. Neuroimage, 2008, 40 (2):746–758. 28. Gougoux F., Belin P., Voss P., et al. Voice per- ception in blind persons: A functional magnetic resonance imaging study. Neurophysiol 2009; 47 (13):2967–2974. 29. Nasconcelos N., Pantojaf J., Belchiora H. et al. Cross-modal responses in the primary visual cortex encode complex objects and correlate with tactile discrimination. PNAS 2011;108;(37): 15408-15413 30. Karlen SJ, Kahn DM, Krubitzer L. Early blind- ness results in abnormal corticocortical and Tha- locortical connections. Neuroscience 2006;142(3): 843-858 31. Kemenes I., Straub V.A., Nikitin E.S. et al. Role of Delayed Nonsynaptic Neuronal Plasticity in Long-Term Associative Memory. Curr Biol 2006;16:1269-1279 DECLARACIÓN DE TRANSPARENCIA El autor/a de este artículo declara no tener ningún tipo de conflicto de intereses respecto a lo expuesto en la presente revisión. Si desea citar nuestro artículo: Ortiz-Alonso T. Neuroplasticidad crosmodal táctil ANALES RANM [Internet]. Real Academia Nacional de Medicina de España; An RANM · Año 2020 · número 137 (01) · páginas 22 – 26 DOI: 10.32440/ar.2020.137.01.rev02