Evoking plasticity through sensory stimulation: Implications for learning and rehabilitation

详细信息    查看全文

• 作者：Hubert R. Dinse (1) (2)
  Martin Tegenthoff (2)
  
  1. Neural Plasticity Lab ; Institute fur Neuroinformatik ; Ruhr University Bochum ; Building NB 3 ; 44780 ; Bochum ; Germany
  2. Neurologische Klinik am Berufsgenossenschaftlichen Universit盲tsklinikum Bergmannsheil ; Ruhr-University ; Bochum ; Germany
  
• 关键词：Plasticity ; Somatosensory systems ; Perceptual learning ; Therapy and intervention ; Aging
• 刊名：e-Neuroforum
• 出版年：2015
• 出版时间：March 2015
• 年：2015
• 卷：6
• 期：1
• 页码：11-20
• 全文大小：943 KB
• 参考文献：1. Amitay, S, Irwin, A, Moore, DR (2006) Discrimination learning induced by training with identical stimuli. Nat Neurosci 9: pp. 1446-1448 CrossRef
  2. Beste, C, Dinse, HR (2013) Learning without training. Curr Biol 23: pp. 4 CrossRef
  3. Bliss, TV, Collingridge, GL (1993) A synaptic model of memory: long-term potentiation in the hippocampus. Nature 361: pp. 31-39 CrossRef
  4. Clapp, WC, Hamm, JP, Kirk, IJ, Teyler, TJ (2012) Translating long-term potentiation from animals to humans: a novel method for noninvasive assessment of cortical plasticity. Biol Psychiatry 71: pp. 496-502 CrossRef
  5. Conforto, AB, Kaelin-Lang, A, Cohen, LG (2002) Increase in hand muscle strength of stroke patients after somatosensory stimulation. Ann Neurol 51: pp. 122-125 CrossRef
  6. Cotman, CW, Monaghan, DT, Ganong, AH (1988) Excitatory Amino Acid neurotransmission: NMDA receptors and Hebb-type synaptic plasticity. Ann Rev Neurosci 11: pp. 61-80 CrossRef
  7. Dinse, HR, Ragert, P, Pleger, B, Schwenkreis, P, Tegenthoff, M (2003) Pharmacological modulation of perceptual learning and associated cortical reorganization. Science 301: pp. 91-94 CrossRef
  8. Dinse, HR, Ragert, P, Pleger, B, Schwenkreis, P, Tegenthoff, M (2003) GABAergic mechanisms gate tactile discrimination learning. Neuroreport 14: pp. 1747-1751 CrossRef
  9. Dinse, HR, Kalisch, T, Ragert, P, Pleger, B, Schwenkreis, P, Tegenthoff, M (2005) Improving human haptic performance in normal and impaired human populations through unattended activation-based learning. Trans Appl Percep 2: pp. 71-88 CrossRef
  10. Dinse, HR, Kleibel, N, Kalisch, T, Ragert, P, Wilimzig, C, Tegenthoff, M (2006) Tactile coactivation resets age-related decline of human tactile discrimination. Ann Neurol 60: pp. 88-94 CrossRef
  11. Dinse HR, Bohland J, Kalisch, Kraemer M, Freund E, Beeser E, H枚mberg V, Stephan KM (2008) Repetitive sensory stimulation training in stroke. Europ J Neurol 15:400
  12. Dinse, HR, Kattenstroth, JC, Gattica Tossi, MA, Tegenthoff, M, Kalisch, T Sensory stimulation for augmenting perception, sensorimotor behavior and cognition. In: Segev, I, Markram, H eds. (2011) EPFL Press. Lausanne, Swizerland, pp. 11-39
  13. Freyer, F, Reinacher, M, Nolte, G, Dinse, HR, Ritter, P (2012) Repetitive tactile stimulation changes resting-state functional connectivity鈥攊mplications for treatment of sensorimotor decline. Front Hum Neurosci 6: pp. 144 CrossRef
  14. Freyer, F, Becker, R, Dinse, HR, Ritter, P (2013) State-dependent perceptual learning. J Neurosci 33: pp. 2900-2907 CrossRef
  15. Godde, B, Spengler, G, Dinse, HR (1996) Associative pairing of tactile stimulation induces somatosensory cortical reorganization in rats and humans. Neuroreport 8: pp. 281-285 CrossRef
  16. Godde, B, Stauffenberg, B, Spengler, F, Dinse, HR (2000) Tactile coactivation induced changes in spatial discrimination performance. J Neurosci 20: pp. 1597-1604
  17. Gutnisky, DA, Hansen, BJ, Iliescu, BF, Dragoi, V (2009) Attention alters visual plasticity during exposure-based learning. Current Biol 19: pp. 555-560 CrossRef
  18. Hoeffken, O, Veit, M, Knossalla, F, Lissek, S, Bliem, B, Ragert, P, Dinse, HR, Tegenthoff, M (2007) Sustained increase of somatosensory cortex excitability by tactile coactivation studied by paired median nerve stimulation in humans correlates with perceptual gain. J Physiol 584: pp. 463-471 CrossRef
  19. Kattenstroth, JC, Kalisch, T, Tegenthoff, M, Dinse, HR (2012) Long-term sensory stimulation therapy improves hand function and restores cortical responsiveness in patients with chronic cerebral lesions. Three single case studies. Front Hum Neurosci 6: pp. 244 CrossRef
  20. Kleim, JA, Chan, S, Pringle, E, Schallert, K, Procaccio, V, Jimenez, R, Cramer, SC (2006) BDNF val66met polymorphism is associated with modified experience-dependent plasticity in human motor cortex. Nat Neurosci 9: pp. 735-737 CrossRef
  21. Kujirai, T, Caramia, MD, Rothwell, JC, Day, BL, Thompson, PD, Ferbert, A, Wroe, S, Asselman, P, Marsden, CD (1993) Corticocortical inhibition in human motor cortex. J Physiol 471: pp. 501-519 CrossRef
  22. Kwakkel, G, Peppen, R, Wagenaar, RC, Wood Dauphinee, S, Richards, C, Ashburn, A, Miller, K, Lincoln, N, Partridge, C, Wellwood, I, Langhorne, P (2004) Effects of augmented exercise therapy time after stroke: a meta-analysis. Stroke 35: pp. 2529-2539 CrossRef
  23. Lynch, MA (2004) Long-term potentiation and memory. Physiol Rev 84: pp. 87-136 CrossRef
  24. Malenka, RC, Bear, MF (2004) LTP and LTD: an embarrassment of riches. Neuron 44: pp. 5-21 CrossRef
  25. Muret, D, Dinse, HR, Macchione, S, Urquizar, C, Farn猫, A, Reilly, K (2014) Touch improvement at the hand transfers to the face. Current Biol 24: pp. R736-737 CrossRef
  26. Nicoll, RA, Malenka, RC (1995) Contrasting properties of two forms of long-term potentiation in the hippocampus. Nature 377: pp. 115-118 CrossRef
  27. Parsons, CG, Danysz, W, Quack, G (1999) Memantine is a clinically well tolerated N-methyl-D-aspartate (NMDA) receptor antagonist鈥揳 review of preclinical data. Neuropharm 38: pp. 735-767 CrossRef
  28. Pleger, B, Dinse, HR, Ragert, P, Schwenkreis, P, Malin, JP, Tegenthoff, M (2001) Shifts in cortical representations predict human discrimination improvement. Proc Nat Acad Sci 98: pp. 12255-12260 CrossRef
  29. Pleger, B, Foerster, AF, Ragert, P, Dinse, HR, Schwenkreis, P, Malin, JP, Nicolas, V, Tegenthoff, M (2003) Functional imaging of perceptual learning in human primary and secondary somatosensory cortex. Neuron 40: pp. 643-653 CrossRef
  30. Ragert, P, Kalisch, T, Bliem, B, Franzkowiak, S, Dinse, HR (2008) Differential effects in human tactile discrimination behavior evoked by tactile high- and low-frequency stimulation. BMC Neurosci 9: pp. 9 CrossRef
  31. Ramachandran, VS, Stewart, M, Rogers-Ramachandran, DC (1992) Perceptual correlates of massive cortical reorganization. Neuroreport 3: pp. 583-586 CrossRef
  32. Sagi, D (2011) Perceptual learning in vision research. Vision Res 51: pp. 1552-1566 CrossRef
  33. Sasaki, Y, Nanez, JE, Watanabe, T (2010) Advances in visual perceptual learning and plasticity. Nat Rev Neurosci 11: pp. 53-60 CrossRef
  34. Sawaki, L, Wu, CW, Kaelin-Lang, A, Cohen, LG (2006) Effects of somatosensory stimulation on use-dependent plasticity in chronic stroke. Stroke 37: pp. 246-247 CrossRef
  35. Seitz, A, Dinse, HR (2007) A common framework for perceptual learning. Current Opin Neurobiol 17: pp. 1-6 CrossRef
  36. Taub, E, Uswatte, G, Elbert, T (2002) New treatments in neurorehabilitation founded on basic research. Nature Rev Neurosci 3: pp. 228-236 CrossRef
  37. Teyler, TJ, Hamm, JP, Clapp, WC, Johnson, BW, Corballis, MC, Kirk, IJ (2005) Long-term potentiation of human visual evoked responses. Eur J Neurosci 21: pp. 2045-2050 CrossRef
  38. Wright, BA, Sabin, AT, Zhang, Y, Marrone, N, Fitzgerald, MB (2010) Enhancing perceptual learning by combining practice with periods of additional sensory stimulation. J Neurosci 30: pp. 12868-12977 CrossRef
  39. Wu, CW, Seo, HJ, Cohen, LG (2006) Influence of electric somatosensory stimulation on paretic-hand function in chronic stroke. Arch Phys Med Rehabil 87: pp. 351-357 CrossRef
  
• 刊物主题：Neurosciences; Neurobiology; Life Sciences, general; Biomedicine general; Neurochemistry; Neurology;
• 出版者：Springer Berlin Heidelberg
• ISSN：1868-856X

文摘

The gold standard for improving sensory, motor and or cognitive abilities is long-term training and practicing. Recent work, however, suggests that intensive training may not be necessary. Improved performance can be effectively acquired by a complementary approach in which the learning occurs in response to mere exposure to repetitive sensory stimulation. Such training-independent sensory learning (TISL), which has been intensively studied in the somatosensory system, induces in humans lasting changes in perception and neural processing, without any explicit task training. It has been suggested that the effectiveness of this form of learning stems from the fact that the stimulation protocols used are optimized to alter synaptic transmission and efficacy. TISL provides novel ways to investigate in humans the relation between learning processes and underlying cellular and molecular mechanisms, and to explore alternative strategies for intervention and therapy.