Ptito et al. (2005)
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'''Cross-Modal Plasticity Revealed by Electrotactile Stimulation of the Tongue in the Congenitally Blind (Ptito et al., 2005)''' | '''Cross-Modal Plasticity Revealed by Electrotactile Stimulation of the Tongue in the Congenitally Blind (Ptito et al., 2005)''' | ||
| - | The experimenters in this study used PET to study cross-modal plasticity in the congenitally blind, using electrotactile | + | The experimenters in this study used PET to study cross-modal plasticity in the congenitally blind, using electrotactile stimulation of the tongue. |
== Participants == | == Participants == | ||
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== Results == | == Results == | ||
| - | Before training, no significant changes in regional cerebral blood flow (rCBF) was observed in the occipital cortex of either group. After practice for the blind, however, activity in the | + | Before training, no significant changes in regional cerebral blood flow (rCBF) was observed in the occipital cortex of either group. After practice for the blind, however, activity in the occipital cortex increased. This increase in activity was not observed in the sighted participants, providing evidence for training-induced plasticity in the congenitally blind. |
| - | An inter-regional correlation analysis showed that task-related rCBF changes in the left posterior parietal cortex | + | An inter-regional correlation analysis showed that task-related rCBF changes in the left posterior parietal cortex were positively correlated with rCBF changes in the occipital area of the trained blind participants. |
== Conclusion == | == Conclusion == | ||
This data revealed that cross-modal plasticity in the blind develops rapidly and that the occipital cortex is part of a functional neural network for tactile discrimination in conjunction with the posterior parietal cortex. Data further showed that the tongue can act as a portal to convey somatosensory information to visual cortex. | This data revealed that cross-modal plasticity in the blind develops rapidly and that the occipital cortex is part of a functional neural network for tactile discrimination in conjunction with the posterior parietal cortex. Data further showed that the tongue can act as a portal to convey somatosensory information to visual cortex. | ||
Revision as of 23:01, 24 April 2008
Cross-Modal Plasticity Revealed by Electrotactile Stimulation of the Tongue in the Congenitally Blind (Ptito et al., 2005)
The experimenters in this study used PET to study cross-modal plasticity in the congenitally blind, using electrotactile stimulation of the tongue.
Contents |
Participants
Participants included 6 blind and 5 sighted blind-folded controls.
Training
Participants were trained to use their tongue in a Snellen orientation detection task. They were scanned before and after training.
Results
Before training, no significant changes in regional cerebral blood flow (rCBF) was observed in the occipital cortex of either group. After practice for the blind, however, activity in the occipital cortex increased. This increase in activity was not observed in the sighted participants, providing evidence for training-induced plasticity in the congenitally blind.
An inter-regional correlation analysis showed that task-related rCBF changes in the left posterior parietal cortex were positively correlated with rCBF changes in the occipital area of the trained blind participants.
Conclusion
This data revealed that cross-modal plasticity in the blind develops rapidly and that the occipital cortex is part of a functional neural network for tactile discrimination in conjunction with the posterior parietal cortex. Data further showed that the tongue can act as a portal to convey somatosensory information to visual cortex.
