Cellular and molecular bases of neuroplasticity: brainstem effects after cochlear damage

After a cochlear lesion or auditory nerve damage, afferent connections from auditory ganglia can be highly altered. This results in a clear reduction of auditory input and an alteration of connectivity of terminals on cochlear nuclei neurons. Such a process could stimulate the reorganization of the...

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Bibliographic Details
Published in:Acta oto-laryngologica 2010-03, Vol.130 (3), p.318-325
Main Authors: Gil-Loyzaga, Pablo, Carricondo, Francisco, Bartolomé, Maria V., Iglesias, Mari C., Rodríguez, Fernando, Poch-Broto, Joaquin
Format: Article
Language:English
Subjects:
Animals
Auditory Pathways - pathology
Auditory Pathways - physiopathology
auditory system
Biological and medical sciences
Brain Stem - pathology
Brain Stem - physiopathology
brainstem
cochlea
Cochlear Nerve - pathology
Cochlear Nerve - physiopathology
cochlear nuclei
Cochlear Nucleus - pathology
Cochlear Nucleus - physiopathology
Disease Models, Animal
GAP-43 Protein - genetics
Gene Expression - genetics
Guinea Pigs
Humans
Medical sciences
Nerve Regeneration - genetics
Nerve Regeneration - physiology
Neuronal Plasticity - genetics
Neuronal Plasticity - physiology
Neuroplasticity
Otorhinolaryngology. Stomatology
Synapses
Young Adult
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Summary:After a cochlear lesion or auditory nerve damage, afferent connections from auditory ganglia can be highly altered. This results in a clear reduction of auditory input and an alteration of connectivity of terminals on cochlear nuclei neurons. Such a process could stimulate the reorganization of the neural circuits and neuroplasticity. Cochlea removal has been demonstrated to be a good model in which to analyse brainstem neuroplasticity, particularly with regard to the cochlear nuclei. After cochlea removal three main periods of degeneration and regeneration were observed. Early effects, during the first week post lesion, involved acute degeneration with nerve ending oedema and degeneration. During the second and, probably, the third post lesion weeks, degeneration was still present, even though a limited and diffuse expression of GAP-43 started. Around 1 month post lesion, degeneration at the cochlear nuclei progressively disappeared and a relevant GAP-43 expression was found. We conclude that neuroplasticity leads neurons to modify their activity and/or their synaptic tree as a consequence of animal adaptation to learning and memory. For the human being neuroplasticity is involved in language learning and comprehension, particularly the acquisition of a second language. Neuroplasticity is important for therapeutic strategies, such as hearing aids and cochlear implants.
ISSN:0001-6489
1651-2251
DOI:10.3109/00016480903127468