neuroplasticity

Go Virtual to Get Real: Virtual Reality as a Resource for Spinal Cord Treatment

Abstract: Increasingly, refined virtual reality (VR) techniques allow for the simultaneous and coherent
stimulation of multiple sensory and motor domains. In some clinical interventions, such as those
related to spinal cord injuries (SCIs), the impact of VR on people′s multisensory perception, movements,
attitudes, and even modulations of socio‐cognitive aspects of their behavior may influence
every phase of their rehabilitation treatment, from the acute to chronic stages. This work describes

Disconnected body representation: neuroplasticity following spinal cord injury

Neuroplastic changes in somatotopic organization within the motor and somatosensory systems have long been observed. The interruption of afferent and efferent brain-body pathways promotes extensive cortical reorganization. Changes are majorly related to the typical homuncular organization of sensorimotor areas and specific "somatotopic interferences". Recent findings revealed a relevant peripheral contribution to the plasticity of body representation in addition to the role of sensorimotor cortices.

Interplay between inflammation and neural plasticity: Both immune activation and suppression impair LTP and BDNF expression

An increasing number of studies show that both inflammation and neural plasticity act as key players in the vulnerability and recovery from psychiatric disorders and neurodegenerative diseases. However, the interplay between these two players has been limitedly explored. In fact, while a few studies reported an immune activation, others conveyed an immune suppression, associated with an impairment in neural plasticity. Therefore, we hypothesized that deviations in inflammatory levels in both directions may impair neural plasticity.

Distinct populations of neurons activated by heroin and cocaine in the striatum as assessed by catFISH

Despite the still prevailing notion of a shared substrate of action for all addictive drugs, there is evidence suggesting that opioid and psychostimulant drugs differ substantially in terms of their neurobiological and behavioral effects. These differences may reflect separate neural circuits engaged by the two drugs. Here we used the catFISH (cellular compartment analysis of temporal activity by fluorescence in situ hybridization) technique to investigate the degree of overlap between neurons engaged by heroin versus cocaine in adult male Sprague Dawley rats.

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