View clinical trials related to Neuronal Plasticity.
Filter by:The objective of this research is to evaluate the benefits of an experimental therapy for motor recovery of the arm after a stroke, which includes the application of a functional electrical stimulation therapy coupled to P-300 based Brain-Computer Interface system (BCI-FES). For this purpose, the investigators will compare two groups, the first one will receive only conventional physical and occupational therapy, while the second one will receive conventional therapy together with BCI-FES therapy. The control and experimental group will receive 20 sessions of conventional physical and occupational therapy at a rate of five sessions per week for 4 weeks (control group double dose of conventional therapy), and the experimental group will receive 20 sessions of rehabilitation with the BCI-FES system at a rate of five sessions per week for 4 weeks. Broadly speaking, the BCI is in charge of determining the movement selected by the individual and assist the hand movement while performing functional tasks. The movements included in the sessions will be hand opening, grasping, pinching, pronation and supination, which are combined to facilitate the execution of functional movements that are performed together with the manipulation of daily used utensils. The visual, sensory and motor feedback provided by the BCI-FES system that enables the individual to replicate the afferent-efferent motor circuit, contributes to the activation and recruitment of neural pathways, which is associated with motor recovery. It should be noted that this BCI-FES system has already been tested previously in a study with healthy individuals, and in a non-randomized pilot study that used this therapy for upper limb motor function recovery in chronic post-stroke patients. To evaluate the results, a series of tests will be applied to assess the motor recovery, including the FMA-UE: Fugl-Meyer Assessment Scale of Upper Extremity, ARAT: Action Research Arm Test, MAS: Modified Ashworth Scale, FIM: Functional Independence Measure and MAL: Motor Activity Log. Likewise, resting state functional magnetic resonance imaging studies will be performed to evaluate the degree of functional connectivity between various brain regions of interest related to the planning and execution of movements. This will determine whether the experimental therapy with BCI-FES favors arm and hand recovery in surviving stroke individuals.
New research in animal models of MS suggests that greater training intensity is required to restore lost functions. We have developed and tested vigorous intensity cool room treadmill training that people with MS who have fatigue and heat-sensitivity can tolerate. This study will focus on the appropriate dosage of training.
Background: Conclusive evidence states that the serotonergic system mediates neuroplasticity from early embryonic development until brain maturation in adulthood. This study aims to demonstrate that selective serotonin reuptake inhibitors (SSRIs) enhance learning-dependent neuroplasticity in vivo, hereby contributing to the investigators understanding of the mechanism of action of therapy with SSRIs. Objectives: 1. To prove a positive influence of SSRIs on structural remodeling during learning, reflected by enhancements of gray and white matter microstructure, connectivity and functionality in brain regions involved in learning processes. 2. To show that this effect is topologically specific, i.e. that enhancements of plasticity markers are found in different regions depending on their involvement during the performance of specific learning tasks. Study design: Randomized, double-blind, placebo-controlled, longitudinal mono-center study. 80 healthy subjects will undergo three MRI scanning sessions: 1. baseline, at study entry, 2. after 3 weeks of facial/emotional (n=40) or Chinese character-meaning learning (n=40) and 3. after 3 weeks learning of new associations under administration of an SSRI or placebo. Methods: MRI measurements will be performed on a 3 Tesla PRISMA MAGNETOM MR scanner. Changes in gray matter microstructure will be assessed using high-resolution structural MRI and analyzed with voxel-based morphometry (VBM). Diffusion tensor imaging (DTI) enables non-invasive investigation of neuroplasticity in the human brain based on the reduction in mean diffusivity associated with swelling of astrocytes after increased synaptic activity. Resting-state functional MRI (fMRI) will allow for the measurement of changes in functional coupling between brain regions, and fMRI during tasks will assess differential activity in brain regions during learning. Relevance and implications: This study aims to provide evidence that SSRIs facilitate cytoarchitectonical restructuring. In addition to expanding the investigators current knowledge on the trophic effects of SSRIs, the results of this study will also elucidate interactions between the serotonergic system and changes to neuronal networks during learning as well as their behavioral consequences. By probing the neurobiological correlates of the antidepressant and anti-anxiety effects of SSRIs, this study will provide a rationale for targeted interventions that harness the neuroplasticity enhancing properties of SSRIs to facilitate therapeutic processes.