We used multipotent stem cells (MSCs) derived from the young rat subventricular zone (SVZ) to study the effects of glutamate in oligodendrocyte maturation. Glutamate stimulated oligodendrocyte differentiation from SVZ-derived MSCs through the activation of specific N-methyl--aspartate (NMDA) receptor subunits. The effect of glutamate and NMDA on oligodendrocyte differentiation was evident in both the number of newly generated oligodendrocytes and their morphology. In addition, the levels of NMDAR1 and NMDAR2A protein increased during differentiation, whereas NMDAR2B and NMDAR3 protein levels decreased, suggesting differential expression of NMDA receptor subunits during maturation. Microfluorimetry showed that the activation of NMDA receptors during oligodendrocyte differentiation elevated cytosolic calcium levels and promoted myelination in cocultures with neurons. Moreover, we observed that stimulation of MSCs by NMDA receptors induced the generation of reactive oxygen species (ROS), which were negatively modulated by the NADPH inhibitor apocynin, and that the levels of ROS correlated with the degree of differentiation. Taken together, these findings suggest that ROS generated by NADPH oxidase by the activation of NMDA receptors promotes the maturation of oligodendrocytes and favors myelination.
Abstract-Stroke is a leading cause of adult disability with upper-limb hemiparesis being one of the most frequent consequences. Given that stroke only affects the paretic arm's control structure (the set of synergies and activation vectors needed to perform a movement), we propose that the control structure of the non-affected arm can serve as a physiological reference to rehabilitate the paretic arm. However, it is unclear how rehabilitation can effectively tune the control structure of a patient. The use of Visual Feedback (VF) is recommended to boost stroke rehabilitation, as it is able to positively modify neural mechanisms and improve motor performance. Thus, in this study we investigate whether VF can effectively modify the control structure of the upper-limb. We asked six neurologically intact subjects to perform a complete upper-limb rehabilitation routine comprised of 12 movements in absence and presence of VF. Our results indicate that VF significantly increases interlimb similarity both in terms of synergies and activation coefficients. However, the magnitude of improvement depended upon each subject. In general, VF brings the control structure of the nondominant side closer to the control structure of dominant side, suggesting that VF modifies the control structure towards more optimized motor patterns. This is especially interesting because stroke mainly affects the activation coefficients of patients and because it has been shown that the control of the affected side resembles that of the nondominant side. In conclusion, VF may enhance motor performance by effectively tuning the control-structure. Notably, this finding offers new insights to design improved stroke rehabilitation.
Abstract-Stroke is a major cause of disability, usually causing hemiplegic damage on the motor abilities of the patient. Stroke rehabilitation seeks restoring normal motion on the affected limb. However, 'normality' of movements is usually assessed by clinical and functional tests, without considering how the motor system responds to therapy. We hypothesized that electromyographic (EMG) recordings could provide useful information for evaluating the outcome of rehabilitation from a neuromuscular perspective. Four healthy subjects were asked to perform 14 different functional movements simulating the action of reaching over a table. Each movement was defined according to the starting and target positions that the subject had to connect using linear trajectories. Bipolar recordings of EMG signals were taken from biceps and triceps muscles, and spectral and temporal characteristics were extracted for each movement. Using pattern recognition techniques we found that only two EMG channels were sufficient to accurately determine the spatial characteristics of motor activity: movement direction, length and execution zone. Our results suggest that muscles may fire in a patterned way depending on the specific characteristics of the movement and that EMG signals may codify such detailed information. These findings may be of great value to quantitatively assess poststroke rehabilitation and to compare the neuromuscular activity of the affected and unaffected limbs, from a physiological perspective. Furthermore, disturbed movements could be characterized in terms of the muscle function to identify, which is the spatial characteristic that fails, e.g. movement direction, and guide personalized rehabilitation to enhance the training of such characteristic.
Abstract-The poor rehabilitation success rate, including the cases of ineffective and detrimental adaptations, make stroke a leading cause of disability. Thus, it is essential to recognize the mechanisms driving healthy motor recovery to improve such rate. Stroke alters the Synergy Architecture (SA), the modular muscle control system. So SA analysis may constitute a powerful tool to design and assess rehabilitation procedures. However, current impairment scales do not consider the patient's neuromuscular state. To gain insights into this hypothesis, we recorded multiple myoelectric signals from upper-limb muscles, in healthy subjects, while executing a set of common rehabilitation exercises. We found that SA reveals optimized motor control strategies and the positive effects of the use of visual feedback (VF) on motor control. Furthermore we demonstrate that the right and left arm's SA share the basic structure within the same subject, so we propose using the unaffected limb's SA as a reference motion pattern to be reached through rehabilitation.
No abstract
Stroke is the leading cause of adult disability, with upper limb hemiparesis being one of the most common consequences. Regaining voluntary arm movement is one of the major goals of rehabilitation. However, even with intensive rehabilitation, approximately 30% of patients remain permanently disabled and only 5 to 20% of them recover full independence. Hence, there is an increasing interest in incorporating the latest advances in neuroscience, medicine and engineering to improve the efficacy of conventional therapies. In the last years, a variety of promising targets have been identified to improve rehabilitation. However, there is no consensus on which measure should be applied as a gold standard to study functional recovery. This fact dramatically hinders the development of new interventions since it turns difficult to compare different clinical trials and draw consistent conclusions about therapeutic efficiency. In addition, available scales are subjective, qualitative and often lead to incongruent outcomes. Indeed, there is increasing suspicion that the lack of optimal assessment measures hampers the detection of benefits of new therapies. Moreover, existing scales totally ignore the neuromuscular state of the patient masking the ongoing recovery processes. In consequence, making appropriate clinical decisions in such environment is almost impossible. In light of all these facts, the need for new objective biomarkers to develop effective therapies is undeniable. To give response to these demands we have organized this thesis into two main branches. On the one hand, we have developed an innovative physiological scale that reveals the neuromuscular state of the patient and is able to discriminate between motor impairment levels. The innovation here resides in the concept of interlimb similarity (ILS). Based on the latest findings about the modular organization of the motor system and taking into account that stroke provokes unilateral motor damage, we propose comparing the control structure of the unaffected arm with the control structure of the paretic arm to quantify motor impairment. We have defined the control structure as the set of muscle synergies and activation coefficients needed to complete a task. The advantage of this approach is not only its capacity to provide neuromuscular information about the patient, but also that the ILS is personalized to each patient and can purposely guide rehabilitation based on the patient¿s own physiological patterns. This supposes a huge advance taking into account the heterogeneity of stroke pathogenesis. On other hand, we have characterized the therapeutic potential of Visual Feedback (VF) as a tool to purposely induce neuroplastic changes. We have chosen VF among the various interventions proven to improve motor performance, because VF is a cheap strategy that can be implemented in almost any rehabilitation center. We demonstrate that VF is able to modulate the human control structure. In healthy subjects, it seems that VF makes accessible the refined dominant motor programs for the nondominant hemisphere giving rise to an increased interlimb similarity of the control structure. Interestingly, in stroke patients VF is able to manipulate the ILS of upper-limb kinematics in favor of finer motor control but a single training session seems not to be enough to fix those changes in the neuromuscular system of a damaged brain. Overall, these findings offer a new promising framework to develop and assess an effective intervention to guide the restoration of the original neuromuscular patterns and avoid unwanted maladaptive neuroplasticity. In conclusion, this thesis seeks moving forward in the understanding of human motor recovery processes and their relationship with neuroplasticity. In this sense, it provides important advances in the design of a new biomarker of motor impairment and tests the power of VF to modulate the neuromuscular control of patients with stroke. L'ictus és la principal causa de discapacitat en adults, essent l'hemiparèsia del membre superior una de les conseqüències més comunes. Els programes de rehabilitació tenen com a objectiu fonamental restituir la mobilitat del braç afectat. No obstant això, es calcula que només entre el 5 i el 20% dels pacients aconsegueixen recuperar la seva independència mentre que el 30% queden incapacitats permanentment. En front d'aquest escenari es fa necessari incorporar els últims avenços de la neurociència, la medicina i l'enginyeria en aquesta àrea. En els darrers anys s'han identificat diversos aspectes clau per intentar millorar la rehabilitació. El problema, però, és que no hi ha consens per definir una mesura com a "gold estàndard" per avaluar la recuperació funcional, motiu pel qual, el desenvolupament de noves teràpies queda profundament afectat, ja que esdevé impossible poder comparar diferents assajos clínics i extreure conclusions consistents sobre la seva eficiència terapèutica. A més, les diverses mesures que s'utilitzen són subjectives, qualitatives i sovint donen resultats incongruents. De fet, se sospita que la manca de mesures d'avaluació òptimes dificulta la detecció dels beneficis de noves teràpies. A tot això se li ha d'afegir que les mesures actuals no consideren l'estat neuromuscular del pacient, emmascarant els processos reparadors subjacents. Així doncs, prendre les decisions clíniques adequades sota aquestes condicions esdevé pràcticament impossible. En aquestes circumstàncies, no es pot ignorar el requeriment de nous biomarcadors que proporcionin dades objectives per catalitzar el disseny de teràpies efectives. Per donar resposta a aquesta situació, la tesi s'ha estructurat en dues parts. Per una banda, s'ha desenvolupat una innovadora escala fisiològica que revela l'estat neuromuscular del pacient i és capaç de discriminar entre diferents nivells d'incapacitat motora. La innovació rau en el concepte de similitud entre membres (ILS, en anglès). Així, basant-nos en els darrers descobriments sobre l'organització modular del sistema motor, i en el fet que l'ictus provoca dany unilateral, proposem comparar l'estructura de control del braç no-afectat amb l'estructura de control del braç parètic per quantificar la incapacitat motora. L'estructura de control l'hem definida com el conjunt de sinergies musculars i coeficients d'activació que es necessiten per a dur a terme una tasca. L'avantatge d'aquesta proposta és doble, ja que proporciona informació sobre l'estat neuromuscular del pacient i en ser personalitzable, pot guiar la rehabilitació d'acord amb els patrons fisiològics propis de cada pacient. Això suposa un enorme avenç en aquesta àrea, donada la immensa heterogeneïtat de la patogènesi d'aquest trastorn. D'altra banda, s'ha caracteritzat el potencial terapèutic del feedback visual (VF) per induir canvis neuroplàstics. Aquesta és una eina molt interessant perquè a més de millorar el control motor, és assequible per gairebé qualsevol centre de rehabilitació. S'ha demostrat que el VF és capaç de modular l'estructura de control. Concretament, el VF sembla transferir els programes motors de l'hemisferi dominant al costat no dominant augmentant així el ILS dels subjectes sans. En pacients amb ictus, el VF és capaç d'augmentar el ILS cinemàtic afavorint patrons de control més fins. En conclusió, l'objectiu d'aquesta tesi és aprofundir en la comprensió dels processos de recuperació motora i la seva relació amb la neuroplasticitat. La tesi ofereix un nou i prometedor marc per desenvolupar i avaluar procediments efectius per guiar la restauració dels patrons neuromusculars originals i evitar que el cervell pateixi canvis neuroplàstics indesitjables. Així, la tesi proporciona avanços importants en el disseny d'un biomarcador per quantificar la incapacitat motora i avaluar el potencial del VF per modular el control neuromuscular de pacients amb ictus.
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