View clinical trials related to Paresis.
Filter by:Hemiparesis is a frequently observed symptom of stroke. There are various therapy options that are used in the rehabilitation of patients. Some studies have shown that, in addition to unilateral arm training, bilateral arm training can also lead to positive results in treatment and is a useful addition to therapy. The newly developed app requires the coordination of both arms in certain time sequences and intensities or rhythms and addresses different sensory modalities (visual, auditory and kinesthetic). The aim of the study is to examine whether tablet-based training improves bimanual coordination.
The return of eyelid function and facial expression in Patients with facial nerve affection is very important for quality of life. Eyelid dysfunction leads to drying and ulceration of cornea which may lead to permanent vision loss. Facial paralysis is distinguished into two main groups according to the presence or absence of facial fibrillations at needle Electromyography. Recent paralysis, mainly lasting less than two years generally show these signs and are eligible for reactivation of facial nerve by anastomosing it to a donor one (early facial reanimation). The masseteric nerve (motor branch of trigeminal nerve ) is a reliable donor nerve on early facial reanimation So on this study we examine the advantages and disadvantages of using masseteric nerve to develop a protocol for use of facial reanimation and restoration of function on facial paresis.
Particularly, muscle respiratory wasting will occur early (18 to 69 hours) in up to 60% of patients with mechanical ventilation (MV), leading rapidly to diaphragmatic weakness, which is associated with prolonged MV use, longer ICU and hospital stay, and higher mortality risk. Sepsis and muscle inactivity, derived from sedation and MV use, are key driver mechanisms for developing these consequences, which can be avoided through early physical activation. However, exercise is limited at the early stages of care, where sedation and MV are needed, delaying muscle activation. Neuromuscular electrical stimulation (NMES) represents an alternative to achieve early muscle contraction in non-cooperative patients, being able to prevent local muscle wasting and, according to some reports, has the potential to shorten the time on MV, suggesting a systemic effect through myokines, a diverse range of cytokines and chemokines secreted by myocytes during muscle contraction. However, no studies have evaluated whether NMES applied to peripheral muscles can exert distant muscle effects over the diaphragm, ameliorating its weakness and if this protective profile is associated with myokine's change in ICU patients. This proposal comprises a randomized controlled study of NMES applied twice daily, for three days, compared to standard care (no NMES). Thirty-two patients will be recruited in the first 48 hours after MV and randomly assigned to the control group or NMES group (16 subjects each). Muscle characterization of quadriceps and diaphragm will be performed at baseline (Day 1, before the first NMES session) and after the last NMES session (morning of day 4). Myokine measurements [IL-1, IL-6, IL-15, Brain-Derived Neurotrophic Factor (BDNF), Myostatin and Decorin], through blood serum obtained from peripheric blood samples, will be performed just before starting NMES (T0) at the end of the session (T0.5), and 2 and 6 hours later (T2 and T6). These myokine curves will be repeated on days 1 and 3 at the first NMES session of the day. The Control group will be assessed in the same way and timing, except that blood samples will be at T0 and T6. Additionally, functional outcomes such as MV time and ICU length of stay will be registered for all patients at ICU discharge. Standard care won´t be altered.
This study aims to examine the acceptability of patients and occupational therapists in following a mental practice protocol and examine the effects of mental practice with individuals with severe upper extremity hemiparesis (weakness) following a stroke. Mental practice is an adjunctive rehabilitation therapy that involves thinking about a motor task without actually moving. Research has shown that mental practice is a safe and feasible intervention that is effective in improving arm movements after a stroke. Patients in the study will participate in audio-guided mental practice, five days a week for two weeks, completing the following tasks: wiping a table and picking up a cup. The patients' ability to move their affected arm will be measured before and after the study to determine the effect of mental practice. Patients and occupational therapists will complete a survey to determine their feelings about performing or facilitating mental practice. The authors hypothesize that the majority of patients and occupational therapists will find mental practice to be feasible/acceptable for the recovery of the affected arm. Furthermore, we anticipate the majority of patients that complete the mental practice protocol will demonstrate improvements in their arm movements.
Constraint-Induced Movement Therapy or CI Therapy is a form of treatment that systematically employs the application of selected behavioral techniques delivered in intensive treatment over consecutive day with the following strategies utilized: behavioral strategies are implemented to improve the use of the more- affected limb in life situation called a Transfer Package (TP), motor training using a technique called shaping to make progress in successive approximations, repetitive, task oriented training, and strategies to encourage or constrain participants to use the more-affected extremity including restraint of the less-affected arm in the upper extremity (UE) protocol. Numerous studies examining the application of CI therapy with UE rehabilitation after stroke have demonstrated strong evidence for improving the amount of use and the quality of the more-affected UE functional use in the participant's daily life situation. CI Therapy studies with adults, to date, have explored intensive treatment for participants with a range from mild-to-severe motor impairment following stroke with noted motor deficits and limited use of the more-affected arm and hand in everyday activities. Each CI Therapy protocol was designed for the level of impairment demonstrated by participants recruited for the study. However, often following stroke, patients not only have motor deficits but somatosensory impairments as well. The somatosensory issues have not, as yet, been systematically measured and trained in CI Therapy protocols with adults and represent an understudied area of stroke recovery. We hypothesize that participants with mild-to-severe motor impairment and UE functional use deficits can benefit from CI therapy protocols that include somatosensory measurement and training components substituted for portions of motor training without loss in outcome measure gains. Further, we hypothesize that adults can improve somatosensory outcomes as a result of a combined CI therapy plus somatosensory component protocol.
The purpose of this study is to improve control of myoelectrically-controlled advanced orthotic devices (an exoskeleton device that use the body's muscle signals to drive movements of a robotic brace) by using advanced predictive decode algorithms, and the use of high count (> 8) surface electromyographic (sEMG) electrodes.
Constraint-Induced Therapy (CI Therapy) is a behavioral approach to neurorehabilitation and consists of multi-components that have been applied in a systematic method to improve the use of the limb or function addressed in the intensive treatment. CI Therapy for the more-affected upper extremity (UE) post-stroke is administered in daily treatment sessions over consecutive weekdays. Sessions include motor training with repeated, timed trials using a technique called shaping, a set of behavioral strategies known as the Transfer Package (TP) to improve the use of the more-affected hand in the life situation, and strategies to remind participants to use the more-affected UE including restraint. Robust improvements in the amount and qualify of use have been realized with stroke participants from mild-to-severe UE impairment.
Stroke survivors experience motor deficits, weak voluntary muscle activations, and low weight-bearing capacity that impair ambulation. Restoring motor function is a priority for people post-stroke, whose gait patterns are slow, and metabolically inefficient. The role of the ankle is crucial for locomotion because it stores mechanical energy throughout the stance phase, leading to a large activation of plantarflexor muscles during push-off for propulsion. After a stroke, paretic plantarflexors undergo changes in their mechanics and activation patterns that yield diminished ankle power, propulsion, and gait speed. Recovery of lost plantarflexor function can increase propulsion and mitigate unnatural gait compensations that occur during hemiparetic walking. In the stance phase, dorsiflexion is imposed at the ankle and the plantarflexors are loaded, which results in excitation of group Ia and II afferents, and group Ib afferents. Load sensing Ib afferents are active in mid-late stance, and through spinal excitatory pathways, reinforces the activation of plantarflexors and propulsive force generation at the ankle. Targeting the excitability of the load sensitive Ib excitatory pathway, propulsive soleus activity and resulting force generation (and thereby gait speed) can be improved after stroke. The long-term research goal is to develop a novel hybrid gait paradigm integrating operant conditioning and powered wearable devices to advance neuro-behavioral training and enhance locomotor ability after stroke. The overall objectives are to 1) modulate the soleus muscle loading response within the stance phase, and 2) develop a dynamic protocol to operantly condition the soleus response in stroke survivors. The central hypothesis is that enhancing the soleus loading response in mid-late stance phase through operant up-conditioning can increase plantarflexor power and forward propulsion after stroke. In working towards attaining the research objective and testing the central hypothesis, the objective of this pilot study is to modulate the soleus loading response in the stance phase during treadmill walking. The specific aims in this study are to 1) apply ankle perturbations in mid-late stance phase combining a control algorithm and a powered device to characterize the changes in soleus EMG between perturbed and unperturbed (i.e., when no perturbations are applied) step cycles in 15 able-bodied individuals; and 2) determine the feasibility of the wearable ankle device and its algorithm in 5 participants with hemiparesis and gait deficits due to a stroke. The testing of the device and its algorithm will provide foundational evidence to adjust the soleus stimuli continuously and reliably, and develop the new walking operant conditioning protocol for stroke survivors. An expected outcome in this pilot is to lay the groundwork to develop the soleus up-conditioning protocol as a potential strategy to improve paretic leg function. If successfully developed, this new protocol proposed in a subsequent study will be the first neurobehavioral training method that targets spinal load-sensitive pathways to improve ankle plantarflexor power and forward propulsion after stroke.
he aim of the "RE PAR EX" research is to evaluate the feasibility of the instrumented examination of the effects of eccentric muscle strengthening in paralytic patients. This project is part of the research axis of the movement analysis laboratory. Following a stroke or spinal cord injury, patients develop a spastic paresis syndrome, which is characterized by the appearance of paresis, musculo-tendinous retractions and muscular hyperactivities. If the traditional treatments proposed (stretching, motor work) show limits, the use of eccentric muscle strengthening in paresis patients has been developing for about ten years, with results superior to the usual treatments. The results of the studies evaluating it are focused on clinical evaluations and do not make it possible to identify the precise origin of the observed responses. A pathophysiological understanding of the therapeutic effects of eccentric strengthening would be possible through instrumented examination of muscle structure and function, combining dynamometry, ultrasound, elastrography and electromyography (EMG). However, the feasibility of this quantified instrumental examination in paretic patients during a strengthening protocol has not been evaluated. The feasibility of a quantified instrumented examination in this setting is the aim of this research, a necessary prerequisite for a larger interventional study to evaluate the biomechanical and neurophysiological effects of eccentric muscle strengthening in paretic patients.
Background: Hand functional impairments are common among stroke patients. Rehabilitation therapies increase the possibility of functional recovery. Stroke patients' engagement and effort to work toward achieving rehabilitation goals is of major significance. Neurologically, patient's engagement is being reflected in their brain activity through high levels of sustained attention while performing therapy exercises. Therefore, greater engagement might lead to better sustained attention. Nevertheless, their therapist's engagement, the type of exercise used and the quality of patient-therapist interaction play a significant role in enhancing patients' engagement. Music therapeutic interaction between stroke patient and music therapist, which involves active music making, enhances patient's engagement and improves their affected hand and finger movement. Objectives: (a) To investigate real-time mechanisms and possible association between: stroke patient's engagement level, music therapist's engagement level and the patient's real-time finger tapping movement of his affected hand. This will be assessed during a Piano Learning exercise versus a Free Improvisation exercise, while the music therapist is musically interacting with the patient on the piano during both exercises. (b) To assess patient's engagement level and real-time finger tapping movement during both exercises when compared to their scores at baseline (when playing alone). Methods: This study, conducted in Reuth Rehabilitation Hospital, Israel, will include 30 right-handed stroke patients, with right impaired hand, 1-12 months following stroke. This is a two-arm, randomized controlled trial (RCT) in which the participants will be randomly assigned to one of two groups. In each group participants will perform the same two exercises with the therapist, but the order of the exercises will be reversed within each group. This will be carried out in a single session. Measurement tools will include an EEG marker - The Cognitive Effort Index (CEI) used for real-time measuring patient's and music therapist's engagement's levels, and a MIDI-based assessment of the patient's finger tapping movement during the session.