View clinical trials related to Spasticity as Sequela of Stroke.
Filter by:Spasticity is characterized by increased muscle tension and is a classic consequence of upper motor neuron (UMN) damage in the central nervous system, such as from stroke or trauma. Clinically, it presents as muscle resistance to passive stretching, along with clasp-knife rigidity, clonus, increased tendon reflexes, and muscle spasms. An imbalance of the descending inhibitory and muscle stretch reflexes is thought to be the cause of spasticity. Post-stroke spasticity is a common condition that occurs in 37.5-45% of cases in the acute stage and 19-57.4% in the subacute stage after a stroke. At 6 months post-stroke, spasticity develops in 42.6-49.5% of cases, and at one year, it affects 35-57.4% of individuals. In patients with cerebral palsy (CP), incidence is almost 80% while in those living with spinal cord injury the number approaches up to 93%. Traumatic brain injury (TBI) patients have a higher prevalence on initial admission to neurorehabilitation but one in three patients will have chronic spasticity. However, the Defense and Veterans Brain Injury Center report a rate of TBIs amongst deployed veterans to be around 11-23% mostly from blast and explosive trauma. There have been studies as early as the 1980s exploring the efficacy of SCS for spasticity control, however, the credibility of many of these studies is constrained due to an incomplete comprehension of spasticity's underlying mechanisms, outdated research methods, and early limitations in implantable device technology. Intrathecal pumps for baclofen have remained as the mainstay for refractory spasticity, however, it comes with associated risks such as chemical dependence leading to acute baclofen withdrawal and requiring frequent refill requirement. Most importantly, it does not yield functional improvement of muscle activity, just suppression of spasticity. Botox is also routinely used but due to heterogeneity in muscle involvement as well as variability in provider skill, results may be inconsistent and short-lasting, requiring frequent clinic visits for repeat injections to the affected muscle groups. SCS may be able to address that gap in spasticity management.
Title: The Effect of Vibrating Splint on Hand Function After Stroke Summary: This study aims to investigate the effectiveness of a vibrating splint in improving hand function and reducing spasticity among individuals who have experienced a stroke. Stroke is a major global health issue, often resulting in long-term disability and impairments in the upper limbs. Spasticity, a common complication of stroke, causes stiffness and involuntary muscle contractions, leading to difficulties in performing daily activities. Current treatment options for spasticity include medications and physical therapy techniques. However, these approaches may have limitations in terms of effectiveness and duration of benefits. Therefore, non-pharmacological interventions are being explored to enhance rehabilitation outcomes. The hypothesis of this study is that the use of a vibrating splint, which applies mechanical vibrations to the hand muscles, will decrease spasticity and improve hand functionality in individuals with chronic stroke. The vibrations from the splint stimulate the sensory receptors in the skin and muscles, leading to muscle relaxation and improved motor control. The study will be conducted as a pilot randomized controlled trial, involving participants who meet specific eligibility criteria. The participants will be divided into three arms, with each arm receiving a different intervention. Outcome measures, including assessments of spasticity, range of motion, pain levels, and functional abilities, will be collected before and after the intervention period. The findings from this study will contribute to the understanding of non-pharmacological approaches in managing spasticity and improving hand function after stroke. If the vibrating splint proves to be effective, it could offer a safe and accessible option for stroke survivors to enhance their recovery and regain independence in daily activities. This research is essential as it addresses the need for more effective interventions for spasticity management and hand rehabilitation after stroke. By providing valuable insights into the potential benefits of the vibrating splint, this study has the potential to improve the quality of life for individuals who have experienced a stroke and empower them to regain control over their hand movements.
Trial design This study is a protocol of a phase II clinical trial which will be conducted in two countries (Belgium and Spain) to compare the effectiveness of DN and BTX A in reducing post-stroke spasticity in the plantar flexor muscles. This study is a prospective randomized, controlled, multiple-baseline design with blinded assessors. The study will be registered in ClinicalTrials.gov and will have a length of 19 weeks Trial population Inclusion Criteria: 1) aged 18-75 years old, 2) having lower limb post-stroke spasticity in ankle plantar flexors (MAS scores of 1, 1+ and 2); 3) having had a first stroke; 4) having no more than 12 months of evolution since stroke; 5) having no previous Dry Needling (DN) or Botulinum Toxin type A (BTX A) treatment for spasticity; 6) having ankle PROM ≥ 20° (approx.) when the knee is supported in ~30° flexion; 7) being able to walk independently with or without aids. Exclusion Criteria: 1) medical conditions interfering with data interpretation; 2) any contraindication to receiving BTX A or PS treatment; 3) If taking anti-spasticity medications, participants must be on stable medication for at least 3 months prior to the start of the study and neither the dose nor the medication can be changed during the tria Interventions Participants will be randomly allocated to the group receiving a session of BTX A or to the group receiving Dry Needling once weekly for 12 weeks. Blinded evaluators will assess the effects before, during, after treatment, and at 4-week follow-up. The trial will have regular monitoring visits by an independent external monitor to ensure compliance with the protocol and Good Clinical Practices. Monitors may review source documents to confirm accurate data on CRD. The investigator and institution will guarantee direct access to source documents for monitors and regulatory authorities.
To investigate the impact of algorithms utilizing artificial intelligence technology and computer vision on the recovery of motor functions within the context of rehabilitation practice for patients who have experienced a cerebral stroke.
The performance of activities of daily living (ADL) depends to a large extent on the functionality of the upper limb and hand. Stroke is the leading cause of disability worldwide, with a significant individual, family and economic impact. After a stroke event, however, a large percentage of affected patients have a deficit of the hand and, six months after the acute event, 65% of patients with a deficit of the hand are unable to use and integrate the affected hand in activities of daily living, significantly reducing its quality. The impairment of strength, grip and general hand function makes it difficult to perform ADLs and affects the independence of functional activities, making the recovery of hand function an extremely challenging field in stroke rehabilitation.
The goal of this study is to define the efficacy of fully remote home-based BCI therapy in chronic hemiparetic subcortical stroke patients. A randomized controlled study using the integrated remote BCI system will be tested against standard exercise therapy to determine the efficacy of motor improvement in chronic stroke patients with an upper extremity hemiparesis. Specifically, the integrated BCI system will include 1) the remote screening and motor assessment system for the upper extremity and 2) the BCI-controlled robotic hand exoskeleton (i.e. IpsiHand).
Stroke is one of the leading cause of death and disability worldwide. Post-stroke spasticity (PSS) is outbreak after a stroke and is featured by disabling muscle stiffness. PSS could manifest in up tp 50% cases within 6 months after a stroke, especially in the upper limb. Despite it is an acknowledged condition it is insufficiently recognized and treated in clinical practice. Focal and regional spasticity could improve with rehabilitation and in selected cases with botulinum neurotoxin (BoNT) type A injections. The latter causes muscle relaxation and fosters neuroplasticity, which is able in turn of ameliorating several patient functional aspects. Recent literature demonstrated that PSS patients treated with early BoNT (within 3 month since PSS outbreak) could improve in their clinical status better than patients with a later treatment. An earlier recognition of PSS predictors could improve patient management. Hence, the investigators are going to perform a multicentric prospective observational real life study with BoNT, based on the best clinical practice and aimed at the early recognition and management of PSS through the identification of 1) early clinical predictors of spasticity (collected within 10 days since stroke), 2) BoNT clinical outcome relative to the timing of the treatment
As human beings live longer, geriatric disease develop, one of which was stroke whose prevalence elevated by aging. Increased spasticity is a common symptom after stroke and may hinder patient from rehabilitation. The spasticity was evaluated by subjective judgement before. However, in the recent studies, the electrophysiological test, an objective evaluation, showed possibly positive correlation with the spasticity. They compared stroke patients' hemiplegic side with non-hemiplegic side by H/M ratio which showed significant difference. The stroke patients included in studies had stroke onset over 2 years. Therefore, investigators wonder if H/M ratio can evaluate spasticity in stroke patients onset within 2 years and if H/M ratio is correlated to spasticity.
TITLE: Immediate effect of Johnstone's Pressure Splint added to Stretching on the spasticity of elbow flexors and wrist in Cerebrovascular Disease (CVD). INTRODUCTION: In the rehabilitation of the upper limb post-CVD to employed exercise modalities such as stretching (S) to control spasticity, improve mobility and functionality. Also it is used the Johnstone´s Pressure Splint (JPS), which exerts circumferential pressure and contribute to spastic pattern inhibition, sensory re-education and increased of the mobility. OBJECTIVE: The aim of the study is to evaluate the immediate effect of JPS added to S on the spasticity of elbow flexors and wrist, the reflex excitability and the joint kinematics in Stroke. MATERIALS AND METHODS: A randomized experimental study with two intervention groups will be performed. Control group (GS): Stretching and experimental group: (GJPS + S): JPS plus S. Measurement times: Before the intervention (T0) and immediately post- intervention (T1). The outcome variables are muscle tone of elbow, wrist and hand assessed with the Modified Ashworth Scale (MAS); H reflex of the Flexor Carpi Radialis muscle, latency (ms), duration (ms) and amplitude (mV) of the M and H waves, and the amplitude the Hmax / Mmax ratio (%). Shoulder, elbow and trunk angles (degrees), trunk displacement (cm) and duration (sec) of the Functional Reach Pattern (PAF) will be evaluated with the software Contemplas. ANALYSIS: Descriptive statistics will be applied and Shapiro Wilk test to evaluate the normality of the variables. Intra-group differences will be assessed with the student t-test paired and intergroup with the student t-test unpaired or the sum of Wilcoxon rank according to the distribution of the variables. EXPECTED RESULTS: Hypotheses and contributions to the scientific evidence on the immediate effect of the S and JPS will be generated, to support the JPS as a complement to the traditional treatment. The results will be socialized in an international scientific event and a publication will be submitted to an impact journal. KEY WORDS: Spasticity, H Reflex, Johnstone's Pressure Splint, Stretching, Functional Reach.