View clinical trials related to Stroke.
Filter by:Carotid artery stenting(CAS) and endarterectomy(CEA) are both important treatment strategy for patients with ICA (internal carotid artery) stenosis. Three dimensional pseudo-continuous arterial spin labeling (pCASL) is a noninvasive perfusion imaging modality to detect reperfusion for recanalization therapy. And it provides information about absolute CBF (ml 100 g−1 tissue min−1) at the brain tissue level. The aim of the present study was to evaluate the series hemodynamic changes in patients who had conducted CAS or CEA by using 3D pseudo-continuous arterial spin labeling (pCASL) to explore the potential pattern of CBF alternation and thus to improve the prevention strategy for hyperperfusion syndrome.
During general anaesthesia, pulmonary atelectasis has been shown to occur in 85 to 90% of patient. Pulmonary atelectasis increases occurrence of postoperative pulmonary complication including pneumoniae. Pulmonary atelectasis can be prevented or reversed by alveolar recruitment manoeuvres (ARM). Two methods for ARMs have been described. A sustained continuous positive airway pressure (CPAP) or a stepwise increase in PEEP.The transient increase in intrathoracic pressure during ARMs decreases venous return and increases pulmonary vascular resistance. This result in a decrease in right and left ventricular stroke volume (SV). Finally, the deleterious hemodynamic effects of ARMs may be exacerbated by hypovolemia, heart failure, and in patients with chronic treatment wich impedes cardiovascular responses to hypovolemia. At our best knowledge, there is no study which compared the hemodynamic effects of ARM using sustained CPAP or stepwise increase in PEEP. Consequently, the present study was designed to examine the hemodynamic effects of 2 ARM methods in anesthetized patients.
A new electromyography (EMG)-driven neuromuscular electrical stimulation (NMES)-cycling system is introduced to stroke survivors for lower-limb rehabilitation. The system will generate NMES to targeted muscle according to the user's voluntary intention, represented by the EMG signal during cycling.
The long-term objective of this research is to develop an efficacious training paradigm to enhance stroke survivors' defense mechanisms against falls and possibly reduce healthcare cost. The Centers for Disease Control and Prevention estimates the direct medical cost for fall related injuries to be $34 billion annually. Forty percent to 70% of community-dwelling stroke survivors experience detrimental falls each year and tend to have 1.5 to 4 times higher risk of hip fracture than their healthy counterparts; with only less than 40% of those individuals regaining independent mobility. Falls, thus not only affect activities of daily living but also reduce mobility, increase risk of second stroke and mortality. Despite potential financial and functional implications of falls in this population, health-care personnel are limited in their ability to develop and validate interventions to reduce fall-risk for them. Further emphasis is placed on locomotor training with focus on enhancing paretic limb function. The project design consists of a randomized controlled trial to examine the ability of chronic stroke survivors to acquire, generalize and retain adaptations to slip-perturbation training for not only mitigating fall risk but also improving walking function. It also explores translation of this paradigm to the sub-acute population. The paradigm is novel in that it targets contributions of the paretic vs. non-paretic limbs on fall-risk through a bilateral training paradigm that involves training the non-paretic side first and then paretic to facilitate acquisition of fall-prevention skills on the paretic side, which may otherwise take longer to acquire training effects. The longer-term benefits of such perturbation training, targeting both limbs for reducing falls will be assessed not only in the laboratory but also in real life via wearable sensors, along with improved community walking function. The hypothesis of this study if supported by the results will provide an evidence-supported training protocol to reduce the fall-risk not only in people living with hemiparetic stroke but also among survivors of other acquired unilateral cortical lesions.
Balance and gait problems in subjects with neurological disease lead to reduced mobility, loss of independence and frequent falls. Treadmill training is a widely used form of treatment and it has been used in subjects with neurological disease to ameliorate walking and balance deficits. The Virtual Reality Treadmill as a therapeutic tool has been recently introduced to practice gait adaptability elicited by aligning foot placement relative to the projected visual context. Forty-eight subjects with neurological disease will receive treadmill training treatment randomly divided in Traditional Treadmill training and Virtual Reality Treadmill training. The aim of this randomized controlled study is to assess whether Treadmill training with Virtual Reality is better than Traditional Treadmill training in improving dynamic balance and cognitive aspects in subjects with neurological diseases.
Stroke is the third most common cause of death and the main cause of acquired adult disability in high-income countries. The most common deficit after stroke is motor impairment of the contralateral arm, with more than 80% of stroke survivors experiencing this condition in the acute phase, and only half regaining some useful upper limb function after six months. Within the European project RETRAINER (grant agreement No 644721), the consortium developed a platform for the rehabilitation of the upper limb after stroke, which combines a passive forearm-hand orthosis for hand-wrist motion stabilization, selective fingers constraining and grasp movement facilitation, Functional Electrical Stimulation (FES) of the extrinsic hand flexor muscles and of the extrinsic hand extensor muscles, interactive objects, and voluntary effort. The system also provides a graphical user interface which helps the therapist set the training session and save the training data and parameters, and provides the subject a visual feedback about his/her active involvement in the exercise. The training consists of the execution of a series of exercises involving the affected arm during daily life activities. Typical exercises include controlled wrist flexion and extension, controlled fingers flexion and extension, anterior reaching and grasping on a plane or in the space, moving an object on a plane or in the space. The aim of this clinical study it to evaluate the efficacy of this novel training platform on patients between two weeks and nine months after their first stroke, who preserved at least a visible muscle contraction for the arm and shoulder muscles. Participants are randomized in an experimental and a control group. The control group is trained with an advanced rehabilitative program, including physical training, occupational therapy, FES, and virtual reality, while the experimental group is trained with the RETRAINER system for about 30 minutes, in addition to the same program of the control group. The daily training time is the same for the two groups. The intervention consists of three sessions a week for nine weeks. Patients are assessed at baseline, soon after the end of the intervention, and in a 4-week follow-up visits. It is planned to recruit 68 subjects for this study. Since the RETRAINER platform was built on the up-to-date theory of motor re-learning, which supports task-oriented repetitive training, a close temporal association between motor intention and stimulated motor response, and an intensive and frequent training paradigm, the study's hypothesis is that the experimental group shows a greater treatment effect than the control group.
A new lower-limb training system is introduced to enhance the clinical service for post-stroke lower limb rehabilitation and to assist the establishment of public clinical trial in different settings and share experiences on the robot-assisted functional training.
Stroke is a leading causes of death and disability. At least 20% of strokes occur during sleep, so- called 'wake up stroke'. Thrombolysis with the clot-busting drug alteplase is effective for acute ischaemic stroke, provided that it is given within 4.5 hours of symptom onset. Patients with wake-up stroke are currently ineligible for clot-busting therapy. Previous studies indicate that many wake-up strokes occur just before awakening. In this study, patients with wake-up stroke will be randomized to thrombolysis with tenecteplase and best standard treatment or to best standard treatment without thrombolysis. Tenecteplase has several potential advantages over alteplase, including very rapid action and that it can be given as a single injection. Prior to thrombolysis, a brain scan must be done to exclude bleeding or significant brain damage as a result from the stroke. We will use a CT scan to inform this decision. CT is used as a routine examination in all stroke patients. Other studies testing clot-busting treatment in wake-up stroke are using alteplase and more complex brain scans, which are not routinely available in the emergency situation in all hospitals.
The aim of the study is to perform a randomized double-blind placebo controlled prospective study in newborn infants with MRI confirmed Middle Cerebral Artery (MCA) Perinatal Arterial Ischemic Stroke (PAIS) with darbepoetin. It will be investigated whether intravenous administered darbepoetin can induce the formation of neuronal tissue and restore brain function in neonates who suffered from PAIS compared to placebo treated controls. The ultimate goal of this study is therefore to develop a therapy using erythropoiesis-stimulating agents (ESA) such as darbepoetin to reduce or even prevent lifelong consequences of PAIS-related brain injury in this group of term newborns.
Stroke is the third most common cause of death and the main cause of acquired adult disability in high-income countries. The most common deficit after stroke is motor impairment of the contralateral arm, with more than 80% of stroke survivors experiencing this condition in the acute phase, and only half regaining some useful upper limb function after six months. Within the European project RETRAINER (grant agreement No 644721), the consortium developed a platform for the rehabilitation of the upper limb after stroke, which combines a passive arm exoskeleton for weight relief supporting both shoulder and elbow movements, Functional Electrical Stimulation (FES) of the two-most impaired muscles of the affected side, interactive objects, and voluntary effort. The system also provides a graphical user interface which helps the therapist set the training session and save the training data and parameters, and provides the subject a visual feedback about his/her active involvement in the exercise. The training consists of the execution of a series of exercises involving the affected arm during daily life activities. Typical exercises are anterior reaching on a plane or in the space, moving an object on a plane or in the space, moving the hand to the mouth, with or without an object in the hand, and lateral elevation of the shoulder. The aim of this clinical study it to evaluate the efficacy of this novel training platform on patients between two weeks and nine months after their first stroke, who preserved at least a visible muscle contraction for the arm and shoulder muscles. Participants are randomized in an experimental and a control group. The control group is trained with an advanced rehabilitative program, including physical training, occupational therapy, FES, and virtual reality, while the experimental group is trained with the RETRAINER system for about 30 minutes, in addition to the same program of the control group. The daily training time is the same for the two groups. The intervention consists of three sessions a week for nine weeks. Patients are assessed at baseline, soon after the end of the intervention, and in a 4-week follow-up visits. It is planned to recruit 68 subjects for this study. Since the RETRAINER platform was built on the up-to-date theory of motor re-learning, which supports task-oriented repetitive training, a close temporal association between motor intention and stimulated motor response, and an intensive and frequent training paradigm, the study's hypothesis is that the experimental group shows a greater treatment effect than the control group.