37 Clinical Trials for Various Conditions
This study aims to answer the question: to assess the safety, and tolerability of gamma light in Parkinson's disease (PD) patients with freezing of gait (FOG). Parkinson's disease (PD) patients often experience a complex gait disorder known as Freezing of Gait (FOG). FOG is characterized by brief arrests of stepping when initiating gait, turning, and walking straight and patients describe it as their feet being "glued" to the floor. FOG in Parkinson's disease (PD) is a considerable public health burden worldwide. It is a poorly understood gait symptom that has potentially grave consequences as FOG is intermittent and unpredictable, a leading cause of falls with injury, and results in loss of independence. FOG is generally found to be associated with cognitive decline, particularly executive dysfunction which, in turn, has been associated with higher spinal fluid amyloid (Aβ42) levels in PD. There is data linking amyloid to FOG. A previous study showed that the gamma light helped reduce some amyloid. The research team is studying if gamma light exposure for 1 hour daily is well tolerated. Also, does it have any effect on freezing of gait severity?
Deterioration in walking performance as a result of disease or simply as a result of aging is a serious threat to independence in older adults. In this project, the investigators propose an innovative visual stimulus, based on advanced mathematical and biological theories, with which older adults can walk in time to improve their walking. The investigators' goal is to apply this simple, cost-effective, and novel gait rehabilitation therapy across all populations who have difficulties walking, e.g. stroke patients, fallers or those who undergo joint replacement.
Parkinson disease (PD) is a progressive neurological disease that results in characteristic gait dysfunction. Gait problems include decreased velocity, decreased stride length, difficulty with initiation of gait, postural stability problems and alteration in joint kinematics.1 In this typically older patient population, these gait deviations affect their participation in household and community activities. The standard of care is currently focused on therapeutic exercise and cueing of various types (visual, auditory, verbal). Current interventions have not been demonstrated to markedly improve gait kinematics, so there is a need to identify interventions that could improve gait performance in this population. Lower extremity bracing is a common and well-established intervention for gait dysfunction with other populations, including stroke and brain injury. The braces allow for improved stability, sensory feedback, and consistent tactile cues to allow patients to have the best gait mechanics with each step. It is reasonable to hypothesize that appropriate bracing may have the potential to improve gait function and kinematics in PD since these patient often have gastroc-soleus weakness. Data from our early pilot studies indicates that bracing individuals with PD can positively impact their mobility. This includes improvements in velocity, step length, and dynamic balance. Additional data supported an upward trend in quality of life.
Freezing of Gait (FoG) is a class of symptoms that occur in Parkinson's patients. Also called motor blocks, FoG is characterized by a sudden inability to move the lower extremities which usually lasts less than 10 seconds. The exact pathophysiology of FoG is poorly understood, but treatment with levodopa appears to improve FoG observed in the off-state. As Parkinson's patients progress in severity, FoG in the on-state can increase in frequency and appears to be resistant to dopaminergic therapies. There is additional evidence that norepinephrine as well as dopaminergic systems may be involved in FoG. Droxidopa has has been approved for use in Japan since 1989 for treatment of frozen gait or dizziness associated with Parkinson's Disease. This study is to further explore the safety and efficacy of droxidopa in this indication.
The purpose of this research is to determine how deep brain stimulation (DBS) for Parkinson's disease affects attention and visuospatial function. Additionally, this study will evaluate how deficits in visual attention are associated with freezing of gait (FOG) in Parkinson's disease. There is currently no reliable treatment for FOG and little is understood about the underlying reason this occurs. Some recent research has found that stimulating the right side of the brain seems to improve FOG. The right side of the brain is also paramount for visual attention, which is why investigators are conducting this study.
The purpose of this pilot study is to investigate the feasibility of 1) providing virtual reality walking training using a custom developed setup able to be replicated in routine clinical practice and 2) combining the virtual reality training with high-intensity gait training.
The purpose of this study is to evaluate the clinical performance of the investigational REEV SENSE gait tracker to measure gait features in subjects with post-stroke gait impairment. REEV SENSE is intended to be used by trained healthcare professionals as a simple procedure adapted to clinical routine. The reference method for performance comparison will be motion capture.
The project will consist of subjects who have suffered Traumatic Brain Injury (TBI) and who are able to ambulate on treadmill with or without a harness system. This will be a 4-week controlled study consisting of two groups of TBI patients, high-intensity intervention group and low-intensity control group. Both groups will receive physical therapy treatment 3 times per week for 1 hour. The intervention group will undergo 30-minute sessions of high-intensity walking on a treadmill with an overhead harness attached for safety. In addition, they will also get up to 30-minutes of low-intensity physical therapy in order to receive 1 hour of treatment time. The control group will undergo only low-intensity physical therapy activities for 1-hour. Low-intensity physical therapy will include strength exercises, stretches, balance, and low-intensity gait training. All participants in both groups will complete these outcome measures on the first day of the study, after 2 weeks of participation, and again at the end of 4 weeks or on their last day before discharge from Carilion's services. Later on, all participants in both groups will be followed up to complete the same set of outcome measures at the end of 1 month since completion of the protocol. This follow up session will take up to 45 minutes to complete.
Postural instability, freezing-of-gait (FOG), and falls are among the greatest unmet needs in Parkinson disease (PD). FOG eventually affects more than half of people with PD, and is notoriously difficult to treat pharmacologically or via deep brain stimulation. Visual cues do improve gait freezing, but their efficacy and adoption is limited because they are not practical to use in all real-world situations. There is a need for a cueing technique that is on-demand and discreet - only perceptible to the patient. Fortunately, recent technological advances in augmented-reality (AR) enable such an approach. In this study, state-of-the-art AR glasses will be used to project digital cues that are only visible to the wearer, to determine if they can improve FOG. 36 individuals with PD and FOG will be recruited to perform an obstacle-course gait task under six cue conditions: no cue, conventional cue, constant-on AR, patient-hand-triggered AR (turns on when patient clicks button), patient-eye-triggered AR (turns on when looking down), and examiner-triggered AR. The AR cue is a set of images that appear on the floor at a patient's feet, mimicking floor lines. Gait performance will be captured on video and via body-worn wireless sensors that detect how each limb is moving. The investigators will determine whether individuals are cue-able with conventional visual cues, whether intermittent cues outperform constant-on cues, and whether cues triggered by an examiner outperform cues triggered by patients themselves.
The purpose of this study is to assess how alternating-frequency Deep Brain Stimulation (DBS) works to improve postural instability and gait, while also treating other motor symptoms of Parkinson Disease (PD).
This study will evaluate the retention effects of a four-week whole-body vibration training intervention in children with Cerebral Palsy. The primary outcomes for this study are gait function, including Timed Up and Go and the two-minute walk test. Secondary outcomes of this study include lower extremity gait function, coordination, and gait variability. For this study, a total of 10 children with Cerebral Palsy (CP) will be recruited with 5 being randomly placed into an experimental group and 5 being randomly placed into a control group. Each participant, regardless of group, will complete pre-, post-, and retention testing, with a four-week whole-body vibration training intervention between the pre- and post-testing. The four-week whole-body vibration training will include three visits per week, with the experimental group receiving a vibration stimulus while standing on a vibration platform. Vibration sessions will consist of three-minutes of vibration, followed by three minutes rest, completing this cycle three separate times. The control group will follow a similar pattern, but rather than experiencing vibration, they will hear a sound of the vibration platform through a speaker. Once the four-week training session is finished, participants will return after a three-month retention period to determine whether ambulation function was retained.
The purpose of this study is to examine the reflex excitability of the rectus femoris in individuals with and without post-stroke Stiff-Knee gait. We use electrical stimulation of the peripheral nerve innervating the rectus femoris for a well-controlled reflex stimulus. We are investigating whether reflex excitability of the rectus femoris correlates with gait kinematics.
The purpose of this research study is to evaluate the usefulness of a wearable robotic exoskeleton device (Ekso-GT), to improve learning and memory, and gait therapy in persons with walking disability due to Multiple Sclerosis. The study will evaluate the mobility, learning and memory, and walking abilities of individuals with multiple sclerosis who went through the traditional as compared to others who used the robotic exoskeleton as part of their therapy.
This project will develop the first sensor-based mobile Pelvic Assist Device (mPAD) that can deliver precise, adaptable, pelvic control to restore natural coordination of upper- and lower-limb movements during gait in children with Cerebral Palsy
This two-group, randomized control trial (RCT) will test the effects of a home-based, 16 week gait/balance training plus resistance (exercise bands) exercise program as compared to an educational cancer survivorship attention control condition to address persistent taxane-induced peripheral neuropathy in 312 patients treated for invasive breast cancer with taxanes at 1 year or more after completion of therapy. Assessments of lower extremity muscle strength, gait/balance, nerve conduction, neuropathy symptoms, and quality of life (QOL) will be performed. The proposed exercise intervention addresses gait/balance impairments and motor (resistance) components of taxane-induced peripheral neuropathy. The mechanism by which the intervention achieves the proposed outcomes is though 1) increasing endoneurial blood flow to peripheral nerves and mitochondria resulting in reduction in neuropathic symptoms (including pain) and clinical manifestations of peripheral neuropathy, while improving gait/balance in those with persistent neuropathy; 2) The subsequent increase in nutrient supply allows the mitochondria to function more efficiently, and may alleviate the neuropathic manifestations of taxane-induced peripheral neuropathy. 15 This is the first study proposing to test the home-delivery of an exercise intervention specifically aimed at persistent (long-term) taxane-induced neuropathy. If successful, this study will provide the only evidence-based intervention for patients suffering from persistent neuropathy from neurotoxic chemotherapy. Additionally, the home-delivery format makes this intervention easily translated into clinical practice. Specific Aims: In a sample of patients who completed a taxane-containing chemotherapy regimen (\> 1 year) for breast cancer and who have a persistent neuropathy (VAS score of \> 3) the specific aims of this RCT are: 1. To test the efficacy of a 16-week -delivered program of gait/balance training plus resistance exercise, compared to an educational attention control condition in increasing muscle strength, improving gait/balance and nerve conduction parameters, decreasing the severity of taxane-induced peripheral neuropathy symptoms, and increasing quality of life. 2. To evaluate for differences in muscle strength, gait/balance, sensory (sural) and motor (peroneal) nerve conduction, peripheral neuropathy symptoms, and quality of life (QOL) between patients who receive the exercise program, compared to those in an educational attention control condition controlling for age, BMI, taxane cycles and intervals, neuropathic pain, neuropathy/pain medications, current resistance exercise participation and falls/near falls experienced.
This pilot study will determine the feasibility of implementing a combinatory rehabilitation strategy involving testosterone replacement therapy (TRT) with locomotor training (LT; walking on a treadmill with assistance and overground walking) in men with testosterone deficiency and walking dysfunction after incomplete or complete spinal cord injury. The investigators hypothesize that LT+TRT treatment will improve muscle size and bone mineral density in men with low T and ambulatory dysfunction after incomplete or complete SCI, along with muscle fundtion and walking recovery in men with T low and ambulatory dysfunction ater incomplete SCI.
The objective of this research is to investigate the feasibility of delivering gait treatment using the Moterum iStride Solution™ to individuals with hemiparetic gait impairments using a telemedicine modality, the Moterum Digital Platform.
This study will enroll patients with Multiple Sclerosis and some difficulty with walking. The purpose of this study is to use Rhythmic Auditory Stimulation (RAS) a music therapy technique that provides rhythmic auditory cues (like a beat) to help improve a patient's movements, especially when walking. Participants will be asked to participate in a walking program (WP) with Rhythmic Auditory Stimulation (RAS), or a WP without RAS.
Individuals with multiple sclerosis (MS) experience in impairments in mobility and cognition that increase the risk for accidental falls. More than 50% of individuals with MS experience injurious falls within a 6-month period. Current interventions to improve fall risk have focused on forward walking (FW) and balance training, resulting in small declines in the relative risk for falls with a large degree of variability. Interestingly, motor differences between MS and healthy controls are more pronounced in backward walking (BW), yet no studies have investigated BW training as an intervention to reduce fall risk in persons with MS. This study will investigate the feasibility, acceptability and impact of BW training compared to forward walking training on motor function and fall risk in persons with MS.
The investigator plans to test the use of the Ekso Bionics® Gait Training (Ekso GT™) exoskeleton for gait training in MS patients. The device will solely be used in the clinic under direct supervision from a physical therapist. This is a small PI-initiated uncontrolled pilot study to gather safety and feasibility data on the exoskeleton in individuals with MS and walking impairment.
Phase II of this study includes a pragmatic clinical trial which will take place at Northwest Rehabilitation Associates (NWRA) in Salem, OR to verify the efficacy of the system in a physical therapy clinic.
The purpose of this study is to compare walking to leg strength and endurance in people with multiple sclerosis (PwMS). Using these findings, we hope to be better understand what causes PwMS to have problems walking.
The purpose of this study is to determine the utility of a performance measure for the dual-task of gait and considering people with multiple sclerosis have both cognitive and motor problems, the secondary aim of this study is to determine the effectiveness of a gait-specific dual-tasking intervention for ambulatory individuals with multiple sclerosis.
The purpose of this research study is to test the utility of an ankle robot in people with ankle weakness and foot drop from a peripheral nervous system injury due to neuromuscular or orthopedic injury.
Hypothesis/Specific Aims: The purpose of this research study is to determine if using an exoskeleton during stair climbing training will result in an improved ability to walk and climb stairs in individuals affected by recent stroke as compared to stair climbing training without an exoskeleton.
The purpose of this study is to investigate longitudinally, the walking ability of individuals with cerebral palsy who are transitioning into adulthood and to cross-sectionally examine the health status of these individuals in the context of their walking ability. Young adults who received instrumented gait analysis (IGA) as children will show significant decreases in overall gait performance, as measured by kinematics, kinetics, temporal-spatial parameters, and gait deviation index, compared to their last childhood IGA.
The objective of this study is to determine the effectiveness of the NESS L300 (L300) in improving gait parameters, function, and quality of life among stroke subjects (greater than or equal to 3 months post stroke)with drop foot.
The purpose of this study is to investigate whether speed-dependent measures of gait can be identified in patients with neurological conditions that affect gait, particularly in subjects with parkinsonian disorders.
The goal of this study is to determine if training in both the forward and reverse modes on the ICARE (motor-assisted elliptical) contributes to improvements in gait and cardiorespiratory fitness.
Lite Run is a new assistive device that may have FDA listing as a Class I device by mid 2017 based on clinical testing of adults, independent agency testing and in-house evaluations. This will be a combined study with multiple purposes with respect to the evaluation of its use with the post-operative pediatric population. A first purpose is to verify safety and feasibility of the device on pediatric patients. A second purpose is to statistically test the effectiveness of Lite Run to decrease physical burden on the therapist during post-operative gait training for children and adolescents with cerebral palsy as compared to current methods of body weight-supported gait training. A third purpose is to measure and qualitatively evaluate the effectiveness of the device on patient outcomes and improving patient and therapist satisfaction.