13 Clinical Trials for Various Conditions
Specific aim: To determine whether optokinetic stimulation can improve gait abnormalities. Hypothesis: Optokinetic stimulation stimulates the vestibular system and can improve vestibular induced gait disorders.
The overall goal of the project is to reduce the incidence of post hip fracture morbidity and mortality by conducting geriatric fellow periodic home visits.The assessment will be multidisciplinary and will include assessments of functional status, depression, environmental risks and medical conditions. This group will be compared against a group followed by the usual standard of care post hip fracture.
Sixty patients will be enrolled in this study who are treated for Parkinson's disease (PD) with bilateral deep brain stimulation of subthalamic nucleus (STN) or globus pallidus (GP), who have a pre- operative 7 Tesla MRI including diffusion tensor imaging for tractography and a postoperative head CT for electrode localization, and in whom at least 3 months have passed since activation of their neurostimulators, for stabilization of clinical stimulator settings. Using their MRI and CT, the investigators will construct patient-specific models of electrical current spread to neuroanatomical tar- gets surrounding the electrode. Then applying nonlinear (particle swarm) optimization, patient- specific stimulator settings will be designed to maximally or minimally activate specific path- ways. In STN DBS: pedunculopallidal vs. pallidopeduncular pathways. In GP DBS: pallidopeduncular pathways at its origin in GP pars interna (GPi) vs. inhibitory afferents to GPi (from GP pars externa GPe). All stimulation falls within the the FDA-approved range for DBS for PD.
This is a mechanistic study to determine the differential effects of the dopaminergic and cholinergic systems on attention, gait, and balance. The primary goal of the study is to evaluate the relative effects of pedunculopontine nucleus (PPN) and subthalamic nucleus (STN) Deep Brain Stimulation (DBS) on these features in persons with Parkinson's Disease (PD) who are eligible for DBS for improvement of their motor symptoms and exhibit gait instability with falls. Patients will be enrolled and implanted with bilateral electrodes in one of the approved DBS locations (subthalamic nucleus: STN), but additionally electrodes will be inserted into the experimental target, namely the PPN bilaterally.
People with chronic ankle instability (CAI) demonstrate altered gait or walking mechanics which cause people to walk on the outside of their foot and increases the risk of additional ankle sprains, abnormal cartilage strain, and early joint degeneration. Evidence indicates that common treatments for CAI do not impact gait, leaving unresolved impairments that can lead to lifelong disability. Recent lab-based gait retraining with visual and auditory feedback has immediately improved walking mechanics. However, real-world training is hypothesized to generate long-term changes by incorporating short, frequent training sessions over a variety of surfaces. These are key training parameters to produce lasting change. Pilot data using real-world vibration feedback (RW-VF) suggest that a single session immediately improves walking mechanics with changes lasting for up to 5 minutes. Despite promising initial results, there remains a critical need to determine the impact of multiple RW-VF sessions as an initial step to developing a protocol capable of long-term improvements. The purpose of this proposal is to determine the extent to which 2-weeks of RW-VF restores gait biomechanics in those with CAI. Twenty people with CAI will be enrolled and complete a two-week gait retraining protocol with vibration feedback. Walking mechanics before, immediately after, and 1 week and 4 weeks following the training will be compared. These contributions can be significant as positive results will support a paradigm shift in treatments for people with CAI and lay the foundation for large scale clinical trials aimed at optimizing long term gains. The outcomes of future research have the potential to advance evidenced based rehabilitation interventions not only for people with CAI but also for people who have sustained a variety of musculoskeletal injuries as there is strong evidence that other lower extremity pathologies cause lifelong limitations, including changes in walking mechanics which lead to degenerative changes to other joints.
Balance problems and falls are among the most common complaints in Veterans with Parkinson's Disease (PD), but there are no effective treatments and the ability to measure balance and falls remains quite poor. This study uses wearable sensors to measure balance and uses deep brain stimulation electrodes to measure electric signals from the brain in Veterans with PD. The investigators hope to use this data to better understand the brain pathways underlying balance problems in PD so that new treatments to improve balance and reduce falls in Veterans with PD can be designed.
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).
Individuals with chronic ankle instability (CAI) have demonstrated altered gait patterns. Gait training may be necessary to address these alterations as protocols focusing solely on strength or balance have not been shown to impact walking gait. Biofeedback about the foot position during walking may help improve gait biomechanics. The purpose is to determine whether a 4-week rehabilitation program that includes biofeedback has beneficial effects on self-reported function and ankle gait kinematics compared to rehabilitation alone in people with CAI. The design is a single-blinded randomized controlled trial. Participants will complete baseline self-reported function questionnaires and walking gait trials and then be randomized to complete 4- weeks of supervised rehabilitation with or without audiovisual biofeedback. Follow up emails will ask for participant information about ankle health and to complete questionnaires about their ankle for 6 months and 12 months after completing rehabilitation.
The purpose of this study is to better understand why individuals with Progressive Supranuclear Palsy (PSP) fall. Understanding the mechanism of gait and balance dysfunction in individuals with PSP may provide us with important early diagnostic tools, allowing for earlier identification of mobility problems and to better evaluate medical therapies aimed at improving motor disability. The investigators will recruit 10 PSP, 10 PD and 10 healthy controls for the study. All subjects will be asked to come to the OHSU clinic at the Center for Health and Healing for an initial screening visit. They will meet with the primary investigator to conduct a brief interview and physical examination. In addition, they will be asked to answer questions regarding current and past medical illness, how often they fall and what kinds of medications they are on. Subjects who agree to participate will come to the Oregon Clinical and Translational Research Institute (OCTRI) at OHSU for balance testing. Subjects will be asked to stand or sit on a movable platform with eyes open or closed. Prior to standing on the platform, the investigators will place 6 small sensors on body which are held in place by velcro straps (one on each wrist, ankles, chest and lower back). The platform will then be moved (tilt or slide) while subjects try to keep their balance. During all of the balance tests described above, body movements will be recorded from the sensors on the subjects' body. This data is directly recorded by a computer and analyzed to help us gain better understanding of the subjects' posture and their ability to remain up right.
This study will collect information on the different ways that people walk, that is, their gait, when they use ankle braces. Patients will visit NIH on at least three and as many as nine separate occasions. A physical therapist will perform a physical examination to determine how patients move, how strong they are and what their comfortable walking speed is. Then patients will sit on a chair while a camera apparatus takes special pictures of their legs, a procedure lasting up to 2 hours. Patients will be asked to return to learn how to walk with the custom Passive Dynamic Ankle-Foot Orthosis (PD-AFO)-a unique ankle brace designed to improve walking ability by providing natural support to the lower limb. Patients 4 and older who are in good health and able to walk repeatedly a distance of 15 meters (approximately 49 feet) independently and unsupervised may be eligible for this study. With this training, patients may return several times to learn how to walk with the brace, but for their protection, they will not be allowed to take it or use it outside the research team's supervision. The researchers will examine the leg to ensure that the brace fits and will ask questions about it. Each training visit will require up to 1.5 hours. When patients have learned to walk with the brace, they will be asked to visit again and walk while scientific pictures are taken of their legs. During the walking test, patients will wear T-shirts and shorts. Patients' arms and legs will be wrapped with a soft, rubber-like material, to allow small plastic reflective balls to be attached. Firm material known as a shell can be attached to the rubber sleeves, with Velcro or a self-sticking bandage. The small balls may also be attached to the skin, with an adhesive. Also, there may be a test of the muscles, through the use of electromyography, or EMG. The test involves attachment of small metal electrodes to the surface of the skin, again with an adhesive. There should not be discomfort with that test. As patients walk several times, scientific cameras will record the positions of the reflective balls. Pictures do not involve patients' faces or other parts of the body. Afterward, a unique chair system called a Biodex will measure the leg muscle strength. Patients will be asked to sit on the chair and place their leg in a foot in an apparatus, a special structure that measures strength. They will repeatedly push against the apparatus, doing so for 3 seconds. Each time patients push, the researchers will touch a small magnetic device to the skin, which will cause the muscles to push harder. Although this procedure should not cause any discomfort, it may feel unusual. If they wish, patients can ask to stop the test at any time. Few risks are involved in participating in this series of activities. There is a slight chance of mild skin irritation from the adhesives used on the skin or from the soft, rubber-like material. But the material is worn for only a brief period, and skin reactions are rare. Also, that material may feel tight, but if it causes discomfort or prevents moving, patients can ask a researcher to adjust it. There is a slight chance of skin irritation from use of the PD-AFO, but adjustment can be made to make patients comfortable. Patients may experience some muscle soreness caused by participating in the muscle strength tests. However, they will be safely monitored by a physical therapist when they try on the brace to adjust to its feel and fit, as well as during testing of gait. This study will not have a direct benefit for participants. However, participants will be paid for their time, with minimum compensation of $50.
The purpose of this study is to determine the effect of 3 types of sensory-targeted rehabilitation interventions on subjective and objective measures of function for those with chronic ankle instability. The investigators hypothesize that subjective and objective measures of function including self-reported disability, balance, and range of motion will improve after 2-weeks of sensory-targeted interventions.
Activities of daily living (ADL) frequently involve the simultaneous performance of two or more tasks, such as crossing the street while holding a conversation, commonly referred to as dual tasking. The simultaneous performance of a motor and a cognitive task increases postural instability, gait dysfunction, and may increase fall rates in Parkinson's disease (PD). The goal of this project is to evaluate the effectiveness of utilizing a digital therapeutic, Dual-task Augmented Reality Treatment (DART) protocol, for the treatment of postural instability and gait dysfunction (PIGD) in individuals with PD. A randomized controlled trial will be conducted at the Main Campus of the Cleveland Clinic (Cleveland, OH). A total of 50 individuals with Parkinson's disease will be randomized into 1) a traditional multi-modal training group, or 2) multi-modal training administered via an augmented reality headset. Multi-modal therapy is where the participant practices performing two things at once (i.e. marching while answering math questions). Augmented reality is a type of head-worn technology that allows the individual to see the real world and places holograms in the space. Both groups will exercise 2x/week for a total of 8 weeks. Assessments involving walking, balancing, and turning will be completed to assess the efficacy of the treatment.
The primary objective of this study is to investigate the effects of a theoretically driven, highly challenging exercise program (balance and strengthening exercises) in reducing fall rate, improving balance and reducing fear of falling in persons with Parkinson's disease. In this pilot, randomized, cross-over study, 32 participants with Parkinson disease will be randomly assigned to either an early start (immediately following enrollment) or late start (3 months after enrollment) multifactorial exercise program which will meet 2 times per week for 1.5 hours over 3 months. The exercise program will consist of balance and strengthening exercises which will be individualized depending on the ability of each participant. Fall rate, balance, walking ability, fear of falling, mood, anxiety, and quality of life will be measured prior to the start, at 3 months and 6 months after enrollment. Subjects will be enrolled for 6-7 months.