52 Clinical Trials for Various Conditions
Does use of the Mobilaser reduce freezing of gait (FOG) and stride reduction in patients with Parkinson's disease and Parkinsonism.
This is a pilot research study aimed at evaluating whether an FDA listed wearable shoe with capability to deliver vibration feedback can be safe and tolerable for patients with Parkinson disease and control participants and explore whether such a feedback can be useful for treating freezing of gait (FOG) in patients with Parkinson disease.
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 goal of this clinical trial is to learn whether a personalized brain stimulation method called repetitive transcranial magnetic stimulation (rTMS), combined with walking exercises, is a practical and tolerable approach to help people with Parkinson's disease who experience freezing of gait (FOG). FOG is a disabling symptom where people temporarily feel stuck and unable to start walking, even though they want to move. The main questions this study aims to answer are: Can people with Parkinson's disease and FOG tolerate this combined rTMS and walking training procedure? Can researchers successfully enroll and retain participants for this multi-visit intervention? Does the combination of rTMS and gait training show early signs of improving gait and reducing freezing episodes? This study does not include a comparison or placebo group. All participants will receive the same intervention. Participants will: Attend up to 15 study visits over about 16 weeks, with the option to combine visits to reduce burden. Complete brain imaging (MRI) before and after the intervention to guide and evaluate treatment. Receive a form of brain stimulation (rTMS) using a safe, non-invasive coil placed over a specific part of the brain called the supplementary motor area (SMA). The target is personalized using each person's MRI data. Participate in walking exercises that include cognitive tasks (dual-task gait training) after each set of brain stimulation sessions. Undergo assessments of walking ability, Parkinson's disease symptoms, and brain response to stimulation. Be videotaped during walking tasks to assess gait changes, while wearing small motion sensors on the body. Complete questionnaires about symptoms, safety, and tolerability. This study is being conducted at the Medical University of South Carolina (MUSC) and includes up to 15 adults between the ages of 50 and 80 who have been diagnosed with Parkinson's disease and experience FOG. Although rTMS is already FDA-cleared for depression and other conditions, it has not been approved for freezing of gait, and its use in this study is considered investigational. The stimulation device used has been determined to be non-significant risk (NSR) by the FDA. The study does not offer direct medical benefit to participants, but results from this trial may help researchers develop future treatments and better understand how brain stimulation affects walking difficulties in Parkinson's disease. Participation is voluntary, and individuals can withdraw from the study at any time without affecting their medical care
The goal of this clinical trial is to learn if adaptive deep brain stimulation (DBS) can decrease or prevent freezing of gait in participants with Parkinson's disease.
The goals of this clinical trial are to 1) learn how two different rehabilitation interventions for PD can reduce Freezing of Gait (FOG) in people with Parkinson's disease, as assessed by patients, clinicians, and wearable sensors, and 2) to explore whether two different rehabilitation intervention can reduce FOG and improve daily life mobility in people with FOG sufficiently to justify a clinical trial. Participants will: * Be randomly assigned to one of two intervention groups (turning-focused agility exercise or strength-based exercise) * Have one-on-one training sessions three times per week for 6 weeks * Perform in-lab assessments before beginning and after completing the study intervention * Use wearable mobility sensors during daily life to measure their walking and balance
Freezing-of-gait (FoG) in Parkinson Disease (PD) is one of the most vivid and disturbing gait phenomena in neurology. Often described by patients as a feeling of "feet getting glued to the floor," FoG is formally defined as a "brief, episodic absence or marked reduction of forward progression of the feet despite the intention to walk." This debilitating gait phenomena is very common in PD, occurring in up to 80% of individuals with severe PD. When FoG arrests walking, serious consequences can occur such as loss of balance, falls, injurious events, consequent fear of falling, and increased hospitalization. Wearable robots are capable of augmenting spatiotemporal gait mechanics and are emerging as viable solutions for locomotor assistance in various neurological populations. For the proposed study, our goal is to understand how low force mechanical assistance from soft robotic apparel can best mitigate gait decline preceding a freezing episode and subsequent onset of FoG by improving spatial (e.g. stride length) and temporal features (e.g. stride time variability) of walking. We hypothesize that the ongoing gait-preserving effects can essentially minimize the accumulation of motor errors that lead to FoG. Importantly, the autonomous assistance provided by the wearable robot circumvents the need for cognitive or attentional resources, thereby minimizing risks for overloading the cognitive systems -- a known trigger for FoG, thus enhancing the repeatability and robustness of FoG-preventing effects.
Currently, there is a lack of comprehensive knowledge about the role of vestibulospinal drive and cortical activity during self-initiated movement transitions in older adults and people with PD (both with and without FOG). This set of experiments has two primary purposes: to (1) understand the pathological neurophysiology underlying freezing of gait (FOG) during movement transitions and FOG-inducing movements and (2) identify neurological biomarkers associated with FOG and FOG-inducing movements. To achieve this, the investigators will assess vestibular activity using the noninvasive neuromodulation technique of electrical vestibular stimulation (EVS, Experiments 1 and 2) and assess cortical activity by recording via electroencephalography (EEG, Experiments 3 and 4, no stimulation included). These experiments will investigate the vestibular (EVS Experiments) and cortical (EEG experiments) contributions to movement transitions during standing, walking, turning, and changing movement rates. Upon completion of this project, the investigators expect to provide a new understanding of key neural systems (vestibular and cortical) involved in the pathogenesis of movement impairment and freezing episodes during movement transitions including gait initiation, turning, and changing movement rates, in people with PD. An increased understanding of the temporal dynamics of systems involved in FOG and FOG-inducing movements could later guide the development and delivery of novel interventions (e.g. closed-loop deep brain stimulation \[DBS\] or non-invasive brain stimulation) to decrease the incidence and severity of FOG episodes, reducing fall risk and morbidity.
The proposed system (haptic module and insole device) for daily in-community use that detects the occurrence of freezing of gait (FOG) in people with Parkinson's disease (PD). and triggers external cueing stimuli to unfreeze the individual. The purpose of the overall Phase II study is to: (1) Develop a production ready system, (2) Develop a companion mobile app for the proposed system and refine previously developed FOG detection algorithms, and (3) Validate the proper operation of the system and demonstrate its efficacy through lab and in-community testing. This study will focus on validating the system and demonstrating efficacy through in-community testing.
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?
The investigators will conduct an randomized controlled trial (RCT) among people with Parkinson disease (PD) and freezing of gait (FOG) to evaluate the feasibility of a mindfulness intervention compared to a educational program about FOG. FOG is a severe motor disturbance that prevents people from stepping normally and is associated with anxiety, frustration, sedentary behaviors, poorer quality of life, and falls. Mindfulness-Based Stress Reduction (MBSR) is an evidence-based practice that creates a culture to reduce stress and anxiety by increasing conscious awareness and self-compassion. In this study, the investigators will develop a mindfulness-based walking intervention to address both mental health and mobility challenges that constitute FOG.
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.
Parkinson disease (PD) is a common disorder in which reduced speed of movement results from inadequate brain production of the chemical dopamine. The most effective treatment for Parkinson disease is the use of drugs that provide dopamine replacement therapy (DRT). However, as the disease progresses there are prominent DRT-resistant features of Parkinson disease that are a major source of disability. These include cognitive (attention, memory) impairments and gait disorders such as freezing and falls. Repetitive transcranial magnetic stimulation (rTMS), a form of non-invasive brain stimulation, holds promise for the study and treatment of motor and cognitive deficits in persons with Parkinson's. To date, there are no conclusive results regarding an optimal rTMS protocol for recovery of motor and cognitive deficits in Parkinson's disease. This study is designed to promote clinical rehabilitation neuroscience research, and aims to improve rehabilitation in persons with Parkinson's with freezing of gait. This work will evaluate the use of a new accelerated, high dose, non-invasive brain stimulation method for treatment of freezing of gait in PD and will test how applying targeted accelerated stimulation to the brain improves gait disturbance due to PD.
A Multi-Center, Controlled Study to Evaluate Use of CereGate Therapy to Reduce Freezing of Gait in Participants Diagnosed with Parkinson's Disease.
The purpose of this research study is to determine if DBS is a safe and effective therapy for severe freezing of gait in patients with Parkinson's Disease. Freezing of gait (FOG) is a particularly debilitating motor deficit seen in a subset of patients with Parkinson's Disease (PD).
Deep Brain Stimulation of the subthalamic nucleus (STN) has become a standard of care, FDA-approved treatment for Parkinson's disease, with stimulation delivered at a constant amplitude and voltage, operating in an open-loop fashion that does not respond to a patient's current state. Although gait deficits and freezing of gait may initially respond to continuous open-loop deep brain stimulation (olDBS) and medication, the symptoms often recur over time. The episodic and predictable nature of FOG makes it well suited for adaptive DBS (aDBS) and a device that overcomes the limitations of traditional high frequency olDBS and is capable of adapting therapy either in the frequency or intensity domain transiently to treat FOG while also treating other PD signs such as tremor and bradykinesia. The purpose of this study is to determine the feasibility of an adaptive DBS system, that responds to patient-specific neural and kinematic variables with customized DBS parameters.
Subjects are being asked to participate in this study to determine the safety and effectiveness of a drug called atomoxetine in the treatment of freezing of gait for Parkinson's Disease patients. Atomoxetine (ATM) is an approved drug currently on the market for the treatment of attention deficit. It works to increase the amount of norepinephrine (a chemical in the brain that helps keep us awake and alert) in our brain. ATM has not been approved by the Food and Drug Administration (FDA) to be used in the treatment of PD, but has been found to be well tolerated in this patient population.
Early stage Parkinson disease (PD) is characterized by a 'honeymoon' phase in terms of responsiveness of motor symptoms, including gait, to dopaminergic pharmacotherapy. Advancing PD is associated with disabling axial motor complications, such as freezing of gait (FoG), with decreased or even refractory dopamine responsiveness in over 50% of patients. The management of dopamine resistant gait problems represents the most important unmet need in PD. This study will related detailed motor testing to brain PET imaging to see if certain molecules (or lack thereof) involved with neurologic transmission in the brain are involved with FoG.
Freezing of gait (FoG) is a common and debilitating condition in Parkinson's Disease (PD) patients. FoG is described as an episodic inability to walk, which often triggers falls, hospitalization and is an important predictor of poor quality of life. As locomotor regions degenerate in PD, gait automaticity is impaired. Patients compensate by increasing volitional control of gait, however, this adaptation has been found to worsen FoG severity. We hypothesize that increased cortical control of gait is maladaptive, and therapies to improve gait automaticity will not be effective unless cortical control of gait is reduced. The long-term goal of this project is to develop a therapeutic approach for FoG that simultaneously reduces cortical control and increases automaticity of gait. The objective is to determine the locomotor network abnormalities responsible for FoG and demonstrate how neuromodulation and rehabilitation can modulate the network. The rationale of this study is that increased connectivity between brainstem locomotor regions and cortical structures represents increased cortical governance of gait, and it can be reversed by the proposed intervention. We will accomplish this by combining a course of inhibitory rTMS (1Hz) to the cortex (supplementary motor area) with a rehabilitation protocol designed to increase gait automaticity (dual task training). We have designed a study that will carefully assess the locomotor network of freezers with resting state functional, diffusion and interleaved TMS/BOLD MRI studies, before and after intervention. Behavioral measures including gait analysis, cognitive and motor assessments will also be conducted at baseline and post treatment. The study aims to determine the effects of our intervention on the locomotor network (assessed with imaging), as well as on FoG severity as quantified through multiple markers obtained through gait analysis. At the conclusion of the study we expect to have determined the network changes central to the pathophysiology of FoG, the effects of 1Hz rTMS + rehabilitation on this network, and on FoG severity. The relevance of this study to public health is to develop a non-invasive effective therapeutic option for one of the most debilitating and untreatable conditions affecting the lives of one million Americans suffering from PD; freezing of gait.
Continuous deep brain stimulation (cDBS) is an established therapy for the major motor signs in Parkinson's disease, however some patients find that it does not adequately treat their freezing of gait (FOG). Currently, cDBS is limited to "open-loop" stimulation,without real-time adjustment to the patient's state of activity, fluctuations and types of motor symptoms, medication dosages, or neural markers of the disease. The purpose of this study is to determine if an adaptive DBS system,responding to patient specific, clinically relevant neural or kinematic feedback related to FOG, is more effective than continuous DBS on the motor Unified Parkinson's Disease Rating Scale (UPDRS III) and gait measures of PD.
Freezing of gait is a late stage complication of Parkinson's disease in which patients note that their feet feel stuck or glued to the ground. This can lead to imbalance and falls and the secondary complications that can result from falls such as fractures and hospitalizations. While levodopa can help freezing of gait in some patients, it does not help in all, and the dose needed to treat freezing may be limited by side effects of the medications. Currently there are no treatments targeted towards freezing of gait and the goal of this research is to see if Modafinil could be one such drug to help freezing of gait in Parkinson's disease.
Our recent study (Xie et al, Neurology 2015; 84: 415-420) found that bilateral STN DBS of 60Hz, compared to the traditional 130Hz, decreased the aspiration frequency and swallowing difficulty, freezing of gait (FOG), and other axial symptoms and parkinsonism in Parkinson patients with FOG refractory to 130Hz and medications. The benefit of 60Hz stimulation persisted during the 6-week study period, but with worsening tremor in one patient. However, it remains unknown whether the benefit of 60Hz would persist on prolonged stimulation period, and whether there is carry-over effect across different conditions. Hence, the investigators would like to test the hypothesis that the 60Hz stimulation, compared to 130Hz might have persistent benefit over an extended period in reducing the swallowing dysfunction, FOG, and other axial symptoms in these PD patients even after correcting the potential carry-over effect.
The purpose of this study is to investigate brain signals related to freezing of gait (FoG), a symptom of Parkinson's Disease, that can lead to dangerous falls. The investigators hypothesize that uncovering these signals can lead to better deep brain stimulation interventions.
Freezing of gait (FOG) is among the most disabling motor features of Parkinson disease (PD) and is present in other forms of parkinsonism as well. FOG is a brief (usually lasting \<30 seconds) episode of absence or a greatly reduced forward movement of the feet despite intention to walk. It typically occurs when patients initiate gait (so-called "start hesitation") and when attempting to turn. It is a leading cause of falls and often results in a wheelchair-dependent state. FOG greatly interferes with activities of daily living, causes social isolation and poor quality of life. FOG is one of the least understood features of PD. It possibly may develop independent of the other motor features of the disease, and be caused by specific pathological changes in the brain. Previous studies on FOG have shown conflicting information and have not lead to clear understanding of the pathophysiology. One key reason for this is that there appears to be multiple subtypes which have rarely been taken into account. The purpose of this study is to show that different types of FOG exist and to see if there is a connection to cognitive differences or gait patterns.
The study objective is to explore Deep Brain Stimulation (DBS) in two specific brain regions (Globus Pallidum, or GPI, plus the pedunculopontine nucleus, or PPN) for on medication freezing of gait (FoG) in Parkinsons Disease (PD). Hopefully, information gathered from these two brain regions after surgery will allow for the development of a personalized DBS system to address FoG. The primary outcome will be a comparison of the pre-operative number of FoG episodes in the laboratory during the FoG battery versus those 6 months post-DBS at the optimized device settings.
This study will evaluate the effects of transcranial direct current stimulation (tDCS) in combination with locomotor training in patients with Parkinson's disease (PD) and freezing of gait (FOG).
This project will relate our new quantification of Freezing of Gait (FoG) in Parkinson's disease, using body worn inertial sensors (Aim I), with abnormalities in state-of-the-art, resting state, functional brain connectivity (Aim II), and determine the number of subjects needed for a future, randomized clinical trial to test the efficacy of our novel, Agility Boot Camp (ABC) rehabilitation intervention for FoG (Aim III). The technological approaches to these aims are cutting edge and will allow us to develop sensitive behavioral and brain biomarkers for gait disorders in Parkinson's disease (PD) for use in future clinical trials.
This study is designed to evaluate whether a specific visuospatial training task will change gait performance of Parkinson's disease (PD) patients in doorways, specifically freezing of gait.
The purpose of this study is to determine whether a laser light beam, attached to a rolling walker and projected onto the floor, reduces freezing episodes in patients with Parkinson's disease.
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.