169 Clinical Trials for Various Conditions
To determine changes in power symmetry, gait symmetry, and functional outcomes for participants' poststroke (Inpatient Rehabilitation Facility) after participating in an intervention using a recumbent cycle with power biofeedback (BFB). To determine how this intervention can impact gait asymmetry, a common disorder poststroke secondary to hemiparesis. Gait asymmetry is a difficult impairment to treat because it is difficult for both therapists and patients to perceive. Training with BFB allows for quantitative data about the power production or lack of that directly impacts safety in walking, increased energy expenditure, and decreased gait speed.
Dysphagia, or difficulty swallowing, is a common symptom of many neurological diseases but its treatment is not well established or easily accessible. To start addressing this gap, the researchers developed and validated a cost-effective wearable surface electromyography (sEMG) biofeedback sensor technology (i-Phagia), optimized to record muscle activity from the head/neck and provide biofeedback to patients and adherence data to clinicians during swallow therapy. This system has been developed with commercially available and widely used materials and the Purdue University IRB has determined that the device is non-significant risk device. The goal of this clinical trial is to learn if this biofeedback (using this new technology/i-Phagia) when used as an adjunct to a standard swallow therapy protocol works to improve swallowing function in patients post chronic stroke or diagnosed with Parkinson's disease. It will also help the investigators learn whether this therapy protocol is equally effective when provided in-person versus via telehealth. Finally, it will determine which patient factors may influence how well the treatment works. The main questions it aims to answer are: * Does biofeedback (using this new technology/i-Phagia) when used as an adjunct to a standard swallow therapy protocol works better than a standard of care treatment to improve swallowing function in patients post chronic stroke or diagnosed with Parkinson's disease? * Is completing the swallow therapy protocol at home (via telehealth) as effective as completing it in-person (in the clinic)? * What factors related to the patients (e.g., age, diagnosis, etc.) may influence how well the treatment works? Participants will: * Complete a 12-week swallow treatment protocol (12 treatment visits) either in-person or at home (via telehealth) * Complete 3 in-person evaluations (pre-treatment; post-treatment; and at a 12-week post treatment follow-up time point) * Exercise at home several days per week and keep a diary/log of their home exercise The hypothesis is that upon study completion, the efficacy of sEMG biofeedback-facilitated swallow therapy for both in-person and telehealth service delivery in two neurogenic dysphagia populations will have been established, and variables determining response to treatment will begin to be identified.
While a majority of surgical ergonomic studies have been evaluating attending surgeons, few have evaluated surgical ergonomics within the surgical resident. Biofeedback devices can be partnered with education and geared towards surgical residents to decrease current and future musculoskeletal disorders, which may in turn lead to longer and more fulfilling careers.
Current clinical assessment tools are often not sensitive enough to detect and treat some subtle (yet troubling) problems after mTBI. In this study, the investigators will use wearable sensors to both assess and treat people with mTBI. Specifically, the investigators will provide immediate feedback, with visual and/or auditory, on movement quality during physical therapy. This immediate feedback on performance may improve outcomes as the investigators will measure multiple body segments including head movements simultaneously with balance and walking exercises. Such complex movements are needed for safe return to high level activity and military duty. The investigators will test this approach against a standard vestibular rehabilitation program. There are few potential risks to this study such as increasing symptoms and a small fall risk. Benefits include physical therapy for balance problems regardless of therapy with or without biofeedback. An indirect benefit is to have data on correct dosage of physical therapy. The investigators will also distinguish which concussion subtype profiles benefit most from physical therapy. This will help healthcare providers and patients by providing more information to help establish clinical guidelines and new tools for physical therapy.
The purpose of this study is to investigate the effectiveness of a biofeedback device (Loadsol) in training healthy subjects to comply with partial weightbearing, and to compare its outcomes with the standard of care training. Partial weightbearing is an essential component of rehabilitation and recovery for many orthopedic patients, yet it remains challenging for individuals to accurately gauge their weightbearing restrictions without proper guidance and feedback. The primary objective of the study is to determine whether the use of the biofeedback device (Loadsol) can reduce the time it takes for healthy subjects to learn and comply with partial weightbearing, compared to traditional training methods. The Loadsol device provides real-time auditory feedback on the individual's weightbearing status, potentially enhancing the learning process and adherence to weightbearing restrictions. Secondary objectives of the study include: Assessing the compliance of subjects with weightbearing restrictions in both the biofeedback and standard of care training groups, and comparing the results to identify any significant differences in adherence to the prescribed weightbearing limitations. Evaluating subject satisfaction with the training methods, as measured through questionnaires and the use of Patient-Reported Outcomes Measurement Information System (PROMIS) tools. This evaluation will help determine if the biofeedback device (Loadsol) leads to higher levels of satisfaction among subjects compared to the standard of care training. By examining these objectives, this study aims to provide valuable insights into the potential benefits of using a biofeedback device in partial weightbearing training, and to establish whether its implementation can lead to improved outcomes in learning, compliance, and overall patient satisfaction.
Paradoxical Vocal Fold Motion (PVFM) is a condition where vocal cords adduct (move toward another) instead of abduct (move away from one another) during inspiration, thus causing shortness of breath. The goal of this pilot randomized controlled trial is to compare the efficacy of biofeedback as compared to laryngeal control therapy (LCT) in the treatment of PVFM. Participants will take surveys about their symptoms and their expectations of treatment prior to initiating treatment and after completion of their assigned treatment. Researchers will compare the biofeedback group to the LCT group to see if participants have differences in changes of their symptoms.
Migraine is a common, debilitating neurologic condition affecting more than 900 million individuals worldwide. Established treatments for migraine include medications, vitamin and herbal supplements, neuromodulation, and behavioral treatment strategies. This study aims to determine whether a novel, home-based behavioral approach, combined biofeedback-virtual reality therapy, can improve self-reported migraine-related outcomes in individuals living with chronic migraine. In this randomized, controlled pilot study, 50 adults with chronic migraine are randomized to the experimental group (frequent use of a heart rate variability biofeedback-virtual reality device plus standard medical care; n=25) or wait-list control group (standard medical care alone; n=25). The primary outcome is reduction in mean monthly headache days between groups at 12 weeks. Secondary outcomes include mean change in acute analgesic use frequency, depression, migraine-related disability, stress, insomnia, and catastrophizing between groups at 12 weeks. Tertiary outcomes include change in heart rate variability and device-related user experience measures.
We are conducting a proof-of-concept trial to study the impact of HRV-biofeedback, a mind-body technique designed to improve stress resilience, on the quality of life, mood, and clinical skin severity of patients with psoriasis.
More than two million Americans are currently living with a full or partial limb loss, and an additional 185,000 amputations occur each year. The majority of amputations occur in the lower limbs. There are many potential causes for amputation, but the majority can be attributed to vascular diseases, such as diabetes, traumatic injury, and cancer. For these individuals, prosthetic devices play an important role in restoring mobility and enabling them to participate in everyday activities. However, when learning to use these devices, patients often alter their movement patterns to compensate for pain or discomfort, a decreased ability to feel what their prosthetic limb is doing, and/or a fear of falling. By changing their movement patterns, patients will tend to am their intact leg, which has been shown to lead to long-term joint damage and chronic injury. For perspective, 75% of United States veterans living with amputation are diagnosed with a subsequent disease affecting their muscle, bone, and/or joint health. Therefore, therapy sessions, known as gait retraining, are an integral part of teaching prosthesis users to walk in a safe and efficient manner. With recent advances in wearable technology, researchers and therapists have begun exploring the use of biofeedback systems to assist with this retraining. In these systems, wearable sensors are used to measure how the patient is moving in real-time, and can provide information on how much time they spend on each leg and how much each joint moves during walking. Biofeedback refers to the process of communicating the information from these sensors back to the patients instruct them whether they need to change their movements. Previous research has shown that these systems have excellent potential for helping patients with physical disabilities improve their quality of motion. However, relatively little research has explored how well individuals with above-knee leg amputations respond to biofeedback during gait retraining. Importantly, the question of whether the new movement patterns taught using biofeedback will persist after training has finished remains unanswered. Therefore, the primary objective of this research is to determine whether biofeedback is a feasible tool for gait retraining with above-knee prosthesis (including a prosthetic knee, ankle, and foot) users. To answer these questions, forty individuals currently using above-knee prosthetic systems will undergo a single session of biofeedback training. Half of these populations will be from the civilian population, and half will be military veterans. During this training, the biofeedback system will apply short vibrations - similar to those generated by cellphones - to their skin every time that the patient reaches the desired degree of hip rotation during walking. Participants will be instructed to keep increasing their hip motion until they feel a vibration on every step. Before training, they will be instrumented with a wearable motion captures system, pressure sensors embedded in their shoes, and a wearable heart rate monitor. Using these devices, researchers will measure the participants' walking patterns without biofeedback determine their current ability. Once training is complete, their walking patterns will be measured again, first while using the biofeedback system, and then again fifteen minutes and thirty minutes after the biofeedback system has been removed. The data measured during these tests will enable researchers to calculate functional mobility scores that are used to evaluate the quality of a patient's walking, and then compare how these scores change before, during, and after biofeedback training. The knowledge gained through this research constitutes a critical step towards identifying optimal biofeedback strategies for maximizing patient mobility outcomes. The findings will be essential for the development of gait retraining protocols designed to reduce the incidence of chronic injury, and enable patients to achieve their full mobility potential. Building on these results, the next research phase will be to incorporate biofeedback training into a standard six-week gait retraining protocol to evaluate its long-term effectiveness as a rehabilitation tool. Unlike traditional gait retraining, which requires patients to visit clinics in-person for all sessions, the wearable, automated nature of biofeedback training will allow patients to continue gait training from home. This ability will enable patients to continue training activities between sessions, and ultimately may be able to substitute for some in-person visits. This potential for remote therapy has exciting implications for improved access to care for individuals living long distances from their rehabilitation providers, or those suffering from social anxiety, as well as during global health pandemics where in-person visits are difficult.
The research team has developed a visual kinematic biofeedback system which is designed to help children with hemiplegic cerebral palsy (CP) correct a pattern of reduced knee extension in terminal swing and early stance. The system provides real-time feedback on the knee angle pattern during walking on a treadmill. From a pilot study on children with CP, the investigators observed that when the system was used in children who have stiff knee gait (SKG), training with knee feedback alone could lead to an increase in hip flexion which in turn led to limited normalization of the knee pattern through the whole gait cycle. This study, funded by the NIDILRR Switzer grant (PI: X Liu, Ph.D.), seeks to address the question of whether a training design with feedback on both the knee and hip joints would reduce this tendency to generate unintended changes in hip joint motion, and in doing so also improve convergence to the intended knee joint pattern. This study will test ten children and young adults with brain injury who have SKG and examine their short term adaptations to two types of kinematic feedback training: feedback training on the knee alone (condition B) and sequential switched feedback training on the knee and the hip (condition A). An additional sensor placed on the pelvis will be added to the current feedback system for measurement and feedback on the hip joint angle. Software enhancements will also be made with methods that will allow study and description of adaptations in measures of inter-limb symmetry during training. The participants will visit twice with a 2-week washout period between the two visits. Five participants will first undergo condition B in the first visit and then condition A in the second visit, while the other five participants will start with condition A in the first visit and then undergo condition B in the second visit. To compare the effects of the conditions on normalizing the joint angle trajectories, the knee and hip kinematics will be collected and analyzed in both the conditions. To investigate the coordination of lower limb segments under feedback training, relative phase measures will be analyzed on the hip and the knee. To examine whether participants adapt to the feedback retraining in terms of improvement in gait quality, symmetry ratios will be analyzed.
The purpose of this study is to conduct a comprehensive clinical and biomechanical screening of high school, collegiate-level, recreational, and Olympic/professional-level athletes with the goal of identifying individual functional and performance deficits that lead to future injury.
This prospective, randomized, longitudinal, controlled study will enroll pediatric CD patients with inflammatory, non-stricturing, and non-penetrating disease type with mild/quiescent disease based on Pediatric Crohn's Disease Activity Index (PCDAI). Participants will be randomized to receive HRV biofeedback intervention daily for 12 weeks or to music relaxation therapy.
Previous research has shown that modulation of a brain region in rodents, the ventral tegmental area (VTA), improves depressive symptoms. Human research has also shown that VTA self-modulation using 'biofeedback' is feasible and successful in healthy volunteers. This biofeedback procedure is a type of cognitive training that includes real-time feedback about brain signal levels from the VTA. Our question is whether VTA self-modulation with biofeedback can influence depression symptoms.
Heart rate variability biofeedback (HRV-B) is a complementary, non-pharmacologic therapy that is being tested to see if it can help cancer survivors reduce their symptoms of pain, stress, insomnia, fatigue, or depression. HRV-B is an interactive procedure in which participants relax and breathe regularly while watching the a computer screen. The computer screen provides feedback that helps people increase their heart rate variability.
Patients with vocal hyperfunction will undergo standard of care voice therapy with ambulatory voice monitoring before therapy and after the first 3 voice therapy sessions. Biofeedback will be added to ambulatory monitoring after the 2nd voice therapy session only.
This first study will enroll 3 groups of patients with vocal fold nodules that will receive different schedules of ambulatory voice biofeedback (100% frequency feedback, 25% frequency feedback, summary feedback) to avoid their upper 15th percentile of vocal loudness.
The investigators propose a randomized controlled trial (RCT) to investigate the feasibility and efficacy of non-intrusive biofeedback devices that can be worn throughout the day in providing therapeutic cues to college students suffering from chronic anxiety. The biofeedback device detects physiological stress indices in real time (e.g., changes in breathing rate) and provides feedback (e.g., through minor vibration or text messages) serving as a cue to the wearer to recall therapeutic steps at exactly those moments they need to exert cognitive control. Students will be randomized in a 1) experimental group with biofeedback device and 2) experimental group without biofeedback device. Experimental groups will undergo an intervention that will strengthening cognitive control through mindfulness-based relaxation techniques. Outcome measures will include a multi-method approach collecting questionnaire, behavioral, and psycho-physiological indices of anxiety and self-control. The proposed study is innovative and has the potential to lead to more effective and cost-efficient types of intervention applications in the future.
The goal of this research study to see whether biofeedback therapy helps treat asthma, and if so, how it works. Biofeedback is a treatment method that can teach how to bodily control. Biofeedback is widely used to help people relax. In this study however, the investigators want to learn if a specific type of biofeedback actually improves asthma in a way that might allow the reduction or elimination of other controller treatments like inhaled-corticosteroids.
The purpose of this study is to evaluate the blood flow to the heart during stress and assess changes in blood flow after psychological treatment in participants with coronary artery disease. The aims of the study are to assess the effects of heart rate variability (HRV) biofeedback (versus usual care) on global and regional myocardial blood flow (MBF), peripheral vascular function, and autonomic changes during mental stress.
Pain initiates a stress response that increases sympathetic output and leads to autonomic imbalance. Heart rate variability (HRV) is a easy to perform, valid measure of autonomic function. HRV biofeedback (HRV-B) is a novel biobehavioral procedure in which patients learn to restore autonomic balance by developing 'HRV Coherence'. Patients in HRV Coherence have improved mood and cognition. The investigators' pilot study showed that HRV-B alleviated chronic pain and stress among Veteran Pain Clinic patients. HRV-B thus has a pivotal role in managing pain. The proposed project is a randomized, sham-controlled, biobehavioral intervention with HRV-B to test the hypotheses that HRV-B increases HRV coherence and reduces pain, stress, fatigue, insomnia and depression and improves sleep, activity, and cognition in Veterans with chronic neuromuscular pain. The investigators hypothesize that HRV-B will (1) reduce self-reported pain and stress ratings, (2) improve objective measures of actigraphic sleep parameters (sleep latency, duration, efficiency, fragmentation), rest/activity rhythms (dichotomy index, interdaily stability) and cognitive function (reaction time, attention); and (3) alleviate self-reported fatigue and depression symptoms. Patients from two groups will be randomized to the investigators' previously established HRV-B or sham protocol (n=40 each), and will complete a baseline assessment, 6 weekly training sessions, a post-training assessment, and 4-week and 8-week follow-up evaluations post-training. Portable, hand-held, data-logging devices will be used to practice attaining HRV coherence at home by the active HRV-B training group, while those in the sham training group will get a 'stress squeeze ball'. Standard methods will quantify HRV coherence and other HRV measures, and validated instruments will be used to assess pain, stress, fatigue, insomnia, depression, and cognitive function. Wrist actigraphy will be used to objectively characterize insomnia via continuous recordings collected 24-hrs/day over three 1-week periods (pre-training, post-training, and at the 4 week follow-up assessments. Tests measuring attention and reaction time will assess changes in cognitive performance. Data analyses will apply linear models for repeated measures to evaluate the effect of HRV-B on study outcomes, and on treatment persistence, after adjusting for confounding factors. This study will be the first to examine HRV-B for pain management among Veteran chronic pain patients.
The study is a multi-center, randomized, placebo controlled trial with participants randomized into one of four groups: 1. placebo/usual care (educational pamphlet) 2. loperamide/usual care (educational pamphlet) 3. placebo/anal exercises with biofeedback 4. loperamide/anal exercises with biofeedback The primary outcome, change from baseline in St. Marks (Vaizey) Score at 24 weeks, will be compared between treatment groups using linear regression.
The overall purpose of this research is to determine the effect of ultrasound imaging biofeedback on urine leakage, pelvic floor muscle contractions, and quality of life in women with stress urinary incontinence. This study will include women 20 years or older with stress urinary incontinence. The study will involve 2 groups: pelvic floor muscle (PFM) exercises with biofeedback using transabdominal Rehabilitative ultrasound imaging (RUSI) (Group A) and PFM exercises alone (Group B). The participants will perform 16 exercise sessions over a period of 8 weeks. Group A will perform 3 pelvic floor exercises using the transabdominal RUSI to provide biofeedback. Group B will perform the same 3 pelvic floor exercises without biofeedback. All participants involved in the study will complete a general medical information questionnaire. In addition, all participants will have their PFM contraction assessed using an ultrasound machine placed over the lower abdomen, quality of life assessed with a written questionnaire, and given a 7-day bladder diary to complete prior to, at 4-weeks, and at completion of the study.
The purpose of this study is to determine if individuals who had a stroke more than one year before entering the study and who remain unable to open their affected hand are better able to sense and move their affected arm after 10-15 weeks of treatment with a new robotic therapy device (the AMES device) and EMG biofeedback.
The purpose of this study is to assess a novel meditation program which is biofeedback reinforced (Healing Rhythms™) as a means to improving stress management in a population of nurses practicing in the hospital setting.
The purpose of this randomized, controlled trial is to examine how well biofeedback treatment works to improve constipation. The study is comparing two kinds of biofeedback treatment: 1) anorectal-specific biofeedback therapy and 2) generalized biofeedback therapy using relaxation techniques. The study will also examine which medical and psychological factors determine biofeedback success for treating constipation, such as bowel habits, emotional reactions to constipation, and levels of stress and psychological distress.
The objective of this study is to determine the efficacy of a portable biofeedback device on improving sleep latency and other sleep variables such as nocturnal awake time and daytime functioning in persons with primary insomnia.
A growing body of evidence suggests that the symptoms of many fibromyalgia syndrome (FMS) sufferers might be the result of an imbalance in one of the major stress response systems, the autonomic nervous system. Thus respiratory sinus arrhythmia (RSA) biofeedback, which has shown promise in other conditions associated with an autonomic nervous system imbalance, could be effective in FMS. With the aid of sensors and computers, biofeedback involves modifying and/or learning how to control normally involuntary processes like blood pressure, heart rate and the autonomic nervous system through relaxation and breathing. The goal of this study is to test the effectiveness of a 10-session RSA biofeedback treatment for the symptoms of fibromyalgia. Forty patients receiving the RSA biofeedback treatment will be compared to 40 patients receiving another form of biofeedback thought to be minimally helpful (control group). Later, control group patients will also receive the RSA biofeedback treatment. We will study improvement in symptoms like pain, fatigue, sleep disturbance and depression in the RSA biofeedback group and compare these improvements to those in the control group. We will also assess whether these improvements persist over time and what if any changes in the autonomic nervous system result from the treatment.
Constipation affects 4% of adults in the United States (U.S.). An estimated half of constipated patients are unable to relax pelvic floor muscles during defecation, a type of constipation called pelvic floor dyssynergia (PFD). Biofeedback has been recommended for the treatment of constipation because uncontrolled studies over the past 10 years suggest that these treatments are as effective as medical or surgical management and involve no risk. However, placebo-controlled trials are still lacking. The aims of this study are: * to compare biofeedback to alternative therapies for which patients have a similar expectation of benefit; * to identify which patients are most likely to benefit; and * to assess the impact of treatment on quality of life.
Fecal incontinence affects 2% of adults in the United States. Biofeedback has been recommended for the treatment of fecal incontinence because uncontrolled studies over the past 25 years suggest that these treatments are as effective as medical or surgical management and involve no risk. However, placebo-controlled trials are still lacking. The aims of this study are: (1) to compare biofeedback to alternative therapies for which patients have a similar expectation of benefit; (2) to identify which patients are most likely to benefit; and (3) to assess the impact of treatment on quality of life.
The purpose of this study is to determine whether the addition of Biofeedback-Assisted Relaxation to standard medication treatment improves outcomes for children with a specific type of recurrent abdominal pain (i.e., eosinophilic gastroenteritis).