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Spinal Cord Injury, Acute
This study is a prospective multi-center trial designed to determine the safety profile and efficacy of modest (33ΒΊC) intravascular hypothermia following acute cervical (C1 to C8) Spinal Cord Injury (SCI).
Spinal Cord Injuries Β· Cerebral Palsy Β· Spinal Dysraphism
This study will assess the benefits of using mobile health system designed for individuals with chronic and complex health conditions (such as those with Spinal Cord Injury,Cerebral Palsy, Spina Bifida, and Traumatic Brain Injury) to improve their wellness and self-management skills compared to those who receive standard of care only.
Spinal Cord Injury, Chronic Β· Spinal Cord Injury Cervical Β· Spinal Cord Injury Thoracic
Spinal cord injuries (SCI) can seriously affect a person's ability to breathe. This happens because the injury can damage the nerves that control the muscles used for breathing. As a result, people with SCI often face breathing problems, a higher risk of lung infections, and even early death. While breathing exercises can help strengthen these muscles, they often aren't intense enough to make a big difference, especially in people with long-term injuries. This research project is exploring a new way to improve breathing in people with chronic SCI. The goal is to "wake up" the remaining nerve pathways that still connect the brain and spinal cord to the breathing muscles. By doing this, the investigators hope to make breathing exercises more effective and improve overall respiratory health. The investigators are testing a combination of two non-invasive (non-surgical) techniques: Transcutaneous Spinal Cord Stimulation (tSCS): This uses small electrical pulses delivered through the skin to stimulate the spinal cord and help activate the muscles used for breathing. Hypercapnic-Hypoxia Protocol (HiCOβ-AIH): This involves breathing air with lower oxygen and higher carbon dioxide for short periods. This naturally increases the brain's drive to breathe and may help strengthen the breathing muscles. The investigators believe that using these two techniques together will "prime" the nervous system, making it more responsive to breathing exercises. This could lead to better outcomes for people with SCI. In addition to testing this treatment, the investigators are also collecting saliva and blood samples to look for biomarkers-biological clues that might help predict who will benefit most from this therapy. These include genetic markers and signs of nerve damage in the blood. Who Can Participate The investigators are looking for adults aged 18 to 70 who: Have had a spinal cord injury for at least one year. Have an injury between the neck and upper back (from C3 to T8). Have an incomplete injury (some nerve function remains). Are medically stable and cleared by a doctor. Have at least a 20% reduction in breathing strength. What Participants Will Do Each participant will complete four rounds of treatment. Each round includes four days in a row of therapy, followed by a three-week break before the next round. Each daily session lasts about two hours and includes: Breathing special air mixtures (low oxygen and high carbon dioxide) for short periods, followed by normal air. A short break. Then, spinal cord stimulation combined with breathing exercises that use resistance (like breathing through a straw). What the Investigators Will Measure The investigators will track: Breathing ability using lung function tests and pressure measurements. Nerve activity using brain and spinal cord stimulation to see how well the diaphragm (the main breathing muscle) responds. Safety by monitoring oxygen levels, heart rate, blood pressure, and breathing responses during each session. Biological Samples Participants will provide: A one-time saliva sample for genetic testing. A one-time blood sample to look for markers of nerve injury. Why This Matters This study could lead to new, non-invasive treatments that improve breathing and quality of life for people living with spinal cord injuries. By identifying who is most likely to benefit from this therapy, the investigators can also move toward more personalized and effective care in the future.
Spinal Cord Injuries (SCI)
What is the ultimate applicability of the research? Individuals with SCI face several challenges when trying to engage in exercise following injury. Barriers to engagement include cost, transportation, and lack of SCI accessible resources. At the same time, individuals with SCI are at risk of developing negative health consequences (e.g., cardiovascular disease) associated with physical inactivity. A critical need exists to improve relevant, accessible, and sustainable home-based exercise interventions for individuals with SCI to lower the risk of developing secondary comorbid diseases from physical inactivity and to promote wellness. This research will investigate a fun and novel in-home virtual reality system aimed toward improving physical fitness of individuals SCI with the ultimate goal of improving physical, emotional, and psychosocial quality of life. Virtual reality gaming has been used for a long time to improve physical fitness, but there have yet to be virtual reality games designed specifically for individuals with SCI. The explicit aim of this research is therefore to develop a therapeutic technology that will be widely accessible to individuals with SCI. What persons with SCI and/or their caregivers will it help, and how will it help them? We aim to provide a readily available exercise platform for individuals with SCI, across a spectrum of physical function. Research has shown that individuals with SCI are particularly prone to be physically inactive. The consequences of physical inactivity have been well documented and include negative outcomes in physical, psychological, and social health with reduced quality of life. For the current study, we will refine our existing virtual reality exercise platform, VR-Move with a focus on non ambulatory individuals with bilaterally preserved C6 function. Our focus on using the exercise platform for this cohort of the SCI population is meant to provide a basis for developing and catering to the platform for higher levels of SCI injury (higher quadriplegic). From our previous work with virtual reality interventions in SCI, we recognize that this product can be widely used by individuals across the age spectrum independently of their home environment. What are the potential clinical applications, benefits, and risks? The proposed virtual reality exercise platform, VR-Move, is intended to provide one of the few accessible exercise modalities designed specifically for individuals with SCI and is readily adaptable across the clinical spectrum - including clinic and self-guided home use. There are no known risks associated with this research. How will the pilot clinical trial advance the research findings along the translational spectrum? This project aims to refine and assess timely therapeutic technology with the specific intention of translating study findings into a clinically validated, widely accessible health product that can be deployed and implemented within the home. The project likewise demonstrates collaboration between academia, industry (a veteran-owned business), and veteran SCI communities. Project completion will offer initial validation of a novel health promoting modality (i.e., virtual reality exercise) informed by individuals living with SCI and experts in SCI to be relevant and responsive to specific health/exercise needs of persons living with SCI. Larger clinical trial testing will subsequently inform product commercialization and dissemination. The resulting platform, developed for unattended in-home use, is expected to make a meaningful contribution to SCI health and physical fitness, accessibility, and quality of life. What is the projected time it may take to achieve a person-related outcome? The team is purposefully refining the existing exercise platform, VR-Move, so that it can be easily implemented within people's homes or in clinic settings. Pending findings from the pilot clinical study, this exercise platform would be available immediately to individuals with SCI What are the likely contributions of the proposed research project to advancing the field of SCI research, patient care, and/or quality of life? The proposed study may make significant contributions across several areas. First, it will facilitate fruitful clinical data and basic lines of scientific inquiry regarding the application of the physical activity paradigm. The study will also increase our knowledge regarding the importance of consumer advocate-driven research for individuals with SCI. Second, low-activity following SCI is consistently associated with reduced quality of life among individuals with SCI and their families; access to an inexpensive portable intervention will therefore significantly improve quality of life among those affected by low-activity SCI.
Spinal Cord Injury
To achieve our specific aims and hypotheses we will conduct a parallel group mixed methods randomized control trial comparing participation in the TEEMS program with exercise via asynchronous video library equivalent (control). The use of mixed methods will allow for the integration of quantitative findings with the qualitative, lived perspective of participants to provide a comprehensive analysis of the tele-exercise program outcomes. All aspects of the study from recruitment, screening, data collection, tele-exercise delivery and team meetings will be virtual to promote access and inclusion by removing barriers and promoting engagement. This study will compare our live group TEEMS program with individual pre-recorded exercise videos. We created TEEMS with the intention of maximizing exercise independence for participants, which decreases need for caregivers during physical activity. The design and participation in TEEMS is meant to increase personal factors that facilitate participation in exercise. These personal factors include confidence and positive associations with exercise. When these personal factors are targeted, individuals with SCI are more likely to participate in physical activity, which supports overall health and QoL.
Spinal Cord Injury
The NACTN Spinal Cord Injury Registry is a network of clinical centers collecting de-identified data from patients admitted through the Emergency Department of a NACTN center at the time of injury with an initial (first time) spinal cord injury (SCI). Information will be collected on the natural history of SCI and course of treatment through the first 12 months from the date of injury or long as medically indicated. Data collected includes imaging information from CT or MRI scans, neurological and general medical outcome and rehabilitation evaluation. No intervention is given other than standard of care for spinal cord injury, intensive monitoring and frequent follow up care.
Spinal Cord Injuries (SCI) Β· Spinal Cord Injury Β· Spinal Cord Injuries (Complete and Incomplete)
Caregivers of persons with Spinal Cord Injury (SCI) face increased risk of psychological distress, health problems, reduced quality of life, relationship strain, and restrictions in social and work participation. Military caregivers (Family Caregivers of wounded or disabled Veterans) reported similar negative effects of becoming a caregiver on their physical and mental health. Using results from our previous work in mHealth interventions for individuals with SCI, we developed a dual-target intervention for both individuals with SCI and their caregivers. The overall objective of this research study is to conduct translational research focused on adapting and tailoring the interactive Mobile Health and Rehabilitation (iMHere) 2.0 system to meet the needs of Veterans with SCI and their family caregivers, expanding the psychosocial intervention, and evaluating the feasibility of implementing the iMHere system among Veterans with SCI and their family caregivers.
Spinal Cord Injuries
The overarching goal of this research study is to evaluate a sensor-enabled, just-in-time adaptive intervention (JITAI) strategy to increase and sustain physical activity levels among individuals with spinal cord injury (SCI) in their communities. A primary objective of this study is to evaluate the integration of a JITAI with a web-based physical activity intervention program. We hypothesize that the integration of web-based physical activity intervention program with JITAI will result in significantly higher physical activity levels compared to the standard web-based physical activity intervention program alone. A secondary objective of this study is to extend existing algorithms that use commercial wearable technology to robustly detect physical activity behaviors to facilitate the delivery of tailored just-in-time actionable feedback and physical activity recommendations for individuals with SCI.
Cervical Spinal Cord Injury Β· Tetraplegia
The goal of this observational study is to determine if nerve transfer surgeries improve upper extremity function and quality of life in patients with a high level cervical spinal cord injury. Participants will: * undergo standard of care pre- and post-op testing and study exams * complete pre- and post-questionnaires * undergo standard of care nerve transfer surgeries * follow-up with surgeon at 6/12/18/24/36 and potentially at 48 months * attend therapy at local therapist for up to 2 years postop.
Neurogenic Detrusor Overactivity Β· Spinal Cord Injuries
This is a first-in-human, Phase 1b/2a, open-label, dose-escalation study of a single treatment course consisting of multiple intradetrusor injections of EG110A in male and female adult participants with Neurogenic Detrusor Overactivity (NDO)-related incontinence following Spinal Cord Injury (SCI), who have persistent incontinence after standard of care therapy and who perform Clear Intermittent Catheterization (CIC) on a regular basis.
Stroke Β· Able Bodied
The goal of this study is to assess cervical (neck) reflexes by intra-operatively stimulating the neck nerve roots to evoke motor responses through their connections to spinal motoneurons. This data is critical to reveal changes to the spinal sensory modulating circuitry in neurological disorders like stroke.
Adjustment Disorder
The purpose of this study is to determine if treatment with a single dose of RE104 for Injection reduces depressive symptoms or depressive symptoms mixed with anxiety symptoms in participants with Adjustment Disorder due to cancer or other illnesses such as Amyotrophic Lateral Sclerosis (ALS), Multiple Sclerosis (MS), Parkinson's Disease (PD) or Idiopathic Pulmonary Fibrosis (IPF) as compared to active-placebo.
Wheelchair Β· Paraplegia Β· Spinal Cord Injury
The objective of this study is to determine the effectiveness of remote manual wheelchair skills training program. First, peer coaches will be enrolled and trained. Then, trainees will be enrolled into one of three interventions: intervention with remote feedback (Group 1), and a wait list control group (Group 2).
Tetraplegia Β· Spinal Cord Injury Β· Brainstem Stroke
The purpose of this research study is to demonstrate the safety and efficacy of using two CRS Arrays (microelectrodes) for long-term recording of brain motor cortex activity and microstimulation of brain sensory cortex.
Stroke Β· Spinal Cord Injuries and Disorders Β· Hemiparesis After Stroke
This study plans to use systems that have been developed by Medtronic to investigate the use of cervical spinal cord stimulation to treat adults with upper limb hemiparesis resulting from a stroke. The spinal cord stimulation (SCS) will be combined with physical training to improve arm and hand motor control. The study is divided into three phases. In the first phase, after baseline assessments, participants will undergo a Physical Training Protocol (PTP) for 6 weeks including 3 sessions of 90 mins/session per week. After receiving the Medtronic implantable system, in Phase 2, they will then repeat the same PTP program in combination with spinal cord stimulation during the entirety of each of the rehabilitation sessions. Finally, in Phase 3, participants will go home, will not be able to use the stimulation at home but will participate in monthly assessments in the laboratory in which the functionality of the Medtronic system and their motor performances will be assessed for up to 6 months.