Active clinical trials for "Spinal Cord Injuries"

The goal of this study is to improve our understanding of speech production, and to translate this into medical devices called intracortical brain-computer interfaces (iBCIs) that will enable people who have lost the ability to speak fluently to communicate via a computer just by trying to speak.

Children who suffer a spinal cord injury in the neck region have difficulty using their hands due to paralysis and/or weakness of their arms and hand muscles. The purpose of this project is to test the safety, comfort, and practicality of a new therapy that stimulates the spinal cord to facilitate activation of arm and hand muscles while practicing grasping, pinching, and reaching movements. The long-term goal is to provide better therapies that will improve the ability of children with SCI to more successfully play and accomplish everyday tasks using their arms and hands, similar to before their injury.

In this study patients with Multiple Sclerosis or Spinal Lesions will participate in two different types of treatments that aim to improve sexual and sentimental life. Behavioral (via questionnaires) and brain (via high-density electroencephalogram) effects associated with treatment will be studied.

This study will assess how the serotonin precursor, 5-HTP, alter nervous system excitability and motor function in individuals with spinal cord injuries of differing chronicity and severity. Participants will visit the lab on 4 separate occasions where they will be administered four different drugs in a randomized, double-blinded, placebo-controlled crossover design.

Intraspinal pressure monitoring has been advanced as a potential technique for evaluating spinal cord perfusion after traumatic spinal cord injury. In this study, the investigators aim to validate the technique for insertion of a fiberoptic pressure monitoring device in the subarachnoid space at the site of injury for measurement of intraspinal pressure and spinal cord perfusion pressure. The primary objective of this study is to validate the methodology of invasive intraspinal pressure monitoring to derive parameters for optimal spinal cord perfusion pressure, spinal cord reserve capacity and spinal reactivity index using data obtained during the patient's stay in the intensive care unit. Secondary objectives of this study will be to a) evaluate the safety of invasive intraspinal pressure monitoring, b) prospectively evaluate the overall relationship between spinal cord perfusion pressure and functional outcomes in patients with acute traumatic spinal cord injury and c) evaluate the relationship between spinal cord perfusion pressure, motor evoked potentials and functional outcomes after incomplete spinal cord injury.

This project adds to non-invasive BCIs for communication for adults with severe speech and physical impairments due to neurodegenerative diseases. Researchers will optimize & adapt BCI signal acquisition, signal processing, natural language processing, & clinical implementation. BCI-FIT relies on active inference and transfer learning to customize a completely adaptive intent estimation classifier to each user's multi-modality signals simultaneously. 3 specific aims are: 1. develop & evaluate methods for on-line & robust adaptation of multi-modal signal models to infer user intent; 2. develop & evaluate methods for efficient user intent inference through active querying, and 3. integrate partner & environment-supported language interaction & letter/word supplementation as input modality. The same 4 dependent variables are measured in each SA: typing speed, typing accuracy, information transfer rate (ITR), & user experience (UX) feedback. Four alternating-treatments single case experimental research designs will test hypotheses about optimizing user performance and technology performance for each aim.Tasks include copy-spelling with BCI-FIT to explore the effects of multi-modal access method configurations (SA1.3a), adaptive signal modeling (SA1.3b), & active querying (SA2.2), and story retell to examine the effects of language model enhancements. Five people with SSPI will be recruited for each study. Control participants will be recruited for experiments in SA2.2 and SA3.4. Study hypotheses are: (SA1.3a) A customized BCI-FIT configuration based on multi-modal input will improve typing accuracy on a copy-spelling task compared to the standard P300 matrix speller. (SA1.3b) Adaptive signal modeling will allow people with SSPI to typing accurately during a copy-spelling task with BCI-FIT without training a new model before each use. (SA2.2) Either of two methods of adaptive querying will improve BCI-FIT typing accuracy for users with mediocre AUC scores. (SA3.4) Language model enhancements, including a combination of partner and environmental input and word completion during typing, will improve typing performance with BCI-FIT, as measured by ITR during a story-retell task. Optimized recommendations for a multi-modal BCI for each end user will be established, based on an innovative combination of clinical expertise, user feedback, customized multi-modal sensor fusion, and reinforcement learning.

The purpose of this study is to test the preliminary effects of an 8-week mobile application-based program (SupportGroove) developed for persons with spinal cord injury and their romantic partners.

Accurate movement execution is a result of a complex interplay between various muscle groups whose activity is controlled by different areas of the central nervous system. Besides the corticospinal system, the phylogenetically old reticulospinal system is a key motor system controlling different elementary movements including posture, locomotion and reaching across all mammals. In contrast to the extensively investigated corticospinal system, there is only sparse knowledge on the motor physiology of the functionally important reticulospinal system in humans. Reticulospinal motor control can be assessed with the StartReact paradigm which is based on the activation of reticulospinal motor circuitries by startling acoustic stimuli. The StartReact phenomenon is characterized by a shortening in movement reaction time which is mediated by a startle-triggered, early release of a planned motor program by the reticulospinal system. Thus, StartReact is a unique tool to examine reticulospinal involvement on human motor control under physiological and pathological conditions. StartReact assessments will be supplemented by comprehensive 3-D kinematic analysis and muscle activity recordings (i.e. electromyography) to gain quantitative insights into reticulospinal movement control. The first objective of this clinical study is to gain more insights into the mechanisms underlying StartReact and to advance the knowledge on reticulo-spinal motor physiology regarding different movement tasks (i.e. simple single-joint movements, complex multi-joint movements and bilateral hand movements) in healthy subjects. The findings of these experiments will provide new insights into proximal-distal, flexor-extensor and upper-lower extremity gradients in reticulospinal motor control of healthy subjects. Moreover, the results will expand the StartReact paradigm to complex, functionally more relevant movements (i.e. reaching and stepping tasks requiring endpoint accuracy; co-operative, bilateral hand movements) for which the involvement of the reticulo-spinal system is not yet understood. The second goal of this project is to use the StartReact paradigm to shed more light onto the role of reticulospinal plasticity in functional recovery of patients with spinal cord injury (SCI). Whereas preclinical findings emphasize a remarkable potential of the reticulospinal system for neuroplastic adaptations underlying functional recovery, there is only little evidence from clinical trials in the field of SCI. First, the study aims at monitoring StartReact effects in hand and leg muscles of patients with acute SCI over a period of 6 months. Simultaneous tracking of StartReact effects and motor recovery will allow to closely relate processes of reticulospinal plasticity to functional recovery in patients with acute SCI. Second, the focus will be on the re-weighting of descending motor control (i.e. cortico- vs. reticulospinal system) in response to SCI and investigate the distinct contributions of the cortico- and reticulospinal system to motor recovery in patients with chronic SCI. The findings of this project will advance the mechanistic understanding on the motor physiology and neurorestorative capacity of the reticulospinal system in humans. New insights from these projects will hopefully translate into a better exploitation of this important motor system in clinical trials that aim to improve motor recovery in patients with SCI.

The new training device, the eccentric arm-crank, will be examined for its training effects in athletes with a spinal cord injury (SCI) by this project. That the training device can be used in patients with paraplegia in the future, the so-called "testing of the applicability of this concept" will be carried out during this study. Fourteen volunteer, healthy athletes with SCI are first tested for their upper body performance, followed by a training phase over 20 trainings and at the end the performance data is collected again. The training intensity and duration is continuously increased during the training phase.

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.