Active clinical trials for "Spinal Cord Injuries"

Although conventional risk factors for coronary heart disease (CHD) have been identified and routinely used to determine risk for CHD in the general population, a systematic approach to determine population-specific risk for CHD has not been performed prospectively in those with SCI. CHD is a leading cause of death in spinal cord injury, occurring at younger ages than in the able-bodied population. Conventional risk factors for CHD are high serum concentrations of low-density lipoprotein (LDL), low serum concentrations of high-density lipoprotein (HDL), diabetes mellitus (DM), positive smoking history, and positive family history of premature CHD. Coronary Artery calcification (CAC) is a commonly occurring phenomenon that does not necessarily indicate significant obstructive disease. Studies have shown that a strong association exists between coronary calcification and coronary heart disease. The purpose of this study is to compare the CAC scores in persons with SCI with a historical control group of able-bodied persons from a national data base who will be matched for conventional risk factors for coronary artery disease (CAD) and to determine the relationship between CAC scores and conventional and emerging risk factors for CAD. Additionally, postprandial lipemic (elevated levels of lipids following ingestion of food) responses among individuals with SCI and control subjects will be compared, as well as the response of inflammatory markers following a high fat meal. Participants will only be tested once for these parameters.

The purpose of this study is to develop and field-test new tools for diagnosis and hazard assessment of cardiometabolic risk (CMR) in people with chronic spinal cord injury (SCI) and to advance the evidence base with much needed information on CMR and cardiovascular disease (CVD) burden in people with SCI. These data can be used to develop screening guidelines for early identification and prevention of CMR in SCI, as well as targeted approaches to primary disease management.

Traumatic spinal cord injury is a common injury to the spine and can lead to a clinical syndrome called central cord syndrome (CCS). CCS is an incomplete spinal cord injury where one starts to lose more motor function in the upper rather than lower extremities. It affects a wide range of the population from the young to the old. However, the natural history of CCS is poorly understood. Research has shown that the injury resulting in CCS might be due to the pinching or compressing of the spinal cord. This creates damage to a part of the spinal cord and creates difficulties in the signal getting through. We believe that we can gain a better understanding of the natural history of incomplete spinal cord injury as well as the recovery process. It is possible to track many changes in the brain and motor function through a variety of methods. One can track the concentrations of different chemicals (metabolites) by using magnetic resonance spectroscopy (MRS), changes in brain activation by using functional magnetic resonance imaging (fMRI) and thread-like nerve fibers in the spine by using diffusion tensor imaging (DTI). In our study we will be detecting differences in brain metabolism and activation of different parts of the brain during specific movement and in the nerve fibers in the brain. We hypothesize that there will be decreased levels of N-acetylaspartate (NAA, a putative marker of neuronal function) and decreased levels of glutamate (the primary excitatory neurotransmitter) in the motor cortex in patients with CCS when compared with controls. Over time, we hypothesize that the normalization of metabolite levels will correlate with the extent of neurologic recovery. We also hypothesize a reorganization of brain activation patterns with time such that patients will show increased volumes of activation in the motor cortex with recovery and that this will correlate with the extent of neurologic outcome. Over time, we predict that there will be normalization of the fibre track anatomy that will correlate with neurological recovery.

In persons with SCI, because of inherent considerations, the use of mechanical stimulation has not been studied to determine improvement in bone mass. To achieve maximum transmission of the vibration from a vibrating plate to the lower body, the legs must be extended and the feet firmly placed against the surface plate of the device. Thus, these logistical considerations must be addressed to perform this mechanical intervention in persons with SCI. In those with complete or almost complete motor injury, there is lack of musculoskeletal function below the level of the lesion, which would prevent rigid straight leg extension and pressing one's feet against a surface, regardless of the angle of tilt that would permit adequate transmission of impulse in an able-bodied individual (preliminary data). However, in one subject with SCI, there was measurable, albeit low level, transmission of vibration with increasing angles of tilt (preliminary data). Because of the ability to transmit some signal in an individual with complete SCI, the possibility exists that with forms or mechanical support/manipulation, greater signal transmission may be possible. The study will be able to determine the best angle to transmit mechanical vibration through the lower body of SCI patients.

Individuals with neurological deficiencies such as those who have spinal cord injury, stroke, traumatic brain injury, Parkinson's disease, and multiple sclerosis often lose their ability to ambulate over ground. Loss of functional mobility not only impedes everyday life, but may also affect many systems and organs in the body. The investigators are interested in obtaining a wide variety of data in order to obtain a better understanding of changes that occur as a result of receiving Lokomat therapy. The investigators will be studying body composition, cardiac, pulmonary, endocrine, metabolic, and molecular changes after a 12-week clinical therapy program.

The purpose of the study is to investigate inflammatory and other substances that may be elevated in the blood and blood cells following spinal cord injury (SCI). These substances will be evaluated in samples from people who have had a spinal cord injury due to trauma (e.g. car accident or a fall) within the first week (acute) or at least one year ago (chronic). Specifically, the study will evaluate the presence and levels of a protein, macrophage migration inhibitory factor (MIF). MIF is released by cells and has a specific effect on the way cells behave, communicate and work together. In several other medical conditions, MIF is known to increase inflammation in the body. By comparing blood samples from individuals with spinal cord injury and uninjured (no spinal cord injury) individuals, the investigators will try to find out if MIF levels are increased in people with SCI. Investigators will also use these samples to measure other proteins that increase inflammation in the body and to see if the biological activities of MIF can be reduced in a test tube by adding other substances to the blood samples. It is hoped that this study of MIF and other proteins related to inflammation will help improve the treatment of SCI in the future. We hope to enroll a total of 312 subjects in this study (50 with acute spinal cord injury, 125 with chronic spinal cord injury, and 137 uninjured individuals).

The purpose of the study is to improve a questionnaire (the Pain Quality Assessment Scale) used for measuring different types of pain people may experience. An improved version of this questionnaire will help researchers better understand the impact of pain treatments on different types of pain through the use of this questionnaire.

The purpose of this study is to evaluate whether scheduled telephone intervention with individuals with spinal cord injury (SCI) and their caregivers in the first year following discharge from acute inpatient rehabilitation will reduce rehospitalizations and emergency room visits as well as improve adjustment to SCI.

The purpose of this study is to determine how blood pressure and blood flow are controlled during head-up tilt in a semi-upright position. In this investigation we are studying blood pressure and blood flow to the brain, with and without a medication which lowers blood pressure (Vasotec). We will determine how persons with a spinal cord injury are able to maintain blood flow to the brain (not get dizzy) as they assume a more upright position and their blood pressure decreases.

The lower urinary tract is innervated by the autonomous (sympathetic, parasympathetic) and the somatic nervous system. Afferent information from the lower urinary tract (LUT) (e.g. filling state and volume of the urinary bladder) is conducted via the dorsal roots to the sacral spinal cord and from there to the pontine micturition center (PMC) in the brain stem. The PMC has several connections to other cortical areas. These complex interactions with the cortex enable voluntary control of the LUT and are crucial for urinary continence. The integrity of this neuronal circuit is crucial for an undisturbed function. Deterioration of the nerve fibers due to a systemic neurological disease (e.g. spinal cord injury) can affect LUT function. Neurogenic lower urinary tract dysfunction can lead to urgency, urge incontinence, reduced bladder capacity and secondary deterioration of the upper urinary tract (i.e. kidneys). First-line therapy of neurogenic detrusor overactivity contains antimuscarinic treatment. In case of side effects or remaining detrusor overactivity, nerve stimulation (e.g. sacral neuromodulation and in effect nerve tibialis stimulation) is an accepted therapy option. The precise mechanism of action of these neuro-modulatory procedures is still unknown. Utilizing state-of-the-art neuroimaging techniques, we intend to investigate the functional activation pattern after afferent tibialis nerve stimulation as well as the association with the architecture of the sacral roots. We aime to get a better insight into functional neuromodulation and central nervous processing. The study aim is to evaluate the feasibility in healthy subjects as a pilot study for the application of these method in patients with chronic, incomplete spinal cord injury.