View clinical trials related to Nerve Degeneration.
Filter by:This is a research study that aims to examine whether Veterans with mild Traumatic Brain Injuries are at risk for dementia by studying their memory, brain wave activity, brain structure and proteins that can be elevated after brain injury and in dementia.
This study is a prospective study with a mean of 7-year follow-up interval, aims to monitor the progression of α-synucleinopathy neurodegeneration by the evolution of prodromal markers and development of clinical disorders in patients with idiopathic REM Sleep Behavior Disorder (iRBD) and healthy controls.
Accumulating evidence indicates that inflammation is prominent both in the blood and central nervous system (CNS) of Alzheimer's disease (AD) patients. These data suggest that systemic inflammation plays a crucial role in the cause and effects of AD neuropathology. Capitalizing on the experience from a previous clinical trial with thalidomide, here, the investigators hypothesize that modulating both systemic and CNS inflammation via the pleiotropic immunomodulator lenalidomide is a putative therapeutic intervention for AD if administered at a proper time window during the course of the disease.
Wolfram syndrome (WFS; OMIM #222300) is a rare autosomal recessive disease clinically defined in 1938 as the combination of childhood-onset insulin dependent diabetes, optic nerve atrophy, diabetes insipidus and deafness. Based on early descriptions, neurological features were thought to appear later in the disease with death occurring in middle adulthood. Importantly, the major causative gene (WFS1) was identified in 1998. This discovery allowed researchers to determine that the WFS1 gene encodes the protein wolframin, which helps protect cells from endoplasmic reticulum (ER) stress-mediated apoptosis, potentially via intracellular calcium homeostasis. Pathogenic mutations in WFS1 can result in death or dysfunction of cells that are under high ER stress, such as insulin-producing pancreatic β cells, causing insulin dependent diabetes. In addition, knowing the causative gene has allowed researchers to identify patients by their WFS1 mutation rather than the classic set of symptoms, leading to the increasing realization that the WFS1-related phenotype (including neurologic symptoms) is much more variable than previously understood. The first iteration of this grant (HD070855 "Tracking Neurodegeneration in Early Wolfram Syndrome") contributed to this shift in understanding. In this time, the research team has built a successful annual research clinic for WFS, that has met or exceeded recruitment goals for patients and controls, validated a clinical severity rating scale for WFS, described an unexpectedly early neurophenotype of reduced balance, smell identification and ventral pons volume, identified alterations in traditional diffusion tensor imaging (DTI) metrics that suggest hypomyelination as a pervasive neuropathological feature of WFS and provided justification for the selection of two primary outcomes (visual acuity and ventral pons volume) in a newly funded clinical efficacy study in WFS (Barrett, PI).
The purpose of this research study is to understand the factors that underlie changes in thinking and memory with increasing age. The investigators will test the usefulness of MRI, PET, and cognitive testing in detecting subtle changes in the brain that precede cognitive decline. An addendum to this study includes additional PET scans to examine the relationship between tau protein in the brain and cognitive decline. Tau is a protein that is known to form tangles in the areas of the brain important for memory, and these tau tangles are a hallmark of Alzheimer's disease. This sub-study research aims to look at the tau accumulation in the brain using an investigational drug called MK-6240, which is a radio tracer that gets injected prior to a positron emission tomography (PET) scan.
Beyond white matter pathology, grey matter damage is considered as a key player in disability onset and progression in Multiple Sclerosis (MS). The underlying substratum of grey matter damage is complex and pluriform, ranging from cortical demyelinating lesions, synapse and dendrite disappearance to neuronal cell death. Current Magnetic Resonance Imaging MRI techniques fail to fully assess and quantify grey matter pathology in this disease. The development of a quantitative marker of neurodegeneration for MS patients would allow: (i) to better understand the pathophysiological mechanisms underlying the distinct forms of MS; (ii) to stratify patients according to their prognosis; and (iii) to evaluate new therapies aimed at promoting neuroprotection. would allow to better understand the mechanisms underlying the distinct forms of MS, to stratify patients according to their prognosis, and to evaluate new therapies aimed at promoting neuroprotection.
Alzheimer's disease (AD) and frontotemporal dementia (FTD) are two of the most common types of age-related neurodegenerative disorders. Identifying at-risk patients and gauging disease progression in a non-invasive manner would be invaluable. Early and correct diagnosis is crucial for coordinating supportive care, patient expectations, caregiver arrangements and family planning. In addition, as treatments become available, beginning therapy early in the disease before symptoms become severe will be important. Multimodal ocular imaging (MOI) includes an ophthalmic (eye) exam and eye photographs to evaluate different layers of the retina, which is the light sensing layer of the eye. Newer technologies make it possible to visualize the disease process occurring in AD and FTD by using MOI to look at the retina, since the retina is fundamentally an outward extension of the brain itself. This study will attempt to correlate signs of disease in the retina, as determined by MOI, with plaque buildup in the brain as seen by imaging. This will demonstrate the sensitivity and specificity of MOI for diagnosing AD and FTD in a noninvasive manner.
Research regarding the effects of anesthesia on the central nervous system remain controversial with some studies suggesting a neurotoxic effect and others indicating a neuroprotective effect. In recent years numerous neuronal proteins have been found to be useful tools for diagnosis and prognosis of cerebral tissue damage. Among these neuronal proteins are the following markers: Neuron Specific Enolase (NSE), Tau protein, Glial Fibrillary Acidic Protein (GFAP), Ubiquitin Carboxy-Hydrolase L1 (UCH-L1). BIS is a non-invasive brain monitoring technology which monitors the depth of anesthesia. In this randomized clinical trial, we aim to examine the effect of anesthetic method (General anesthesia and neuroaxial anesthesia) on neuronal damage as measured by NSE serum levels. One hundred and forty patients aged 18 and above undergoing Transurethral resection of the prostate, Trans Urethral Resection of the Bladder Tumor, Tension Free Vaginal Tap , Trans Obturator Tension Free Vaginal Tap and pelvic floor repair surgeries will be enrolled in the study. Patients will randomly be assigned to undergo the study either under general anesthesia or with neuroaxial anesthesia. Participants will be monitored using the BIS monitor, to measure the depth of anesthesia. Additionally, 9 cc of venous blood be collected from each participant in the surgery room prior to anesthesia induction, throughout anesthesia and one hour following surgery in the PACU in order to assess NSE levels.
This study is a prospective study with a mean of 5-year follow-up interval, aims to monitor the progression of α-synucleinopathy neurodegeneration by the evolution of prodromal markers and development of clinical disorders in first-degree relatives (FDRs) of idiopathic REM Sleep Behavior Disorder (RBD) patients and healthy controls.
To generate pilot data to investigate the potential to use in vivo iron- and neuromelanin-quantification as imaging tools for the diagnostic evaluation of movement disorders with predominant dystonia / parkinsonism. To this end we are planning to compare the MR imaging neuromelanin and iron-pattern and content in midbrain, striatum and further brain structures in clinically similar entities and respective, sex- and age-matched healthy controls.