View clinical trials related to Infectious Encephalitis.
Filter by:Carotid artery stenosis is observed in about 3% of ≥ 60 years subjects and accounts for around 10-20% of all ischemic strokes. Beyond the degree of stenosis, plaque composition affects the risk of ischemic stroke. Identification of patients with vulnerable plaques at higher risk of stroke who might benefit from carotid revascularization is crucial. A growing body of evidence suggests that the lectin pathway of the complement system, and especially the ficolin-2, is involved in atherosclerosis. It has been hypothesized that circulating levels of ficolin-2 increase during chronic inflammatory conditions (i.e. growing atherosclerotic plaque) whereas they fall during sub-acute or acute inflammatory conditions (i.e. plaque rupture and acute ischemic stroke) because of consumption (binding to targets). Therefore, ficolin-2 has been proposed as a biomarker informing on the specific state of the plaque. However, in acute ischemic stroke due to carotid stenosis, both plaque rupture and stroke injury contribute to lectin pathway activation, thus affecting circulating levels of ficolin-2. Until now, the relative contribution of plaque and brain inflammation on circulating levels of ficolin-2 has not been documented. In the present study the investigators aim to assess the association between circulating levels of ficolin-2 and carotid and brain inflammation on [18F]DPA-714 positron emission tomography (PET)/MRI in patients with transient ischemic attack or acute ischemic stroke due to carotid stenosis. For that purpose, the investigators intend to include 30 patients with transient ischemic attack or acute ischemic stroke due to ≥ 50%. carotid stenosis. Each patient will have a measure of plasmatic level of ficolin-2 as well a [18F]DPA-714 PET/MRI to quantify the fixation of the radiotracer on carotid and brain.
Spinal Cord Injury (SCI) leads to alterations in brain structure and function by spinal nerve damage, secondary inflammatory responses, and by the consequences of living with paralysis and neuropathic pain. Physical inactivity due to lower body paralysis rapidly leads to loss of muscle, and risk of heart disease. The leading cause of death after a spinal cord injury is cardiovascular disease, and just a year after injury, those with SCI have a peak exercise capacity half that of the unfit general population. The good news is that aerobic exercise reduces the risk of chronic metabolic and cardiorespiratory diseases, reduces inflammation and pain, and increases mood and quality of life. Exercise can also reduce brain inflammation, enhance endogenous analgesia, and increases the size of the hippocampus. The issue is that muscle paralysis in SCI restricts the ability to achieve the levels of exercise that is necessary for broad analgesic, anti-inflammatory and neuroprotective benefits. Arm exercise can have some effects on heart and lung capacity, but the small muscle mass is insufficient to produce more than modest aerobic work. With functional electrical stimulation (FES), leg muscles that are paralyzed can be made to contract, thereby allowing more of the body to be exercised. The full rowing stroke is produced by both the (stimulated) legs and arms, increasing the active muscle mass and resulting in an aerobic work-out that is intensive enough to improve heart, lung, and - maybe - brain function. In this clinical trial of sub-acute spinal cord injured subjects, the investigators will study how 12 weeks of FES-RT, in comparisons to 12 weeks of wait-list, changes pain, brain structure, endogenous opioid function and brain inflammation. The investigators will measure changes using positron emission tomography and magnetic resonance imaging. The investigators hypothesize a decrease in pain interference, an increase in hippocampal volume, increased endogenous opioid transmission in the periaqueductal gray, and decreased hippocampus neuroinflammation.
This research study will evaluate the effectiveness and estimate the feasibility of administering an investigational drug called 'CN-105' (the study drug), to prevent postoperative cognitive decline, delirium (serious confusion) and underlying brain inflammatory and brain activity changes in adults 60 years and older undergoing surgery.
The primary objective of the study is to evaluate the safety and immunogenicity of non-adjuvanted and adjuvanted monovalent VEE VLP Vaccine in healthy adults (ages 18-50 years) when administered via intramuscular (IM) injection at escalating doses of 2 μg, 10 μg, and 20 μg as a 2-dose primary series (Day 0, Day 28) with a Day 140 booster dose. The secondary objective of the study is to evaluate immunogenicity of the vaccine at the aforementioned time points
For this project, neflamapimod and placebo will be provided free of charge by the EIP company (www.eippharma.com). Neflamapimod is currently tested in 2 clinical trials in AD, one in Europe (The Netherlands) and one in the USA (clinical trials.gov/VX-745). The company commenced in May 2015 dosing in two phase 2a clinical studies in patients with Early AD: one in the Netherlands that is focused on PET amyloid imaging as the primary biomarker of drug effect, and one in the US (California) that is focused on Cerebrospinal fluid (CSF) evaluation to determine CSF drug concentrations and effects on inflammatory markers and disease biomarkers. Pharmacokinetic evaluation in these patients has demonstrated blood drug concentration levels in the predicted therapeutic range; and importantly, the data from the US study demonstrate that the drug achieves target drug concentrations in CSF, thus confirming the drug robustly enters the brain in humans. The present project offers us a unique chance to test this promising drug in AD patients. The aim of the study is to focus on PET neuroinflammation imaging as the primary biomarker of this drug effect. The chosen biomarker for imaging neuroinflammation in patients is [1 8F]-DPA714.
Background: - Brain inflammation due to high alcohol intake may affect thinking, memory, and concentration. Researchers want to measure this using positron emission tomography (PET). Objective: - To study how excessive alcohol consumption affects brain function. Eligibility: - Adults 30-75 years old who are moderate or severe alcohol drinkers. - Healthy volunteers. Design: - Participants will be screened with medical history, physical exam, interview, and blood and urine tests. Their breath will be tested for alcohol and recent smoking. - Phase 1: - Participants will stay in the hospital 3 days. They will have blood and heart tests and daily urine tests. - A small plastic tube will be inserted by needle in each arm. One will go in a vein, the other in an artery. - Participants will have 2 PET scans with 2 different radioactive compounds. Participants will lie on a bed that slides in and out of the scanner with a cap on their head. - Participants will have magnetic resonance imaging (MRI) scans. Participants will lie in the scanner either resting with their eyes open or while performing an attention task. - Participants will have tests of memory, attention, concentration, and thinking. They may answer questions, take tests, and perform simple actions. - Phase 2 of the study will only be done if Phase 1 results show brain inflammation. - Phase 2 will repeat Phase 1. - For healthy volunteers, Phase 2 will begin 3 weeks after Phase 1. - Other volunteers must not have alcohol for at least 3 weeks and stay in a hospital up to 4-6 weeks between Phase 1 and Phase 2. After Phase 2, they will have 5 follow-up calls over 3 months.