View clinical trials related to Wounds and Injuries.
Filter by:Background: People with a traumatic brain injury (TBI) can have trouble making the best possible decisions. Researchers want to learn more about the parts of the brain that control decision making. They also want to know how these are different between people. This may help predict how people make decisions after TBI. Objective: To learn more about which parts of the brain are involved in making decisions and how decisions may be hurt after TBI. Eligibility: Adults age 18 to 60. Design: Participants will be screened with medical history and physical exam. They will also take memory, attention, concentration, and thinking tests. Participants will do up to 2 experiments. For Experiment 1, participants may have 3 scans: PET: a chemical is injected through a thin tube into an arm vein. Participants lie on a bed that slides in and out of the scanner. MRI: a strong magnetic field and radio waves take pictures of the brain. Participants lie on a table that slides in and out of a metal cylinder. It makes loud knocking noises. Participants will get earplugs. They might be asked to do a task. A coil will be placed over the head. MEG: a cone with magnetic field detectors is lowered onto participants head. After the scans, participants will perform a decision-making task. For Experiment 2, participants will perform a decision-making task before and after receiving transcranial direct current stimulation (tDCS). tDCS: wet electrode sponges are placed over participants' scalp and forehead. A current passes between the electrodes. It stimulating the brain. Participants will return 24-48 hours later to repeat the decision-making task.
We are extending the researches of Taiwan neurosurgery traumatic brain injury (TBI) database which is led by Professor WT Chiu in Taipei Medical University and will recruit mild TBI (mTBI) participants who have ever been registered in the database. This database has been established for over 15 years and contains the information of over 150000 patients. It is one of the largest TBI database in the world. TBI usually results from traffic accidents, falls or violence events. Most of the victims are young people and the victims suffer from life-threatening and mental-physical deficits. Mild TBI (mTBI) usually was neglected before because its symptoms, signs are mild and mTBI patients usually were not obtained enough initial treatment. Therefore, mTBI might result in long-term cognitive and affective impairments, such as depression, indifference, anxiety, memory impairment, loss of attention and executive function. These late effects not only decrease the life quality of patients and their family but also increase the social and medical burden. Recent epidemiology studies have pointed out that TBI would increase the risk for dementia, especially Alzheimer disease (AD) by 2-4 times. However, the association between TBI severity, number of repeats, genetic factors and onset of AD remains further investigation. Amyloid-β (Aβ) plaques and neurofibrillary tangles are the pathological hallmarks for AD. Accumulation of Aβ is considered to be the first step of pathophysilogy of AD. Compelling researches have supported TBI accelerates the formation and accumulation of Aβ. These findings could link TBI with AD but the previous researches had limitations. There was lack of mTBI pathology data so the impacts of mTBI on Aβ accumulation were still obscure. By amyloid-PET, we could study the effects of mTBI on the accumulation of Aβ and this tool could be helpful for understanding the real impacts and pathophysiological mechanisms of mTBI on AD.
Objective/Hypothesis: An eight-week course of forty low-pressure Hyperbaric Oxygen Treatment's (HBOT's) can significantly improve symptoms and cognitive function in subjects with the persistent-post concussion syndrome (PPCS) of mild traumatic brain injury (mTBI).
After a mild traumatic brain injury (mTBI) people often report balance problems. At Parkwood hospital we have noticed that balance is improved when patients with mTBI wear a weighted compression vest. This follow up pilot study looks at the immediate effects of weighted compression vests on participants with altered balance after mTBI. Participants will be recruited from the Ministry of Health Outpatient Acquired Brain Injury (ABI) Program wait list. Then each participant will perform a series of balance and walking tests under 2 conditions : 1) wearing a weighted compression vest , 2) not wearing a weighted compression vest. It will be randomized whether participants wear the vest on the first or second testing day. Participants will also be asked how confident they are about their balance and how anxious they felt performing the assessments after each testing session. We hypothesize that the weighted compression vest will improve fatigue and anxiety immediately and 24 hours after performing a complex task, and will improve static and dynamic balance, gait variability, and walking speed in patients with mTBI, during the tasks.
A wound comprises a break in epithelial continuity and disruption of structure and function of underlying tissues, the treating and repairing is always a great challenge in clinical practice. The complex healing process make the wound easy to get a tendency of nonhealing and result in a heavy burden of life quality. Nowadays surgical repairing is still the main method, but there was still no effective and satisfy outcomes. Because none of the treatments could repair skin both on structure and function. Now the investigators provide a quick and effective method to rebuilt complete structure and function of the skin based on tissue-engineered skin technology. To further test the efficacy and safety of this new method, the investigators propose a prospective randomized controlled multicenter trial to compare this method with traditional skin graft.
Management of intracranial hypertension (ICH) in patients with severe traumatic brain injury (sTBI) is crucial to their survival and optimal recovery. The evidence-based Guidelines for the Management of Severe Traumatic Brain Injury, 3rd Edition recommends use of intracranial pressure (ICP) monitors to assess ICH and guide intervention. Unfortunately, only a small percentage of the world has the resources and capability to routinely monitor ICP. The objective of this proposal is to create and test guidelines for the treatment of severe TBI in the absence of ICP monitoring.
The purpose of this study is to test the accuracy of urinary neutrophil-gelatinase associated lipocalin (NGAL) and other biomarkers (plasma renin, norepinephrine) to predict acute kidney injury (AKI) development in patients with cirrhosis and bacterial infection and to predict response to AKI treatment with albumin and albumin with terlipressin in patients with suspected hepatorenal syndrome.
Traumatic Brain Injury (TBI) is a common injury in combat, terrorist attacks and sports such as football and hockey. Unnecessary delays in the diagnosis and treatment of brain damage in patients who can benefit from evacuation procedures can lead to worse brain injury, worse outcome and, sometimes, unnecessary death. However, there is no reliable and sensitive method for diagnosis of TBI severity in the field. In this study we will examine the feasibility of using this a multifocal chromatic pupillometer for monitoring TBI, by examining the pupillary response to multifocal chromatic stimuli in intracranial pressure (ICP)-monitored severe TBI patients. As control, normal subjects will be tested for pupillary responses using this device.
To analyse differences in protein expression in multiple trauma patients for identification of potential biomarkers to predict organ dysfunction.
The purpose of this study is to collect and compare information from cranial ultrasounds, magnetic resonance imaging scans, neurological exam and neuropsychological assessments of children. The investigators hope that the information collected in this study will help with early screening, diagnosis and treatment of brain injury in newborns as well as identify a connection between MR imaging (MRI-magnetic resonance imaging, MRS-magnetic resonance spectroscopy) and neurodevelopmental outcome.