Active clinical trials for "Brain Injuries"

Problem: Depressive symptoms are a common mental health problem following traumatic brain injury (TBI), occurring in up to 87% of patients. Depression following TBI has important consequences including poor functioning, lack of ability to return to work and family activities and prolonged TBI symptoms. The reason depression develops in some patients following TBI is unknown, making treatment difficult. One type of brain protein that shows genetic differences between people is called the serotonin transporter. People can be divided by whether or not they have a short protein (S allele) or a long protein (L allele) which influences the amount of serotonin transporter. Serotonin is a key brain chemical in depression in many mental/psychiatric illnesses. We think that the genetic differences in the serotonin transporter, that may not make a difference before TBI, may become important after TBI due to the nature of these injuries. Methods: A consecutive sample of 200 patients attending a TBI clinic who have sustained a mild-to-moderate TBI (American Congress of Rehabilitation Medicine criteria) within the last 2 months will be assessed for the presence of major depression (standard criteria, standardized interview). In phase I, blood samples from patients with mild-to-moderate TBI with depression and without depression will be checked for the presence of the 5-HTTPR genetic difference. This will allow us to study if the S allele is more likely in TBI patients with depression. In phase II, the patients with depression will be treated with the SSRI citalopram for 6 weeks. At 6 weeks, or upon discontinuation of citalopram, depression will be assessed again. This will allow us to study if depressed patients with the S allele respond more poorly to treatment. Persons assessing depression after treatment will not know the genetic makeup of each patient. Results Expected: If the serotonin transporter genetic difference confers susceptibility to depression following TBI, this will provide important information on what causes depression following TBI and document a risk factor for depression previously unstudied in this population. Also, as SSRI antidepressants are used to treat depression in TBI, this study may identify a subgroup of TBI patients in whom different medications should be given or additional medications are required.

This is an intervention study for informal caregivers of adult patients with an acquired brain injury (stroke, traumatic brain injury or cerebral haemorrhage). It will determine whether an internet-based supportive coaching offers benefits to the caregivers in their own process of coping in the aftermath of a brain injury of a close relative. We expect the internet-based supportive coaching to be more effective in the treatment of emotional distress reactions and caregiver burden than the treatment as usual.

This study evaluates and addresses challenges to implementing an acupuncture intervention for adults who have headaches after sustaining a moderate traumatic brain injury. Eligible participants will be recruited from Seattle and the surrounding areas to receive weekly acupuncture for 12 consecutive weeks. Participants will complete questionnaires to assess headache impact, depression, health-related quality of life, and cognitive function at the beginning of the study and every two weeks for the duration of the study. Participants will participate in structured interviews after the study for their views on the acceptability and tolerability of the study protocol.

Despite the decline in fatal traumatic brain injury (TBI) incidence in recent years, TBI morbidity remains a public health challenge and is the leading cause of disability in the United States. Detailed knowledge of the metabolic alterations following TBI will provide a significant advancement to our understanding of the hypometabolic response to TBI, which is key information for the future development and testing of novel therapeutic interventions that by-pass or compensate for the metabolic dysfunction. The goal of this study is to determine the clinical utility of in vivo 13C MRS to identify specific metabolic alterations following TBI. We hypothesize that following TBI, metabolic pathways are altered causing an incomplete oxidative of glucose in neurons and astrocytes resulting in a decrease in cerebral metabolism.

Mild Traumatic Brain Injury (mTBI), including concussion, is a real public health problem. Indeed mTBI might induce long-term brain disorders with increased risk of neurodegenerative diseases and the healthcare costs can be significant for both the individual and the society. However mTBI is called the "silent epidemic", because of the lack of research in this field in France as well as in the rest of the world. Most of the time, mTBI is associated with sports injuries, road traffic accidents and falls. The risk of neurodegenerative diseases is significantly increased with the repetition of mTBI, which may have a cumulative effect. In this context, playing football (or 'soccer') is associated with a high risk of concussion and with frequent head-ball contacts which are repeated during the training and matches. Moreover, football is the most popular team sport in the world, with more than 265 million players. The long-term impact of "heading" in football is still debated in the literature. Nevertheless, several studies suggest the possible emergence of early neurocognitive disorders. Otherwise, while mTBI is usually characterized by normal brain images using traditional neuroimaging techniques, microscopic anatomical changes might be detectable by new neuroimaging techniques. According to recent studies, cognitive dysfunctions could be based on these microstructural changes in the gray matter and white matter, secondary to the primary mechanical injury. Studies that have examined the structural changes in the brain white matter in football players are rare and lack of evidence regarding the consequences of accumulated brain impacts explains the lack of preventive measures in this sport. In addition, post-traumatic secondary lesions cause functional alterations of the neurovascular unit and its effect on cerebral perfusion may play a crucial role, which has never been yet explored in humans over the long term. In this research, the investigators will develop a unique multi-modal neuroimaging protocols to assess brain changes after minor head trauma and over the time. Investigators want to perform magnetic resonance imaging (MRI) to assess cerebral blood flow using Arteria Spin Labelling (ASL), structural changes using Diffusion Tensor Imaging (DTI), susceptibility weighted imaging (SWI), and functional changes using BOLD resting-functional MRI.

Symptoms resulting from mild/moderate trauma to the brain are as varied as the individuals who sustain them. The currently held belief is that the majority of healing and functional recovery occurs within the first two years post injury. A large proportion of individuals who sustain mild/moderate brain injuries (mTBIs) do not fully recover, and continue to experience symptoms well beyond two years post injury. Cognitive rehabilitation programs have been shown to be somewhat effective in helping mTBI patients regain some functionality in these executive domains. The purpose of the current study is to use an objective assessment of brain function to track changes during either a full-time or part-time holistic cognitive rehabilitation program, specifically the ABI Wellness (ABIW) program. The NeuroCatch Platform™ test will be used to assess brain functioning before, during and after 3 months in the ABIW program. The NeuroCatch Platform™ test uses electroencephalography (EEG) to measure event-related potential (ERP) signals produced by the brain, in response to an auditory stimulus. Three brain processes are examined with this test: Auditory sensation (ERP marker is the N100), Basic attention (ERP marker is the P300), and Cognitive processing (ERP marker is the N400).

Patients with severe brain injuries often have slow accumulating recoveries of function. In ongoing studies, we have discovered that elements of electrical activity during sleep may correlate with the level of behavioral recovery observed in patients. It is unknown whether such changes are causally linked to behavioral recovery. Sleep processes are, however, associated with several critical processes supporting the cellular integrity of neurons and neuronal mechanisms associated with learning and synaptic modifications. These known associations suggest the possibility that targeting the normalization of brain electrical activity during sleep may aid the recovery process. A well-studied mechanism organizing the pattern of electrical activity that characterizes sleep is the body's release of the substance melatonin. Melatonin is produced in the brain and released at a precise time during the day (normally around 8-10PM) to signal the brain to initiate aspects of the sleep process each day. Ongoing research by other scientists has demonstrated that providing a small dose of melatonin can improve the regular pattern of sleep and help aid sleep induction. Melatonin use has been shown to be effective in the treatment of time change effects on sleep ("jet lag") and mood disturbances associated with changes in daily light cues such as seasonal affective disorder. We propose to study the effects of melatonin administration in patients with severe structural brain injuries and disorders of consciousness. We will measure the patient's own timing of release of melatonin and provide a dose of melatonin at night to test the effects on the electrical activity of sleep over a three month period. In addition to brain electrical activity we will record sleep behavioral data and physical activity using activity monitors worn by the patients. Patient subjects in this study will be studied twice during the three month period in three day inpatient visits where they will undergo video monitoring and sampling of brain electrical activity using pasted electrodes ("EEG"), hourly saliva sampling for one day, and participation in behavioral testing.

The aim of the study is to evaluate the feasibility of a newly developed intervention to improve family support for patient with acquired brain injury (ABI) in early phase of hospitalization (SAFIR): the main components are the assessment of the family, the emotional support for the families, the information giving to the families, the inclusion of the families in the care process and the care coordination between the inter professional team. The main outcomes of the study are feasibility and acceptability outcomes of the newly developed intervention, and trend in efficacy in the family functioning, coping and perceived support from the nurses.

The purpose of the study is to calibrate and to validate the accuracy of the oximeter with an estimate of brain oxygen levels assessed by measuring arterial and internal jugular vein blood oxygen saturations.

Traumatic brain injury (TBI) is an important public health problem with an estimated 1.7 million new cases in the United States each year. Although the vast majority of these victims sustain mild TBI, many still develop headache, difficulty concentrating, and decreased memory with potential for serious long-term consequences. In particular, mild TBI is an important consequence of combat-related injuries sustained by military personnel and sports-related injuries in young adults. Unfortunately, treatment of mild TBI is usually limited to oral analgesics for headache pain such as acetaminophen (Tylenol) or ibuprofen (Motrin or Advil). Since there are no previous randomized trials of these medications for mild TBI, their comparative effectiveness is not known. Increasing animal based evidence suggests that mild TBI is related to brain cell injury caused by overexpression of a cellular enzyme (COX-2) that causes neuroinflammation. Fortunately, inhibition of COX-2 is easily achieved using ibuprofen. We hypothesize that head injured patients treated with ibuprofen will have a lower incidence of mild TBI symptoms than patients treated with acetaminophen. We will conduct a randomized clinical trial to measure the comparative effects of ibuprofen versus acetaminophen on the incidence of specific symptoms of mild TBI in emergency department patients with head injury.