View clinical trials related to Brain Ischemia.
Filter by:To determine the safety of single and repeated intravenous doses of hCT-MSC in newborn infants with HIE.
This observational study focus on a new parameter of cerebral perfusion derived form digital substraction angiography.
The goal of this study is to develop a large longitudinal cohort of individuals diagnosed with or at high risk for brain diseases (both neurological and psychiatric in nature), in order to identify risk factors that contribute to neurological and psychiatric diseases over time. The investigators seek to capture relevant information from medical records, electronically administered questionnaires and follow up phone-based interviews. The investigators expect to eventually have sufficient power from our dataset to examine risk factors for a variety of brain disorders, both individually and in aggregate. Our ultimate goal is to offer scientifically validated ways to preserve and promote brain health by working with our patients' needs and tracking their progress over time.
We and other investigations suggested that the activation of nerve cell cycle following cerebral ischemia led to neuronal apoptosis, glial cell proliferation and the formation of glial scar.The cyclin-dependent kinases (CDKs) and cyclins jointly promoted the cell cycle progression. Our preliminary clinical trial found a new microRNA-miR-494, which involved in the occurrence of acute ischemic stroke. In our animal experiment, miR-494 could relieve cerebral ischemia injury through inhibiting cyclin-dependent kinase 6(CDK6), ubiquitin-conjugating enzyme E2L6 (UBE2L6) and histone deacetylase 3 (HDAC3), which suggested that miR-494 might play an important role in the regulation of cell cycle following cerebral ischemia. This project intends to verify the following hypothesis:①miR-494 suppresses CDK6, and/or fibroblast growth factor16(FGF16)-Ras-extracellular signal-regulated kinase(ERK)--v-myc avian myelocytomatosis viral oncogene homolog(MYC) pathway, and/or phosphatase and tensin homolog(PTEN)-/protein kinase B(AKT)-mechanistic target of rapamycin(mTOR)-S6k pathway;②miR-494 inhibits UBE2L6, upregulates the hypoxia-inducible factor 1 α(HIF-1α) expression in nerve cells, thereby increases the p21 and p27 protein levels and inhibits cyclin-dependent kinase2(CDK2)activity;③miR-494 represses HDAC3 and downregulates the cyclin-dependent kinase1(CDK1)protein level. These all mediate the cell cycle arrest of neurons and astrocytes, reduce the neuronal apoptosis and glial scar formation,promote the recovery of neurological function and provide new targets for the treatment of ischemic stroke.
The research project investigates the incidence of the hyperintense acute reperfusion marker (HARM) in patients with transient ischemic attack (TIA) or transient neurological attack (TNA). Initially, HARM was described after acute ischemic stroke and is caused by a blood-brain barrier disorder after recanalization of an acute vessel occlusion and consecutive reperfusion. These result in a contrast agent extravasation into the subarachnoid space, which can be easily detected on fluid attenuated inversion recovery (FLAIR) images. TIA is defined as a transient focal neurological deficit with a probably cerebrovascular cause. In contrast, TNA is defined as a transient non-focal neurological deficit with multiple causes, including cerebrovascular. The clinical diagnosis of TIA is often flawed and the delineation of TIA and TNA can be difficult. MRI is the most important diagnostic method for the detection or exclusion of cerebral ischemia in patients with TIA/TNA in daily clinical practice. However, on diffusion-weighted imaging (DWI) approximately two-thirds of TIA cases and only one-fifth of TNA cases demonstrate acute cerebral ischemia. Supplementary perfusion-weighted imaging (PWI) scans can only slightly increase this percentage. The well-known HARM could prove to be complementary to DWI and PWI and close or at least reduce the existing gap. In the case of TNA in particular, this could be of clinical relevance in order to avoid mistreatment or even dismissal without further clarification after supposedly inconspicuous imaging. Therefore, the aim of this study is to record the incidence of HARM in a statistically significant number of cases of patients with TIA and TNA and to investigate relationships with symptom duration and anatomical localization. In addition, the dynamics of contrast enhancement in the subarachnoid space in TIA and TNA cases with HARM will be analyzed in detail.
Perinatal asphyxia is common cause of acquired neonatal brain injury in neonates associated with hypoxic-ischemic encephalopathy, leading to long-term neurologic complication or death. In 2000, the neonatal mortality rate in Egypt was found to be 25 per 1000 live birth. In this survey, hypoxic ischemic encephalopathy accounts for 18% of neonatal mortality and is the second most common cause of neonatal death.
Neonates presenting with neurologic symptoms require rapid, non-invasive imaging with high spatial resolution and tissue contrast. The purpose of this study is to evaluate brain perfusion using contrast-enhanced ultrasound CEUS in bedside monitoring of neonates and infants with hypoxic ischemic injury. Investigational CEUS scan will be performed separately from clinically indicated conventional US, in the ICU. Subjects will be scanned with CEUS at two different time-points (at the time HII is first suspected or diagnosed and at time of MRI scan), separately from clinically indicated ultrasound. The CEUS scan will be interpreted by the sponsor-investigator. The study will be conducted at one site, The Children's Hospital of Philadelphia. It is expected that up to 100 subjects will be enrolled per year, for up to two years, for a total enrollment of up to 200 subjects.
This study is a sub-study to the large pragmatic Target Temperature Management 2 Trial (TTM2-trial, ClinicalTrials.gov Identifier: NCT02908308), assessing effectiveness of controlled hypothermia after out-of-hospital cardiac arrest (OHCA). This study is designed to provide detailed information on cognition after OHCA and its relationship to associated factors as emotional function, fatigue, and sleep. A secondary aim is to utilize this information to validate a neurocognitive screening battery used 6 months after OHCA in the TTM2-trial. Approximately 7 and 24 months after OHCA, survivors at selected TTM2 study sites will perform a standardized neuropsychological assessment including performance-based tests of cognition and questionnaires of behavioral and emotional function, fatigue, and insomnia. At 1:1 ratio, a control group of myocardial infarction (MI) patients but no occurrence of cardiac arrest will be recruited and perform the same test battery. Group differences at 7 and 24 months will be analyzed per cognitive domain (verbal, visual/constructive, short-term working memory, episodic memory, processing speed, executive functions). Results of the OHCA survivors on the TTM2 neurocognitive screening battery will be compared with neuropsychological test results at 7 months time.
There have been many studies on the use of running training in older children to improve gait development in children with cerebral palsy. The aim of our study was to conduct early treadmill training in infants who were highly suspected of cerebral palsy and to follow up on their long-term gait development.
There is no international application of infant running stimulation system to evaluate the brain injury in children with various stages of nerve and motor development in a large sample of studies. The study of neonatal brain injury is only limited to intraventricular hemorrhage(IVH),periventricular leukomalacia(PVL), Down's syndrome(DS), premature birth of these four conditions, and the number of samples in the single digits, there is no representative of the disease population. Therefore, from the newborn to the infant development of the critical period, the investigator will refer to the previous treadmill parameters set on the research results, optimize the application of neonatal treadmill. The study hypothesized that neonatal treadmill stimulation with brain-injured children could improve his / her staggered gait characteristics and long-term nerve development through large sample data. It is important to preserve and analyze the gait characteristics and the changes of nerve development in every stage of growth and development of neonates with brain injury so as to provide clinical evidence for rehabilitation intervention. It is of great significance to judge whether this technique can be used in the early stage of brain injury in neonates.