In November 2017, the Lancet Neurology Commission on Traumatic Brain Injury (TBI) highlighted existing deficiencies in epidemiology, patient characterization, identifying best practice, outcome assessment, and evidence generation. The Commission concluded that C needed to address deficiencies in prevention , and made a recommendation for large collaborative studies which could provide the framework for precision medicine and comparative effectiveness research (CER).
Summary: These experiments examined the effects of moderate hypothermia on mortality and neurological def icits observed after experimental traumatic brain injury (TBI) in the rat. Brain temperature was measured contin uously in all experiments by intraparenchymal probes, Brain cooling was induced by partial immersion (skin pro tected by a plastic barrier) in a water bath (OOe) under general anesthesia (1.5% halothane170% nitrous oxide/ 30% oxygen). In experiment I, we examined the effects of moderate hypothermia induced prior to injury on mortal ity following fluid percussion TBI. Rats were cooled to 36°e (n = 16), 33°e (n = 17), or 300e (n = II) prior to injury and maintained at their target temperature for I h after injury. There was a significant (p < 0.04) reduction in mortality by a brain temperature of 30oe. The mortality rate at 36°e was 37.5%, at 33°e was 41 %, and at 300e wasThe cerebral protective effects of profound hypo thermia «18°C) have been known for many years. As early as 1950, reports of cerebral protection from global ischemia by profound hypothermia in animals stimulated clinical interest (Mohri and Me rendino, 1969). By 1955, 100 cardiac surgical cases had been performed under deep hypothermia with cardiac arrest (Mohri and Merendino, 1969). As pump oxygenators became more efficient, deep hy pothermia and cardiac arrest were only occasion ally used in adult cardiac surgery (Crawford and Saleh, 1981). In pediatric cardiac surgery, however, conditions were encountered routinely where total cessation of circulation at temperatures of 17-20°C Abbreviations used: ANOYA, analysis of variance; TB1, trau matic brain injury, 114 9.1 %. In experiment II, we examined the effects of mod erate hypothermia or hyperthermia initiated after TBI 01 long-term behavioral deficits. Rats were cooled to 36°e (I = 10), 33°e (n = 10), or 300e (n = 10) or warmed to 38°( (n = 10) or 400e (n = 12) starting at 5 min after injury an( maintained at their target temperatures for I h. Hypother mia-treated rats had significantly less beam-walking beam-balance, and body weight loss deficits compared t( normothermic (38°C) rats. The greatest protection wa: observed in the 300e hypothermia group, Since a temper ature of 300e can be induced in humans by surface cool ing without coagulopathy or ventricular fibrillation, hy pothermia to 300e may have potential clinical value fOJ treatment of human brain injury.
Small direct current (DC) electric fields (EFs) guide neurite growth and migration of rodent neural stem cells (NSCs). However, this could be species dependent. Therefore, it is critical to investigate how human NSCs (hNSCs) respond to EF before any possible clinical attempt. Aiming to characterize the EF-stimulated and guided migration of hNSCs, we derived hNSCs from a well-established human embryonic stem cell line H9. Small applied DC EFs, as low as 16 mV/mm, induced significant directional migration toward the cathode. Reversal of the field polarity reversed migration of hNSCs. The galvanotactic/electrotactic response was both time and voltage dependent. The migration directedness and distance to the cathode increased with the increase of field strength. (Rho-kinase) inhibitor Y27632 is used to enhance viability of stem cells and has previously been reported to inhibit EF-guided directional migration in induced pluripotent stem cells and neurons. However, its presence did not significantly affect the directionality of hNSC migration in an EF. Cytokine receptor [C-X-C chemokine receptor type 4 (CXCR4)] is important for chemotaxis of NSCs in the brain. The blockage of CXCR4 did not affect the electrotaxis of hNSCs. We conclude that hNSCs respond to a small EF by directional migration. Applied EFs could potentially be further exploited to guide hNSCs to injured sites in the central nervous system to improve the outcome of various diseases.
To compare the effect of long-term mild hypothermia versus short-term mild hypothermia on the outcome of 215 severe traumatic brain injured patients with cerebral contusion and intracranial hypertension. At three medical centers, 215 patients aged 18 to 45 years old with an admission Glasgow Coma Scale <-8 within 4 h after injury were randomly divided into two groups: long-term mild hypothermia group (n = 108) for 5 +-1.3 days mild hypothermia therapy and short-term mild hypothermia group (n = 107) for 2 +-0.6 days mild hypothermia therapy. All patients had intracranial hypertension and frontotemporoparietal contusion with midline shift > 1 cm confirmed on computed tomographic scan. Glasgow Outcome Scale at 6-month follow-up, 47 cases had favorable outcome (43.5%), and other 61 cases had unfavorable outcome (56.5%) in the long-term mild hypothermia group. However, only 31 cases had favorable outcome (29.0%), and other 76 cases had unfavorable outcome (71.0%) in the short-term mild hypothermia group (P < 0.05). The intracranial pressure significantly rebounded after rewarming in the short-term mild hypothermia group, but not in the long-term mild hypothermia (P < 0.05). Furthermore, the incidence of stress ulcer, epilepsy, pulmonary infection, intracranial infection did not significantly differ between the two groups (P > 0.05). Compared with short-term mild hypothermia, long-term mild hypothermia significantly improves the outcome of severe traumatic brain injured patients with cerebral contusion and intracranial hypertension without significant complications. Our data suggest that 5 days of longterm cooling is more efficacious than 2 days of short-term cooling when mild hypothermia is used to control refractory intracranial hypertension in patients with severe traumatic brain injury.
SummaryLimited migration of neural stem cells in adult brain is a roadblock for the use of stem cell therapies to treat brain diseases and injuries. Here, we report a strategy that mobilizes and guides migration of stem cells in the brain in vivo. We developed a safe stimulation paradigm to deliver directional currents in the brain. Tracking cells expressing GFP demonstrated electrical mobilization and guidance of migration of human neural stem cells, even against co-existing intrinsic cues in the rostral migration stream. Transplanted cells were observed at 3 weeks and 4 months after stimulation in areas guided by the stimulation currents, and with indications of differentiation. Electrical stimulation thus may provide a potential approach to facilitate brain stem cell therapies.
Recent work has shown that mild to moderate levels of hypothermia may profoundly reduce the histological and biochemical sequelae of cerebral ischemic injury. In the present study, the authors examined the effect of fluid-percussion injury on brain temperature in anesthetized rats and the effect of anesthesia on brain temperature in uninjured rats. The relationship between the brain, rectal, and temporalis muscle temperatures during normothermia, hypothermia, and hyperthermia was studied following a moderate magnitude of fluid-percussion brain injury (2.10 to 2.25 atmospheres) in rats. The results showed that mean brain temperature in 10 anesthetized injured rats, in 21 anesthetized uninjured rats, and in 10 unanesthetized uninjured rats was a mean (+/- standard error of the mean) of 36.04 degrees +/- 0.20 degrees C, 36.30 degrees +/- 0.08 degrees C, and 37.95 degrees +/- 0.09 degrees C, respectively. There was no significant difference in temperature under general anesthesia between injured and uninjured rats (p greater than 0.05). In the absence of brain injury, mean brain temperature was significantly lower in anesthetized rats than in unanesthetized rats (p less than 0.001). In anesthetized brain-injured rats, temporalis muscle temperature correlated well with brain temperature over a 30 degrees to 40 degrees C range, even when brain temperature was rapidly changed during induction of hypothermia or hyperthermia (r = 0.9986, p less than 0.0001). In contrast, rectal temperature varied inconsistently from brain temperature. These observations indicated that: 1) brain injury itself does not influence brain temperature in this model; 2) anesthesia alone decreases brain temperature to levels producing cerebral protection in this model; and 3) external monitoring of temporalis muscle temperature can provide a reliable indirect measure of brain temperature in the course of experimental brain injury. The authors believe that it is essential to monitor or control brain temperature in studies of experimental brain injury.
The effects of postinjury hypothermia on behavioral outcome following moderate fluid percussion traumatic brain injury (TBI) were examined. In Experiment I, three groups of rats were examined. The first group was normothermic (37.5 degrees C); and hypothermia (30 degrees C) was initiated 15 min and 30 min postinjury in the second and third groups, respectively. Whole body cooling was achieved by ventral ice pack. Cooling of the brain to 30 degrees C was achieved in 25 min and maintained for 60 min. Brain temperature was measured indirectly by a probe in the temporalis muscle. Behavioral outcome was assessed by beam-balance performance, beam-walking performance, and body weight loss measured daily for 5 days after TBI. Both the normothermic group and the 30-min postinjury hypothermic group exhibited significant (p < 0.05) beam-balance and beam-walking deficits on days 1 through 5 after TBI. In contrast, the 15-min postinjury hypothermic group exhibited significant (p < 0.05) beam-walking deficits only on day 1 after TBI and significant (p < 0.05) beam-balance deficits on days 1, 3, and 4 after TBI. In Experiment II, subcortical brain temperature was compared to temporalis muscle temperature in normothermic (37.5 degrees C) and hypothermic (30 degrees C) rats subjected to TBI. In both groups brain temperature tracked within 0.4 degree C of temporalis muscle temperature. These results are similar to post-TBI excitatory receptor antagonist studies and indicate a therapeutic window for moderate hypothermia of less than 30 min after moderate fluid percussion TBI in the rat.
We have identified alterations in the responses of muscarinic and metabotropic receptors in rat hippocampus that persist for at least 15 days after central fluid percussion injury. This study compares the effect of lateral fluid percussion and central fluid percussion on these responses. Moderate injury was obtained by displacement and deformation of the brain within the closed cranial cavity using a fluid percussion device positioned either centrally or laterally. Carbachol and (+/-)-1-aminocyclopentane-trans-1,3-dicarboxylic acid (trans-ACPD)-stimulated polyphosphoinositide (PPI) hydrolysis was assayed in hippocampus from injured and sham-injured controls at 15 days following injury. At 15 days after central fluid percussion traumatic brain injury (TBI), the response to carbachol was enhanced by 30% and the response to trans-ACPD was enhanced by 75% compared to sham-injured animals. At 15 days after lateral fluid percussion TBI the response to trans-ACPD was enhanced by 40% both ipsilateral and contralateral to the side of injury. In contrast, the response to carbachol was enhanced by 29% contralateral to the side of injury but was diminished by 12% ipsilateral to the side of injury. Cresyl violet staining shows no hippocampal cell death after central fluid percussion injury or on the side contralateral to lateral fluid percussion injury but on the ipsilateral side cell death was identified in hippocampal area CA3. Thus, abnormal hippocampal cell signaling through the phosphoinositide pathway occurs in the absence of cell death and may contribute to cognitive impairment.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.