Vindeburnol Induces Neuroprotection in Rat Traumatic Brain Injury via Adrenergic Receptor Antagonism.

Traumatic brain injury (TBI) continues to be a major cause of death and disability worldwide. This study assessed the effectiveness of non-invasive vagus nerve stimulation (nVNS) in reducing brain lesion volume and improving neurobehavioral performance in a rat model of TBI. Animals were randomized into three experimental groups: (1) TBI with sham stimulation treatment (Control), (2) TBI treated with five lower doses (2-min) nVNS, and (3) TBI treated with five higher doses (2 × 2-min) nVNS. We used the gammaCore nVNS device to deliver stimulations. Magnetic resonance imaging studies were performed 1 and 7 days post-injury to confirm lesion volume. We observed smaller brain lesion volume in the lower dose nVNS group compared with the control group on days 1 and 7. The lesion volume for the higher dose nVNS group was significantly smaller than either the lower dose nVNS or the control groups on days 1 and 7 post-injury. The apparent diffusion coefficient differences between the ipsilateral and contralateral hemispheres on day 1 were significantly smaller for the higher dose (2 × 2 min) nVNS group than for the control group. Voxel-based morphometry analysis revealed an increase in the ipsilateral cortical volume in the control group caused by tissue deformation and swelling. On day 1, these abnormal volume changes were 13% and 55% smaller in the lower dose and higher dose nVNS groups, respectively, compared with the control group. By day 7, nVNS dampened cortical volume loss by 35% and 89% in the lower dose and higher dose nVNS groups, respectively, compared with the control group. Rotarod, beam walking, and anxiety performances were significantly improved in the higher-dose nVNS group on day 1 compared with the control group. The anxiety indices were also improved on day 7 post-injury compared with the control and the lower-dose nVNS groups. In conclusion, the higher dose nVNS (five 2 × 2-min stimulations) reduced brain lesion volume to a level that further refined the role of nVNS therapy for the acute treatment of TBI. Should nVNS prove effective in additional pre-clinical TBI models and later in clinical settings, it would have an enormous impact on the clinical practice of TBI in both civilian and military settings, as it can easily be adopted into routine clinical practice.

Traumatic brain injury (TBI), which can lead to disability, dysfunction, and even death, is a prominent health problem worldwide. Effective therapy for this serious and debilitating condition is needed. Human umbilical cord matrix, known as Wharton's jelly (WJ), provides a natural, interface scaffold that is enriched in mesenchymal stem cells. In this study, we tested the efficacy of WJ tissue transplantation in a weight-drop model of TBI in rats. WJ tissue was cultured and transplanted into the injury site 24 h after TBI. The modified neurologic severity score, body weight, brain edema, and lesion volume were evaluated at various time points after TBI. Cognitive behavior was assessed by the novel object recognition test and the Morris water maze test. Expression of brain-derived neurotrophic factor (BDNF) in the perilesional brain area was measured at day 14 after TBI. We found that WJ tissue transplantation lessened TBI-induced brain edema (day 3), reduced lesion volume (day 28), improved neurologic function (days 21-28), and promoted memory and cognitive recovery. Additionally, expression of BDNF mRNA and protein was higher in WJ tissue-treated rats than in sham-operated or vehicle-treated rats. These data suggest that WJ tissue transplantation can reduce TBI-induced brain injury and may have therapeutic potential for the treatment of TBI.

Traumatic brain injury (TBI) is a multifaceted injury and a leading cause of death in children, young adults, and increasingly in Veterans. However, there are no neuroprotective agents clinically available to counteract damage or promote repair after brain trauma. This study investigated the neuroprotective effects of normobaric oxygen (NBO) after a controlled cortical impact in rats. The central hypothesis was that NBO treatment would reduce lesion volume and functional deficits compared with air-treated animals after TBI by increasing brain oxygenation thereby minimizing ischemic injury. In a randomized double-blinded design, animals received either NBO (n = 8) or normal air (n = 8) after TBI. Magnetic resonance imaging (MRI) was performed 0 to 3 hours, and 1, 2, 7, and 14 days after an impact to the primary forelimb somatosensory cortex. Behavioral assessments were performed before injury induction and before MRI scans on days 2, 7, and 14. Nissl staining was performed on day 14 to corroborate the lesion volume detected from MRI. Contrary to our hypothesis, we found that NBO treatment increased lesion volume in a rat model of moderate TBI and had no positive effect on behavioral measures. Our results do not promote the acute use of NBO in patients with moderate TBI.

Traumatic brain injury (TBI), which is the brain impairment and lesion caused by the external force injuring the head and the underlying brain, can cause pediatric death, disability, neurological disorders, and even lifelong disability. This study was to explore the effect of riboflavin (RF) on neurological rehabilitation and functional recovery after TBI. The rat models of TBI were constructed by treating rats with controlled cortical impact (CCI). By treating TBI rats with RF, we investigated whether the administration of RF would affect the sensorimotor function and cognitive ability recovery through adhesive removal test, modified neurological severity score (mNSS), corner test, wire-grip test and the Morris water maze. The effects of RF on lesion volume and water content were investigated using hematoxylin and eosin (H&E) staining and wet-dry method. The Nissl staining and terminal deoxynucleotidyl transferase (TdT)-mediated dUTP nick end labeling (TUNEL) staining were used to demonstrate the effect of RF on neural apoptosis. Inflammation-related cytokines of interleukin (IL)-6, IL-1β, tumor necrosis factor (TNF)-α, and transforming growth factor (TGF)-β1 were measured by enzyme-linked immunosorbent assay (ELISA) to evaluate the effect of RF on neuroinflammation. The impact of RF on oxidative stress was assessed by measuring malondialdehyde (MDA) content and superoxide dismutase (SOD) activity, and the platelet endothelial cell adhesion molecule-1 (CD31) staining for observing vessel density, the reverse transcription quantitative real-time polymerase chain reaction (RT-qPCR) for measuring vascular endothelial growth factor (VEGF) mRNA expression and western blot for VEGF protein expression were used for evaluated angiogenesis. The administration of RF could facilitate the recovery of neurological function by promoting the recovery of sensorimotor function and cognitive ability (p < 0.05). Furthermore, RF could reduce the lesion volume and water content after TBI and ameliorate neural apoptosis, neuroinflammation, and oxidative stress (p < 0.05). Finally, RF increased vessel density (p < 0.01) and VEGF levels (p < 0.01) in brain tissues after TBI, promoting angiogenesis. RF benefits neurological rehabilitation after TBI by promoting neurological function recovery, ameliorating the pathogenesis after TBI, and facilitating brain vascular remodeling. These findings provide a novel mechanism for RF treating pediatric TBI.

Introduction: Traumatic brain injury (TBI) is the leading cause of disability and death in children in the U.S. There are limited data as to how to improve neurologic outcome after pediatric TBI. Progesterone has been well-studied in animal models and clinically in adult TBI, and previous work in our laboratory has shown that progesterone prevents mitochondrial dysfunction and reduces lesion volume after TBI in immature rats. In this study we hypothesized that progesterone would improve long-term neurologic outcome in a rat model of pediatric TBI. Methods: Immature (PND 17) male rats (n=9–10/group) underwent controlled cortical impact (CCI) to the left parietal cortex, with control rats undergoing sham craniotomy. Rats were then assigned to receive progesterone (10mg/kg i.p. at 1h, 6h s.c., Q24h s.c. for 7 days) or vehicle (22.5% cyclohexdrin). At day 7, 14, 21, and 28 neurologic testing (rotarod, beam walking, cylinder testing, and novel object recognition) was performed. Results: Progesterone resulted in a trend toward improved rotarod performance at 7d (p=0.06). At 14, 21 and 28d after CCI, progesterone-treated rats had the longest rotarod latencies of all groups, but these were not significantly different from vehicle-treated rats. There were no differences in cylinder testing between groups. Progesterone improved novel object recognition testing at 14d after TBI. Progesterone did not worsen outcome in any neurologic test at any time point studied. Conclusions: Progesterone treatment improved performance in rotarod at 7d and novel object recognition at 14d after TBI in immature rats. This study provides support for planning future clinical trials of progesterone in pediatric TBI.

Tauroursodeoxycholic acid reduces brain lesion volume and cortical edema in a rat model of Traumatic brain injury.

BackgroundThe attainment of extensive neurological function recovery remains the key challenge for the treatment of traumatic brain injury (TBI). Transplantation of bone marrow-derived mesenchymal stem cells (BMSCs) has been shown to improve neurological function recovery after TBI. However, the survival of BMSCs after transplantation in early-stage TBI is limited, and much is unknown about the mechanisms mediating this neurological function recovery. Secretion of neurotrophic factors, including neurotrophin 3 (NT3), is one of the critical factors mediating BMSC neurological function recovery. Gene mutation of NT3 (NT3P75-2) has been shown to enhance the biological function of NT3 via the reduction of the activation of the P75 signal pathway. Thus, we investigated whether NT3P75-2 gene-modified BMSCs could enhance the survival of BMSCs and further improve neurological function recovery after TBI.MethodsThe ability of NT3P75-2 induction to improve cell growth rate of NSC-34 and PC12 cells in vitro was first determined. BMSCs were then infected with three different lentiviruses (green fluorescent protein (GFP), GFP-NT3, or GFP-NT3P75-2), which stably express GFP, GFP-NT3, or GFP-NT3P75-2. At 24 h post-TBI induction in mice, GFP-labeled BMSCs were locally transplanted into the lesion site. Immunofluorescence and histopathology were performed at 1, 3, and/or 7 days after transplantation to evaluate the survival of BMSCs as well as the lesion volume. A modified neurological severity scoring system and the rotarod test were chosen to evaluate the functional recovery of the mice. Cell growth rate, glial activation, and signaling pathway analyses were performed to determine the potential mechanisms of NT3P75-2 in functional recovery after TBI.ResultsOverall, NT3P75-2 improved cell growth rate of NSC-34 and PC12 cells in vitro. In addition, NT3P75-2 significantly improved the survival of transplanted BMSCs and neurological function recovery after TBI. Overexpression of NT3P75-2 led to a significant reduction in the activation of glial cells, brain water content, and brain lesion volume after TBI. This was associated with a reduced activation of the p75 neurotrophin receptor (P75NTR) and the c-Jun N-terminal kinase (JNK) signal pathway due to the low affinity of NT3P75-2 for the receptor.ConclusionsTaken together, our results demonstrate that administration of NT3P75-2 gene-modified BMSCs dramatically improves neurological function recovery after TBI by increasing the survival of BMSCs and ameliorating the inflammatory environment, providing a new promising treatment strategy for TBI.

Salubrinal offers neuroprotection through suppressing endoplasmic reticulum stress, autophagy and apoptosis in a mouse traumatic brain injury model.

H₂O₂ preconditioning enhances the transplantation-mediated therapeutic effect of bone marrow-derived mesenchymal stem cells after traumatic brain injury.

Aim: To develop poly(lactide-co-glycolide)-graft-polyethylenimine (PgP) as a nanocarrier for the delivery of rolipram (Rm) and evaluate the therapeutic efficacy of Rm-loaded PgP (Rm-PgP) on secondary injury and motor function in a rat traumatic brain injury (TBI) model. Materials& methods: Rm-PgP was injected in the injured brain lesion immediately after TBI using a microinjection pump. Secondary injury pathologies such as inflammatory response, apoptosis and astrogliosis were assessed by histological analysis and functional recovery was assessed by assorted motor function tests. Results: Rm-PgP restored cyclic adenosine monophosphate level in the injured brain close to the sham level and Rm-PgP treatment reduced lesion volume, neuroinflammation and apoptosis and improved motor function at 7days post-TBI. Conclusion: One single injection of Rm-PgP can be effective for acute mild TBI treatment.

Head trauma is a dynamic process characterized by a cascade of metabolic and molecular events. Erythropoietin (EPO) has been shown to have neuroprotective effects in animal models of traumatic brain injury (TBI). Acute in vivo mechanisms and pathological changes associated with EPO following TBI are unknown. In this study the authors compare acute metabolic and pathological changes following TBI with and without systemically administered EPO. Right frontal lobe microdialysis cannulae and right parietal lobe percussion hubs were inserted into 16 Sprague-Dawley rats. After a 4- to 5-day recovery, TBI was induced via a DragonFly fluid-percussion device at 2.5-2.8 atm. Rats were randomized into 2 groups, which received 5000 U/kg EPO or normal saline intraperitoneally 30 minutes after TBI. Microdialysis samples for glucose, lactate, pyruvate, and glutamate were obtained every 25 minutes for 10 hours. Rats were killed, their brains processed for light microscopy, and sections stained with H & E. Erythropoietin administered 30 minutes after TBI directly affects acute brain metabolism. Brains treated with EPO maintain higher levels of glucose 4-10 hours after TBI (p<0.01), lower levels of lactate 6-10 hours after TBI (p<0.01), and lower levels of pyruvate 7.5-10 hours after TBI (p<0.01) compared with saline-treated controls. Erythropoietin maintains aerobic metabolism after TBI. Systemic EPO administration reduces acute TBI-induced lesion volume (p<0.05). Following TBI, neuron use initially increases, with subsequent depletion of extracellular glucose, resulting in increased levels of extracellular lactate and pyruvate. This energy requirement can result in cell death due to increased metabolic demands. These data suggest that the neuroprotective effect of EPO may be partially due to improved energy metabolism in the acute phase in this rat model of TBI.

Cerebral inflammation involves molecular cascades contributing to progressive damage after traumatic brain injury (TBI). The chemokine CC ligand-2 (CCL2) (formerly monocyte chemoattractant protein-1, MCP-1) is implicated in macrophage recruitment into damaged parenchyma after TBI. This study analyzed the presence of CCL2 in human TBI, and further investigated the role of CCL2 in physiological and cellular mechanisms of secondary brain damage after TBI. Sustained elevation of CCL2 was detected in the cerebrospinal fluid (CSF) of severe TBI patients for 10 days after trauma, and in cortical homogenates of C57Bl/6 mice, peaking at 4 to 12 h after closed head injury (CHI). Neurological outcome, lesion volume, macrophage/microglia infiltration, astrogliosis, and the cerebral cytokine network were thus examined in CCL2-deficient (-/-) mice subjected to CHI. We found that CCL2-/- mice showed altered production of multiple cytokines acutely (2 to 24 h); however, this did not affect lesion size or cell death within the first week after CHI. In contrast, by 2 and 4 weeks, a delayed reduction in lesion volume, macrophage accumulation, and astrogliosis were observed in the injured cortex and ipsilateral thalamus of CCL2-/- mice, corresponding to improved functional recovery as compared with wild-type mice after CHI. Our findings confirm the significant role of CCL2 in mediating post-traumatic secondary brain damage.

Previous studies from our laboratory indicate that traumatic brain injury (TBI) in humans results in proteolysis of neuronally-localized, intracellular microtubule associated protein (MAP)-tau to produce cleaved tau (C-tau). The present study evaluated the utility of C-tau to function as a biomarker of neuronal injury and as a biomarker for evaluating neuroprotectant drug efficacy in a controlled cortical impact model of rat TBI. Brain C-tau was determined in rats subjected to controlled cortical impact-induced mild, moderate or severe levels of TBI. A significant severity-dependent increase in C-tau levels was observed in the cortex and hippocampus (1.5-8-fold) of TBI rats compared to shams 72 h after impact. C-tau rat brain and serum time course was determined by measuring levels at 0.25, 6, 24, 48, 72 and 168 h after TBI. A significant time-dependent increase in C-tau levels was observed in ipsilateral cortex (5-16-fold) and hippocampus (2-40-fold) compared to sham animals. C-tau levels increased as early as 6 h after TBI with peak C-tau levels observed 168 h after injury. Elevated brain C-tau levels were associated with TBI-induced tissue loss, which was histologically determined. The effect of cyclosporin-A (CsA), previously demonstrated to be neuroprotective in rat TBI, on brain C-tau levels was examined. CsA (20 mg/kg i.p., 15 min and 24 h after TBI) significantly attenuated the TBI-induced increase in hippocampal C-tau levels observed in vehicle-treated animals confirming CsA's neuroprotectant effect. CsA treatment also lowered ipsilateral cortical C-tau levels, although it did not reach statistical significance. CsA's neuroprotectant effect was confirmed utilizing histologic measures of TBI-induced tissue loss. In addition, serum C-tau levels were significantly increased 6 h after TBI but not at later time points. These results suggest that C-tau is a reliable, quantitative biomarker for evaluating TBI-induced neuronal injury and a potential biomarker of neuroprotectant drug efficacy in the rat TBI model. Serum data suggests that C-tau levels are dependent both on a compromised blood-brain barrier as well as release of TBI biomarkers from the brain, which has implications for the study of human serum TBI biomarkers.

Selective NLRP3 inflammasome inhibitor reduces neuroinflammation and improves long-term neurological outcomes in a murine model of traumatic brain injury

Androgen is responsible for enhanced susceptibility of melatonin against traumatic brain injury in females