The expression changes of Numblike in rat brain cortex after traumatic brain injury

Numblike (Numbl) plays an important role in ependymal wall integrity and subventricular zone neuroblast survival. And Numbl is specifically expressed in the brain. However, its expression and function in the central nervous system lesion are still unclear. In this study, we performed a traumatic brain injury (TBI) model in adult rats and investigated the dynamic changes of Numbl expression in the brain cortex. Western blot and immunohistochemistry analysis revealed that Numbl was present in normal brain. It gradually decreased, reached the lowest point at day 3 after TBI, and then increased during the following days. Double immunofluorescence staining showed that Numbl immunoreactivity was found in neurons, but not astrocytes and microglia. Moreover, the 3rd day post injury was the apoptotic peak implied by the alteration of caspase-3. All these results suggested that Numbl may be involved in the pathophysiology of TBI and further research is needed to have a good understanding of its function and mechanism.     

Increased expression of BAG-1 in rat brain cortex after traumatic brain injury

BAG-1 protein was initially identified as a Bcl-2-binding protein. It was reported to enhance Bcl-2 protection from cell death, suggesting that BAG-1 represents a new type of anti-cell death gene. Moreover, recent study has shown that BAG-1 can enhance the proliferation of neuronal precursor cells, attenuate the growth inhibition induced by siah1. However, its function and expression in the central nervous system lesion are not been understood very well. In this study, we performed a traumatic brain injury (TBI) model in adult rats and investigated the dynamic changes of BAG-1 expression in the brain cortex. Double immunofluorescence staining revealed that BAG-1 was co-expressed with NEURON and glial fibrillary acidic protein (GFAP). In addition, we detected that proliferating cell nuclear antigen had the co-localization with GFAP, and BAG-1. All our findings suggested that BAG-1 might involve in the pathophysiology of brain after TBI.     

Upregulation of p21-activated Kinase 6 in rat brain cortex after traumatic brain injury

p21-activated Kinase 6 (PAK6) is a serine/threonine kinase belonging to the p21-activated kinase (PAK) family. PAK kinases are well-known regulators of a wide variety of cellular functions, including regulation of cytoskeleton rearrangement, cell survival, apoptosis and the mitogen-activated protein kinase signaling pathway. To elucidate the expressions and possible functions of PAK6 in central nervous system (CNS) lesion and repair, we performed a traumatic brain injury (TBI) model in adult rats. Western blot analysis revealed that PAK6 level significantly increased at day 3 after damage, and then declined during the following days. Besides, double immunofluorescence staining showed PAK6 was primarily expressed in the neurons and a few of glial cells in the normal group. While after injury, the expression of PAK6 was increased significantly in the astrocytes and neurons, and the astrocytes had largely proliferated. We also examined the expression of proliferating cell nuclear antigen (PCNA) whose change was correlated with the expression of PAK6. Importantly, double immunofluorescence staining revealed that cell proliferation evaluated by PCNA appeared in many PAK6-expressing cells at day 3 after injury. In addition, injury-induced expression of PAK6 was co-labeled by active caspase-3 during neuronal apoptosis after injury. Collectively, we hypothesized PAK6 may play important roles in CNS pathophysiology after TBI and further research is needed to have a good understanding of its function and mechanism.     

Regulated expression of pancreatic triglyceride lipase after rat traumatic brain injury

Pancreatic triglyceride lipase (PTL), an enzyme of digestive system, plays very important roles in the digestion and absorption of lipids. However, its distribution and function in the central nervous system (CNS) remains unclear. In the present study, we mainly investigated the expression and cellular localization of PTL during traumatic brain injury (TBI). Western blot and RT–PCR analysis revealed that PTL was present in normal rat brain cortex. It gradually increased, reached a peak at the 3rd day after TBI, and then decreased. Double immunofluorescence staining showed that PTL was co-expressed with neuron, but had a few colocalizations in astrocytes. When TBI occurred in the rat cortex, the expression of PTL gradually increased, reached the peak at the 3rd day after TBI, and then decreased. Importantly, more PTL was colocalized with astrocytes, which is positive for proliferating cell nuclear antigen (PCNA). In addition, Western blot detection showed that the 3rd day post injury was not only the proliferation peak indicated by the elevated expression of PCNA, glial fibrillary acidic protein (GFAP) and cyclin D1, but also the apoptotic peak implied by the alteration of caspase-3 and bcl-2. These data suggested that PTL may be involved in the pathophysiology of TBI and PTL may be complicated after injury, more PTL was colocalized with astrocytes. Importantly, injury-induced expression of PTL was colabelled by proliferating cell nuclear antigen (proliferating cells marker), and the western blot for GFAP, PCNA and cyclin D1, showed that 3 days post injury was the proliferation peak, in coincidence to it, the protein level change of caspase-3 and bcl-2 revealed that the stage was peak of apoptotic too. These data suggested that PTL may be involved in the pathophysiology of TBI and that PTL may be implicated in the proliferation of astrocytes and the recovery of neurological outcomes. But the inherent mechanisms remained unknown. Further studies are needed to confirm the exact role of PTL after brain injury.     

Ghrelin attenuates brain injury after traumatic brain injury and uncontrolled hemorrhagic shock in rats

Traumatic brain injury (TBI) and hemorrhagic shock often occur concomitantly due to multiple injuries. Gastrointestinal dysfunction occurs frequently in patients with TBI. However, whether alterations in the gastrointestinal system are involved in modulating neuronal damage and recovery after TBI is largely neglected. Ghrelin is a "gut-brain" hormone with multiple functions including antiinflammation and antiapoptosis. The purpose of this study was to determine whether ghrelin attenuates brain injury in a rat model of TBI and uncontrolled hemorrhage (UH). To study this, brain injury was induced by dropping a 450-g weight from 1.5 m onto a steel helmet attached to the skull of male adult rats. Immediately after TBI, a midline laparotomy was performed and both lumbar veins were isolated and severed at the junction with the vena cava. At 45 min after TBI/UH, ghrelin (4, 8 or 16 nmol/rat) or 1 mL normal saline (vehicle) was intravenously administered. Brain levels of TNF-α and IL-6, and cleaved PARP-1 levels in the cortex were measured at 4 h after TBI/UH. Beam balance test, forelimb placing test and hindlimb placing test were used to assess sensorimotor and reflex function. In additional groups of animals, ghrelin (16 nmol/rat) or vehicle was subcutaneously (s.c.) administered daily for 10 d after TBI/UH. The animals were monitored for 28 d to record body weight changes, neurological severity scale and survival. Our results showed that ghrelin downregulated brain levels of TNF-α and IL-6, reduced cortical levels of cleaved PARP-1, improved sensorimotor and reflex functions, and decreased mortality after TBI/UH. Thus, ghrelin has a great potential to be further developed as an effective resuscitation approach for the trauma victims with brain injury and severe blood loss.     

Spatial calcium kinetics after a traumatic brain injury

Biomechanics and Modeling in Mechanobiology - Accurate modelling of intracellular calcium ion ( $$Ca^{2+}$$ ) concentration evolution is valuable as it is known to rapidly increase during a...     

Alterations of cerebral cortex and hippocampal proteasome subunit expression and function in a traumatic brain injury rat model

Following cellular stress or tissue injury, the proteasome plays a critical role in protein degradation and signal transduction. The present study examined the β-subunit expression of constitutive proteasomes (β1, β2, and β5), immunoproteasomes (β1i, β2i, and β5i) and the 11S proteasome activator, PA28α, in the rat CNS after traumatic brain injury (TBI). Concomitant measures assessed changes in proteasome activities. Quantitative real time PCR results indicated that β1 and β2 mRNA levels were not changed, while β5 mRNA levels were significantly decreased in injured CNS following TBI. However, β1i, β2i, β5i, and PA28α mRNA levels were significantly increased in the injured CNS. Western blotting studies found that β1, β2, β5, β2i, and β5i subunit protein levels remained unchanged in the injured CNS, but β1i and PA28α protein levels were significantly elevated in ipsilateral cerebral cortex and hippocampus. Proteasome activity assays found that peptidyl glutamyl peptide hydrolase-like and chymotrypsin-like activity were significantly reduced in the CNS after TBI, and that trypsin-like proteasome activity was increased in the injured cerebral cortex. Our results demonstrated that both proteasome composition and function in the CNS were affected by trauma. Treatments that preserve proteasome function following CNS injury may be beneficial as an approach to cerebral neuroprotection.     

Neuroglobin expression and oxidant/antioxidant balance after graded traumatic brain injury in the rat

Neuroglobin is a neuron-specific hexacoordinated globin capable of binding various ligands, including O₂, NO, and CO, the biological function of which is still uncertain. Various studies seem to indicate that neuroglobin is a neuroprotective agent when overexpressed, acting as a potent inhibitor of oxidative and nitrosative stress. In this study, we evaluated the pathophysiological response of the neuroglobin gene and protein expression in the cerebral tissue of rats sustaining traumatic brain injury of differing severity, while simultaneously measuring the oxidant/antioxidant balance. Two levels of trauma (mild and severe) were induced in anesthetized animals using the weight-drop model of diffuse axonal injury. Rats were then sacrificed at 6, 12, 24, 48, and 120 h after traumatic brain injury, and the gene and protein expression of neuroglobin and the concentrations of malondialdehyde (as a parameter representative of reactive oxygen species-mediated damage), nitrite + nitrate (indicative of NO metabolism), ascorbate, and glutathione (GSH) were determined in the brain tissue. Results indicated that mild traumatic brain injury, although causing a reversible increase in oxidative/nitrosative stress (increase in malondialdehyde and nitrite + nitrate) and an imbalance in antioxidants (decrease in ascorbate and GSH), did not induce any change in neuroglobin. Conversely, severe traumatic brain injury caused an over nine- and a fivefold increase in neuroglobin gene and protein expression, respectively, as well as a remarkable increase in oxidative/nitrosative stress and depletion of antioxidants. The results of this study, showing a lack of effect in mild traumatic brain injury as well as asynchronous time course changes in neuroglobin expression, oxidative/nitrosative stress, and antioxidants in severe traumatic brain injury, do not seem to support the role of neuroglobin as an endogenous neuroprotective antioxidant agent, at least under pathophysiological conditions.     

人参总皂苷治疗创伤性脑损伤有效剂量和时间窗的研究

目的:探讨人参总皂苷(GTS)治疗大鼠创伤性脑损伤(TBI)的有效剂量和有效时间窗。方法:采用改良Feeney法制备TBI后,腹腔注射GTS,对伤后大鼠神经功能和伤侧脑组织形态学进行观察。结果:TBI后6 h开始治疗,GTS不同剂量干预,神经行为学与组织学结果显示:伤后2~14 d,(10,20,40,60,80 mg/kg)GTS组与TBI组比较,差异具有统计学意义(P<0.05),其中(20,40,60 mg/kg)GTS的治疗效果更显著,能明显改善神经行为,减少海马部位神经细胞的丢失。在有效时间窗研究中,采用GTS 20 mg/kg,于TBI后3 h、6 h时间点开始治疗,GTS组效果明显,与TBI组比较,差异有统计学意义,TBI后12 h、24 h开始治疗,无明显效果。结论:TBI后给予GTS治疗,可减轻脑组织损伤,促进神经功能恢复,在10~80 mg/kg剂量范围均有一定疗效,最佳剂量范围为20~60 mg/kg;GTS有效时间窗为伤后6 h。     

The expression pattern of ADP-ribosyltransferase 3 in rat traumatic brain injury

Mammalian ecto ADP-ribosyltransferases (ARTs) can regulate the biological functions of various types of cells by catalyzing the transfer of single ADP-ribose moiety from NAD⁺ to a specific amino acid in a target protein. ART3 is a member of the known ART family which is involved in cell division, DNA-repair and the regulation of the inflammatory response. To elucidate the expression, cellular localization and possible functions of ART3 in central nervous system (CNS) lesion and repair, we performed an acute traumatic brain injury model in adult rats. Western blot analysis showed that the expression of ART3 in ipsilateral brain cortex increased, then reached a peak at day 3 after traumatic brain injury (TBI), and gradually declined during the following days. But in the contralateral brain cortex, no obvious alterations were observed. Immunohistochemistry revealed the highly significant accumulation of ART3 at the ipsilateral brain in comparison to contralateral cerebral cortex. Double immunofluorescence labeling suggested that ART3 was localized mainly in the plasmalemma of neurons, but not in astrocytes or microglias within 3 mm from the lesion site at day 3 post-injury. In addition, we detected the expression profiles of caspase-3 and growth associated protein 43 (GAP-43) whose changes were correlated with the expression profiles of ART3 in this TBI model. Besides, co-localization of ART3/active caspase-3 and ART3/GAP43 were detected in NeuN-positive cells, respectively. Moreover, Pheochromocytoma (PC12) cells were treated with H₂O₂ to establish an apoptosis model. The results showed that the expression of ART3 was increased in the concentration and time dependence way. To further examine the involvement of ART3 in apoptosis of PC12, 3-Methoxybenzamide was used in flow cytometry analysis of apoptotic cells stained with Annexin V and PI. The experimental group in which 3-Methoxybenzamide used had a relative low level of apoptotic index compared with the untreated group. Together with previous reports, we hypothesize that ART3 may play important roles in CNS pathophysiology after TBI and further research is needed to have a good understanding of its function and mechanism.     

Change in plasma visfatin level after severe traumatic brain injury

Higher plasma visfatin concentration has been associated with ischemic stroke. Thus, we sought to investigate change in plasma visfatin level after traumatic brain injury and to evaluate its relation with disease outcome. Seventy-six healthy controls and 98 patients with acute severe traumatic brain injury were recruited. Twenty-seven patients (27.6%) died and 48 patients (49.0%) suffered from unfavorable outcome (Glasgow outcome scale score of 1–3) in 6 months. On admission, plasma visfatin level was increased in patients than in healthy controls and was highly correlated with Glasgow Coma Scale score. A multivariate analysis identified plasma visfatin level as an independent predictor for 6-month mortality and unfavorable outcome. According to receiver operating characteristic curve analysis, the predictive value of the plasma visfatin concentration was similar to Glasgow Coma Scale score's. In a combined logistic-regression model, visfatin did not improve the predictive value of Glasgow Coma Scale score. Thus, increased plasma visfatin level is associated with 6-month clinical outcomes after severe traumatic brain injury.     

Mitochondrial dysfunction early after traumatic brain injury in immature rats

Mitochondria play central roles in acute brain injury; however, little is known about mitochondrial function following traumatic brain injury (TBI) to the immature brain. We hypothesized that TBI would cause mitochondrial dysfunction early (<4 h) after injury. Immature rats underwent controlled cortical impact (CCI) or sham injury to the left cortex, and mitochondria were isolated from both hemispheres at 1 and 4 h after TBI. Rates of phosphorylating (State 3) and resting (State 4) respiration were measured with and without bovine serum albumin. The respiratory control ratio was calculated (State 3/State 4). Rates of mitochondrial H(2)O(2) production, pyruvate dehydrogenase complex enzyme activity, and cytochrome c content were measured. Mitochondrial State 4 rates (ipsilateral/contralateral ratios) were higher after TBI at 1 h, which was reversed with bovine serum albumin. Four hours after TBI, pyruvate dehydrogenase complex activity and cytochrome c content (ipsilateral/contralateral ratios) were lower in TBI mitochondria. These data demonstrate abnormal mitochondrial function early (相似文献   

Sirtuin 1 alleviates neuroinflammation-induced apoptosis after traumatic brain injury

Sirtuin 1 (SIRT1) plays a very important role in a wide range of biological responses, such as metabolism, inflammation and cell apoptosis. Changes in the levels of SIRT1 have been detected in the brain after traumatic brain injury (TBI). Further, SIRT1 has shown a neuroprotective effect in some models of neuronal death; however, its role and working mechanisms are not well understood in the model of TBI. This study aimed to address this issue. SIRT1-specific inhibitor (sirtinol) and activator (A3) were introduced to explore the role of SIRT1 in cell apoptosis. Results of the study suggest that SIRT1 plays an important role in neuronal apoptosis after TBI by inhibiting NF-κB, IL-6 and TNF-α deacetylation and the apoptotic pathway sequentially, possibly by alleviating neuroinflammation.     

肌苷促进脑损伤后神经功能恢复的实验研究

目的：中枢损伤是目前致残率最高的疾病之一,肌苷对于神经损伤后功能恢复的促进作用已经成为研究热点,本研究拟建立一侧前肢瘫痪的大鼠脑外伤模型,证实肌苷治疗促进中枢损伤后上肢功能恢复的有效性,同时初步探索其机制。方法：建立一侧运动皮层冲击损毁的大鼠模型,通过肢体不对称实验、抓取实验等行为学观察证实其惠侧上肢功能受损,后在实验组进行肌苷药物14天,观察28天内上肢功能的恢复情况,与对照组作对比。证实其行为学上的有效性,同时对损伤侧大脑进行顺行BDA染色,探索其内在机制。结果：通过28天的观察发现经过肌苷治疗的的实验组大鼠肢体不对称实验、抓取实验等行为学评分明显好于隐性对照组,顺行BDA染色证实其有促进损伤周围健存皮层突触再生和代偿的作用。结论：肌苷可以促进中枢损伤后大鼠残存神经元得突触再生,使其大脑能在最大程度上代偿其丧失的功能,该药物可能会成为一种新的中枢损伤治疗的前体药物。     

肌苷促进脑损伤后神经功能恢复的实验研究

目的:中枢损伤是目前致残率最高的疾病之一,肌苷对于神经损伤后功能恢复的促进作用已经成为研究热点,本研究拟建立一侧前肢瘫痪的大鼠脑外伤模型,证实肌苷治疗促进中枢损伤后上肢功能恢复的有效性,同时初步探索其机制。方法:建立一侧运动皮层冲击损毁的大鼠模型,通过肢体不对称实验、抓取实验等行为学观察证实其患侧上肢功能受损,后在实验组进行肌苷药物14天,观察28天内上肢功能的恢复情况,与对照组作对比,证实其行为学上的有效性,同时对损伤侧大脑进行顺行BDA染色,探索其内在机制。结果:通过28天的观察发现经过肌苷治疗的的实验组大鼠肢体不对称实验、抓取实验等行为学评分明显好于隐性对照组,顺行BDA染色证实其有促进损伤周围健存皮层突触再生和代偿的作用。结论:肌苷可以促进中枢损伤后大鼠残存神经元得突触再生,使其大脑能在最大程度上代偿其丧失的功能,该药物可能会成为一种新的中枢损伤治疗的前体药物。