ABSTRACT
Cognitive dysfunction caused by blast traumatic brain injury (bTBI) is a serious neurological disease with high incidence, serious condition and poor prognosis. bTBI can lead to a series of symptoms such as short-term memory loss, inattention or multi-tasking difficulties. In severe cases, bTBI can develop into Alzheimer′s disease, which has a great impact on patients′ normal work and life. At present, researches on cognitive dysfunction caused by bTBI mainly involve model construction, pathogenesis, pathophysiological changes, diagnosis and treatment, etc., and the molecular mechanism of its occurrence remains to be further studied. Under normal physiological conditions, the release of excitatory and inhibitory neurotransmitters, the release and uptake of Ca 2+, oxidation and antioxidant systems, and the promotion and inhibition of apoptosis are in a dynamic balance. bTBI disturbs the balance, which will lead to the damage of nerve cells at the molecular level, thus resulting in the occurrence of cognitive dysfunction. To this end, the authors summarized the aspects of excitatory toxicity and Ca 2+homeostasis disorder, oxidative stress, inflammation and edema, apoptosis, etc., and reviewed the research progress on the molecular mechanism of cognitive dysfunction caused by bTBI, so as to provide a reference for the treatment and rehabilitation of cognitive dysfunction in patients with bTBI.
ABSTRACT
Objective:To investigate the effects of thermobaric charge explosion simulated gas on long-term neurobehavior and hippocampal neurogenesis in rats.Methods:A total of 48 male SPF grade SD rats aged 8-10 weeks were randomly divided into control group, 5 min exposure group, 10 min exposure group and 15 min exposure group, with 12 rats in each group. Twenty-eight days after inhalation of infection, the anxiety-like behavior of rats was evaluated by an elevated cross maze, and the learning and memory function of rats was evaluated by two-way active avoidance experiment. The number of positive cells of rat hippocampal dentate gyrus neural stem cells marker molecule neural epithelial cell protein (SOX2) and mature neuron marker molecular neuronal nuclei (NeuN) was detected by immunofluorescence staining. Western blot was used to detect SOX2 and NeuN protein expression in the hippocampal tissues of rats. GraphPad prism 8.0 software was used for data analysis.The comparison of repeated measurement design data was carried out by repeated measurement ANOVA.One-way ANOVA was used for inter group comparisons, and Tukey test was used for pairwise comparison. Hippocampal nerve cells were counted using the Image J software.Results:(1) The experimental results of the elevated cross maze showed that the percentage of arm opening and the percentage of open arm residence time in each group had significant group effects ( F=22.31, 5.43, all P<0.05). The percentage of open arm entry times of rats in the 5 min, 10 min and 15 min exposure group ((28.85±1.47)%, (15.04±4.69)%, (12.66±2.89)%) and the percentage of residence time in open arm ((12.12±2.64)%, (12.16±1.11)%, (8.73±3.52)%) were all lower than those of the control group ((65.40±1.86)%, (42.92±3.12)%) (all P<0.05). There were no statistically significant differences in pairwise comparison among the three exposure groups (all P>0.05). (2)During the memory acquisition period, the results of repeated-ANOVA showed that the time main effect ( F=56.46), the group main effect ( F=16.64) and the interaction effect had significant differences( F=4.21)(all P<0. 05). The difference values of active avoidance number between the 4th day and 1st day among the four groups were significant different ( F=68.63, P<0.05). During the memory reproduction period, there were significant differences in active avoidance number and active avoidance time among the four groups ( F=8.17, 8.28, both P<0.05). The active avoidance numbers in 10 min and 15 min exposure groups((2.50±0.26) times, (2.33±0.06) times)were significantly lower than those in the control group ((8.33±3.72) times) (both P<0.05), and the active avoidance time ((6.25±0.40)s, (6.61±1.63)s) were significantly higher than those in the control group((3.69±1.41)s) (both P<0.05). The active avoidance numbers in 10 min and 15 min exposure groups were significantly lower than that in 5 min exposure group (both P<0.05). (3) The results of immunofluorescence staining showed that the numbers of SOX2-positive cells in the four groups were statistically significant ( F=5.33, P<0.05). The SOX2-positive cells in 15 min exposure group (4.33±1.12) was significantly lower than that in control group (7.67±1.52) ( P<0.05). The numbers of NeuN-positive cells in the four groups were significantly different ( F=11.06, P<0.05), and the NeuN-positive cells in the 10 min and 15 min exposure groups((105.67±8.50), (88.33±9.50)) were significantly lower than that in the control group (127.00±6.56) ( P<0.05). The NeuN-positive cells in 15 min exposure group were significantly lower than that in 5 min exposure group (110.67±8.32) ( P<0.05). (4) Western blot results showed that the relative expression of SOX2 and NeuN proteins in the four groups was statistically significant ( F=11.560, 7.035, both P<0.05). The relative expression of SOX2 and NeuN proteins in the 15 min exposure group were significantly lower than those in control group (both P<0.05). The relative expression of SOX2 protein in 15 min exposure group was significantly lower than that in 5 min exposure group ( P<0.05). Conclusion:Acute exposure to warm pressure charge explosion simulated gas can lead to anxiety-like behavior, learning and memory deficits in rats, and significantly reduce the protein expression levels of hippocampal dentate gyrus neural stem cells and mature neuronal marker molecules SOX2 and NeuN.
ABSTRACT
Lung is one of the most sensitive target organs of human beings under the shock waves. Due to its serious injury, rapid development and high mortality, blast lung injury has been a widely concerned research topic in the field of military medicine. In the normal physiological state, the body is in a dynamic balance between pro-inflammaton and anti-inflammation, oxidation and anti-oxidation, promoting apoptosis and inhibiting apoptosis. While blast lung injury breaks the balance and causes physiological, biochemical and pathological changes in the body, seriously leading to acute respiratory distress syndrome and multiple organ dysfunction syndrome, and eventually the mortality. So far, the researches on blast lung injury mainly involve damage model, pathogenesis, pathological changes, intervention treatment and so on, which has achieved great research findings. In the review, the authors summarize the progress of molecular mechanism for blast lung injury from the perspective of inflammatory reaction, oxidative stress, apoptosis and so on, which may promote the discovery of new targets for the diagnosis, treatment and rehabilitation intervention of blast lung injury.
ABSTRACT
Glioblastoma (GBM) is the most common and lethal primary neoplasm in the central nervous system. Despite intensive treatment, the prognosis for patients with GBM remains poor, with a median survival of 14-16 months. 90% of GBMs are primary GBMs that are full-blown at diagnosis without evidences of a pre-existing less-malignant precursor lesion. Therefore, identification of the cell(s) of origin for GBM-the normal cell or cell type that acquires the initial GBM-promoting genetic hit(s)-is the key to the understanding of the disease etiology and the development of novel therapies. Neural stem cells and oligodendrocyte precursor cells are the two major candidates for the cell(s) of origin for GBM. Latest data from human samples have reignited the longstanding debate over which cells are the clinically more relevant origin for GBMs. By critically analyzing evidences for or against the candidacy of each cell type, we highlight the most recent progress and debate in the field, explore the clinical implications, and propose future directions toward early diagnosis and preventive treatment of GBMs.