Objective To summarize the research progress on the mechanism related to traumatic brain injury (TBI) to promote fracture healing, and to provide theoretical basis for clinical treatment of fracture non-union. Methods The research literature on TBI to promote fracture healing at home and abroad was reviewed, the role of TBI in fracture healing was summarized from three aspects of nerves, body fluids, and immunity, to explore new ideas for the treatment of fracture non-union. Results Numerous studies have shown that fracture healing is faster in patients with fracture combined with TBI than in patients with simple fracture. It is found that the expression of various cytokines and hormones in the body fluids of patients with fracture and TBI is significantly higher than that of patients with simple fracture, and the neurofactors released by the nervous system reaches the fracture site through the damaged blood-brain barrier, and the chemotaxis and aggregation of inflammatory cells and inflammatory factors at the fracture end of patients with combined TBI also differs significantly from those of patients with simple fracture. A complex network of humoral, neural, and immunomodulatory networks together promote regeneration of blood vessels at the fracture site, osteoblasts differentiation, and inhibition of osteoclasts activity. Conclusion TBI promotes fracture healing through a complex network of neural, humoral, and immunomodulatory, and can treat fracture non-union by intervening in the perifracture microenvironment.
ObjectiveTo investigate the possibility and effect of chitosan porous scaffolds combined with bone marrow mesenchymal stem cells (BMSCs) in repair of neurological deficit after traumatic brain injury (TBI) in rats.MethodsBMSCs were isolated, cultured, and passaged by the method of bone marrow adherent culture. The 3rd generation BMSCs were identified by the CD29 and CD45 surface antigens and marked by 5-bromo-2-deoxyuridine (BrdU). The chitosan porous scaffolds were produced by the method of freeze-drying. The BrdU-labelled BMSCs were co-cultured in vitro with chitosan porous scaffolds, and were observed by scanning electron microscopy. MTT assay was used to observe the cell growth within the scaffold. Fifty adult Sprague Dawley rats were randomly divided into 5 groups with 10 rats in each group. The rat TBI model was made in groups A, B, C, and D according to the principle of Feeney’s free fall combat injury. Orthotopic transplantation was carried out at 72 hours after TBI. Group A was the BMSCs and chitosan porous scaffolds transplantation group; group B was the BMSCs transplantation group; group C was the chitosan porous scaffolds transplantation group; group D was the complete medium transplantation group; and group E was only treated with scalp incision and skull window as sham-operation group. Before TBI and at 1, 7, 14, and 35 days after TBI, the modified neurological severity scores (mNSS) was used to measure the rats’ neurological function. The Morris water maze tests were used after TBI, including the positioning voyage test (the incubation period was detected at 31-35 days after TBI, once a day) and the space exploration test (the number of crossing detection platform was detected at 35 days after TBI). At 36 days after TBI, HE staining and immunohistochemistry double staining [BrdU and neurofilament triplet H (NF-H) immunohistochemistry double staining, and BrdU and glial fibrillary acidic protein (GFAP) immunohistochemistry double staining] were carried out to observe the transplanted BMSCs’ migration and differentiation in the damaged brain areas.ResultsFlow cytometry test showed that the positive rate of CD29 of the 3rd generation BMSCs was 98.49%, and the positive rate of CD45 was only 0.85%. After co-cultured with chitosan porous scaffolds in vitrofor 48 hours, BMSCs were spindle-shaped and secreted extracellular matrix to adhere in the scaffolds. MTT assay testing showed that chitosan porous scaffolds had no adverse effects on the BMSCs’ proliferation. At 35 days after TBI, the mNSS scores and the incubation period of positioning voyage test in group A were lower than those in groups B, C, and D, and the number of crossing detection platform of space exploration test in group A was higher than those in groups B, C, and D, all showing significant differences (P<0.05); but no significant difference was found between groups A and E in above indexes (P>0.05). HE staining showed that the chitosan porous scaffolds had partially degraded, and they integrated with brain tissue well in group A; the degree of repair in groups B, C, and D were worse than that of group A. Immunohistochemical double staining showed that the transplanted BMSCs could survive and differentiate into neurons and glial cells, some differentiated neural cells had relocated at the normal brain tissue; the degree of repair in groups B, C, and D were worse than that of group A.ConclusionThe transplantation of chitosan porous scaffolds combined with BMSCs can improve the neurological deficit of rats following TBI obviously, and also inhabit the glial scar’s formation in the brain damage zone, and can make BMSCs survive, proliferate, and differentiate into nerve cells in the brain damage zone.
ObjectiveTo investigate the effects of large trauma craniotomy on severe traumatic brain injury. MethodsA total of 132 cases of severe traumatic brain injury adopted large trauma craniotomy between July 2008 and August 2013, and the clinical data were retrospectively analyzed. ResultsAccording to the results of GOS assessment at discharge, 67 patients (50.75%) were satisfied, 26 (19.70%) were mildly disable, 10 (7.58%) were severely disable, 12 (9.09%) were in vegetative state, and 17 (12.88%) were dead. ConclusionCorrect use of large trauma craniotomy on severe brain injury cases will help to improve the treatment outcome, reduce complications and improve quality of survival.
ObjectiveTo study the effect of hyperbaric oxygen combined with nimodipine in the treatment of cerebral dysfunction resulted from traumatic brain injury. MethodWe retrospectively collected and analyzed the data of 124 patients with cerebral dysfunction induced by traumatic brain injury, admitted to the Neurosurgery Department during February 2011 to February 2014. All the patients were divided into the traditional treatment group (n=45), the traditional treatment with hyperbaric oxygen group (HBO group, n=40) and the traditional treatment with nimodipine and hyperbaric oxygen group (integrated group, n=39). The differences among the three groups in neurological injury severity evaluated by National Institute of Health Stroke Scale and the cerebral blood flow were recorded and analyzed at three time points (before the treatment, 2 and 4 weeks after treatment). ResultsThere was no significant difference in neurological injury severity and cerebral blood flow among these three groups before treatment (P>0.05). Evaluated at 2 and 4 weeks after treatments, the neurological injury severity of HBO group and integrated group were significantly less than the traditional treatment group (P<0.05); the neurological severity score of integrated group was significantly lower than the HBO group (P<0.05); the cerebral blood flow of HBO group and integrated group were significantly higher than the traditional treatment group (P<0.05); and the cerebral blood flow of integrated group was significantly higher than the HBO group (P<0.05). ConclusionsThe combination therapy of hyperbaric oxygen combined with nimodipine is effective in the treatment of cerebral dysfunction induced by traumatic brain injury, because of its attenuation of neurological injury severity and increase of cerebral blood flow.
Mild traumatic brain injury has a large number of patients in China. In recent years, studies have pointed out that the return to work is a key goal for rehabilitation, indicating that patients can start integrating into society again and resume normal work and life as soon as possible, which has a positive impact on their rehabilitation. This article summarizes the relevant factors that affect the return to work from four aspects: individual, disease, occupation, and social support, and introduces intervention measures such as follow-up and health education, neuromodulatory technology, symptom management, social support, cognitive and occupational rehabilitation, and multidisciplinary occupational rehabilitation, aiming to provide a reference for promoting the research and development of patients with mild traumatic brain injury returning to work in China.
Objective To collect the clinical data of victims with traumatic brain injury (TBI) admitted in the West China Hospital of Sichuan University within 2 weeks after 4.20 Lushan earthquake, and to analyze their clinical characteristics and effects of early rehabilitation, so as to provide baseline data for rescue TBI victims with the early rehabilitation treatment during emergency medical rescue. Methods A total of 392 victims admitted in the hospital from April 20th, 2013 to May 3rd, 2013 were screened, of which the TBI victims were clinically assessed and treated with early rehabilitation. Then both the activities of daily living (ADL) and the Rancho Los Amigos Cognitive Recovery Scale (RLA) before and after the treatment were analyzed. The data were input by Excel software, and the statistical analysis was performed by SPSS softwar. Results A total of 51 TBI victims at age from 3 to 84 years old were included finally. The categories of TBI included subarachnoid hemorrhage (41.2%), intracranial hematoma (33.3%) and mixed type (33.3%), and the severity were associated with the type of TBI. The GCS score of cerebral concussion was higher (13.25 ± 0.62) while that of the diffuse axonal injury was lower (4.50 ± 0.71). All victims (100%) had limited ADL, 74.51% had cognitive dysfunction, 9.80% had speech disorder, and 7.84% had dysphagia. After the early rehabilitation treatment, both ADL (before treatment: 34.82 ± 58.29, after treatment: 69.63 ± 22.29) and RLA (pre-treatment: 4.16 ± 1.24, treatment: 7.20 ± 1.69) were obviously higher than those before treatment, with statistical differences (both P lt;0.05). Conclusion The TBI categories of Lushan earthquake victims are various and mixed, and the severity associated with the type of TBI. All TBI victims are accompanied with more clinical problems and functional limitation. Early rehabilitation treatment is safe and effective to improve ADL and RLA as well.
Objective To review the possible mechanisms of the mammal ian target of rapamycin (mTOR) in theneuronal restoration process after nervous system injury. Methods The related l iterature on mTOR in the restoration ofnervous system injury was extensively reviewed and comprehensively analyzed. Results mTOR can integrate signals fromextracellular stress and then plays a critical role in the regulation of various cell biological processes, thus contributes to therestoration of nervous system injury. Conclusion Regulating the activity of mTOR signaling pathway in different aspects cancontribute to the restoration of nervous system injury via different mechanisms, especially in the stress-induced brain injury.mTOR may be a potential target for neuronal restoration mechanism after nervous system injury.
ObjectiveTo build core items of database for traumatic brain injury (TBI) in rehabilitation medical database.MethodsRelevant factors in TBI database were summarized through database search in combination of acknowledged relevant items of TBI in rehabilitation medical database. Delphi method was used for experts to determine which items should be included by two rounds of questionnaires.ResultsThe average authority coefficient of experts was 0.94. After two rounds of questionnaires, 73 were included. Its contents include: general conditions, brain damage and disposal, relevant rehabilitation assessment scales, previous rehabilitation treatment, treatment expenses, and contents that require attention during re-evaluation.ConclusionsAfter two rounds of Delphi evaluation, the core items of database for TBI are identified with high recognition and consistency from experts.
Objective To explore the number variation trend of inpatients with traumatic brain injury (TBI) in high altitude and plain areas. Methods The first page information in medical records of TBI patients, who were admitted to military hospitals from 2001 to 2007, was searched and extracted from the Chinese Trauma Database. Two military hospitals in high altitude area and another two in the same hospital level in plain area were selected. Then, the number variation trend of TBI inpatients in those two areas was compared. Results In high altitude area, the proportion of male patients and their median inpatient days were higher, while the age, proportion of Han patients and surgery rate were lower than those in plain area (all Plt;0.001). During 2001-2007, there were 9 141 TBI patients discharged from the four hospitals, and the average annual growth rate was 13.15%. In high altitude area, the average annual growth rate of discharged inpatients was 24.00%, while in plain area, it was just 7.09%. The 4 common categories of TBI were intracranial injury, open wound of the head, neck and trunk, skull fracture, and other injuries. Conclusion Compared with the plain area, there are significant differences in the demographics, hospital stay and surgery of inpatients in high altitude area. The average annual growth rate of TBI inpatients discharged from hospitals in high altitude area is faster than that in plain area, to which should be paid attention by relevant departments.
The finite element method is a new method to study the mechanism of brain injury caused by blunt instruments. But it is not easy to be applied because of its technology barrier of time-consuming and strong professionalism. In this study, a rapid and quantitative evaluation method was investigated to analyze the craniocerebral injury induced by blunt sticks based on convolutional neural network and finite element method. The velocity curve of stick struck and the maximum principal strain of brain tissue (cerebrum, corpus callosum, cerebellum and brainstem) from the finite element simulation were used as the input and output parameters of the convolutional neural network The convolutional neural network was trained and optimized by using the 10-fold cross-validation method. The Mean Absolute Error (MAE), Mean Square Error (MSE), and Goodness of Fit (R2) of the finally selected convolutional neural network model for the prediction of the maximum principal strain of the cerebrum were 0.084, 0.014, and 0.92, respectively. The predicted results of the maximum principal strain of the corpus callosum were 0.062, 0.007, 0.90, respectively. The predicted results of the maximum principal strain of the cerebellum and brainstem were 0.075, 0.011, and 0.94, respectively. These results show that the research and development of the deep convolutional neural network can quickly and accurately assess the local brain injury caused by the sticks blow, and have important application value for understanding the quantitative evaluation and the brain injury caused by the sticks struck. At the same time, this technology improves the computational efficiency and can provide a basis reference for transforming the current acceleration-based brain injury research into a focus on local brain injury research.