Guanyu Jiang

Rapid detection of pneumothorax by ultrasonography in patients with multiple trauma.

IntroductionEarly detection of pneumothorax in multiple trauma patients is critically important. It can be argued that the efficacy of ultrasonography (US) for detection of pneumothorax is enhanced if it is performed and interpreted directly by the clinician in charge of the patients. The aim of this study was to assess the ability of emergency department clinicians to perform bedside US to detect and assess the size of the pneumothorax in patients with multiple trauma.MethodsOver a 14 month period, patients with multiple trauma treated in the emergency department were enrolled in this prospective study. Bedside US was performed by emergency department clinicians in charge of the patients. Portable supine chest radiography (CXR) and computed tomography (CT) were obtained within an interval of three hours. Using CT and chest drain as the gold standard, the diagnostic efficacy of US and CXR for the detection of pneumothorax, defined as rapidity and accuracy (sensitivity, specificity, positive predictive value, negative predictive value), were compared. The size of the pneumothorax (small, medium and large) determined by US was also compared to that determined by CT.ResultsOf 135 patients (injury severity score = 29.1 ± 12.4) included in the study, 83 received mechanical ventilation. The time needed for diagnosis of pneumothorax was significantly shorter with US compared to CXR (2.3 ± 2.9 versus 19.9 ± 10.3 minutes, p < 0.001). CT and chest drain confirmed 29 cases of pneumothorax (21.5%). The diagnostic sensitivity, specificity, positive and negative predictive values and accuracy for US and radiography were 86.2% versus 27.6% (p < 0.001), 97.2% versus 100% (not significant), 89.3% versus 100% (not significant), 96.3% versus 83.5% (p = 0.002), and 94.8% versus 84.4% (p = 0.005), respectively. US was highly consistent with CT in determining the size of pneumothorax (Kappa = 0.669, p < 0.001).ConclusionBedside clinician-performed US provides a reliable tool and has the advantages of being simple and rapid and having higher sensitivity and accuracy compared to chest radiography for the detection of pneumothorax in patients with multiple trauma.

Penehyclidine hydrochloride attenuates LPS-induced acute lung injury involvement of NF-κB pathway

To investigate the protective effects of penehyclidine hydrochloride (PHC) in lipopolysaccharide (LPS)-induced acute lung injury (ALI) and the underlying molecular mechanism. ALI was induced by intravenous injection of LPS (5mg/kg). Male Sprague-Dawley (SD) rats challenged with or without LPS were pretreated with varied doses of PHC 0.5h before injection of LPS or saline. Blood gas in arterial blood, lung weight gain, bronchoalveolar lavage fluid (BALF), and neutrophils sequestration were examined 6h after administration of LPS. Pathological changes of lung tissue were measured by light microscopy. Phosphorylation of mitogen-activated protein kinase (MAPK) family and NF-kappaB were detected by western blot. All animals demonstrated drops in arterial oxygen tension (PaO(2)) after LPS application, which were significantly reversed by PHC pretreatment. Administration of PHC reduced lung water gain, bronchoalveolar lavage protein content, infiltration of neutrophils, malondialdehyde (MDA) content, and lactate dehydrogenase (LDH) activity and enhanced superoxide dismutase (SOD) activity. Histopathological study also indicated that PHC treatment markedly attenuated lung histopathological changes, alveolar hemorrhage, and inflammatory cells infiltration with evidence of decreasing of myeloperoxidase (MPO) activity. Furthermore, p38MAPK, ERK, and NF-kappaB were activated in 6h after LPS treatment, which could be blunted by PHC, while JNK remained unchanged. These findings confirmed significant protection by PHC against LPS-induced lung vascular leak and inflammation and implicated inhibition of p38MAPK activation signaling a potential role for PHC in the management of ALI.

The analysis of risk factors of impacting mortality rate in severe multiple trauma patients with posttraumatic acute respiratory distress syndrome

OBJECTIVE We hypothesize that not all of the traditional risk factors of impacting mortality rate in commonly traumatic populations with posttraumatic acute respiratory distress syndrome (ARDS) are independently associated with those patient populations identified with severe multiple trauma. Rather, we postulate that there may exist significantly different impacting degrees of specific risk factors in stratified patients (surviving beyond 24 and 96 hours)--more severe multiple trauma with higher injury score and long-term mechanical ventilation as well. METHODS This is a retrospective cohort study regarding trauma as a single cause for emergency intensive care unit admission. Twenty-two items of potential risk factors of impacting mortality rate were calculated by univariate and multivariate logistic analyses to find distinctive items in these severe multiple trauma patients. RESULTS The unadjusted odds ratio and 95% confidence intervals of mortality rate were found to be associated with 6 (out of 22) risk factors, namely, (1) Acute Physiology and Chronic Health Evaluation II score, (2) duration of trauma factor, (3) aspiration of gastric contents, (4) sepsis, (5) pulmonary contusion, and (6) duration of mechanical ventilation. Significant results also appeared in stratified patients. CONCLUSIONS Impact of pulmonary contusion and Acute Physiology and Chronic Health Evaluation II score contributing to prediction of mortality may exist in the early phase after trauma. Sepsis is still a vital risk factor referring to systemic inflammatory response syndrome, infection, secondary multiple organ dysfunction, etc. Discharging trauma factors as early as possible becomes the critical therapeutic measure. Aspiration of gastric contents in emergency intensive care unit admission could lead to incremental mortality rate due to aspiration pneumonia. Long-standing mechanical ventilation should be constrained because it is likely to cause severe refractory complications.

Comparison of the new injury severity score and the injury severity score in multiple trauma patients

OBJECTIVE To assess whether these characteristics of less misclassification and greater area under receiver operator characteristic (ROC) curve of the new injury severity score (NISS) are better than the injury severity score (ISS) as applying it to our multiple trauma patients registered into the emergency intensive care unit (EICU). METHODS This was a retrospective review of registry data from 2 286 multiple trauma patients consecutively registered into the EICU from January 1,1997 to December 31, 2006 in the Second Affiliated Hospital, Medical School of Zhejiang University in China. Comparisons between ISS and NISS were made using misclassification rates, ROC curve analysis, and the H-L statistics by univariate and multivariate logistic progression model. RESULTS Among the 2 286 patients, 176 (7.7%) were excluded because of deaths on arrival or patients less than 16 years of age. The study population therefore comprised 2 110 patients. Mean EICU length of stay (LOS) was 7.8 days ?2.4 days. Compared with the blunt injury group, the penetrating injury group had a higher percentage of male, lower mean EICU LOS and age. The most frequently injured body regions were extremities and head/neck, followed by thorax, face and abdomen in the blunt injury group; whereas, thorax and abdomen were more frequently seen in the penetrating injury group. The minimum misclassification rate for NISS was slightly less than ISS in all groups (4.01% versus 4.49%). However, NISS had more tendency to misclassify in the penetrating injury group. This, we noted, was attributed mainly to a higher false-positive rate (21.04% versus 15.55% for ISS, t equal to 3.310, P less than 0.001), resulting in an overall misclassification rate of 23.57% for NISS versus 18.79% for ISS (t equal to 3.290, P less than 0.001). In the whole sample, NISS presented equivalent discrimination (area under ROC curve: NISS equal to 0.938 versus ISS equal to 0.943). The H-L statistics showed poorer calibration (48.64 versus 32.11, t equal to 3.305, P less than 0.001) in the penetrating injury group. CONCLUSIONS NISS should not replace ISS because they share similar accuracy and calibration in predicting multiple blunt trauma patients. NISS may be more sensitive but less specific than ISS in predicting mortality in certain penetrating injury patients.

Protective effect of raloxifene on lipopolysaccharide and acid- induced acute lung injury in rats

AbstractAim:To evaluate the protective effect of oral raloxifene on acute lung injury.Methods:Thirty adult, male Sprague-Dawley rats each weighing 180–210 g were used and divided into 3 groups: the raloxifene-lipopolysaccharide (LPS)-HCl group (n=10), the LPS-raloxifene-HCl group (n=10), and the placebo group (n=10). All the rats were injected intraperitoneally (ip) with 5 mg/kg LPS, and raloxifene (30 mg/kg) was orally administered 1 h before and 14 h after LPS injection into the raloxifene-LPS-HCl and the LPS-raloxifene-HCl groups, respectively; the placebo group received nothing. Sixteen hours after LPS injection, all the animals were anesthetized and the femoral artery was cannulated. All the rats received a direct intratracheal (IT) injection of HCl (pH 1.2; 0.5 mL/kg). The mean arterial pressure (MAP) and blood gas concentrations were measured. Fifteen rats (5 in each group, respectively) underwent a micro positron emission tomography (microPET) scan of the thorax 4 h after HCl instillation. The wet/dry (W/D) weight ratio determination and histopathological examination were also performed.Results:The rats in the LPS-raloxifene-HCl group had a lower [18F]fluorodeoxyglucose uptake compared with the rats in the placebo group (4.67±1.33 vs 9.01±1.58, respectively, P<0.01). The rats in the LPS-raloxifene-HCl group also had a lower histological lung injury score (8.20±1.23 vs 12.6±0.97, respectively, P<0.01) and W/D weight ratio (5.335±0.198 vs 5.886±0.257, respectively, P< 0. 01) compared to the placebo group. The rats in this group also showed better pulmonary gas exchange and more stable mean arterial pressure (MAP) compared to the placebo group.Conclusion:Raloxifene provides a significant protective effect on acute lung injury in rats induced first by LPS ip injection and then by HCl IT instillation.

Structural and functional improvement of injured brain after severe acute carbon monoxide poisoning by stem cell-based therapy in rats.

Objective: We investigated the feasibility and efficacy of bone marrow mesenchymal stem cells (BMSCs)–derived neural stem-like cells (MS-NSCs) therapy on injured brain in rats after severe acute carbon monoxide (CO) poisoning. Design: Controlled animal study. Setting: Research laboratory of a university hospital. Subjects: Sprague-Dawley rats weighing 230 ± 20 g and 90 ± 10 g. Interventions: The rats were exposed to 1000 ppm CO in air for 40 minutes and then to 3000 ppm for another 20 minutes until they lost consciousness. Approximately 7 × 106 allogeneic BMSCs or MS-NSCs labeled with BrdU were infused into the poisoned rats via the internal carotid after a 24-hour resuscitation. The rats with and without CO poisoning were used as placebo and sham controls, respectively. Measurements and Main Results: The neurologic and cognitive functions were evaluated by Neurologic Severity Scores and Morris water maze tests. Examinations with immunohistochemistry, myelin, and hematoxylin–eosin staining were made to assess cerebral structure after 5 weeks. Histologically, the compactness and arrangement of the insulted white matter were improved by the cellular treatments. The transplanted MS-NSCs were positive for microtubule-associated protein 2 in hippocampus, 84.6% ± 5.6%, and for glial fibrillary acidic protein in subventricular white matter and hippocampus, 32.2% ± 2.5% and 9.7% ± 1.2%, respectively, although the MS-NSCs group showed a larger fraction in the expression of the above markers in corresponding domains compared with the BMSCs group. The MS-NSCs also displayed a higher survival rate than BMSCs in most domains of diffusively injured brain, leading to a better improvement in the Morris water maze test (p < 0.05). Conclusions: The stem cell–based therapy could be advantageous for improving the structure and function of injured brain in rats after severe acute CO poisoning, indicating the potential use as a novel approach for severely CO-poisoned patients with delayed neurologic sequelae. Furthermore, MS-NSCs may render better therapeutic effects after neurologic injury than untreated BMSCs.

Development of the science of mass casualty incident management: reflection on the medical response to the Wenchuan earthquake and Hangzhou bus fire *

ObjectiveIn this paper, we review the previous classic research paradigms of a mass casualty incident (MCI) systematically and reflect the medical response to the Wenchuan earthquake and Hangzhou bus fire, in order to outline and develop an improved research paradigm for MCI management.MethodsWe searched PubMed, EMBASE, China Wanfang, and China Biology Medicine (CBM) databases for relevant studies. The following key words and medical subject headings were used: ‘mass casualty incident’, ‘MCI’, ‘research method’, ‘Wenchuan’, ‘earthquake’, ‘research paradigm’, ‘science of surge’, ‘surge’, ‘surge capacity’, and ‘vulnerability’. Searches were performed without year or language restriction. After searching the four literature databases using the above listed key words and medical subject headings, related articles containing research paradigms of MCI, 2008 Wenchuan earthquake, July 5 bus fire, and science of surge and vulnerability were independently included by two authors.ResultsThe current progresses on MCI management include new golden hour, damage control philosophy, chain of survival, and three links theory. In addition, there are three evaluation methods (medical severity index (MSI), potential injury creating event (PICE) classification, and disaster severity scale (DSS)), which can dynamically assess the MCI situations and decisions for MCI responses and can be made based on the results of such evaluations. However, the three methods only offer a retrospective evaluation of MCI and thus fail to develop a real-time assessment of MCI responses. Therefore, they cannot be used as practical guidance for decision-making during MCI. Although the theory of surge science has made great improvements, we found that a very important factor has been ignored—vulnerability, based on reflecting on the MCI response to the 2008 Wenchuan earthquake and July 5 bus fire in Hangzhou.ConclusionsThis new paradigm breaks through the limitation of traditional research paradigms and will contribute to the development of a methodology for disaster research.概要研究目的系统回顾大规模伤亡事件(MCI)经典研究范式, 结合2008年汶川地震和2014年杭州7·5公交车起火事件, 优化MCI应对的研究范式。创新要点需求激增理论是MCI应对实时评估的显著进步, 结合2008年汶川地震和2014年杭州7·5公交车起火事件, 我们发现MCI应对评估中一个非常重要的脆弱性因素被忽略。研究方法采用关键词和医学主题词(大规模伤亡事件、 MCI、 研究方法、 汶川、 地震、 研究范式、 激增科学、 激增、 激增应对能力和脆弱性等), 通过检索数据库PubMed、 EMBASE、 中国万方及中国生物医学(CBM)的相关研究资料库, 进行理论的回顾性分析和结合实际案例的分析。重要结论除需求激增理论中的激增和激增应对能力这二个基本维度外, 应引入第三个维度脆弱性, 形成更为全面和客观的三个互为关联维度构建MCI的新研究范式, 突破MCI传统研究范式的局限性。

Evaluation of the inflammatory response in a two-hit acute lung injury model using [18F]FDG microPET

The aim of this study was to investigate whether a two-hit acute lung injury (ALI) model is better than a one-hit model in simulating ALI, and to evaluate the inflammatory response in the lungs in these two models using micro-positron emission tomography (microPET) with [18F]fluorodeoxyglucose (FDG). Sprague Dawley rats were divided into four groups; rats in the lipopolysaccharide (LPS; n=10) and LPS-HCl (n=10) groups were challenged by the intraperitoneal administration of 5 mg/kg LPS, while rats in the normal saline (NS; n=3) and HCl (n=10) groups received the same volume of normal saline solution. Sixteen hours following the administration, the rats in the HCl and LPS-HCl groups received an acid instillation (IT) of 0.5 ml/kg HCl (pH=1.2), while the rats in the remaining two groups received the same volume of normal saline solution. The mean arterial blood pressure (MAP) and blood gas concentrations were measured in all four groups. MicroPET was performed 4 h following HCl IT and the lungs were excised for histopathological examination. The rats in the LPS-HCl group exhibited a higher arterial PaO2 and a lower arterial PaCO2 compared with the rats in the remaining groups. The MAP decreased markedly in the LPS-HCl group, but remained stable in the LPS, HCl and NS groups. MicroPET results identified that the region of interest ratio in the LPS-HCl group (9.00±1.41) was significantly higher compared with those in the LPS (4.01±0.60) and HCl (3.33±0.55) groups (P<0.01). In addition, histological examination showed that the mean lung injury score in the LPS-HCl group (12.70±0.95) was significantly higher compared with those in the HCl (8.40±1.26) and LPS (7.00±0.82) groups (P<0.01). The present study demonstrates that LPS pretreatment significantly magnifies and prolongs the inflammatory response to subsequent acid IT in the lungs. Moreover, it is simpler to induce ALI using the two-hit model than with the one-hit model, and [18F]FDG microPET is a useful tool for evaluating the inflammatory reaction during ALI.

Review article: Very serious and non-ignorable problem: crisis in emergency medical response in catastrophic event

The crisis of medical response caused by catastrophic events might significantly affect emergency response, and might even initiate more serious social crisis. Therefore, early identification and timely blocking the formation of crisis in the early phase after a major disaster will improve the efficiency of medical response in a major disaster and avoid serious consequences. In the present paper, we described the emergency strategy to crisis management of medical response after a major disaster. Major catastrophic events often lead to various crises, including excess demand, the crisis of response in barrier and the structural crisis in response. The corresponding emergency response strategies include: (i) shunt of catastrophic medical surge; (ii) scalability of medical surge capacity; (iii) matching of the structural elements of response; (iv) maintaining the functions of support system for medical response and maximising the operation of the integrated response system; and (v) selection of appropriate care ‘standard’ in extreme situations of overload of disaster medical surge. In conclusion, under the impact of a major catastrophic event, medical response is often complex and the medical surge beyond the conventional response capacity and it is easy to be in crisis. In addition to the current consensus of disaster response, three additional aspects should be considered. First, all relevant society forces led by the government and military should be linkages. Second, a powerful medical response system must be based on a strong support system. Third, countermeasures of medical surge should be applied flexibly to the special and specific disaster environment, to promote the effective medical response force.

Very serious and non‐ignorable problem: Crisis in emergency medical response in catastrophic event

The crisis of medical response caused by catastrophic events might significantly affect emergency response, and might even initiate more serious social crisis. Therefore, early identification and timely blocking the formation of crisis in the early phase after a major disaster will improve the efficiency of medical response in a major disaster and avoid serious consequences. In the present paper, we described the emergency strategy to crisis management of medical response after a major disaster. Major catastrophic events often lead to various crises, including excess demand, the crisis of response in barrier and the structural crisis in response. The corresponding emergency response strategies include: (i) shunt of catastrophic medical surge; (ii) scalability of medical surge capacity; (iii) matching of the structural elements of response; (iv) maintaining the functions of support system for medical response and maximising the operation of the integrated response system; and (v) selection of appropriate care ‘standard’ in extreme situations of overload of disaster medical surge. In conclusion, under the impact of a major catastrophic event, medical response is often complex and the medical surge beyond the conventional response capacity and it is easy to be in crisis. In addition to the current consensus of disaster response, three additional aspects should be considered. First, all relevant society forces led by the government and military should be linkages. Second, a powerful medical response system must be based on a strong support system. Third, countermeasures of medical surge should be applied flexibly to the special and specific disaster environment, to promote the effective medical response force.