Objective:To investigate the distribution rules of artemisia pollen and the clinical sensitization characteristics of allergic rhinitis (AR) induced by artemisia pollen in three urban and rural areas of Inner Mongolia.Methods:From March to October 2019, in 3 central cities (Chifeng, Hohhot, Ordos) and rural areas of Inner Mongolia, an epidemiological investigation method combining multi-stage stratified random sampling and face-to-face questionnaire survey was adopted to screen suspected AR patients, and skin prick test (SPT) was applied for diagnosis. At the same time, pollen monitoring was carried out in 3 areas to analyze the distribution and clinical sensitization characteristics of artemisia pollen.SPSS26.0 statistical software was used to process all the data. Chi-square test was used to compare rates among different age, sex, region and nationality, Spearman test was used to describe correlation analysis, and pairwise comparison of positive rates among multiple samples was used Bonferroni method.Results:Among the 6 393 subjects, 1 093 cases were diagnosed with AR, and the prevalence of AR was 17.10% (1 093/6 393). Among them, pollen-induced allergic rhinitis, the prevalence of PiAR was 10.97% (701/6 393), accounting for 64.14%(701/1 093).The highest incidence was in the youth group (20-39 years old), accounting for 46.94% (329/701).The diagnosed prevalence was higher in females than in males (11.35% vs. 10.64%, χ2 value 12.304, P<0.001).The prevalence rate of ethnic minority was higher than that of Han nationality (13.01% vs. 10.65%, χ2 value 6.296, P=0.008).The prevalence in urban areas was also significantly higher than that in rural areas (18.40% vs. 5.50%, χ2 value 10.497, P<0.001).There was significant difference in prevalence rate among the three regions in Inner Mongolia (6.06% in Chifeng, 13.46% in Hohhot, 16.39% in Ordos, χ2 value 70.054, P<0.001).The main clinical symptoms of artemisia PiAR were sneezing (95.58%), nasal congestion (91.73%) and nasal itching (89.30%).Allergic conjunctivitis accounted for 79.60% (558/701), chronic sinusitis for 55.63% (390/701), asthma for 23.25% (163/701).The pattern of artemisia pollen sensitization was mainly multiple sensitization, and the frequency of clinical symptoms and clinical diseases induced by hypersensitization with other allergens accounted for more than that caused by single artemisia pollen. The spread period of Artemisia pollen in the three regions was from June to October, and the peak state was in August in summer. The peak time of clinical symptoms in artemisia PiAR patients was about 2 weeks earlier than the peak time of pollen concentration, and the two were significantly positively correlated ( R=0.7671, P<0.001). Conclusion:Artemisia pollens are the dominant pollens in late summer and early autumn in Inner Mongolia, and the prevalence of artemisia PiAR is high. Controlling the spread of Artemisia pollens is of great significance for the prevention and treatment of AR.

Objective:To investigate the distribution rules of artemisia pollen and the clinical sensitization characteristics of allergic rhinitis (AR) induced by artemisia pollen in three urban and rural areas of Inner Mongolia.Methods:From March to October 2019, in 3 central cities (Chifeng, Hohhot, Ordos) and rural areas of Inner Mongolia, an epidemiological investigation method combining multi-stage stratified random sampling and face-to-face questionnaire survey was adopted to screen suspected AR patients, and skin prick test (SPT) was applied for diagnosis. At the same time, pollen monitoring was carried out in 3 areas to analyze the distribution and clinical sensitization characteristics of artemisia pollen.SPSS26.0 statistical software was used to process all the data. Chi-square test was used to compare rates among different age, sex, region and nationality, Spearman test was used to describe correlation analysis, and pairwise comparison of positive rates among multiple samples was used Bonferroni method.Results:Among the 6 393 subjects, 1 093 cases were diagnosed with AR, and the prevalence of AR was 17.10% (1 093/6 393). Among them, pollen-induced allergic rhinitis, the prevalence of PiAR was 10.97% (701/6 393), accounting for 64.14%(701/1 093).The highest incidence was in the youth group (20-39 years old), accounting for 46.94% (329/701).The diagnosed prevalence was higher in females than in males (11.35% vs. 10.64%, χ2 value 12.304, P<0.001).The prevalence rate of ethnic minority was higher than that of Han nationality (13.01% vs. 10.65%, χ2 value 6.296, P=0.008).The prevalence in urban areas was also significantly higher than that in rural areas (18.40% vs. 5.50%, χ2 value 10.497, P<0.001).There was significant difference in prevalence rate among the three regions in Inner Mongolia (6.06% in Chifeng, 13.46% in Hohhot, 16.39% in Ordos, χ2 value 70.054, P<0.001).The main clinical symptoms of artemisia PiAR were sneezing (95.58%), nasal congestion (91.73%) and nasal itching (89.30%).Allergic conjunctivitis accounted for 79.60% (558/701), chronic sinusitis for 55.63% (390/701), asthma for 23.25% (163/701).The pattern of artemisia pollen sensitization was mainly multiple sensitization, and the frequency of clinical symptoms and clinical diseases induced by hypersensitization with other allergens accounted for more than that caused by single artemisia pollen. The spread period of Artemisia pollen in the three regions was from June to October, and the peak state was in August in summer. The peak time of clinical symptoms in artemisia PiAR patients was about 2 weeks earlier than the peak time of pollen concentration, and the two were significantly positively correlated ( R=0.7671, P<0.001). Conclusion:Artemisia pollens are the dominant pollens in late summer and early autumn in Inner Mongolia, and the prevalence of artemisia PiAR is high. Controlling the spread of Artemisia pollens is of great significance for the prevention and treatment of AR.

Human breast milk-derived exosomes (HMDEs) are newly discovered active signaling vesicles in breast milk, which are rich in nucleic acids, proteins, and lipids. These exosomes play an essential role in the development and maturation of the intestinal mucosal barrier in newborns. In addition, HMDEs possess distinctive properties that allow for remodeling and modification, thereby are expected to provide more efficient prevention and treatment strategies for neonatal intestinal diseases. This article aims to provide a comprehensive review of the origin, isolation, identification, labeling, structural features, composition, and biological functions, and their unique impact on the intestinal mucosal barrier function in newborns.

Background: Cardiopulmonary resuscitation (CPR) strategies in COVID-19 patients differ from those in patients suffering from cardiogenic cardiac arrest. During CPR, both healthcare and non-healthcare workers who provide resuscitation are at risk of infection. The Working Group for Expert Consensus on Prevention and Cardiopulmonary Resuscitation for Cardiac Arrest in COVID-19 has developed this Chinese Expert Consensus to guide clinical practice of CPR in COVID-19 patients. Main recommendations: 1) A medical team should be assigned to evaluate severe and critical COVID-19 for early monitoring of cardiac-arrest warning signs. 2) Psychological counseling and treatment are highly recommended, since sympathetic and vagal abnormalities induced by psychological stress from the COVID-19 pandemic can induce cardiac arrest. 3) Healthcare workers should wear personal protective equipment (PPE). 4) Mouth-to-mouth ventilation should be avoided on patients suspected of having or diagnosed with COVID-19. 5) Hands-only chest compression and mechanical chest compression are recommended. 6) Tracheal-intubation procedures should be optimized and tracheal-intubation strategies should be implemented early. 7) CPR should be provided for 20-30 min. 8) Various factors should be taken into consideration such as the interests of patients and family members, ethics, transmission risks, and laws and regulations governing infectious disease control. Changes in management: The following changes or modifications to CPR strategy in COVID-19 patients are proposed: 1) Healthcare workers should wear PPE. 2) Hands-only chest compression and mechanical chest compression can be implemented to reduce or avoid the spread of viruses by aerosols. 3) Both the benefits to patients and the risk of infection should be considered. 4) Hhealthcare workers should be fully aware of and trained in CPR strategies and procedures specifically for patients with COVID-19.

During the epidemic of coronavirus disease 2019 (COVID-19), the infection of the elderly population will bring great challenges to clinical diagnosis and treatment, outcome and management.Combined with the characteristics of anesthesia and the pathophysiological characteristics of COVID-19 on lung function impairment in elderly patients, Chinese Society of Anesthesiology formulated the " Recommendations for anesthesia management and infection control in elderly patients with COVID-19″. This recommendation expounds preoperative visit and infection control, anesthesia management protocol, anesthesia monitoring, anesthesia induction/endotracheal intubation, anesthesia maintenance and infection control, intraoperative lung protection strategy, anti-stress and anti-inflammatory management, hemodynamic optimization, infection control during emergence from anesthesia, and postoperative analgesia in elderly patients with COVID-19, and provides the reference for the safe and effective implementation of anesthesia management in elderly patients during the prevention and control of COVID-19 epidemic.

Objective To investigate the relationship between plasma oxidative stress factors levels and organ damage parameters as well as prognosis in patients with sepsis. Methods A case-control study was conducted. Twenty-five patients admitted to surgical intensive care unit (ICU) of the First Affiliated Hospital of Sun Yat-sen University from March to December in 2016 and diagnosed as sepsis were enrolled as study subjects. Another 15 patients without sepsis admitted to surgical ICU in the same period were enrolled as controls. General demographic data, main diagnoses, acute physiology and chronic health evaluation Ⅱ (APACHEⅡ) score within 24 hours, clinical laboratory indicators [alanine aminotransferase (ALT), aspartate transaminase (AST), serum creatinine (SCr), blood urea nitrogen (BUN), C-reactive protein (CRP), procalcitonin (PCT), white blood count (WBC)] and oxidative stress indicators [superoxide dismutase (SOD), malondialdehyde (MDA) and nitric oxide (NO)] as well as length of ICU stay, total hospital stay and 28-day mortality were recorded. Spearman or Pearson correlation method was used to analyze the correlation between oxidative stress indicators and organ damage indicators as well as prognosis in patients with sepsis. Receiver operator characteristic (ROC) curve was plotted to evaluate the predictive value of oxidative stress indicators for 28-day mortality in patients with sepsis. Results The length of ICU stay in sepsis group was significantly longer than that in non-sepsis group [days: 7.0 (5.5, 11.0) vs. 4.0 (1.0, 11.0), P < 0.05], and AST, BUN, CRP, PCT, plasma MDA and NO levels were significantly higher than those in non-sepsis group [AST (U/L): 50.76±19.53 vs. 28.53±14.02, BUN (mmol/L): 9.99±5.26 vs. 6.97±4.32, CRP (mg/L): 109.28±42.79 vs. 60.33±46.68, PCT (μg/L): 5.4 (0.3, 24.0) vs. 0.6 (0.1, 1.5), MDA (ng/L): 488.31±76.68 vs. 399.30±50.23, NO (ng/L): 5.08±0.89 vs. 4.42±0.88, all P < 0.05]. There was no significant difference in gender, age, APACHEⅡ score, total hospital stay, 28-day mortality, ALT, SCr, WBC or plasma SOD activity between the two groups. The correlation analysis between oxidative stress parameters and organ damage parameters as well as prognosis in patients with sepsis showed that MDA and NO were positively correlated with SCr (r value was 0.426 and 0.431, respectively, both P < 0.05), and there was a positive correlation between MDA and NO (r = 0.990, P < 0.01); plasma SOD activity was negatively correlated with 28-day mortality (r = -0.468, P < 0.05), while MDA and NO levels were positively correlated with 28-day mortality (r value was 0.598 and 0.611, respectively, both P < 0.01). ROC curve analysis showed that plasma SOD, MDA and NO levels had a good independent predictive effect on 28-day mortality, the area under ROC curve (AUC) was 0.816±0.087, 0.904±0.078 and 0.912±0.071, and the best cut-off value was 40.76% (sensitivity 68.4%, specificity 100%), 487.93 ng/L (sensitivity 83.3%, specificity 89.5%) and 5.31 ng/L (sensitivity 83.3%, specificity 89.5%), respectively. Conclusions The plasma levels of oxidative stress factors in patients with sepsis are significantly increased, which is closely related to organ damage and poor prognosis. The plasma SOD, MDA and NO levels can be used as independent bio-marker to predict the 28-day mortality of patients with sepsis.

Objective: To study the influential factor of hyperlactatemia after the brain tumor craniotomy. Methods: Patients who underwent selective brain tumor (including glioma, meningioma and acoustic schwannoma) craniotomyin the neurosurgery intensive care unit (NSICU) of the First Affiliated Hospital, Sun Yat-sen University from December 1st 2018 to May 20th 2019 were enrolled. The incidence of hyperlactatemia after the brain tumor craniotomy was investigated. Univariate and multivariate linear regression analysis were performed to identify the association of initial artery lactate with the operation duration, the intraoperative blood loss, the total intraoperative fluid infusion, intraoperative ringer lactate fluid infusion, intraoperative urine volume, intraoperative fluid balance, the total intraoperative corticosteroids dosage and the tumor type. Pearson method was used to analyze the correlation between lactate in arterial blood and independent related factors. Results: A total of 148 patients were enrolled including 45 patients (30.41%) with glioma, 64 patients (43.24%) with meningioma, and 39 patients (26.35%) with acoustic schwannoma. The initial lactate level in arterial blood increased significantly in 148 patients, with a median of 4.80 (3.68, 5.90) mmol/L. Among them, 78 patients (52.70%) had mild elevation of lactate in arterial blood (2 mmol/L < lactate ≤ 5 mmol/L), 61 patients (41.22%) had significant elevation of lactate in arterial blood (5 mmol/L < lactate ≤ 10 mmol/L), and 2 patients (1.35%) had serious elevation of artery lactate (> 10 mmol/L). And only 7 patients (4.73%) had normal level of lactate in arterial blood (≤ 2 mmol/L). Univariate analysis showed that initial postoperative artery lactate was positively correlated with the operation duration [β = 0.556, 95% confidence interval (95%CI) was 0.257-0.855, P < 0.001] and the total intraoperative corticosteroids dosage (β = 0.477, 95%CI was 0.174-0.779, P = 0.002). There was no significant correlation between the initial postoperative artery lactate and tumor types, the intraoperative blood loss, the total fluid infusion, the ringer lactate fluid infusion, urine volume, and the fluid balance. Further multivariate linear regression analysis showed that the operation duration (β = 0.499, 95%CI was 0.204-0.795, P = 0.001) and the total intraoperative corticosteroids dosage (β = 0.407, 95%CI was 0.111-0.703, P = 0.008) were independent risk factors affecting the initial postoperative artery lactate. The correlation analysis showed that there was a significant positive correlation between lactate in arterial blood and operation time and total hormone dosage during operation (r₁ = 0.289, r₂ = 0.248, both P < 0.01). Conclusion Initial artery lactate after brain tumor craniotomy is associated with surgery duration and exogenous administration of corticosteroids.

Objective: To evaluate cerebrospinal fluid (CSF) vancomycin concentrations and identify factors influencing CSF vancomycin concentrations in critically ill neurosurgical patients. Methods: A retrospective study was conducted. Adult patients who received vancomycin treatment and CSF vancomycin concentrations monitoring admitted to neurosurgical intensive care unit (ICU) of the First Affiliated Hospital of Sun Yat-sen University from January 2016 to June 2019 were enrolled. General information, vancomycin dosing regimens, CSF vancomycin concentrations, CSF drainage methods and volume of the previous day, and concurrent medications, etc. were collected for analysis. CSF vancomycin concentrations of patients with definite or indefinite central nervous system (CNS) infection, different vancomycin dosing regimens and their influencing factors were analyzed. Results: A total of 22 patients were included. 168 CSF specimens were collected for culture, 20 specimens of which were culture positive, with a positive rate of 11.9%. Sixty cases of CSF vancomycin concentration were obtained. Among the 22 patients, 7 patients (31.8%) were diagnosed with proven CNS infection, 11 patients (50.0%) clinically diagnosed, 2 patients (9.1%) diagnosed with uncertain CNS infection, and 2 patients (9.1%) diagnosed without CNS infection. Intravenous (IV) administration of vancomycin alone was used in 15 cases (25.0%), intrathecal injection in 17 cases (28.3%), IV+intrathecal injection in 23 cases (38.3%), and IV+intraventricular administration in 5 cases (8.3%). The CSF vancomycin concentrations ranged from < 0.24 to > 100 mg/L, with an average level of 14.40 (4.79, 42.34) mg/L.①Administration methods of vancomycin affected CSF vancomycin concentrations. The CSF vancomycin concentration with intrathecal injection or intraventricular administration was higher than that of IV administration alone [mg/L: 25.91 (11.28, 58.17) vs. 2.71 (0.54, 5.33), U = 42.000, P < 0.01].②When vancomycin was administered by IV treatment alone, CSF vancomycin concentrations were low in both groups with definite CNS infection (proven+probable) and indefinite CNS infection (possible+non-infection), the CSF vancomycin concentrations of which were 4.14 (1.40, 6.36) mg/L and 1.27 (0.24, 3.33) mg/L respectively, with no significant difference (U = 11.000, P = 0.086).③CSF vancomycin concentrations rose with the increased dose of vancomycin delivered by intrathecal injection or intraventricular administration. According to the dose of vancomycin administered locally on the day before therapeutic drug monitoring (TDM), cases were divided into the following groups: 0-15 mg group (n = 22), 20-35 mg group (n = 33), and 40-50 mg group (n = 5), the CSF vancomycin concentrations of which were 4.14 (1.09, 8.45), 30.52 (14.31, 59.61) and 59.43 (25.51, 92.45) mg/L respectively, with significant difference (H = 33.399, P < 0.01). Moreover, the cases of CSF vancomycin concentration of≥10 mg/L accounted for 18.2%, 84.8% and 100% of these three groups, respectively. CSF vancomycin concentrations mostly reached target level when dose of vancomycin administered locally were 20 mg/L or more. Conclusions It is difficult to reach target CSF vancomycin concentration for critically ill neurosurgical patients with or without CNS infection by IV treatment. Local administration is an effective treatment regimen to increase CSF vancomycin concentration.

Objective: To evaluate trough serum vancomycin concentrations and identify their influencing factors in critically ill neurosurgical patients. Methods: A retrospective study was conducted. Adult patients who received vancomycin with at least one appropriate monitoring of trough serum vancomycin concentration and admitted to neurosurgical intensive care unit (ICU) of the First Affiliated Hospital of Sun Yat-sen University from November 2017 to July 2019 were enrolled. General information including gender, age, comorbidities, etc., trough serum vancomycin concentrations, vancomycin dosage, duration of vancomycin therapy, urine output, serum creatinine (SCr), concurrent medications (including mannitol, diuretic, vasopressors, non-steroidal anti-inflammatory drugs, polymyxin, aminoglycosides and contrast medium, etc.) were collected for analysis. Trough serum vancomycin concentrations were evaluated and their influencing factors were analyzed by multiple linear regression method. Results: In total, 81 trough serum vancomycin concentration data sets obtained from 28 patients were evaluated. ① The initial daily dose of vancomycin was 2.00 (2.00, 2.00) g/d. After 4-6 doses, the trough serum vancomycin concentration obtained from initial blood draw was 10.99 (6.98, 16.25) mg/L, of which only 17.9% (5/28) achieving targeted concentrations (15-20 mg/L), 71.4% (20/28) subtherapeutic level and 10.7% (3/28) supratherapeutic level. ② The duration of vancomycin therapy was 8.0 (6.0, 15.0) days. With average daily dose of 2.00 (1.75, 3.00) g/d, targeted trough vancomycin concentrations were achieved in only 30.9% (25/81) of all cases, subtherapeutic concentrations in 49.4% (40/81) and supratherapeutic concentrations in 19.7% (16/81). ③ There were significant differences in age, comorbidities, vancomycin dosage, diuretics use and mannitol dosage, etc. among different vancomycin concentration groups. Multiple linear regression analysis suggested that the trough serum vancomycin concentration increased by 0.14 mg/L [95% confidence interval (95%CI) was 0.06-0.22] for every 1 year increase in age, increased by 7.22 mg/L (95%CI was 2.08-12.36) in patients with multiple comorbidities (concomitant hypertension, diabetes and coronary heart disease) compared with those without comorbidities, increased by 2.78 mg/L (95%CI was 0.20-5.35) in patients treated with diuretics compared with those without diuretics. The effect of other variables was not statistically significant. It suggested that age, multiple comorbidities (concomitant hypertension, diabetes and coronary heart disease), and diuretic usage affected trough serum vancomycin concentrations. Conclusions Targeted trough serum vancomycin level is not often achieved in neurosurgical ICU patients following standard dosing. Younger patients are associated with lower trough serum vancomycin concentrations, while diuretic usage, combined with multiple comorbidities are associated with higher trough serum vancomycin concentrations.

OBJECTIVE: To study the influential factor of hyperlactatemia after the brain tumor craniotomy. METHODS: Patients who underwent selective brain tumor (including glioma, meningioma and acoustic schwannoma) craniotomyin the neurosurgery intensive care unit (NSICU) of the First Affiliated Hospital, Sun Yat-sen University from December 1st 2018 to May 20th 2019 were enrolled. The incidence of hyperlactatemia after the brain tumor craniotomy was investigated. Univariate and multivariate linear regression analysis were performed to identify the association of initial artery lactate with the operation duration, the intraoperative blood loss, the total intraoperative fluid infusion, intraoperative ringer lactate fluid infusion, intraoperative urine volume, intraoperative fluid balance, the total intraoperative corticosteroids dosage and the tumor type. Pearson method was used to analyze the correlation between lactate in arterial blood and independent related factors. RESULTS: A total of 148 patients were enrolled including 45 patients (30.41%) with glioma, 64 patients (43.24%) with meningioma, and 39 patients (26.35%) with acoustic schwannoma. The initial lactate level in arterial blood increased significantly in 148 patients, with a median of 4.80 (3.68, 5.90) mmol/L. Among them, 78 patients (52.70%) had mild elevation of lactate in arterial blood (2 mmol/L < lactate ≤ 5 mmol/L), 61 patients (41.22%) had significant elevation of lactate in arterial blood (5 mmol/L < lactate ≤ 10 mmol/L), and 2 patients (1.35%) had serious elevation of artery lactate (> 10 mmol/L). And only 7 patients (4.73%) had normal level of lactate in arterial blood (≤ 2 mmol/L). Univariate analysis showed that initial postoperative artery lactate was positively correlated with the operation duration [β = 0.556, 95% confidence interval (95%CI) was 0.257-0.855, P < 0.001] and the total intraoperative corticosteroids dosage (β = 0.477, 95%CI was 0.174-0.779, P = 0.002). There was no significant correlation between the initial postoperative artery lactate and tumor types, the intraoperative blood loss, the total fluid infusion, the ringer lactate fluid infusion, urine volume, and the fluid balance. Further multivariate linear regression analysis showed that the operation duration (β = 0.499, 95%CI was 0.204-0.795, P = 0.001) and the total intraoperative corticosteroids dosage (β = 0.407, 95%CI was 0.111-0.703, P = 0.008) were independent risk factors affecting the initial postoperative artery lactate. The correlation analysis showed that there was a significant positive correlation between lactate in arterial blood and operation time and total hormone dosage during operation (r₁ = 0.289, r₂ = 0.248, both P < 0.01). CONCLUSIONS Initial artery lactate after brain tumor craniotomy is associated with surgery duration and exogenous administration of corticosteroids.
Adrenal Cortex Hormones/therapeutic use* ; Arteries ; Brain Neoplasms ; Craniotomy ; Humans ; Retrospective Studies