Objective To investigate the high risk factors for wheezing of low birth weight premature infants with wheezing.Methods A cohort study of 143 premature infants,whose gestation less than 37 weeks and birth weight less than 2 500 g,were collected from Neonatal Intensive Care Unit of Kunming Children's Hospital,from December 2012 to November 2013.Follow-up investigation was conducted,and those with wheezing were enrolled in the study.Many possible factors causing wheezing were analyzed,such as general conditions in the neonatal period,family conditions,and treatment.SPSS 17.0 statistical software was used to analyze the data.Single factor analysis was used by x2 test and rank sum test to evaluate the possible risk factors.Multiple factors analysis was made by Logistic regression analysis.P ＜ 0.05 was viewed as having statistical difference.Results (1) The risk factors for wheezing in the premature infants were:continuous positive airway pressure (CPAP) noninvasive ventilation (x2 =8.531,P =0.003),ventilation (x2 =4.800,P =0.028),caesarean section (x2 =6.787,P =0.009),the use of pulmonary surfactant (x2 =5.455,P =0.020),using antibiotics used at hospital (x2 =5.192,P =0.023),father smoking(x2 =5.406,P =0.020),maternal smoking (x2 =8.531,P =0.003),maternal allergic history (x2 =8.297,P =0.004),compatriot history of allergies (x2 =8.297,P =0.004) or asthma (x2 =9.774,P =0.002),family environment with dust and excitant gas (x2 =12.831,P =0.000) were the risk factors for the wheezing in the low birth weight premature infants.(2)Multi-factor classification Logistic regression analysis showed that CPAP (OR =58.414,95 ％ CI:3.317-1 028.646,P =0.005),mother smoking during pregnancy (OR =11.953,95 ％ CI:1.309-109.120,P =0.028),compatriot history of allergies (OR=135.769,95％ CI:4.914-3 751.419,P =0.004),family environment(OR =83.738,95％ CI:4.416-1 587.982,P =0.003),were independent risk factors for wheezing in low birth weight premature infants;natural labor was protective factor for wheezing in low birth weight premature infants (OR =0.045,95％ CI:0.004-0.574,P =0.017).(3)The sensitivity and specificity of risk factors were analyzed.The highest sensitivity was estimated for the father's history of allergy(83.3％).The highest specificity was estimated for the use of antibiotics at hospital (76.7％).Conclusions The study shows that CPAP noninvasive ventilation,mother smoking during pregnancy,allergy history of their brothers and sisters,family environment with dust and excitant gas are independent risk factors for wheezing in the low birth weight premature infants.There is no single risk factor with both high sensitivity and high specificity.

Objective:To investigate the effect of positive and negative pressure extubation on mechanical ventilation patients in the intensive care unit (ICU).Methods:A prospective randomized controlled study was performed, 105 ICU patients who successfully passed the spontaneous breathing test (SBT) after mechanical ventilation of Nanjing Jiangbei Hospital Affiliated to Nantong University from January 2019 to March 2021 were enrolled. According to random number table method, they were randomly divided into positive pressure extubation group (53 cases) and negative pressure extubation group (52 cases). During extubation, all patients were placed in semi-decubitus position (raising the head of bed at an angle range from 30°- 45°), the secretions from mouth, nose, throat and trachea were removed. In the negative pressure extubation group, the sputum suction tube was inserted into the tracheal tube and passed over the distal opening to carry out continuous negative pressure suction in the tracheal tube after disconnecting the ventilator. Meanwhile, after the tracheal tube balloon was evacuated, the sputum suction tube was pulled out together with the tracheal tube. In the positive pressure extubation group, the patients were guided to inspiratory forcibly under the original SBT mode. When the patients reached the inspiratory peak, the ballon was evacuated and the tracheal tube was removed. After extubation, all patients were given nasal catheter oxygen inhalation (oxygen flow 5 L/min). Arterial blood gas analysis indexes [pH value, arterial partial pressure of oxygen (PaO 2) and arterial partial pressure of carbon dioxide (PaCO 2)] were recorded 5 minutes and 1 hour after extubation in both groups. Vital signs (including tachypnea, tachycardia, elevated blood pressure and decreased oxygen saturation) and complications (including severe cough, airway hyperresponsiveness and pneumonia) were observed 30 minutes after extubation in both groups. Results:Five minutes after extubation, blood gas analysis showed that the PaO 2 of positive pressure extubation group was significantly higher than that of negative pressure extubation group [mmHg (1 mmHg≈0.133 kPa): 123.4±30.2 vs. 111.0±21.1, P < 0.05], the pH value and PaCO 2 in positive pressure extubation group were slightly lower than that of negative pressure extubation group [pH value: 7.411±0.042 vs. 7.419±0.040, PaCO 2 (mmHg): 39.7±4.7 vs. 40.5±5.6], but the differences were not statistically significant (both P > 0.05). One hour after extubation, the pH value, PaO 2 and PaCO 2 in positive pressure extubation group were slightly lower than those in negative pressure extubation group, but the differences were not statistically significant. Within 30 minutes after extubation, the incedences of tachypnea, tachycardia, elevated blood pressure and oxygen desaturationin in positive pressure extubation group were significantly lower than those in negative pressure extubation group [tachypnea: 9.4% (5/53) vs. 28.8% (15/52), tachycardia: 15.1% (8/53) vs. 32.7% (17/52), elevated blood pressure: 11.3% (6/53) vs. 30.8% (16/52), oxygen desaturation: 7.5% (4/53) vs. 34.6% (18/52), all P < 0.05], the incidence of severe cough in positive pressure extubation group was significantly lower than that in negative pressure extubation group [9.4% (5/53) vs. 30.8% (16/52), P < 0.05], but there was no significant difference in the incidence of complications of airway hyperresponsiveness between the two groups [1.9% (1/53) vs. 5.8% (3/52), P > 0.05]. No pneumonia occurred in both groups within 48 hours after extubation. Conclusion:The positive pressure extubation method can ensure full oxygenation of patients undergoing mechanical ventilation in ICU, avoid hypoxia, and reduce the occurrence of hypoxia and severe cough, which is more conducive to the stability of vital signs.

Objective:To investigate the diagnostic value of neutrophil CD64 index in sepsis patients in intensive care unit (ICU).Methods:A prospective case-control study was conducted, the patients admitted to ICU of Jiangbei People's Hospital Affiliated to Nantong University from December 2016 to June 2020 were enrolled. According to the criteria of Sepsis 3, 107 patients diagnosed with sepsis were classified as the sepsis group, 112 patients without infection were classified as control group. Peripheral venous blood samples were collected within 24 hours after ICU admission, neutrophil CD64 index, C-reactive protein (CRP), procalcitonin (PCT), white blood cell count (WBC) were detected. Receiver operating characteristic curve (ROC curve) was used to evaluate the diagnostic value of neutrophil CD64 index, CRP, PCT and WBC for sepsis.Results:The neutrophil CD64 index, CRP and PCT in sepsis group were significantly higher than those in control group [neutrophil CD64 index: 9.03±5.59 vs. 3.18±1.50, CRP (mg/L): 146.9±68.3 vs. 46.5±35.8, PCT (ng/L): 31.82±14.71 vs. 1.87±1.42, all P < 0.05]. ROC curve analysis showed that neutrophil CD64 index, CRP and PCT had certain diagnostic value for sepsis, the area under ROC curve (AUC) were 0.924, 0.915 and 0.879, respectively, the 95% confidence intervals (95% CI) were 0.871-0.978, 0.855-0.975, 0.807-0.951, respectively, P values were 0.016, 0.017 and 0.026, respectively. Among the three indicators, the diagnostic value of neutrophil CD64 index was much higher. When the optimal cut-off value was 4.32, the sensitivity and specificity were 83.6% and 88.7%, respectively, which were higher than the sensitivity (75.1%, 76.3%) and specificity (87.2%, 82.5%) of CRP and PCT. Conclusion:Neutrophil CD64 index is a valuable biomarker for the diagnosis of sepsis in ICU.

Objective:To analyze the clinical characteristics of intestinal tuberculosis improving the diagnosis rate of intestinal tuberculosis.Methods:From January 2014 to June 2018, at Wuhan Pulmonary Hospital, the data of clinical symptoms, laboratory examination, imaging, endoscopy, surgery and pathological examination of 205 patients with intestinal tuberculosis were retrospectively analyzed. Descriptive analysis was performed for statistical analysis.Results:Among 205 patients with intestinal tuberculosis, 145 cases were male and 60 cases were female, aged 14 to 85 years old. A total of 189 cases (92.2%) were complicated with lung tuberculosis, of which 151 cases (79.9%) were positive for sputum acid fast staining. A total of 126 cases were tested for feces acid fast staining, of which 83 cases (65.9%) were positive. A total of 60 cases (29.3%) were tested for GeneXpert Mycobacterium tuberculosis/rifampicintablet (GeneXpert MTB/RIP), of which 49 cases (81.7%) were positive. A total of 44 cases of intestinal tuberculosis were diagnosed by biopsy under electronic enteroscopy, and 21 cases were pathologically diagnosed with intestinal tuberculosis after surgical resection. The 21 patients were tested for GeneXpert MTB/RIP, of which 19 cases (90.5%) were positive and 10 cases (47.6%) were positive for tuberculin test. Six patients were clinically diagnosed with intestinal tuberculosis after effective treatment of antituberculosis drugs. Conclusions:Combination of clinical symptoms and laboratory, imaging, endoscopic and pathological examination, as well as the therapeutic effect of diagnostic antituberculosis treatment could make comprehensive diagnosis of intestinal tuberculosis. The GeneXpert MTB/RIP examination is of great value in the diagnosis of intestinal tuberculosis.