There is limited research on aspiration pneumonia-induced ARDS (Acute Respiratory Distress Syndrome), and currently there is a lack of studies on corresponding biomarkers and pathogenic mechanisms. We hypothesize that pH and amylase in BAL (Bronchoalveolar Lavage) may serve as candidate biomarkers for inhalation-induced ARDS. Furthermore, we use EIT analysis to explore the pathological mechanisms of ARDS induced by AP and evaluate the clinical value of NO in improving hypoxemia.
Aspiration pneumonia leading to acute respiratory distress syndrome (ARDS) is not uncommon in clinical practice, but sometimes it occurs covertly and is not easily detected by doctors or family members. Sometimes, acute respiratory failure occurs suddenly due to massive aspiration. Aspiration of gastric contents is the main cause of reflux aspiration, and there is also aspiration of pharyngeal secretions in patients with impaired swallowing function. Finding the cause of ARDS is of great significance for guiding treatment and determining prognosis, but currently there is limited research on aspiration pneumonia leading to ARDS, and there is a lack of effective biomarkers in clinical practice. Fiberoptic bronchoscopy is a commonly used examination and treatment method for ARDS patients. We hypothesize that the detection of pH or amylase in bronchoalveolar lavage fluid (BALF) may have diagnostic significance for reflux aspiration-induced ARDS. Changes in cell subgroups and cytokines in BALF are important for understanding the pathogenesis. Therefore, in our prospective study, we collected BALF from patients admitted to the ICU who underwent endotracheal intubation due to ARDS and required bronchoscopy examination. We tested the pH and amylase levels in the lavage fluid. We analyzed the causes of ARDS and compared the differences in pH and amylase levels in BALF between patients with reflux aspiration-induced ARDS and non-reflux aspiration-induced ARDS. In addition, we will also explore the changes in cells, cytokines, and omics differences in BALF of confirmed cases of reflux aspiration-induced ARDS to search for possible pathogenic mechanisms. This study's use of bronchoscopy examination is in line with patient treatment needs and will not increase patient suffering or burden. Informed consent will be obtained from all patients admitted to the ICU with ARDS before enrollment. Recently, a retrospective analysis comparing the differences in amylase and pancreatic enzyme levels in BALF between aspiration pneumonia and non-aspiration pneumonia was published in Pulmonology. Based on the number of cases and ROC results, PASS (2021, v21.0.3) was used, requiring 22 cases (11 each) with a 20% dropout rate, resulting in 28 cases (14 each). In statistical analysis, data is presented as mean ± standard deviation or the interquartile range (IQR) of 25-75% as the median. F test was performed to compare the means of the two groups. Student's t-test and Welch's t-test were used to compare values with and without homogeneity, respectively. One-way analysis of variance was used for multiple comparisons. Mann-Whitney U test and Wilcoxon signed-rank test were used for comparing median values between independent variables and dependent variables. Kruskal-Wallis test was used for multiple comparisons. Receiver operating characteristic (ROC) curve analysis was used to evaluate the clinical effectiveness of BAL-amylase and BAL-pH, and chi-square test was used to examine their relationship with risk factors for aspiration-induced ARDS. Univariate and multivariate logistic regression analyses were performed to investigate the relationship between BAL-amylase or BAL-pH and ARDS, expressed as odds ratios (OR) with 95% confidence intervals (CI). All analyses were conducted using PASS. EIT is often used in ARDS patients to assess ventilation function and titrate appropriate PEEP. In these patients, we perform EIT for ventilation-perfusion detection as clinically needed. This is a non-invasive procedure, while blood gas analysis is also essential for ARDS detection. For some patients, when judged by doctors and consented by family members, we administer nitric oxide (NO) inhalation therapy, and conduct follow-up EIT after NO inhalation according to the patient's condition changes. Therefore, for patients with AP-ARDS, we also monitor the changes in EIT ventilation-perfusion and record the blood gas changes and CT findings.
Based on whether the patient meets the diagnosis of aspiration pneumonia.
Performing bronchoscopy.
Local pulmonary ventilation and perfusion are measured by electrical impedance tomography (EIT). For perfusion imaging, 10 ml of 5% saline is injected as a central venous bolus. The matching of ventilation and perfusion reveals intrapulmonary shunting.
Zhongshan Hospital Fudan University
Shanghai, China
pepsin levels in BAL
Performing detection of pepsin in BAL
Time frame: Submit for examination within 24 hours after each BAL acquisition.
PH levels in BAL
Performing detection of PH in BAL
Time frame: Submit for examination within 24 hours after each BAL acquisition.
EIT V/Q
Local pulmonary ventilation and perfusion are measured by electrical impedance tomography (EIT). For perfusion imaging, 10 ml of 5% saline is injected as a central venous bolus. The matching of ventilation and perfusion reveals intrapulmonary shunting.
Time frame: Submit for examination within 30min after BAL acquisition.
P/F ratio
Take the first blood gas after enrollment as the baseline, and record all blood gas values within 24 hours.
Time frame: All blood gas changes within 24 hours after enrollment
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Study Type
OBSERVATIONAL
Enrollment
28
According to the physician's judgment and the family members' consent, the patient is administered nitric oxide inhalation at a dosage of 20-30 parts per million (ppm).