A Combination of Chest Radiography and Estimated Plasma Volume May Predict In-Hospital Mortality in Acute Heart Failure

Background: Patients with heart failure (HF) often display dyspnea associated with pulmonary congestion, along with intravascular congestion, both may result in urgent hospitalization and subsequent death. A combination of radiographic pulmonary congestion and plasma volume might screen patients with a high risk of in-hospital mortality in the emergency department (ED).Methods: In the pathway of dyspneic patients in emergency (PARADISE) cohort, patients admitted for acute HF were stratified into 4 groups based on high or low congestion score index (CSI, ranging from 0 to 3, high value indicating severe congestion) and estimated plasma volume status (ePVS) calculated from hemoglobin/hematocrit.Results: In a total of 252 patients (mean age, 81.9 years; male, 46.8%), CSI and ePVS were not correlated (Spearman rho <0 .10, p > 0.10). High CSI/high ePVS was associated with poorer renal function, but clinical congestion markers (i.e., natriuretic peptide) were comparable across CSI/ePVS categories. High CSI/high ePVS was associated with a four-fold higher risk of in-hospital mortality (adjusted-OR, 95%CI = 4.20, 1.10-19.67) compared with low CSI/low ePVS, whereas neither high CSI nor ePVS alone was associated with poor prognosis (all-p-value > 0.10; Pinteraction = 0.03). High CSI/high ePVS improved a routine risk model (i.e., natriuretic peptide and lactate)(NRI = 46.9%, p = 0.02), resulting in high prediction of risk of in-hospital mortality (AUC = 0.85, 0.82-0.89).Conclusion: In patients hospitalized for acute HF with relatively old age and comorbidity burdens, a combination of CSI and ePVS was associated with a risk of in-hospital death, and improved prognostic performance on top of a conventional risk model.

Role of point-of-care lung ultrasound in different respiratory disorders

Point-of-care lung ultrasound either standalone or in a combination with other ultrasound techniques is a useful diagnostic method for patients with different respiratory disorders. Nowadays lung ultrasound helps to identify emergency conditions, such as acute respiratory distress syndrome, pneumothorax, cardiac arrest, acute respiratory failure, pneumonia. Moreover, a semi-quantitative evaluation of pulmonary congestion can be performed to determine the severity of interstitial syndrome and COVID‑19 associated pneumonia. In this review the basic semiotics of ultrasound are described, as well as the role of point-of-care lung ultrasound in various respiratory disorders.

A neoprene vest hastens dyspnoea and leg fatigue during exercise testing: entangled breathing and cardiac hindrance?

Symptoms and contributing factors of immersion pulmonary oedema (IPO) are not observed during non-immersed heart and lung function assessments. We report a case in which intense snorkelling led to IPO, which was subsequently investigated by duplicating cardiopulmonary exercise testing with (neoprene vest test – NVT) and without (standard test – ST) the wearing of a neoprene vest. The two trials utilised the same incremental cycling exercise protocol. The vest hastened the occurrence and intensity of dyspnoea and leg fatigue (Borg scales) and led to an earlier interruption of effort. Minute ventilation and breathing frequency rose faster in the NVT, while systolic blood pressure and pulse pressure were lower than in the ST. These observations suggest that restrictive loading of inspiratory work caused a faster rise of intensity and unpleasant sensations while possibly promoting pulmonary congestion, heart filling impairment and lowering blood flow to the exercising muscles. The subject reported sensations close to those of the immersed event in the NVT. These observations may indicate that increased external inspiratory loading imposed by a tight vest during immersion could contribute to pathophysiological events.

Nitrogen dioxide component of air pollution increases pulmonary congestion assessed by lung ultrasound in patients with chronic coronary syndromes

Pulmonary congestion is an intermediate biomarker and long-term predictor of acute decompensated heart failure.To evaluate the effects of air pollution on pulmonary congestion assessed by lung ultrasound.In a single-center, prospective, observational study design, we enrolled 1292 consecutive patients with chronic coronary syndromes referred for clinically indicated ABCDE-SE, with dipyridamole (n = 1207), dobutamine (n = 84), or treadmill exercise (n = 1). Pulmonary congestion was evaluated with lung ultrasound and a 4-site simplified scan. Same day values of 4 pollutants were obtained on the morning of testing (average of 6 h) from publicly available data sets of the regional authority of environmental protection. Assessment of air pollution included fine (< 2.5 µm diameter) and coarse (< 10 µm) particulate matter (PM), ozone and nitrogen dioxide (NO2).NO2 concentration was weakly correlated with rest (r = .089; p = 0.001) and peak stress B-lines (r = .099; p < 0.001). A multivariable logistic regression analysis, NO2 values above the median (23.1 µg/m3) independently predicted stress B-lines with odds ratio = 1.480 (95% CI 1.118–1.958) together with age, hypertension, diabetes, and reduced (< 50%) ejection fraction. PM2.5 values were higher in 249 patients with compared to those without B-lines (median and IQR, 22.0 [9.1–23.5] vs 17.6 [8.6–22.2] µg/m3, p < 0.001). No other pollutant correlated with other (A-C-D-E) SE steps.Higher concentration of NO2 is associated with more pulmonary congestion mirrored by B-lines at lung ultrasound. Local inflammation mediated by NO2 well within legally allowed limits may increase the permeability of the alveolar-capillary barrier and therefore pulmonary congestion in susceptible subjects.ClinicalTrials.gov Identifier: NCT030.49995.

Lung Ultrasound versus Pulmonary Auscultation in Detecting Pulmonary Congestion in the Critically Ill

BACKGROUND: In critically ill patients, auscultation might be challenging as dorsal lung fields are difficult to reach in supine-positioned patients, and the environment is often noisy. In recent years, clinicians have started to consider lung ultrasound (LUS) as a useful diagnostic tool for a variety of pulmonary pathologies, including pulmonary edema. AIM: The aim of this study was to compare LUS versus pulmonary auscultation for detecting pulmonary edema in critically ill patients. PATIENTS AND METHODS: Sixty-one patients were included in this study, all included patients underwent clinical examination, chest auscultation of anterior and lateral (axillary) chest wall and back in each hemithorax in supine position was done, followed by LUS using Bedside LUS in Emergency (BLUE) protocol. LUS score was recorded; abnormal auscultation was defined as the presence of rales or wheezes. Laboratory tests were done on admission such as pro-BNP, renal function, and blood gases. Pro-BNP was used as diagnostic tool for volume overload and was correlated with LUS and stethoscope for detecting pulmonary edema. Pneumonia was excluded with normal total leukocyte counts, C-reactive protein, and absence of fever. RESULTS: This study included 61 patients with diagnosis of pulmonary edema, all data were recorded on admission and showed that there was statistically significant good positive correlation between LUS and Pro-BNP (p < 0.05), and Pearson correlation between LUS and Pro-BNP among the studied patients is statistically significant at the 0.01 level (two-tailed). Furthermore, we found that both LUS and Pro-BNP were statistically significant higher among patients with rales (p < 0.05) only 36 (59%) patients were positive as pulmonary edema with pulmonary auscultation (presence of rales) and 25 (41%) patients were negative for pulmonary edema (NO RALES) while they were positive for pulmonary edema with LUS (high LUS score)and pro-BNP. CONCLUSION: Pulmonary auscultation has poor sensitivity for pulmonary congestion while LUS had statistically significant higher sensitivity for pulmonary edema.