Persistent pulmonary congestion before discharge predicts rehospitalization in heart failure: a lung ultrasound study.

BACKGROUND: B-lines evaluated by lung ultrasound (LUS) are the sonographic sign of pulmonary congestion, a major predictor of morbidity and mortality in patients with heart failure (HF). Our aim was to assess the prognostic value of B-lines at discharge to predict rehospitalization at 6 months in patients with acute HF (AHF).
METHODS: A prospective cohort of 100 patients admitted to a Cardiology Department for dyspnea and/or clinical suspicion of AHF were enrolled (mean age 70 ± 11 years). B-lines were evaluated at admission and before discharge. Subjects were followed-up for 6-months after discharge.
RESULTS: Mean B-lines at admission was 48 ± 48 with a statistically significant reduction before discharge (20 ± 23, p < .0001). During follow-up, 14 patients were rehospitalized for decompensated HF. The 6-month event-free survival was highest in patients with less B-lines (≤ 15) and lowest in patients with more B-lines (> 15) (log rank χ(2) 20.5, p < .0001). On multivariable analysis, B-lines > 15 before discharge (hazard ratio [HR] 11.74; 95 % confidence interval [CI] 1.30-106.16) was an independent predictor of events at 6 months.
CONCLUSIONS: Persistent pulmonary congestion before discharge evaluated by ultrasound strongly predicts rehospitalization for HF at 6-months. Absence or a mild degree of B-lines identify a subgroup at extremely low risk to be readmitted for HF decompensation.

Introduction

Heart failure (HF) afflicts 1–2 % of people in the western world, with an incidence of 5–10 per 1000 persons per year [1]. Acute heart failure (AHF) is the most common reason for hospitalization in patients aged > 65 years [2, 3]. Despite significant improvement in signs and symptoms during hospitalization, post-discharge outcomes for patients hospitalized for AHF are poor. Up to 25 % of AHF patients are readmitted within 30 days of discharge, with a high mortality rate during this period [4].

Pulmonary congestion is a major predictor of morbidity and mortality in HF [5]. It is the single most important contributor to hospitalization, more significant than a low cardiac output [6]. Congestion is often not adequately addressed during hospitalization; patients experience improved symptoms, and may be free of clinical congestion but have persistent hemodynamic or pulmonary congestion [5, 7–9]. Failure to adequately relieve congestion during hospitalization is associated with increased morbidity and mortality, whereas patients discharged without congestion show better outcomes [10, 11].

Lung ultrasound (LUS) is a simple, accurate, and patient-friendly tool to assess pulmonary congestion, by evaluation of B-lines (previously called ultrasound lung comets) [12, 13]. B-lines are the sonographic sign of the pulmonary interstitial syndrome, representing the pulmonary interstitial edema in patients with AHF. Many studies have shown their utility in the differential diagnosis of acute dyspnea [14-20]. As such, assessment of B lines is now recommended in the pre-hospital and hospital management of AHF, as a bedside tool to enable direct visualization of interstitial edema in patients with suspected AHF [21]. Fewer studies are available on the prognostic role of pulmonary congestion assessed by B-lines, especially at discharge.

The aim of our study was to assess the prognostic significance of pulmonary congestion at discharge, as assessed by LUS B-lines, in patients admitted to a Cardiology Department with a suspicion of AHF. The study hypothesis is that in patients with detectable LUS at discharge the rate of events during follow-up is higher.

Methods

Patient population

A prospective cohort of 118 patients admitted to a Cardiology Department at a single center were enrolled. The inclusion criterion was the presence of signs and/or symptoms of AHF, irrespective of the etiology. Exclusion criteria were: 1) Inability to provide informed consent; 2) Known history of pulmonary fibrosis, pneumothorax, fibrothorax, lung cancer; 3) Patients not discharged home, but transferred to another department. From the initial population, 5 patients were excluded: 2 for known pulmonary fibrosis (1 patient with systemic sclerosis and 1 patient with post-irradiation thoracic fibrosis), 1 for fibrothorax, 1 for lung cancer, and 1 because she was transferred to another department and not discharged home.

The local Ethical Committee approved the protocol and all patients gave informed consent. The study conforms to the principles outlined in the Declaration of Helsinki.

Lung ultrasound

Experienced sonographers (cardiologists and technicians accredited in transthoracic echocardiography by the European Association of Cardiovascular Imaging) performed the LUS examinations. LUS was performed twice in all patients: the first evaluation was done at admission at the end of standard echocardiography. The second evaluation was performed before discharge at the end of echocardiography, in case a second echocardiography was requested by the attending physicians, or as stand-alone examination. Patients were in the supine or near-to-supine position. The ultrasound scanning of the anterior and lateral chest was obtained as previously described on the right and left hemithoraxes. A detailed video showing how to perform a LUS examination to detect B-lines can be freely accessed at the following link: http://www.youtube.com/watch?v=amsULL ws8GI. A B-line was defined as a discrete laser-like vertical hyperechoic reverberation artifact that arises from the pleural line, extends to the bottom of the screen without fading, and moves synchronously with lung sliding [12]. In each intercostal space, the number of B-lines was recorded, and the sum of B-lines of each scanning sites yielded a score denoting the extent of the pulmonary interstitial edema. Zero was defined as a complete absence of B-lines in a scanning site. The presence of B-lines was staged in three grades, according to previous literature [22]: mild (a total of 6–15 B-lines on all scanning sites), moderate (a total of 16–30 B-lines on all scanning sites), and severe (>  30 B-lines on all scanning sites). The LUS examinations were performed with the same probe and same setting routinely used for echocardiographic studies. The intra- and interobserver variability of B-lines quantification have been previously tested in our laboratory as 5.1 and 7.4 %, respectively [23, 24]. A high reproducibility has been reported by other studies [25, 26].

Reference standard definition of heart failure

Two cardiologists, who were blinded to the results of LUS evaluation, reviewed all the available medical records pertaining to the patient, and made an independent assessment of the probability of the patient having HF. Confirmation of AHF was based on the Framingham criteria, with corroborative information including clinical diary, information on hospital course, response to diuretics and other drugs, haemodynamic monitoring, electrocardiograms, chest X-ray, echocardiography, natriuretic peptides, and results of subsequent cardiac testing, including nuclear medicine or magnetic resonance imaging. For patients with a diagnosis other than HF, confirmation was attempted using the following variables: normal chest X-ray (lack of heart enlargement and signs of pulmonary congestion), normal systolic and diastolic heart function by echocardiography, normal valve function at echocardiography, normal natriuretic peptides, hospital clinical course. In cases when the two cardiologists failed to agree on a diagnosis, a consensus was reached with a third expert.

Follow-up data

Follow-up data were obtained from at least 1 of 4 sources: review of the patient's hospital record, personal communication with the patient’s physician and review of the patient’s chart, a telephone interview with the patient conducted by trained personnel, a staff physician visiting the patients at regular intervals in the out-patient clinic. According to study protocol, follow-up information were obtained at 6 months. By inclusion criteria, follow-up data were obtained in all patients. Events were defined as rehospitalization for AHF in the 6 months following discharge. The development or progression of HF was defined according to the same criteria used for the reference standard definition of HF at admission. Patients who died were censored at the time of death.

Statistical analysis

Continuous variables are expressed as mean ± SD. Two-sample comparisons were performed using t-test if variables were normally distributed, the Mann–Whitney U test for not normally distributed data, and the chi-squared test for categorical data. Death rates were estimated with Kaplan-Meier curves and compared by the log-rank test. A sample size calculation established a number of 91 patients to get an alpha error of 0.05, and a power of 0.9. The association of selected variables with outcome was assessed with the Cox’s proportional hazard model using univariable and stepwise multivariable procedures. A significance of p<0.05 was required for a variable to be included into the multivariable model, whilst p<0.1 was the cut-off value for exclusion. The following covariates were analysed at multivariable analysis: NYHA class, haemoglobin, NT-proBNP at discharge, B-lines at admission and at discharge. Hazard ratios (HR) with the corresponding 95 % confidence interval (CI) were estimated. Statistical significance was set at p < 0.05. All analyses were conducted with the Statistical Package for the Social Sciences (SPSS Inc., Chicago, Illinois, version 20) and GraphPad Prism version 6 (GraphPad Software Inc., San Diego, CA, USA).

Results

Cardiopulmonary ultrasound

Nine patients were excluded, after blinded reclassification, because of lack of signs and symptoms of HF. One patient was excluded because of in-hospital death. Three patients were lost at follow-up. Clinical characteristics of the final study population of 100 patients are shown in Table 1 and cardiac and lung ultrasound data are shown in Table 2. Ejection fraction was < 50 % in 74 patients; a significant diastolic dysfunction with restrictive pattern was present in 23 patients; 15 patients had a severe mitral regurgitation, 1 patient had a severe mitral stenosis, 3 patients had a severe aortic stenosis and 1 patient had a severe aortic regurgitation. The main aetiology of HF was coronary artery disease (52 patients), dilated cardiomyopathy (18 patients), valvular heart disease (15 patients), hypertensive heart disease (6 patients), arrhythmias (5 patients), hypertrophic cardiomyopathy (3 patients), chemotherapy-related cardiomyopathy (1 patient).

Table 1

Clinical characteristics of the study population

Patients n = 100
Male (n, %)	73 (73 %)
Age (years)	70 ± 11
NYHA class	2.9 ± 0.9
SAP (mmHg)	126 ± 24
Diabetes Mellitus (n, %)	39 (39 %)
Hypertension (n, %)	57 (57 %)
Dyslipidemia (n, %)	39 (39 %)
Current smokers (n,%)	12 (12 %)
Creatinine (mg/dl)	1.3 ± 0.6
Hemoglobin (g/dl)	12.9 ± 2.1
CRP (mg/l)	1.4 ± 2
NT-proBNP (ng/l)	5291 ± 5877

NYHA New York Heart Association, SAP systolic arterial pressure, CRP C-reactive protein

Table 2

Cardiac and pulmonary ultrasound data of the study population

Ejection fraction (%)	37 ± 14
Wall motion score index	1.8 ± 0.56
LV end-diastolic diameter (mm)	58 ± 10
Impaired relaxation (n, %)	20 (20 %)
Pseudonormal pattern (n, %)	11 (11 %)
Restrictive pattern (n, %)	23 (23 %)
Moderate to severe mitral valve disease (n, %)	54 (54 %)
Moderate to severe aortic valve disease (n, %)	12 (12 %)
TAPSE (mm)	16.5 ± 4.7
PASP (mmHg)	49 ± 15
Pericardial effusion (n, %)	9 (9 %)
Pleural effusion (n, %)	24 (24 %)
B-lines at admission	48 ± 48
B-lines before discharge	20 ± 23

LV left ventricular, TAPSE tricuspid annular plane systolic excursion, PASP pulmonary artery systolic pressure

LUS scanning was feasible in 100 % of the cases and time needed for the examination was always less than 5 min. Mean B-lines at admission was 48 ± 48 with a statistically significant reduction before discharge (20 ± 23, p < .0001, Fig. 1). In 27 % of patients with a severe degree of B-lines at admission, the attending physician did not report pulmonary crackles at physical examination.

Fig 1

Individuals dynamic changes in admission-to-discharge B-lines

Outcomes

The patient who died during hospitalization had a severe degree of B-lines in the last LUS scanning, the same day of his death. This patient was excluded from the analysis. During the 6-month follow-up a total of 14 rehospitalization for HF and 4 deaths occurred. Mean follow-up was 159 ± 50 days.

A ROC analysis was performed to identify > 50 B-lines at admission as the best cut-off to predict readmission for HF during follow-up with a sensitivity of 71.4 %, specificity of 69.8 % negative predictive value of 93.7 %, positive predictive value of 27.8 %, negative likelihood ratio of 0.41, positive likelihood ratio of 2.36 (area under the curve 0.71, 95 % confidence interval 0.58–0.85, p = .011). A ROC analysis was performed to identify > 15 B-lines at discharge as the best cut-off to predict readmission for HF during follow-up with a sensitivity of 92.9 %, specificity of 68.6 % negative predictive value of 98.3 %, positive predictive value of 32.5 %, negative likelihood ratio of 0.1, positive likelihood ratio of 2.96 (area under the curve 0.83, 95 % confidence interval 0.74–0.92, p < .0001). The 6-month event-free survival showed a significantly better outcome for those patients with ≤ 15 B-lines at discharge, whereas a worse outcome was observed in patients with > 15 B-lines at discharge (log rank χ2 20.5, p < .0001) (Fig. 2). Table 3 shows the parameters that were significantly different between patients with and without events. Predictors of HF hospitalization by univariate and multivariate analysis are reported in Table 4. At multivariable analysis, only a number of B-lines > 15 before discharge was an independent predictor of HF readmission at 6 months (hazard ratio [HR] 11.74; 95 % confidence interval [CI] 1.30–106.16).

Fig 2

Kaplan-Meier survival curves in HF patients stratified according to the number of B-lines before discharge, at 6-months follow-up

Table 3

Different parameters in patients with and without events (HF readmission at 6 months)

	No HF readmission (n = 86)	HF readmission (n = 14)	p
Male sex	62 (72 %)	11 (79 %)	0.61
Age (years)	70.3 ± 10.9	69.8 ± 0.51	0.87
NYHA class	2.7 ± 0.9	3.4 ± 0.9	0.02
SAP (mmHg)	126 ± 22	124 ± 140	0.79
Diabetes Mellitus (n, %)	31 (36 %)	8 (57 %)	0.14
Hypertension (n, %)	49 (58 %)	8 (57 %)	0.37
Creatinine (mg/dl)	1.3 ± 0.5	1.6 ± 1.2	0.09
Hemoglobin (g/dl)	13.0 ± 2.1	12.0 ± 2.4	0.10
CRP (mg/l)	1.4 ± 2.1	1.1 ± 1.3	0.56
NT-proBNP (ng/l) at admission	5091 ± 5929	6203 ± 5821	0.57
NT-proBNP (ng/l) at discharge	3065 ± 4103	3816 ± 2764	0.09
Ejection fraction (%)	37 ± 13	37 ± 19	0.99
Wall motion score index	1.85 ± 0.57	1.83 ± 0.68	0.88
Restrictive pattern (n, %)	22 (26 %)	1 (7 %)	0.25
TAPSE (mm)	16.8 ± 4.7	14.5 ± 4.2	0.14
PASP (mmHg)	48 ± 14	54 ± 15	0.20
Pericardial effusion (n, %)	7 (8 %)	2 (14 %)	0.51
Pleural effusion (n, %)	19 (23 %)	5 (36 %)	0.42
B-lines at admission	43 ± 43	79 ± 66	0.01
B-lines at discharge	17 ± 22	40 ± 24	<0.0001

NYHA New York Heart Association, SAP systolic arterial pressure, CRP C-reactive protein, TAPSE tricuspid annular plane systolic excursion, PASP pulmonary artery systolic pressure

Table 4

Univariate and multivariate analysis to predict events (HF readmission at 6 months)

Univariate analysis			Multivariate analysis
	HR (95 % CI)	p	HR (95 % CI)	p
Age a	0.99 (0.95 – 1.04)	0.88
NYHA class a	2.31 (1.16 – 4.60)	0.017	1.48 (0.63 – 3.49)	0.37
Diabetes Mellitus	2.19 (0.76 – 6.31)	0.15
Creatinine a	1.58 (0.90 – 2.76)	0.11
Hemoglobin a	0.77 (0.59 – 1.02)	0.07
Hemoglobin < 10 g/dl	5.75 (1.76 – 18.78)	0.004	3.96 (0.52 – 30.10)	0.52
NT-proBNP at admission a	1.01 (0.99 – 1.01)	0.54
NT-proBNP at discharge a	1.01 (0.99 – 1.01)	0.55
NT-proBNP at discharge > 1635 ng/l	10.65 (1.35 – 84.26)	0.025	3.98 (0.43 – 37.18)	0.23
Ejection fraction a	1.01 (0.96 – 1.04)	0.91
Wall motion score index a	0.88 (0.35 – 2.17)	0.77
Restrictive pattern	0.33 (0.04 – 2.72)	0.30
TAPSE a	0.91 (0.80 – 1.03)	0.13
PASP a	1.03 (0.99 – 1.07)	0.11
Pericardial effusion (n, %)	1.68 (0.38 – 7.51)	0.49
Pleural effusion (n, %)	1.67 (0.51 – 5.49)	0.39
B-lines at admission a	1.01 (1.01 – 1.02)	0.004
B-lines at admission > 50	5.83 (1.82 – 18.62)	0.003	4.87 (0.88 – 27.06)	0.07
B-lines at discharge a	1.03 (1.01 – 1.04)	0.001
B-lines at discharge > 15	24.12 (3.15 – 184.55)	0.002	11.74 (1.30 – 106.16)	0.028

NYHA New York Heart Association, TAPSE tricuspid annular plane systolic excursion, PASP pulmonary artery systolic pressure, HR hazard ratio, CI confidence interval

a = continuous variable

When considering a follow-up of 3 months, the same cut-off of > 15 B-lines predicted readmission for HF with a sensitivity of 100 % and specificity of 64.8 %. The ROC analysis identified > 20 B-lines at discharge as the best cut-off to predict readmission for HF at 3 months follow-up, with a sensitivity of 100 %, a specificity of 74.7 %, negative predictive value of 100 %, positive predictive value of 28.1 %, negative likelihood ratio of 0, positive likelihood ratio of 3.96 (area under the curve 0.88, 95 % confidence interval 0.81-0.96, p < .0001). Kaplan-Meier curves depicting the prognostic value of > 20 B-lines before discharge at a 3 months follow-up are shown in Fig. 3 (log rank χ2 22.96, p < .0001).

Fig 3

Kaplan-Meier survival curves in HF patients stratified according to the number of B-lines before discharge, at 3-months follow-up

Discussion

In patients admitted with AHF to a cardiology department, the absence of significant pulmonary congestion before discharge, assessed by lung ultrasound, identifies a subgroup at a very low risk of being readmitted for decompensated HF in the following 6 months.

Pathophysiology of persistent congestion

The role of persistent congestion at hospital discharge is relevant in the outcome of patients with AHF. The early post-discharge time interval immediately after hospitalization, which is often addressed to as the vulnerable phase [27], has been recognized as a crucial moment in the management of AHF, when the majority of events occur [28, 29]. Patients with HF die or are hospitalized for different reasons, including ischemia, arrhythmias, worsened hemodynamics. However, in the vast majority the underlying pathophysiology is primarily related to increasing left ventricular filling pressures [30]. In the continuum of the congestion cascade in HF, it is important to distinguish the different phases of congestion [5, 31]: increased left ventricular filling pressures represent a phase of hemodynamic congestion, which is different from pulmonary, and from systemic and clinical congestion. In this cascade, pulmonary congestion more specifically refers to extravascular lung water (EVLW). Patients with the same degree of LV filling pressures may have significantly different degrees of pulmonary congestion, from complete absence of EVLW to alveolar pulmonary edema. These differences rely on many aspects, which are often difficult to be assessed, including the integrity of alveolar-capillary membrane – that depends also on the length of the disease -, the systemic inflammation status which may influence vascular permeability, and lymphatic drainage. LUS evaluation of B-lines offers a specific visualization of pulmonary congestion [32], thus easily allowing a non-invasive and bedside assessment of the degree of EVLW in any single patient. This information adds to the assessment of hemodynamic congestion that can be non-invasively performed through echoDoppler parameters. Natriuretic peptides, which are very useful at all steps of the management of HF patients, reflect more hemodynamic than pulmonary congestion. This can explain why natriuretic peptides and B-lines are somehow correlated in relatively large populations [15], but can provide very different information in the single patient, one enhancing the value of the other, especially in patients with natriuretic peptides in the grey zone [16, 17].

It is worth highlighting that there is no standardized method to assess pulmonary congestion in the clinical arena [5]. Chest X-ray is the most widely used tool to establish the presence and degree of EVLW, allowing a visualization of the lungs in the context of the whole chest. However, both sensitivity and specificity to detect signs of pulmonary congestion are suboptimal. Nearly 20 % of patients with HF have a normal chest X-ray, limiting overall sensitivity [21, 33].

Comparison with previous studies

The search for an optimal tool to predict rehospitalization for HF has been going on for years. Some scores have been proposed, although predictive models of HF hospitalization are still not currently implemented in the clinical practice. Most scores have been validated on chronic HF in ambulatory outpatients, and include clinical, biochemical and sometimes instrumental data, such as the HFPSI (Heart Failure Patient Severity Index) [34], the CHARM score [35], and more recently the REDIN score [36].

Previous studies have demonstrated the prognostic role of B-lines as an independent predictor of events in patients admitted with dyspnea and/or chest pain, in acute coronary syndromes, in hemodialysis, and in chronic HF even when assessed by a hand-held ultrasound device [37-41]. However, these analysis refer to admission exams and not to discharge, when the clinical information derived from a timely assessment can be relevant not only in a population-based approach, but also in a patient-based risk assessment, useful for management decisions, including discharge therapy, diuretic dosage, follow-up timing.

Clinical implications

In the last few years the use of B-lines in the management of patient with acute and chronic HF has moved from the research setting to the clinical arena, and its assessment is now included in Recommendation papers [21, 42, 43].

Our data shows that patients with persistent sonographic pulmonary congestion have an increased risk for rehospitalization for HF in the next 6 months, but the main finding of our study is the very low risk of readmission in patients with ≤ 15 B-lines before discharge. Thus, assessment of B-lines would allow for tailored discharge risk stratification. While further studies are needed, persistent presence of B-lines may be useful to titrate therapy as well as to personalize discharge planning and timing of follow-up.

It is interesting to note that although both B-lines at admission and at discharge are predictors of rehospitalization at univariate analysis, B-lines at discharge have a higher hazard ratio and are the only independent predictors of events at multivariate analysis. The best cut-offs obtained by ROC analysis to maximize accuracy are also different: at admission a higher number of B-lines is needed to confer an increased risk of events at 6-months, compared to discharge. This is reasonable, given the dynamic behavior of B-lines that can be highly responsive to treatment [44], and may rapidly change even after the short time of a dialysis session [25, 45], or increase significantly during the few minutes of a stress-echo test [46].

The possibility to count B-lines has been debated in the past. B-lines are substantially rough ultrasound artifacts, but by now many studies have shown the good correlations between the somehow “imprecise” number of B-lines and more established parameters of increased EVLW and decompensation [15, 17, 24, 25, 47–52]. In the clinical routine, however, the eyeballing imaging of B-lines (the whiter the image under the pleural line, the more B-lines) can be enough to get quick but meaningful information on the degree of pulmonary congestion. Moreover, the possibility to implement specific software which may aid in establishing the severity of B-lines, would further simplify the process [53].

We found > 15 and > 20 B-lines to be the best cut-offs to maximize accuracy in the prediction of HF readmission at 6 and 3 months. This cut-offs, although derived from independent statistical analysis, are consistent with previous studies showing that ≥ 15 B lines predicts decompensation in outpatients with HF [54]. It is worth noting however, that counting B-lines should not be equated to a precise assessment such as dosing a metabolite, and a difference in a few B-lines is not of clinical importance. The spatial distribution of B-lines and not only the absolute number of B-lines should be taken into account: first, it is known that a few B-lines, especially at pulmonary bases, can be found in normal subjects [13]; then, a very small number of B-lines found in many different scanning sites, although yielding an absolute high total number, may be less clinically relevant than many B-lines in a smaller number of scanning sites. As with any other test, B-lines should not be interpreted in isolation, but integrated with the overall clinical picture.

Despite not being a sophisticated, high tech parameter, this simple ultrasound biomarker seems to effectively help in the management of patients with HF, in a very sustainable and patient-friendly approach.

Limitations

This is a single-centre study with a relatively small study group of patients with HF of different aetiologies. This limitation however reflects the potentialities of LUS B-lines in different clinical scenarios, including patients with HF due to acute coronary syndromes. Given the relatively small study population, the number of events is also low. However, the number of patients enrolled was determined as sufficient according to sample size calculation. It should be emphasized that B-lines are a non-specific sign of pulmonary interstitial syndrome, which can be found also in interstitial pulmonary fibrosis, interstitial pneumonia and acute respiratory distress syndrome. This is crucial especially when using B-lines for the differential diagnosis of dyspnoea. When B-lines are used to determine persistent pulmonary congestion in patients with an already established diagnosis of HF, this limitation is less relevant. Interpreting B-lines not as a single image, but in a specific clinical context, is the key to avoid gross misinterpretation of this sign. When presence or persistence of B-lines is totally unrelated to the clinical picture, caution should be used and other causes of B-lines should be taken into account (pulmonary fibrosis in patients on amiodarone, non cardiogenic pulmonary edema, interstitial lung disease). Persistent pulmonary congestion can be related to the dosage of pharmacological therapy, especially diuretics; unfortunately, we did not add the specific dosage of therapies administered during hospital stay in our study population. Our findings should be confirmed in a larger multicentre study.

Conclusions

In AHF patients, persistent pulmonary congestion as defined by ≥ 15 B lines strongly predicts rehospitalization in the following 6-months. Absence or a mild degree of B-lines identify a subgroup at extremely low risk to be readmitted for AHF. Sonographic B-lines can be useful not only for the differential diagnosis of acute dyspnea, but also for the prognostic stratification of HF patients.