Impact of renal dysfunction on the management and outcome of acute heart failure: results from the French prospective, multicentre, DeFSSICA survey.

OBJECTIVES: Cardiorenal syndrome (CRS) is the combination of acute heart failure syndrome (AHF) and renal dysfunction (creatinine clearance (CrCl) ≤60 mL/min). Real-life data were used to compare the management and outcome of AHF with and without renal dysfunction.
DESIGN: Prospective, multicentre.
SETTING: Twenty-six academic, community and regional hospitals in France. PARTICIPANTS: 507 patients with AHF were assessed in two groups according to renal function: group 1 (patients with CRS (CrCl ≤60 mL/min): n=335) and group 2 (patients with AHF with normal renal function (CrCl >60 mL/min): n=172).
RESULTS: Differences were observed (group 1 vs group 2) at admission for the incidence of chronic heart failure (56.42% vs 47.67%), use of furosemide (60.9% vs 52.91%), insulin (15.52% vs 9.3%) and amiodarone (14.33% vs 4.65%); additionally, more patients in group 1 carried a defibrillator (4.78% vs 0%), had ≥2 hospitalisations in the last year (15.52% vs 5.81%) and were under the care of a cardiologist (72.24% vs 61.63%). Clinical signs were broadly similar in each group. Brain-type natriuretic peptide (BNP) and BNP prohormone were higher in group 1 than group 2 (1157.5 vs 534 ng/L and 5120 vs 2513 ng/mL), and more patients in group 1 were positive for troponin (58.2% vs 44.19%), had cardiomegaly (51.04% vs 37.21%) and interstitial opacities (60.3% vs 47.67%). The only difference in emergency treatment was the use of nitrates, (higher in group 1 (21.9% vs 12.21%)). In-hospital mortality and the percentage of patients still hospitalised after 30 days were similar between groups, but the median stay was longer in group 1 (8 days vs 6 days).
CONCLUSIONS: Renal impairment in AHF should not limit the use of loop diuretics and/or vasodilators, but early assessment of pulmonary congestion and close monitoring of the efficacy of conventional therapies is encouraged to allow rapid and appropriate implementation of alternative therapies if necessary. © Author(s) (or their employer(s)) 2019. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.

A large-scale, prospective, real-life study for the management and outcome of patients with cardiorenal syndrome compared with patients with acute heart failure without renal dysfunction.

Only two groups were included (ie, patients with or without kidney dysfunction), rather than for each stage of chronic kidney disease although the creatinine clearance cut-off (60 mL/min) is commonly used.

Glomerular filtration rate was calculated using three different methods.

Glomerular filtration rate estimations were performed by local laboratories for each centre (ie, a real-life situation).

There was no clearance monitoring after hospital discharge.

Background

Heart failure (HF) has an incidence of approximately 2% in adults in developed countries1 and mainly affects elderly patients, who may have multiple comorbidities. One such comorbidity, impaired renal function, has been shown to be a stronger predictor of mortality than impaired cardiac function2 3 and can be present in 50% of patients treated for acute HF (AHF).4 The prognostic importance of the association of renal dysfunction (creatinine clearance (CrCl) ≤60 mL/min) and AHF (cardiorenal syndrome (CRS)) has only been demonstrated recently. This represents a complex pathophysiological condition that has been classified into five stages.5 6 It is worth noting that this is a mechanistic classification and the patients’ clinical management must consider the full clinical presentation.

Even moderate degrees of renal insufficiency are independently associated with an increased risk of mortality from any cause in patients with HF.7 As such, CRS can lead to hesitancy among some clinicians to implement appropriate treatments for HF, such as diuretics, due to the effect that these may have to worsen the renal insufficiency. However, additional prospective research is needed and current recommendations are to maintain such treatments in patients with CRS,8 9 although the emergency physician should make an appropriate risk:benefit assessment for each patient.

In this context, a subanalysis was conducted using real-life data from the Description de la Filière de Soins dans les Syndromes d’Insuffisance Cardiaque Aigue (DeFSSICA study), a large-scale, prospective study that was conducted in patients with suspected dyspnoea of cardiac origin in emergency departments (EDs) throughout France.10 The aim of this subanalysis was to compare the management and outcome of patients with CRS to patients with AHF without renal dysfunction in France using novel real-life data, based on the hypothesis that patients with CRS and AHF would have the same outcome if the management of CRS was based on that for patients with AHF without renal dysfunction.

Methods

Study design

This was a prospective, multicentre study in patients presenting with suspected HF dyspnoea in 26 EDs in academic, community and regional hospitals (the DeFSSICA study) for which the rationale and design are reported elsewhere.10 Written information regarding the objectives of the survey was provided to all patients prior to their inclusion according to French law. Each participating physician presented the study to the patient and/or the patient’s family. The patient and/or the patient’s family could choose for the patient to withdraw from the study at any time. The study did not affect the patient–physician relationship or the patient’s care and follow-up.

Patient involvement

The research question was based on the prognostic importance of CRS and a need for real-life data on the management and outcome of patients with CRS. Patients were not involved in the design, recruitment and conduct of the study, and there is no plan to disseminate the results specifically to the patients who provided data used in this analysis.

Selection of participants

In the DeFSSICA survey, patients >18 years of age with dyspnoea compatible with AHF, defined as dyspnoea associated with peripheral oedema and/or pulmonary crackles and/or excessive weight gain and/or use of furosemide, were eligible for inclusion after ED admission and prior to chest X-ray and laboratory tests. Patient enrolment occurred between 16 June 2014 and 7 July 2014.

In this analysis, only patients with known CrCl were included and were divided into those with CrCl ≤60 mL/min, that is, renal dysfunction (group 1) and those with CrCl >60 mL/min, that is, normal renal function (group 2). Glomerular filtration rate (GFR) was calculated using either the Cockroft-Gault (9 centres), modification of diet in renal disease study (12 centres) or Chronic Kidney Disease (CKD) Epidemiology Collaboration equations (14 centres) (8 centres used two methods and 18 centres used one method).11 12

Study assessments

Patients’ baseline characteristics, medical history, social factors, in-hospital diagnostic tests and treatment, destination after ED discharge, in-hospital mortality and length of stay were recorded by emergency physicians in a case report form, which was structured according to the progress of care. Cardiac sonographic evaluations were performed at the discretion of the emergency physician. Abnormal chest X-ray was defined by the presence of cardiomegaly and/or alveolar oedema and/or interstitial opacity, and/or pleural effusion. The choice of treatment was at the emergency physician’s discretion and according to his/her usual practice. A final diagnosis of AHF was made by the emergency physician using a combination of a clinical history, abnormal chest X-ray, elevated brain-type natriuretic peptide (BNP) or BNP prohormone (pro-BNP), and echocardiographic signs.

Although it was not possible to impose any randomisation or blinding since this was an observational study, any potential bias in the study assessments was minimised by the provision of standard instructions to all participating physicians.

Data were entered into a secure database located at the Réseau Cardiologie Urgence (Cardiovascular Emergency Network) Coordination Centre.

Statistical analysis

Medians and IQRs are provided for continuous variables, and numbers and percentages for qualitative variables. Comparative analyses were performed using the χ2 or Fisher’s exact test for binary variables and the Wilcoxon test for analysis of variance for continuous variables.13 The 5% level was used to identify differences between groups that were of statistical significance (p<0.05). Statistical evaluations were performed using R Statistical Software (V.3.4.1).

Results

Patient disposition and prevalence of CRS

A total of 64 281 ED consultations took place during the survey period and 699 patients with dyspnoea of cardiac origin were included in DeFSSICA study. Of these, 537 patients were identified as having AHF, of whom only those with known CrCl (n=507) were included in this analysis.

Patients in group 1 (n=335 (66.1%)) had renal dysfunction (CrCl ≤60 mL/min) and comprised the population with CRS. In this group, 99 patients (29.6%) had severe renal dysfunction (stage 4 or 5: CrCl: <30 mL/min) and 120 (35.8%) had a known history of chronic renal failure. All patients in group 2 (n=172 (33.9%)) had normal renal function (CrCl >60 mL/min).

Patient disposition is presented in figure 1.

Figure 1

Patient disposition. DeFSSICA, Description de la Filière de Soins dans les Syndromes d’Insuffisance Cardiaque Aigue; HF, heart failure.

Baseline characteristics

The baseline characteristics of patients in group 1 and group 2 are shown in table 1. There was no difference between group 1 and group 2 in age (median (IQR): 84 (88–79) years and 82 (75–88) years; p=0.09) or sex distribution (42.99% male in group 1 and 44.19% male in group 2; p=0.87).

Table 1

Baseline characteristics of patients with confirmed AHF syndrome

	All patients with AHF (n=507)	Group 1 (n=335)	Group 2 (n=172)	P value
Age, year	83 (77; 88)	84 (78; 89)	82 (75; 88)	0.09
Men	220 (43.39%)	144 (42.99%)	76 (44.19%)	0.87
Comorbidities
Hypertension	353 (69.63%)	234 (69.85%)	119 (69.19%)	0.79
Chronic HF	271 (53.45%)	189 (56.42%)	82 (47.67%)	<0.05
Atrial fibrillation	223 (43.98%)	151 (45.07%)	72 (41.86%)	0.43
Coronary heart disease	150 (29.59%)	98 (29.25%)	52 (30.23%)	1.00
Diabetes type I	14 (2.76%)	12 (3.58%)	2 (1.16%)	0.26
Diabetes type II	132 (26.04%)	93 (27.76%)	39 (22.67%)	0.20
Chronic renal failure	114 (22.49%)	108 (32.24%)	6 (3.49%)	<0.01
Chronic respiratory failure	87 (17.16%)	60 (17.91%)	27 (15.7%)	0.46
Known valvular disease	95 (18.74%)	70 (20.9%)	25 (14.53%)	0.07
Priori medications
Furosemide	295 (58.19%)	204 (60.9%)	91 (52.91%)	<0.05
ACEI/ARB	225 (44.38%)	153 (45.67%)	72 (41.86%)	0.30
β-blocker	214 (42.21%)	147 (43.88%)	67 (38.95%)	0.20
Anticoagulant	221 (43.59%)	151 (45.07%)	70 (40.7%)	0.24
Aspirin	155 (30.57%)	110 (32.84%)	45 (26.16%)	0.08
Other antiplatelet	56 (11.05%)	37 (11.04%)	19 (11.05%)	0.73
Oral antidiabetic	66 (13.02%)	47 (14.03%)	19 (11.05%)	0.22
Insulin	68 (13.41%)	52 (15.52%)	16 (9.3%)	0.03
Amiodarone	56 (11.05%)	48 (14.33%)	8 (4.65%)	<0.01
Aldosterone antagonist	38 (7.5%)	26 (7.76%)	12 (6.98%)	0.48
Digoxin	38 (7.5%)	18 (5.37%)	20 (11.63%)	0.10
Thiazidine	32 (6.31%)	21 (6.27%)	11 (6.4%)	0.70
None	28 (5.52%)	14 (4.18%)	14 (8.14%)	0.38
Unknown	13 (2.56%)	7 (2.09%)	6 (3.49%)	1.00
Prior hospitalisation for HF during past year
0	287 (56.61%)	180 (53.73%)	107 (62.21%)	0.14
1	130 (25.64%)	83 (24.78%)	47 (27.33%)	0.86
≥2	62 (12.23%)	52 (15.52%)	10 (5.81%)	<0.01
Followed by a cardiologist	348 (68.64%	242 (72.24%)	106 (61.63%)	0.02
Residence
At home	423 (83.43%)	287 (85.67%)	136 (79.07%)	0.06
Retirement institution	74 (14.6%)	43 (12.84%)	31 (18.02%)	0.18
Other institution	8 (1.58%)	4 (1.19%)	4 (2.33%)	0.75
Self-sufficient	258 (50.89%)	162 (48.36%)	96 (55.81%)	0.19
Home assistance
Housekeeper	151 (29.78%)	111 (33.13%)	40 (23.26%)	0.02
Family support	121 (23.87%)	87 (25.97%)	34 (19.77%)	0.10
Nurse	134 (26.43%)	98 (29.25%)	36 (20.93%)	0.04
Known cognitive impairment	83 (16.37%)	49 (14.63%)	34 (19.77%)	0.26
Bedridden	45 (8.88%)	25 (7.46%)	20 (11.63%)	0.28

Data are median (IQR) age or number (%) of patients.

Group 1: patients with CRS; group 2: patients with normal renal function.

ACEI, ACE inhibitor; AHF, acute heart failure; ARB, angiotensin II receptor blocker; CRS, cardiorenal syndrome; HF, heart failure.

As well as the higher incidence of chronic renal failure in group 1, patients with CRS were more likely to have chronic HF (56.42% in group 1 vs 47.67% in group 2; p<0.05). There was no difference in the incidence of any other comorbidity between groups. Patients in group 1 were more likely than patients in group 2 to receive furosemide (60.9% vs 52.91%; p<0.05), insulin (15.52% vs 9.3%; p=0.03) and amiodarone (14.33% vs 4.65%; p<0.01), but there were no other differences between groups for medications. Additionally, patients in group 1 were more likely to have been hospitalised for HF at least twice during the last year (15.52% vs 8.81%; p<0.01), and to be under the care of a cardiologist (72.24% vs 61.63%; p=0.02). The incidence of patients carrying a defibrillator and of pacemakers (single, dual or triple) are not presented since the sample sizes were small (n=16 and n=17, n=36 and n=6, respectively) and so the data were not considered sufficiently robust. Patients in group 1 were more likely to have a housekeeper (31.13% vs 23.26%; p=0.02) and nurse (29.25% vs 20.93%; p=0.04), but there was no difference between groups regarding family support, known cognitive impairment or the incidence of being bedridden.

Hospitalisation and clinical status

Although there were few statistically significant differences between groups in hospitalisation and clinical status parameters (table 2), there was a consistent trend towards more congestion in group 1, including higher levels of dyspnoea, more pulmonary infiltrates on chest X-ray, higher BNP and pro-BNP (table 3 and below).

Table 2

Hospitalisation route and clinical status of patients with confirmed AHF syndrome

	All patients with AHF (n=507)	Group 1 (n=335)	Group 2 (n=172)	P value
Means of transport
Personal	232 (45.76%)	157 (46.87%)	75 (43.6%)	0.50
Ambulance	89 (17.55%)	56 (16.72%)	33 (19.19%)	0.63
Firemen	55 (10.85%)	34 (10.15%)	21 (12.21%)	0.65
MICU	40 (7.89%)	29 (8.66%)	11 (6.4%)	0.41
Interhospital transfer	6 (1.18%)	5 (1.49%)	1 (0.58%)	0.48
Clinical signs
Warm extremities	390 (76.92%)	257 (76.72%)	133 (77.33%)	0.23
Cold extremities	61 (12.03%)	45 (13.43%)	16 (9.3%)	0.97
Signs of right heart failure	216 (42.6%)	144 (42.99%)	72 (41.86%)	0.69
Inspiratory retraction	146 (28.8%)	107 (31.94%)	39 (22.67%)	0.02
Inability to speak	42 (8.28%)	25 (7.46%)	17 (9.88%)	0.54
First recorded vital signs
Heart failure, beats/min	85 (71; 102)	85 (72; 102)	85 (72; 104.25)	0.49
SBP, mm Hg	140 (121; 160)	140 (121; 160)	140 (124; 162)	0.11
DBP, mm Hg	76 (65; 90)	75 (63.5; 89)	78 (67.75; 92.25)	0.03
SBP <100 mm Hg	34 (6.71%)	27 (8.06%)	7 (4.07%)	0.13
Respiratory rate, breaths/min	25 (20, 30)	26 (20, 30)	24 (20, 29)	0.16
Pulse oximetry, %	94 (90; 96.25)	94 (90; 97)	94 (89; 96)	0.72
GCS <15	48 (9.47%)	31 (9.25%)	17 (9.88%)	0.94
Temperature >37°C	13 (2.56%)	12 (3.58%)	1 (0.58%)	0.37
Killip status
1	128 (25.25%)	76 (22.69%)	52 (30.23%)	0.26
2	269 (53.06%)	181 (54.03%)	88 (51.16%)	0.30
3	84 (16.57%)	60 (17.91%)	24 (13.95%)	0.11
Signs of shock	15 (2.96%)	8 (2.39%)	7 (4.07%)	0.89

Data are median (IQR) beats/minute, median (IQR) mm Hg, median (IQR) breaths/minute, median (IQR) % or number (%) of patients.

Group 1: patients with CRS; group 2: patients with normal renal function.

AHF, acute heart failure; CRS, cardiorenal syndrome; DBP, diastolic blood pressure; GCS, Glasgow Coma Scale; MICU, mobile intensive care unit; SBP, systolic blood pressure.

Table 3

Biological and diagnosis tests of patients with confirmed AHF syndrome

	All patients with AHF (n=507)	Group 1 (n=335)	Group 2 (n=172)	P value
Biological analysis
Performed	507 (100%)	335 (100%)	172 (100%)
Sodium, mmol/L	138 (135; 141)	138 (135; 141)	139 (135; 141)	0.40
Potassium, mmol/L	4 (4, 5)	4 (4, 5)	4 (4, 5)	0.89
Creatinine clearance, mL/min	50 (35; 69.05)	40 (29; 49.9)	78.5 (67; 91)	<0.01
Creatinine clearance <30 mL/min	89 (17.55%)	89 (26.57%)	0 (0%)	<0.01
Haemoglobin, g/L	130 (110, 140)	120 (110, 130)	130 (130, 140)	0.06
Troponin positive	271 (53.45%)	195 (58.21%)	76 (44.19%)	<0.01
BNP, ng/L	991 (507.5; 2443.5)	1157.5 (569.25; 2680.5)	534 (291; 1292)	<0.01
Pro-BNP, ng/L	4025 (1729; 8863)	5120 (2520; 12 399.75)	2513 (1146.5; 5376.5)	<0.01
ECG
Performed	500 (98.61%)	329 (98.20%)	171 (99.41%)
Sinusal	220 (44%)	145 (43.28%)	75 (43.6%)	0.92
Atrial fibrillation	213 (42.01)	139 (41.49%)	74 (43.02%)	1.00
Driven	44 (8.8%)	33 (9.85%)	11 (6.4%)	0.19
AVB	21 (4.14%)	14 (4.18%)	7 (4.07%)	0.86
LBBB	86 (17.2%)	64 (19.1%)	22 (12.79%)	<0.05
RBBB	59 (11.8%)	34 (10.15%)	25 (14.53%)	0.43
Repolarisation disorder	101 (20.2%)	73 (21.79%)	28 (16.28%)	0.09
Chest X-ray
Performed	481 (94.87%)	318 (94.92%)	163 (94.76%)
Normal	24 (4.73%)	11 (3.28%)	13 (7.56%)	0.20
Cardiomegaly	235 (48.86%)	171 (51.04%)	64 (37.21%)	0.01
Interstitial opacities	284 (59.04%)	202 (60.3%)	82 (47.67%)	0.02
Alveolar opacities	108 (22.45%)	64 (19.1%)	44 (25.58%)	0.05

Data are median (IQR) mmol/L, median (IQR) mL/min, median (IQR) g/dL, median (IQR) ng/L or number (%) of patients.

Group 1: patients with CRS; group 2: patients with normal renal function.

AHF, acute heart failure; AVB, atrioventricular block; BNP, brain natriuretic peptide; CRS, cardiorenal syndrome; LBBB, left bundle branch block; RBBB, right bundle branch block.

There were no significant differences between groups in their means of transport to the ED (most commonly by personal means (45.76% overall)), Killip status (most patients in each group had a Killip status of 2 (53.06% overall) and signs of cardiogenic shock (2.96% overall).

Early management and diagnosis

At admission, blood samples from all patients underwent biological analysis (table 3). As well as the differences between groups for CrCl, significant differences were observed for BNP, which was 2.2-fold higher in group 1 than group 2 (1157.5 ng/L vs 534 ng/L; p<0.01) and pro-BNP, which was twofold higher in group 1 than group 2 (5120 ng/L vs 2513 ng/L; p<0.01). Additionally, troponin was more likely to be positive in patients in group 1 than group 2 (58.21% vs 44.19%; p<0.01). There were no differences between groups for sodium, potassium or haemoglobin.

Most patients underwent under an ECG (98.61% overall) chest X-ray (94.87% overall). Patients in group 1 were more likely than those in group 2 to have left bundle branch block (19.1% vs 12.79%; p<0.05), cardiomegaly (51.04% vs 37.21%; p=0.01) and interstitial opacities (60.3% vs 47.67%; p=0.02).

Echography was only performed for 82 patients and so the data were not considered sufficiently robust for inclusion in the analysis.

Emergency treatments

Patients in group 1 were more likely than group 2 to receive emergency treatment of nitrates (21.19% vs 12.21%; p<0.01), but there were no group differences in other emergency measures (furosemide, oxygen, anticoagulant, continuous positive airway pressure, non-invasive ventilation, antiarrhythmics, ionotropic agents, tracheal intubation) (table 4). Overall 6.31% of patients received no emergency treatment, with no difference between groups.

Table 4

Emergency treatment of patients with confirmed AHF syndrome

	All patients with AHF (n=507)	Group 1 (n=335)	Group 2 (n=172)	P value
Furosemide	376 (74.16%)	252 (75.22%)	124 (72.09%)	0.26
Oxygen	337 (66.47%)	225 (67.16%)	112 (65.12%)	0.43
Nitrates	92 (18.15%)	71 (21.19%)	21 (12.21%)	0.01
Anticoagulant	37 (7.3%)	22 (6.57%)	15 (8.72%)	1.00
CPAP	8 (1.58%)	6 (1.79%)	2 (1.16%)	0.24
NIV	45 (8.88%)	30 (8.96%)	15 (8.72%)	0.58
Antiarrhythmics	23 (4.54%)	15 (4.48%)	8 (4.65%)	0.60
Ionotropic agents	3 (0.59%)	3 (0.9%)	0 (0%)	0.11
Tracheal intubation	1 (0.2%)	1 (0.3%)	0 (0%)	0.20
None	32 (6.31%)	17 (5.07%)	15 (8.72%)	0.58

Data are number (%) of patients.

Group 1: patients with CRS; group 2: patients with normal renal function.

AHF, acute heart failure; CPAP, continuous positive airway pressure; CRS, cardiorenal syndrome; NIV, non-invasive ventilation.

Outcomes

Precipitating factors were not determined in 42.21% of cases overall, with no overall difference between groups (table 5). The most common determined precipitating factors were an infection (25.25% overall), arrhythmia (15.19% overall) and hypertension (10.65% overall). Diabetes decompensation was considered to be the precipitating factor for AHF in 2.99% of patients in group 1 but none in group 2 (p=0.01). There were no other group differences in precipitating factors.

Table 5

Outcomes of patients with confirmed AHF syndrome

	All patients with AHF (n=507)	Group 1 (n=335)	Group 2 (n=172)	P value
Precipitating factors
Unknown	214 (42.21%)	138 (41.19%)	76 (44.19%)	0.82
Infection	128 (25.25%)	84 (25.07%)	44 (25.58%)	0.89
Rhythm disorder	77 (15.19%)	47 (14.03%)	30 (17.44%)	0.67
Hypertension	54 (10.65%)	39 (11.64%)	15 (8.72%)	0.19
Non-adherence to treatment	30 (5.92%)	17 (5.07%)	13 (7.56%)	0.92
Acute coronary syndrome	21 (4.14%)	15 (4.48%)	6 (3.49%)	0.32
Eating disorder	20 (3.94%)	14 (4.18%)	6 (3.49%)	0.39
Diabetes decompensation	10 (1.97%)	10 (2.99%)	0 (0%)	0.01
Discharge destination
Cardiology	142 (28.01%)	100 (29.85%)	42 (24.42%)	0.33
Geriatric medicine	61 (12.03%)	34 (10.15%)	27 (15.7%)	0.06
Other medical unit	99 (19.53%)	67 (20%)	32 (18.6%)	0.98
CICU	62 (12.23%)	42 (12.54%)	20 (11.63%)	1.00
Resuscitation unit	16 (3.16%)	11 (3.28%)	5 (2.91%)	0.98
ED hospitalisation unit	74 (14.6%)	48 (14.33%)	26 (15.12%)	0.72
Back home	26 (5.13%)	14 (4.18%)	12 (6.98%)	0.14
Other	24 (4.73%)	18 (5.37%)	6 (3.49%)	0.78
Destination considered appropriate	382 (75.35%)	246 (73.43%)	136 (79.07%)	0.13
Outcome
In-hospital mortality	30 (5.92%)	24 (7.16%)	6 (3.49%)	0.97
Still hospitalised at 30 days	32 (6.31%)	20 (5.97%)	12 (6.98%)	1.00
Length of stay, days	7 (4; 13)	8 (4; 13)	6 (3; 12)	0.03

Data are number (%) of patients or median (IQR) days.

Group 1: patients with CRS; group 2: patients with normal renal function.

AHF, acute heart failure; CICU, cardiac intesive care unit; CRS, cardiorenal syndrome; ED, emergency department.

There was no difference between groups in discharge destination (which was most often cardiology (28.01% overall)), and the discharge destination was deemed appropriate for a similar number of patients in each group (75.35% overall).

Neither in-hospital mortality (5.92% overall) nor the percentage of patients still hospitalised at 30 days (6.31% overall) was significantly different between group 1 and group 2. However, the median length of stay was 2 days longer in group 1 than in group 2 (8 days vs 6 days; p=0.03) (table 5).

Discussion

The DeFSSICA study was a large-scale, prospective, real-life study conducted following the admission of patients with AHF to EDs throughout France. As such, the data are primarily applicable to the French population, although wider extrapolation is possible due to coherences with similar studies in other geographical regions. The overall DeFSSICA study data are presented elsewhere10 and the present subanalysis reports real-life data from subgroups of patients with AHF with or without concomitant renal dysfunction, based on a CrCl threshold of 60 mL/min. The results show that AHF admissions to EDs are often associated with renal impairment, with almost two-thirds of AHF admissions having CrCl ≤60 mL/min. This prevalence is comparable to published data from France,14 Italy,15 16 Poland,17 Spain,18 19 Taiwan20 and the USA,21–23 as well as from pan-European24 25 and wider international studies.26 In these studies,14–26 the prevalence of renal impairment on the admission of patients with AHF ranged from 54.5% to 64%, including 12.4% to 27.4% of patients with severe renal insufficiency. Patients with a history of chronic renal failure ranged from 21.4% to 32.5%, which is also comparable to the findings of the DeFSSICA survey. However, it should be noted that impaired cardiac function leads to reduced renal perfusion, which could be in addition to an underlying chronic renal insufficiency. Additionally, increased abdominal pressure at admission that can result from ascites can lead to renal vein compression and reduced GFR at admission, which could also result in elevated serum creatinine. It is likely, therefore, that a proportion of acute kidney injury diagnosed at admission based on serum creatinine could be due to temporary changes in perfusion pressures rather than kidney damage per se; these functional reductions in GFR would be expected to recover once a normal haemodynamic function is restored. While it is therefore important to consider the use of biomarkers to provide a more precise assessment of kidney function than serum creatinine,27 28 it is also important to note that the evidence supporting the preferential use of novel biomarkers rather than serum creatinine to detect acute kidney injury can be inconsistent and remains an area for further research.29–32

The overall baseline characteristics, clinical status, biological and diagnostic tests, emergency treatment, and outcome of the patients included in this subanalysis was similar to the overall population in the DeFSSICA study; however, some differences were observed between patients with AHF with and without renal dysfunction, including a trend towards more congestion in patients with CRS. As would be expected due to reduced kidney excretion,33 and as described elsewhere,34–37 BNP and pro-BNP levels were higher in patients with CRS than in patients with AHF with normal renal function and the percentage of troponin-positive patients was also higher in the CRS group. These biomarkers probably reflect the congestion status and remain formally recommended for the management of patients with AHF, especially for their prognostic value. The appropriate use of loop diuretics and/or vasodilators38 in the CRS group, as well as in the AHF group without renal dysfunction, may explain in part the similar intrahospital mortality rate in each group and the similar proportion of patients with AHF with and without renal dysfunction who were still in hospital 30 days after ED admission. Importantly, therefore, the prognosis of patients with CRS was not significantly different using loop diuretics and/or nitrates to those without renal dysfunction. As such, it appears that the correct congestive assessment is vital in this complex clinical situation with concomitant failures in two organs.

Recent publications suggest that appropriate, fast-acting decongesting therapies, as recommended by international guidelines, improve the prognosis for patients with AHF as long as such therapies are introduced early, even if renal impairment develops at the same time.8 Furthermore, it appears that renal impairment in patients with AHF does not have an adverse impact on patient prognosis provided that the congestion is improved. Renal function should be assessed according to the level of patient congestion, and so tools for the assessment of congestion such as the BNP or pro-BNP biomarkers,39 lung ultrasound B-lines (38) or the assessment of the dimensions and compliance of the inferior vena cava are vital. Additionally, haemoconcentration monitoring can be useful for monitoring congestion and significantly improves the short-term outcome of patients with AHF40 and several routinely assessed biological parameters, for example, serum protein, albumin, haemoglobin and haematocrit have been proposed as surrogate markers.41 Furthermore, formulae have been developed to indirectly estimate plasma volume using haemoglobin and/or haematocrit data.42 43 Further research is needed to establish the ability of novel biomarkers such as urinary angiotensinogen,44 neutrophil gelatinase-associated lipocalin,45 46 kidney injury molecule-1,47 interleukin-18,48 49 N-acetyl-β-d-glucosaminidase,50 cystatine C51 52 or a combination of some or all of these could also be used to improve clinical decision-making and therapy. The assessment of diuresis and natriuresis, which reflect both glomerular and tubular function, could offer a strategy to achieve decongestion.50 53 54 Ferreira et al 55 and Palazzuoli et al 56 showed that the lack of a diuretic response is a more important prognostic factor than the use of loop diuretics. This suggests a new diagnostic challenge, that is to assess the patient’s response to diuretics.57–60 However, despite some proposals to define diuretic resistance (eg, persistent congestion despite adequate and escalating doses of diuretic with >80 mg furosemide/day, amount of sodium excreted as a percentage of filtered load <0.2%, failure to excrete ≥90 mmol of sodium within 72 hours of a 160 mg oral furosemide dose given two times daily) and the means of evaluation (eg, weight loss per unit of 40 mg furosemide (or equivalent), net fluid loss/mg of loop diuretic (40 mg of furosemide or equivalent) during hospitalisation, natriuretic response to furosemide),61 there is currently no consensus for commonly accepted standards. Additionally, it is important that any alteration of GFR should be interpreted in the context of the deterioration of the clinical situation.

Another alternative therapy in CRS is the use of mineralocorticoid antagonists. These have been associated with an improvement in both congestion62 63 and mortality in patients with HF,64 65 although the Aldosterone Targeted Neurohormonal Combined with Natriuresis Therapy in Heart Failure (ATHENA-HF) trial results are less conclusive.66 Combined therapies have also been evaluated, including hypotonic saline serum in combination with diuretic therapy to improve diuresis67 68 and mannitol in combination with furosemide,61 although their benefit in diuretic-resistant patients is not confirmed. The addition of metolazone to furosemide could be of interest because of its capacity to produce diuresis even in patients with low GFR.69 70 In a meta-analysis, Wang et al showed that tolvaptan, an oral vasopressin V2-receptor antagonist, may also represent an alternative therapy in worsening renal function (WRF).71 Several studies have shown that tolvaptan can decrease WRF in patients treated with furosemide.72 73 Finally, venous ultrafiltration allows controlled hydrosodic depletion by subtracting isotonic fluid, compared with diuretics that allow the subtraction of hypotonic fluid. Other studies suggest that the effectiveness of ultrafiltration is associated with a reduction in inflammatory cytokines.74 These and other approaches in patients with cardiac insufficiency and resistance to diuretics have recently been reviewed.61

The CRS analysis using data from the DeFSSICA survey has some limitations. First, only two groups have been analysed (ie, patients with or without renal dysfunction), whereas CKD is characterised by five stages.5 However, as noted earlier, this is a mechanistic classification and in the present analysis the use of the CrCl threshold of 60 mL/min, which is commonly used to define renal dysfunction,2 37 75–77 is considered to be satisfactory, especially since the small number of patients would not allow a thorough analysis for five subcategories. However, the pathophysiology of WRF in AHF is complex78 and using a spot measurement of serum creatinine to classify CRS has limitations. This approach does not allow the separation of patients with acute and chronic CRS: in the present study, 35.8% of patients included in the CRS group had a history of chronic renal failure and so may not have suffered any acute change in renal function, whereas patients with acute changes in serum creatinine compared with their own baseline but not fulfilling the <60 mL/min criterion would not have been included in the CRS group. That said, the presence of renal failure on admission remains strongly associated with a poor prognosis irrespective of the anterior renal status and despite the lack of WRF in the first 5 days.79 While the choice of a CrCl threshold of 30 mL/min could have led to a greater chance of obtaining a significant difference between groups in terms of outcome, we based our analysis on the 60 mL/min cut-off since it is more widely used. Second, since the data used are observational, it was not possible to impose any randomisation or blinding, and the number of patients in each group was not balanced. Third, GFR assessments were performed by local laboratories for each centre, rather than standardised at a single centre, and repeated measures of GFR could have improved their accuracy and comparability. The use of different formulae to evaluate CrCl in a chronic disease state and an acute context without knowledge of the baseline value reflects the real-life situation. While potentially problematic, with the possibility of some incorrect classification of CKD, numerous previous studies of the impact of renal failure in AHF have used a similar approach.2 37 75 Finally, it was not possible to subclassify different types of CRS in this analysis since Kidney Disease Improving Global Outcomes data were not collected, although as described earlier the small number of patients would not have allowed a thorough analysis for each subcategory.

Conclusion

These real-life data suggested that patients with CRS have the same outcome as patients with AHF without renal dysfunction when the treatment of the former group is modelled on that for the latter group. This finding should not limit the use of loop diuretics and/or vasodilators as long as the patients present congestion as assessed using biomarkers and ultrasound. The use of diuretic treatment should be based on a more rapid diagnosis of congestion and evaluation of an inadequate response to diuretics, allowing the rapid and appropriate implementation of alternative therapies if necessary.