Efficacy and safety of nesiritide in patients with decompensated heart failure: a meta-analysis of randomised trials.

OBJECTIVES: Current evidence suggests that nesiritide may have effects on renal function and decrease the incidence of mortality. However, a clear superiority using nesiritide in terms of renal toxicity and mortality in patients with heart failure was not consistently proven by previous studies. We performed a meta-analysis of all randomised trials to obtain the best estimates of efficacy and safety of nesiritide for the initial treatment of decompensated heart failure.
METHOD: We performed a meta-analysis of randomised trials of nesiritide in patients with decompensated heart failure (n=38,064 patients, in 22 trials). Two reviewers independently extracted data. Data on efficacy and safety outcomes were collected. We calculated pooled relatives risk (RRs), weighted mean difference and associated 95% CIs.
RESULTS: Compared with placebo, dobutamine and nitroglycerin, nesiritide indicated no increasing risk of total mortality. Compared with the combined control therapy, nesiritide was associated with non-significant differences in short-term mortality (RR 1.24; 95% CI 0.85 to 1.80; p=0.27), mid-term mortality (RR 0.86; 95% CI 0.60 to 1.24; p=0.42) and long-term mortality (RR 0.94; 95% CI 0.75 to 1.18; p=0.61). Nesiritide therapy increased the risk of hypotension (p<0.00 001) and bradycardia (p=0.02) when compared with control therapy. Compared with dobutamine or placebo therapy, no differences in serum creatinine, blood urea nitrogen and creatinine clearance, and no risk of the need for dialysis was observed in nesiritide therapy.
CONCLUSIONS: Our findings indicated that, in patients with heart failure, nesiritide was not associated with the risk of mortality. However, it increased the risk of cardiovascular adverse events. The change of serum creatinine and creatinine clearance had no significant difference, and no risk of the need for dialysis was observed after low-dose nesiritide treatment. Published by the BMJ Publishing Group Limited. For permission to use (where not already granted under a licence) please go to http://www.bmj.com/company/products-services/rights-and-licensing/

In this meta-analysis, we evaluated the efficacy and safety of nesiritide in patients with decompensated heart failure. We demonstrated that nesiritide was not associated with total mortality, short-term mortality, mid-term mortality and long-term mortality. However, it increased the risk of cardiovascular adverse events.

Several limitations of the present meta-analysis should be considered. First, the primary limitation is lack of complete mortality data. Not all the studies in this report described total mortality and long-term mortality. Second, all the studies lasted for <12 weeks and no study lasted more than a year which limited our assessment of long-term mortality. Finally, this analysis has not reached out to all racial and ethnic groups, and we only include English language studies.

Introduction

Advanced decompensated chronic heart failure (CHF) is one of the most frequent reasons for hospital admissions in patients over the age of 65 years,1 with more than one million people in the USA hospitalised each year.2 Decompensated heart failure is a complex syndrome mainly caused by left or right ventricular dysfunction rather than being a single problem of low cardiac output. It is associated with endothelial dysfunction, which contributes to the pathophysiology of the syndrome,3 4 and is also connected with increased local and systemic release of oxygen-derived free radicals that cause myocardial dysfunction in patients with this syndrome.5 Inflammatory and neurohormonal activation play a significant role in the pathophysiology of decompensated heart failure.6 Despite optimal diuretics, vasodilators and oral therapy, patients with evidence of peripheral hypoperfusion and clinical deterioration also may receive positive inotropic agents, usually milrinone or dobutamine.

Nesiritide, a vasodilator agent and recombinant human brain or B-type natriuretic peptide7–9 for the treatment of acutely decompensated heart failure produced primarily by the ventricular myocardium in response to volume and pressure overload,10 was approved by the Food and Drug Administration in 2001, and became the first new therapy for acute decompensated heart failure in 14 years.

In clinical studies, nesiritide had been found to acutely reduce pulmonary capillary wedge pressure (PCWP), systemic blood pressure, left ventricular filling pressure and systemic vascular resistance (SVR).8 11–13 It also increased cardiac output without direct inotropic effects, promoted diuresis by opposing the effects of endothelin 1, and improved short-term symptoms of dyspnoea and glomerular filtration rate.8 11 However, two recently published meta-analyses14 15 and one large randomised trial16 prompted further debate about the role of nesiritide for the initial treatment of heart failure. Two meta-analyses illustrated that worsening renal function and higher short-term mortality were associated with nesiritide,14 15 whereas one large randomised trial by O’Connor et al16 showed that nesiritide was not associated with a worsening of renal function and the risk of mortality.

When properly applied, meta-analysis can increase the statistical power of primary endpoints, clarity disagreement among studies, and estimate effect sizes to quantify outcomes from a set of individual studies.17 To further clarify the role of nesiritide, we performed an updated meta-analysis of randomised trials comparing nesiritide with placebo, dobutamine, or nitroglycerin, for the initial treatment of decompensated heart failure, with particular references to the efficacy and safety.

Methods

We attempted to identify all relevant published randomised studies comparing nesiritide with dobutamine, nitroglycerin, or placebo, for the initial treatment of decompensated heart failure. We searched between October 1950 and October 2015 from MEDLINE, between January 1980 and October 2015 from EMBASE, and between January 1976 and October 2015 from the Cochrane Library for English-language randomised controlled trials, using the terms “heart failure”, “nesiritide”, “dobutamine”, “placebo”, “nitroglycerin”, “controlled clinical trial”, “randomized controlled trial” and “random”. We also performed a manual search of references from original articles and pertinent reviews.

Study selection

The articles were independently assessed by two investigators (BG and ZW). Disagreements were resolved by consensus with a third reviewer.

Criteria for inclusions were: (1) randomised, (2) conducted in patients with heart failure, (3) compared nesiritide with dobutamine, nitroglycerin, or placebo for the initial treatment of heart failure, (4) low doses of nesiritide (≤0.015 µg/kg/min) and high doses of nesiritide (>0.015 µg/kg/min) and (5) use of objective methods to assess one or more clinical outcomes, including the efficacy and safety outcomes.

Outcomes

Study outcomes were analysed comparing the results from 22 trials with nesiritide versus dobutamine, placebo, or nitroglycerin.

The efficacy outcomes were PCWP, right atrial pressure (RAP), SVR, systolic blood pressure (SBP), diastolic blood pressure (DBP), serum creatinine (SCr), blood urea nitrogen (BUN) and creatinine clearance (CrCl).

The safety outcomes were mortality, non-cardiovascular adverse events and cardiovascular adverse events. According to its follow-up duration, mortality was divided into three parts: early term (≤30 days), midterm (>30 days to 6 months), and long term (>6 months). Non-cardiovascular adverse events were nausea, headache, abdominal pain and the need for dialysis. Cardiovascular adverse events were hypotension (asymptomatic and symptomatic), ventricular extrasystole, ventricular tachycardia (sustained and non-sustained), cardiac arrest, bradycardia and angina pectoris.

Statistical analyses

We determined pooled relative risks (RRs), weighted mean difference (WMD) and corresponding 95% CIs, for mortality, non-cardiovascular adverse events, cardiovascular adverse events, haemodynamic parameters and renal function parameters, in patients with heart failure who received nesiritide or treatment with dobutamine, nitroglycerin, or placebo. Furthermore, heterogeneity was assessed using the χ2 test and the I2 measure of inconsistency. If no heterogeneity was found, meta-analysis was performed using a fixed effects model (Mantel-Haenszel method).18 Results obtained with a fixed effects model were also compared with those obtained with a random-effects model. All analyses were performed using Review Manager (V.5.1).

Results

Study selection and characteristics

There were 22 studies including 38 064 patients with decompensated heart failure in the present meta-analysis (study characteristics are listed in table 1).8 11 12 16 19–36

Table 1

Characteristics of the 22 studies included in the meta-analysis

Study	Year	Country and centres	Blinding	Sample size	Population	Intervention drug	Nesiritide bolus, µg/kg	Nesiritide infusion, µg/kg/min	Nesiritide duration, h	Control drug	Follow-up, months	Lost to follow-up, days	Jadad score
Abraham et al19	2005	Multicentres	Double blind	489	Acutely decompensated congestive heart failure	Nesiritide	2	0.01	24	Nitroglycerin and placebo	Hosp	0	5
Burger et al20	2001	Multicentres	Open	261	Acutely decompensated congestive heart failure	Nesiritide	0.3	0.015 and 0.03	UNK	Dobutamine	21 days	0	3
Burger et al12	2002	Multicentres	Open	255	Decompensated congestive heart failure	Nesiritide	0	0.015 and 0.03	24	Dobutamine	14 days	0	3
O’Connor et al16	2011	Multicentres	Double blind	7141	Acute heart failure	Nesiritide	2	0.01	24	Placebo	30 days	0	5
Arora et al21	2007	USA, single centre	UNK	206	Acute decompensated heart failure	Nesiritide	2	0.01	24	Placebo	Hosp	0	3
Silver et al22	2002	Multicentres	Double blind	261	Decompensated heart failure	Nesiritide	0.3 and 0.6	0.015 and 0.03	24	Dobutamine	6	2	4
Witteles et al23	2007	Multicentres	Double blind	75	Acute decompensated heart failure	Nesiritide	2	0.01	48	Placebo	30 days	0	5
Aronson and Burger24	2002	Multicentres	UNK	82	Decompensated congestive heart failure	Nesiritide	UNK	0.015 and 0.03	24	Dobutamine	Hosp	0	4
The VMAC study11	2002	Multicentres	Double blind	489	Decompensated congestive heart failure	Nesiritide	1	0.01	24	Nitroglycerin and placebo	6	0	5
Colucci et al8	2000	Multicentres	Open	432	Symptomatic congestive heart failure	Nesiritide	0.3 and 0.6	0.015 and 0.03	3	Placebo	21 days	0	4
Chen et al25	2013	Multicentres	Double blind	360	Acute heart failure and renal dysfunction	Nesiritide	0	0.005	24	Dobutamine and placebo	180 days	4	5
Chow et al26	2011	USA, single centre	Open	89	Acutely decompensated heart failure	Nesiritide	2	0.01	24	Nitroglycerin	Hosp	UNK	3
Peacock et al27	2005	Multicentres	Double blind	237	Acutely decompensated heart failure	Nesiritide	2	0.01	12	Placebo	Hosp	UNK	4
Peacock et al28	2004	Multicentres	Double blind	61	Patients with dyspnoea at restresulting from heart failure	Nesiritide	2	0.01	24	Nitroglycerin	6	0	5
Peacock et al29	2005	Multicentres	Double blind	250	Acutely decompensated heart failure	Nesiritide	2	0.01	12	Placebo	30 days	1	5
Styron et al30	2009	Multicentres	UNK	595	Heart failure	Nesiritide	UNK	NA	UNK	Placebo	180days	0	3
Carroll et al31	2007	Multicenters	Open	25 330	Congestive heart failure	Nesiritide	UNK	NA	UNK	Placebo	Hosp	0	3
Yancy and Singh32	2006	Multicentres	Open	138	Advanced heart failure and renal insufficiency	Nesiritide	1 and 2	0.005 and 0.01	14 days	Placebo	3	4	3
Chow et al33	2011	USA, single centre	UNK	89	Cardiorenal syndrome with acute decompensated heart failure	Nesiritide	2	0.01	48	Nitroglycerin	6	0	3
Yancy et al34	2004	Multicentres	Open	210	Decompensated heart failure	Nesiritide	1 and 2	0.005 and 0.01	6	Placebo	3	0	3
Yancy et al35	2008	Multicentres	Double blind	911	Acutely decompensated heart failure	Nesiritide	2	0.01	6	Placebo	3	5	5
Mills et al36	1999	Multicentres	Double blind	103	Decompensated heart failure	Nesiritide	0.25, 0.5 and 1.0	0.015 and 0.03	24	Placebo	Hosp	UNK	5

Hosp, during hospitalisation; NA, not applicable; UNK, unknown.

Fourteen trials were double blind,11 16 19 22 23 25 27–29 35 36 seven were open-label trials8 12 20 26 31 32 34 and the remaining had concealed allocation.21 24 30 33 The dose of nesiritide varied between 0 and 2 µg/kg (as an intravenous bolus) or between 0.005 and 0.03 µg/kg/min (as a continuous infusion). Follow-up durations were ≤30 days in 14 trials,8 12 16 19–21 23 24 26 27 31 36 37 3 months in 3 trials32 34 35 and 6 months in 6 trials.11 22 25 28 30 33 A PRISMA flow diagram is shown in figure 1.

Figure 1

PRISMA flow diagram.

Methodological quality

We summarised the methodological quality of the Jadad score of the reported studies in table 1. The bias assessments are shown in figure 2 according to the risk of bias.

Figure 2

Methodological quality of included studies according to the Cochrane Collaboration’s tool for assessing risk of bias.

Meta-analysis

Efficacy outcomes

The effect of nesiritide versus nitroglycerin, dobutamine or placebo on PCWP, RAP, SVR, SCr, BUN and CrCl in patients with decompensated heart failure are shown in table 2.

Table 2

Measures of clinical outcomes after the therapeutic intervention

Control group	Outcome	Studies, n	WMD	95% CI	p Value
High-dose nesiritide
Placebo	SVR (dynes/s/cm−5)	2	−305.17	−493.96 to −116.38	0.002
	SBP (mm Hg)	2	−6.87	−11.01 to −2.73	0.001
Dobutamine	DBP (mm Hg)	1	−6.3	−12.39 to −0.21	0.04
	SBP (mm Hg)	1	−6.3	−12.39 to −0.21	0.04
Low-dose nesiritide
Placebo	PCWP (mm Hg)	3	−4.35	−4.35 to −3.33	<0.00 001
	SVR (dynes/s/cm−5)	3	−95.35	−178.09 to −12.06	0.02
	RAP (mm Hg)	3	−5.6	−8.99 to −2.21	0.001
	SCr (mg/dL)	1	−0.02	−0.11 to 0.07	0.66
	BUN (mg/dL)	1	−2.9	−8.85 to 3.05	0.34
Dobutamine	DBP (mm Hg)	2	−2.21	−3.43 to −0.98	0.0004
Nitroglycerin	PCWP (mm Hg)	2	−2.21	−3.43 to −0.98	0.0004
	RAP (mm Hg)	1	−2.2	−3.45 to−0.95	0.0005
	SBP (mm Hg)	1	−3.9	−6.92 to −0.88	0.01
	SCr (mg/dL)	2	−0.04	−0.17 to 0.08	0.49
	CrCl (mL/min)	2	−0.82	−6.95 to 5.31	0.79

BUN, blood urea nitrogen; CrCl, creatinine clearance; DBP, diastolic blood pressure; PCWP, pulmonary capillary wedge pressure; RAP, right atrial pressure; SBP, systolic blood pressure; SCr, serum creatinine; SVR, systemic vascular resistance; WMD, weighted mean difference.

There were no significant differences between low-dose nesiritide and nitroglycerin in the efficacy outcomes of SCr (WMD, −0.04 mg/dL; 95% CI −0.17 to 0.08 mg/dL; p=0.43) and CrCl (WMD, −0.82 mL/min; 95% CI −6.95 to 5.31 mL/min; p=0.79). When we compared low-dose nesiritide with placebo, there were no consistent changes in SCr and BUN. Combining data from studies comparing high-dose nesiritide with placebo, results showed significant difference in SVR (WMD, −305.17 dynes/s/cm5; 95% CI −493.96 to −116.38 dynes/s/cm5; p=0.002).

Safety outcomes

Mortality outcomes

Forest plots of mortality outcomes are summarised in figures 3–8. Three trials contributed to the analysis on total mortality with a comparison between nesiritide and placebo (figure 3).16 21 23 30–35 Compared with placebo, nesiritide indicated no increasing risk of total mortality, with an RR of 1.04 (95% CI 0.79 to 1.38; p=0.76; figure 3). As shown in figure 4, there was no significant difference between the nesiritide and dobutamine group, regarding total mortality (RR 0.69; 95% CI 0.46 to 1.05; I2=0%; p=0.09).12 20 22 Reanalysis with a random-effects model did not change this result (RR 0.69; 95% CI 0.46 to 1.02; p=0.89). Compared with nitroglycerin, nesiritide indicated no reduction in total mortality, with an RR of 1.10 (95% CI 0.81 to 1.49; p=0.55; figure 5).11 28 29 Reanalysis with a random-effects model did not change this result (RR 1.10; 95% CI 0.52 to 2.34; p=0.24). Compared with the combined control therapy, nesiritide was associated with non-significant differences in short-term mortality (RR 1.24; 95% CI 0.85 to 1.80; p=0.27; figure 6),12 16 20 21 23 26 27 30 31 mid-term mortality (RR 0.86; 95% CI 0.60 to 1.24; p=0.42; figure 7)32 34 35 and long-term mortality (RR 0.94; 95% CI, 0.75 to 1.18; p=0.61; figure 8).11 22 26 28 30 However, no study had data regarding the safety outcome of more than 12 months.

Figure 3

Meta-analysis for the comparison of total mortality in nesiritide versus placebo group (RR, risk ratio).

Figure 4

Meta-analysis for the comparison of total mortality in nesiritide versus dobutamine group (RR, risk ratio).

Figure 5

Meta-analysis for the comparison of total mortality in nesiritide versus nitroglycerin group. (RR, risk ratio).

Figure 6

Funnel plots of studies assessing the comparison of short-term mortality in nesiritide therapy versus control therapy (RR, risk ratio).

Figure 7

Funnel plots of studies assessing the comparison of mid-term mortality in nesiritide therapy versus control therapy (RR, risk ratio).

Figure 8

Funnel plots of studies assessing the comparison of long-term mortality in nesiritide therapy versus control therapy (RR, risk ratio).

Cardiovascular adverse events

Table 3 summarises cardiovascular adverse events identified in this meta-analysis.

Table 3

Summary risk ratios of safety outcomes with nesiritide treatment versus control treatment

Adverse event	Studies, n	Nesiritide group, n	Control group, n	Risk ratio	95% CI	I2, %
Non-cardiovascular adverse events
Nausea	2	347	245	0.82	0.39 to 1.73	54
Headache	4	786	666	0.37	0.27 to 0.51	19
Abdominal pain	1	273	216	0.29	0.09 to 0.89	NA
Dialysis	2	84	80	0.31	0.01 to 7.34	73
Cardiovascular adverse events
Hypotension	16	6026	5182	1.76	1.62 to 1.91	65
Hypotension asymptomatic	10	5545	4754	1.72	1.56 to 1.90	54
Hypotension symptomatic	13	5778	4915	1.59	1.12 to 2.27	48
Ventricular extrasystole	2	451	227	0.51	0.25 to 1.01	0
Ventricular tachycardia	5	977	460	0.43	0.30 to 0.62	32
Sustained ventricular tachycardia	4	857	343	0.21	0.09 to 0.49	25
Non-sustained ventricular tachycardia	5	977	460	0.43	0.23 to 0.81	56
Cardiac arrest	3	694	260	0.08	0.01 to 0.45	0
Bradycardia	4	927	501	4.46	1.32 to 15.02	0
Angina pectoris	1	273	216	0.79	0.23 to 2.70	NA

NA, not applicable.

In studies, nesiritide therapy increased risks of hypotension (RR 1.76; 95% CI 1.62 to 1.91; p<0.00 001), asymptomatic hypotension (RR 1.72; 95% CI 1.56 to 1.90; p<0.00 001), symptomatic hypotension (RR 1.59; 95% CI 1.12 to 2.27; p=0.01) and bradycardia (RR 4.46; 95% CI 1.32 to 15.02, p=0.02) in patients with heart failure compared to those using the combined control therapy. Combing data from trials comparing nesiritide therapy with the combined control therapy, the results showed significant differences in ventricular tachycardia (RR 0.43; 95% CI 0.30 to 0.62; p<0.00 001), sustained ventricular tachycardia (RR 0.21; 95% CI, 0.09 to 0.49; p=0.0004), non-sustained ventricular tachycardia (RR 0.43; 95% CI 0.23 to 0.81; p=0.009) and cardiac arrest (RR 0.08; 95% CI 0.01 to 0.45; p=0.004). The pooled data revealed non-statistically significant differences in ventricular extrasystole and angina pectoris.

Non-cardiovascular adverse events

Table 3 summarises non-cardiovascular adverse events identified in this meta-analysis.

Comparing nesiritide therapy with combined control therapy, the data revealed differences in the risks of headache (RR 0.37; 95% CI 0.27 to 0.51, p<0.00 001) and abdominal pain (RR 0.29; 95% CI 0.09 to 0.89, p=0.03), but not in the need for dialysis.

Discussion

The objective of our meta-analysis was to assess the efficacy and safety of nesiritide, nearly 14 years after its approval for clinical use. In this meta-analysis of 22 studies involving 38 064 patients, we demonstrated no significant increase in the risks of short-term, mid-term and long-term mortality. Compared with placebo, nesiritide indicated no increasing risk of total mortality. There was no significant difference between the nesiritide and dobutamine group, regarding total mortality. Compared with nitroglycerin, nesiritide indicated no reduction in total mortality. We found that, when we compared nesiritide therapy with control therapy, nesiritide therapy was associated with an increased risk of cardiovascular adverse events, such as bradycardia and hypotension (hypotension asymptomatic and hypotension symptomatic). Compared nesiritide therapy with the combined control therapy, the pooled data revealed a non-statistically significant increase in the need for dialysis, and a significant increase in headache and abdominal pain. Importantly, in our analysis, nesiritide treatment was associated with a significant decrease in PCWP, SVR, RAP and DBP; there was no significant difference in SCr, BUN and CrCl, and none in the need for dialysis was observed.

The results of previous studies on the effect of nesiritide on survival in patients with heart failure were conflicting. Some studies showed no significant effect on mortality,11 16 31 35 and a meta-analysis of clinical trials provided a conflicting conclusion about an increased risk of mortality.15 In what concerns short-term and long-term outcomes, a meta-analysis of seven randomised controlled trials updated in 2006 reported no significant increase in the risk of short-term and long-term mortality in nesiritide-treated patients.38 An updated meta-analysis published in 2014 provided evidence that nesiritide was not associated with the risk of short-term and long-term mortality.39 Our meta-analysis included a larger number of patients, and thus had increased power. Similarly, we demonstrated that nesiritide was not associated with the risk of mortality.

To the best of our knowledge, only some previous studies showed that nesiritide had effects on haemodynamic parameters such as PCWP, SVR and SBP.8 11 In the Nesiritide Study,8 nesiritide infusion at rates of 0.015 and 0.030 µg/kg/min caused a dose-related increase in cardiac index and a dose-related decrease in PCWP, SVR and SBP. The study published by the Vasodilation in the Management of Acute CHF (VMAC) investigators in 2002 showed that nesiritide therapy reduced PCWP significantly more than standard therapy did, and a sustained effect was observed for at least 24 h.11 In the PROACTION study, Peacock et al29 demonstrated that, in the emergency department, nesiritide favourably decreased SBP of patients with elevated baseline SBP. Similarly, our meta-analysis demonstrated that nesiritide resulted in beneficial effects on haemodynamic parameters, such as decreases in SVR, SBP, DBP, PCWP and RAP. It is well known that kidney function assessment takes an essential role in patients with heart failure who have renal dysfunction. Renal insufficiency may increase risk of heart failure progression, and the pathophysiology of renal dysfunction during the process of heart failure is complex. Previous meta-analyses and studies have provided conflicting conclusions about the effect of renal function of nesiritide therapy in patients with acute decompensated heart failure. Nesiritide may be associated with a reduction in estimated glomerular filtration rate and an attenuated increase in SCr.14 23 37 40 A 2005 meta-analysis that focused on renal function of nesiritide found a factor of 1.5 increase in the rate of worsening renal function.14 However, a randomised controlled trial comparing nesiritide with placebo in patients with acute heart failure indicated that nesiritide was not associated with a worsening of renal function,16 and this result was in accord with some other previous studies.34 41 42 In addition, according to one study, nesiritide did not induce changes in urine output, effective renal plasma flow and glomerular filtration rate.11 A current meta-analysis also found that nesiritide may have a dose-dependent effect on renal function in patients with acute decompensated heart failure. In the high-dose nesiritide group, nesiritide treatment was strongly associated with renal function (p=0.001). However, in standard-dose and low-dose groups, no statistical differences were observed.43

Our meta-analysis is in agreement with previous studies showing that nesiritide has no significant effects on SCr, BUN and CrCl, and has no risk of the need for dialysis.

Nesiritide not only has a greater incidence of cardiovascular adverse events, but also has a higher risk of non-cardiovascular adverse events. It provides rapid effects by itself and has a distribution half-life of approximately 2 min, a mean terminal elimination half-life of approximately 18 min and multiple routes of elimination. The half-life of 18 min of nesiritide is associated with favourable adverse events in patients with heart failure. Earlier reports have described cardiovascular adverse events, including hypotension, ventricular tachycardia, cardiac arrest, bradycardia, atrial fibrillation and ventricular extrasystole. It is noteworthy that nesiritide causes a dose-dependent increase in hypotension as the most common adverse effect, usually with asymptomatic or mild symptoms.8 16 The effects of nesiritide on bradycardia and hypotensive may be associated with the autonomic nervous system. This effect is mediated by both central inhibition of sympathetic neurotransmission and inhibition of sympathetic-mediated reduction.44 45 One study documented that the incidence of sustained ventricular tachycardia and cardiac arrest increased by approximately 12-fold, and the risk of non-sustained ventricular tachycardia increased by 1.5-fold, in the dobutamine group compared with nesiritide group.20 Our meta-analysis demonstrated no significant adverse events such as nausea and the need for dialysis, however, it did show adverse events for the infusion of nesiritide in patients with heart failure. However, levosimendan therapy showed higher risks of hypotension, ventricular tachycardia, cardiac arrest, bradycardia, headache and abdominal pain than control therapy did.

Conclusions

In conclusion, this meta-analysis confirmed that nesiritide therapy was not found to have significant impacts on SCr, BUN and CrCl,, and no risk of the need for dialysis was observed. In contrast, nesiritide treatment was associated with significant positive effects on haemodynamic parameters. In view of the wide choice of heart failure treatment, nesiritide was not associated with the risk of mortality. Significant differences in adverse events for infusion of nesiritide in hypotension and bradycardia were observed. However, no significant difference on the need for dialysis was found.