Open Journal of Clinical Diagnostics
Vol.2 No.2(2012), Article ID:19886,7 pages DOI:10.4236/ojcd.2012.22003

The role of B-type natriuretic peptide in the evaluation of congestive heart failure patients in emergency department

Hao Wang*, Tiffany Littleton, Sonya J. Wilson, Ferran Ros, Richard D. Robinson, Kathleen A. Delaney

Department of Emergency Medicine, JPS Health Network, Fort Worth, USA

Email: * hwang01@jpshealth.org

Received 29 November 2011; revised 27 December 2011; accepted 16 January 2012

Keywords: Congestive Heart Failure; B-Type Natriuretic Peptide; Clinical Variables; Emergency Department

ABSTRACT

Aim: Congestive heart failure (CHF) is a severe cardiovascular disorder seen in the Emergency Department (ED). B-type Natriuretic Peptide (BNP) is usually ordered to evaluate the CHF severity. However, it is difficult to interpret serum BNP level when different clinical entities existed. The aim of this study is to illustrate the correlation between serum BNP level and relevant clinical variables and further determine the role of serum BNP in different CHF patients. Methods: Univariate comparisons between 26 clinical variables and serum BNP level were analyzed. In order to avoid confounding factors, potential independent clinical variables were analyzed together using multivariate regression. Results: 529 CHF patients were reviewed and divided into different groups by 26 clinical variables. Serum BNP levels were found statistically significant different by univariate compareson between groups divided by 8 clinical variables that included obesity, diastolic/systolic heart failure (HF), serum blood urea nitrogen (BUN) level, serum creatinine (Cr) level, serum sodium (Na) level, patients taking loop diuretics, history of cerebrovascular accident (CVA), and history of dementia. Among all 8 clinical variables, obesity, serum BUN, Cr level, and diastolic/systolic HF had weak-to-moderate correlation effects with serum BNP level by correlation coefficient analysis. However, only obesity and diastolic/systolic HF were two moderately stronger clinical variables that can affect the serum BNP levels by multivariate regression. Analyzing CHF patients separately by obesity and diastolic/systolic HF subsets showed longer hospitalization in diastolic HF patients with relatively higher serum Cr level. In addition, poor correlation was found between serum BNP level and length of hospitalization (LOH) as well. Conclusion: High variability of serum BNP levels exists in CHF patients with weak-to-moderate correlation effects particularly on obesity and diastolic/systolic HF. It is recommended that physicians should be cautious on interpreting BNP in different CHF populations.

1. INTRODUCTION

Congestive heart failure (CHF) is a common disorder seen in the Emergency Department (ED). B-type Natriuretic Peptide (BNP) is one of the common serum markers to evaluate the clinical conditions of CHF patients [1,2]. Results from previous studies showed serum BNP levels correlated well with the severity of CHF patients [3]. Patients with higher serum BNP levels required more aggressive treatment and longer hospitalization [4]. However, multiple clinical variables could affect the serum BNP level in CHF patients, making it hard to interpret [5,6]. CHF Patients with renal insufficiency tend to have higher serum BNP levels than ones with normal renal functions [7]. Obese CHF patients seem to have relatively lower serum BNP levels than non-obese groups [8]. Diastolic HF patients usually have lower serum BNP levels compared with systolic HF patients [9]. Till now, it is still unclear whether these clinical variables are independent predictors, and to what extent they can affect the serum BNP levels in CHF patients. Hence, to properly interpret serum BNP levels in CHF patients will help ED physician providing appropriate treatment and disposition.

The aim of this study is to evaluate the correlations between serum BNP level and these relevant clinical variables and further help physicians to interpret its variability in different CHF patients.

2. MATERIAL AND METHODS

2.1. Study Design

Data were collected from patients with history of CHF seen in an urban county hospital ED. The diagnosis of CHF was confirmed by cardiologists using echocardiography (at least once in the past 6 month before the index visit) and/or clinical signs and symptoms and was reflected by the discharge ICD-9 code. All eligible male and female adult patients were included. Our population is subject to a high risk of chronic disease exacerbation. Fewer than 2.5% have commercial insurance. Various factors that include transportation, homelessness, and communication access limit the ability to outpatient follow-up.

Collected data included patient information, past medical history, history of chronic medication, vital signs upon patient arrival in ED, initial electrocardiogram (EKG), initial laboratory evaluation, patient disposition, and length of hospitalization (LOH) if patients were admitted.

Different clinical variables (26 variables) that could potentially affect the serum BNP levels were selected that included age, gender, obesity, vital signs (including heart rate, respiratory rate, blood pressure, and pulse oxymetry), blood urea nitrogen (BUN), creatinine (Cr), sodium (Na), diastolic versus systolic heart failure (diastolic/systolic HF), atrial fibrillation with rapid ventricular response (A-fib with RVR) upon arrival at ED, using long-term angiotension converting enzyme inhibitor (ACEI), beta-blocker, loop diuretics, or digoxin, history of coronary artery disease (CAD), hypertension (HTN), diabetes (DM), chronic obstructive pulmonary disease (COPD), cerebrovascular accident (CVA), hepatic cirrhosis, dementia, cancer, smoking history, and admission to hospital.

Body mass index (BMI) was calculated as weight in kilograms divided by the square of height in meters and was used as an index to evaluate the severity of obesity [10]. CHF patients were divided into four different groups according to their BMI. Group 1 was normal/underweight patients with BMI ≤ 24 kg/m2, group 2 was overweight patients with BMI 24 - 30 kg/m2, group 3 was obese patients with BMI 30 - 40 kg/m2 (including 30 kg/m2), group 4 was morbidly obese patients with BMI ≥ 40 kg/m2. BNP values were compared among these four groups.

Univariate comparisons between serum BNP and different clinical variables were performed initially. Correlation coefficient was calculated between serum BNP and each clinical variable. Multivariate regression analysis was then analyzed on clinical variables with statistically significant difference found on univariate analysis. Relatively moderate to strong clinical predictors were further selected to evaluate the relationships with serum BNP. This study was approved by the hospital Institutional Review Board.

2.2. Statistics

Serum BNP levels were compared in groups divided by different clinical variables using student t test analysis. Correlation between serum BNP level and each clinical variable was measured by correlation coefficient analysis. To compare the serum BNP level in different BMI groups, a one way analysis of variance (ANOVA) using the Bonferroni test was performed. In order to avoid confounding factors, multiple potential independent clinical variables were analyzed using multivariate regression. Beta weights (β) were calculated to determine the correlation effect (β between 0.2 and 0.5 is considered a moderate effect, and β > 0.5 is considered a strong effect). All statistical analyses utilized Stata 11.0 statistical software (College Station, TX). A p value less than 0.05 was considered to be statistically significant.

2.3. Results

Comparison of serum BNP levels in CHF patients grouped with different clinical variables From Jan. 2008 till Dec. 2010, a total of 529 CHF patients’ clinical data were reviewed. All of these patients were diagnosed as CHF previously. Systolic heart failure (HF) was defined as impaired LVEF < 40% on echocardiogram and those with reserved LVEF (≥40%) were diagnosed as diastolic HF. In order to determine which variables that can affect the serum BNP level in CHF patients, Serum BNP levels were compared in CHF patients groups with 26 different variables as mentioned in study design. Eight out of 26 variables can affect the serum BNP levels and reached statistically significant difference (see Table 1). Overall, Significantly high difference found on serum BNP levels between patients grouped by 4 clinical variables (obesity, diastolic/systolic HF, serum BUN, and Cr levels). Obese CHF patients had more diastolic heart failure than non-obese patients (55.8% vs. 43.5%, p = 0.005). They also tended to be younger, with a higher incidence of diabetes (DM) and hypertension (HTN). Obese CHF patients were more likely to be hypoxic and to receive non-invasive positive pressure ventilation (NIPPV) at ED. In addition, serum BNP levels in obese CHF patients were significantly lower compared with those of the non-obese ones (p < 0.001, see Table 1).

Serum BNP level was inversely proportional to the severity of obesity CHF patients were also subdivided into four different groups based on the severity of obesity. Our results showed that the level of BNP was inversely proportional to the severity of obesity in CHF patients, reaching statistically significant difference between groups (p < 0.001, see Figure 1). However, serum BNP level only moderately correlated with the severity of obese in CHF patients (r = –0.3248, p < 0.001). This indicates that obesity is not the only variable that can affect the serum BNP level in CHF patients.

Table 1. Comparison of serum BNP levels between groups with different clinical variables in CHF patients.

Figure 1. Box plots showed the relationship between obesity and BNP levels. Figure showed that the BNP level was reversely proportional to the BMI level. *BMI not including 30 kg/m2.

Univariate comparison and multiple regression analysis of serum BNP levels with different clinical variables.

To avoid the confounding factors among independent variables, multiple regression analysis was also performed in these 8 variables to see whether they have strong relationships with serum BNP level in CHF patients. Our results showed serum Na level had no statistically significant effect and was considered as a confounding factor. History of CVA, dementia, and taking loop diuretics were weak predictors. Serum BUN and Cr levels had moderate relationships with serum BNP levels in CHF patients. The two clinical variables showing the strongest predictors in this study were: diastolic vs systolic heart failure (β = –0.173, p < 0.001) and obesity (β = –0.257, p < 0.001) (see Table 2).

Analyzing CHF patients separately by obesity and diastolic/systolic HF showed longer hospitalization in diastolic HF patients with relatively higher serum Cr levels.

Since diastolic vs systolic heart failure and obesity are two clinical variables that had relatively stronger relationships with serum BNP level. Further analysis was performed by subdividing CHF patients into four different groups (obese diastolic HF, obese systolic HF, non-obese diastolic HF, and non-obese systolic HF groups). Due to moderate predictive effects on BNP levels, serum BUN and Cr levels were also included in this analysis. Previous studies showed that the level of BNP was associated with the severity of CHF and could possibly affect the LOH [11]. Our results showed diastolic HF patients including both obese and non-obese patients had relatively higher serum Cr level and tended to stay longer in hospital than systolic HF patients though no statistically significant difference reached (see Table 3). Statistically significant difference found on serum BUN levels in different groups and diastolic HF patients tended to have higher serum BUN level than systolic HF patients which was also consistent with the findings of serum Cr level. There were strong linear correlation between serum Cr and BNP levels in diastolic HF patients. However, very poor correlations were found between serum BNP and LOH in all four groups (see Table 3). Multiple regression analysis was again performed in these four different groups with six clinical variables (serum BUN, Cr, Na level, history of CVA, dementia, and taking loop diuretics). Our results showed only serum Cr level had moderate correlation effect with serum BNP levels in both diastolic obese CHF (β = 0.4046, p < 0.001) and diastolic non-obese CHF groups (β = 0.2418, p = 0.047), which were consistent with the results of correlation coefficient analysis.

Table 2. Correlation coefficient and multivariate regression analysis of clinical variables that affect serum BNP levels in CHF patients.

Table 3. Clinical information of CHF patients divided into four different groups by two clinical variables (obese versus non-obese and diastolic versus systolic HF).

3. DISCUSSION

CHF is a severe cardiovascular disease that requires regular clinical visits to maintain stability. Patients will usually seek care in the ED when decompensated. Serum BNP level is one of the serum markers that is usually ordered by ED physicians to further evaluate the CHF conditions. BNP plays an important role in the regulation of cardiac remodeling, ventricular stretching, vasodilatation, and sodium homeostasis [12,13]. Serum BNP levels usually will be elevated in patients with worsening CHF conditions. The results of some studies showed serum BNP level could be used as an independent clinical variable to predict the severity of CHF and suggested acutely decompensated CHF patients with higher serum BNP level needed to be treated aggressively [14,15]. Serum BNP level was also closely related to the mortality in CHF patients [16]. However, other studies showed the variability of serum BNP levels and were unable to predict the severity concisely in different CHF populations [17,18]. Some clinical variables which could affect the serum BNP level were evaluated in many studies before [19,20]. However, the results were quite controversial. Many variables were clinically dependent and thus could be acting as confounding factors [21]. Hence, in our study, 26 clinical variables were selected based on the results of previous studies and the relations between these variables and serum BNP level were analyzed together to determine the independent predictors thus avoiding the internal bias.

Our results showed serum BNP levels were inversely proportional to the severity of obesity which was consistent to the majority of previous studies [8,17-18]. Results from some studies showed lower serum adiponectin levels in obese patient and serum adiponectin correlated inversely with BMI. The hypoadiponectinemia stimulated cardiac remodeling and decreased stretching resulting in lower serum BNP level [22,23]. Visceral fat expansion also could increase the clearance of serum BNP by increasing the expression of clearance receptors on adipocytes [24]. In addition, ectopic lipid deposition in the heart may exert lipotoxic effect by altering cardiac lipid metabolism which could reduce the production of BNP in the cardiac ventricles as impaired cardiac function [25]. Overall, the mechanisms of lower serum BNP levels in obese CHF patients are multifactorial with resultant of several pathophysiological interactions.

Results from previous studies are controversial on whether lower serum BNP level is associated with diastolic HF. Some reported that left ventricular end diastolic wall stress was inversely associated with serum BNP level and BMI independently [26], while others showed positive or no correlation [27,28]. Our study found that diastolic HF patients had lower serum BNP levels than systolic HF patients in both obese and non-obese CHF groups. Furthermore, more obese patients had diastolic HF compared with non-obese CHF patients. When analyzed together, obesity and diastolic HF were two moderately stronger clinical variables that could affect the serum BNP levels.

Serum BNP level is also affected by renal function that reported in previous study [7]. In our study, serum BUN and Cr levels showed moderate correlation with BNP overall but strong correlation in diastolic HF patients. In our study, it seemed that chronic renal insufficiency occurred more often in diastolic (40.46%, 106/ 262) compared with systolic HF patients (32.58%, 87/ 267), yet no statistically significant difference reached (p = 0.06). The results are consistent with recent study showing more diastolic HF occurred in chronic renal insufficiency patients [29]. Taking loop diuretics will cause lower serum Na level more often since 84.1% of hyponatremia patients in our study took loop diuretics which could make serum Na level as a confounding variable. Additionally, 87.05% (168/193) of patients with elevated serum Cr level and 90.45% (161/178) of patients with elevated serum BUN level took loop diuretics which could explain the weak correlation between loop diuretics and serum BNP level as well. Increased serum BNP levels in stroke and dementia patients were also reported in some studies though a weak correlation found [30,31]. However, studies were also found that the majority of stroke patients were hypertensive. By subdivideing stroke patients in groups with or without hypertension made no correlation with serum BNP levels [32]. Dementia patients usually have higher incidence of CVA or blood brain barrier disturbance resulting in higher BNP levels [33]. In addition, higher serum BNP levels are associated with impaired endothelial function which also linked to CVA and dementia as well [34]. In our study, these two clinical variables (history of CVA and dementia) showed weak correlations with serum BNP level and also hard to validate the accuracy due to relatively small sample size.

Some studies reported that prolonged hospitalization was found in CHF patients with higher serum BNP levels [11]. Our results showed poor correlation between serum BNP level and LOH in general. However, it seems that diastolic HF patients had higher serum Cr level and tended to stay longer in hospital than systolic HF patients though no statistically significant difference reached. This may attribute in part that more comorbidities found in diastolic HF patients in our study (data not shown).

Overall, in our study, the association between different clinical variables and serum BNP level were analyzed. High variability of serum BNP levels existed in CHF patients. Obesity and diastolic HF are two moderately stronger independent clinical predictors that could affect the serum BNP level. Hence, it is worthwhile to consider these predictors and to know the variability when interpreting BNP levels in different CHF patients.

4. LIMITATION

The retrospective methodology and relatively small sample size of our study may limit its applicability. In addition, using BMI to determine the obesity may not be very accurate since some CHF patients had signs and symptoms of volume overload that could affect the BMI. Other clinical variables that could potentially associated with serum BNP level were not included in this study, such as the ED revisits within 30 days, readmission within 30 days, intensive care units visit, the severity of pulmonary edema, etc. Follow-up was limited in many cases due to homelessness, incorrect registration information, or lack of access to communication devices. Overall, a large prospective study is required to confirm the effects of clinical variables on serum BNP levels in CHF patients.

5. CONCLUSION

Obesity and diastolic heart failure are two moderately stronger independent clinical variables that could affect the serum BNP level in CHF patients. Only in diastolic HF patients, serum Cr levels show moderate-to-strong correlation with serum BNP levels but not in systolic HF patients. In addition, serum BNP level is not a suitable clinical variable to predict the length of hospitalization in CHF patients. Therefore, it is recommended that physiccians should be cautious on interpreting BNP in different CHF populations.

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NOTES

*Corresponding author.