This is a prospective observational study including adult patients hospitalized by stroke at the Santa Lucia University Hospital from Cartagena, Spain; and designed following the STARD guidelines.18 The recruitment period was from March 1, 2019 to March 1, 2020. All adult patients (≥18 years) with clinically suspected stroke in Emergency Department were eligible for the study. Exclusion criteria were: presence of (a) solid tumours or lymphomas; (b) chronic and acute heart failure; (c) haemorrhagic stroke; (d) brain bleeding secondary to amyloid congophyl angiopathy, aneurysms, subarachnoid haemorrhage; (e) concomitant infections; (f) other complications such as epileptic seizures or acute myocardial infarction and (g) lack of analytical/clinical data.

Stroke diagnosis was performed by trained neurologists according to the World Health Organization definition19 and confirmed by neuroimaging. Symptoms severity was assessed by using the National Institutes of Health20 and the following variables related to the stroke were collected: systolic and diastolic blood pressure, glucose, LDL-cholesterol and creatinine. Stroke acute treatment and its secondary prevention treatment were carried out by neurologists following approved clinical guidelines21–24 but not any specific treatment or intervention for this study. Patients’ medical history was reviewed and collected the following covariates: high blood pressure, diabetes, dyslipidemia, atrial fibrillation, cardiac valvulopathy or shunt, chronic kidney disease, previous stroke, tobacco and alcohol consume, anticoagulants and antiplatelets intake.

Blood samples were collected by venipuncture into tubes with separator gel (BD Vacutainer SST II Advance 8.5mL) within the first 24h of admission. Tubes were immediately centrifuged (3500rpm for 10min at room temperature) and separated serum was used for the immediate measurement of NT-proBNP, the results of which were not reported to the attending physicians.

Serum NT-proBNP levels were measured on a Cobas e702 analyzer (Roche Diagnostics, Mannheim, Germany) by an electrochemiluminescence immunoassay (ECLIA). According to manufacturer's data, detection limit, functional sensitivity and measurement range were 10pg/mL, 50pg/mL and 10–35,000pg/mL, respectively.

Continuous variables were tested for normal distribution using the Kolmogorov–Smirnov's test. Data are summarized as numbers and frequencies for categorical variables and medians with interquartile ranges (IQRs) for continuous data. Comparisons between groups were performed with Chi-squared test for categorical data and Mann–Whitney U and Kruskal–Wallis for continuous data.

For the first purpose, discriminatory ability of NT-proBNP for cardioembolic stroke was evaluated by calculating the area under the receiver operating characteristic curve (AUC-ROC) and we additionally calculated the optimal ROC-derived cutoff value according to Youden Index. Binary logistic regression was performed to identify variables associated with cardioembolic stroke. To achieve the best set of predictors, only variables with a statistical trend in univariate analysis (p<0.10) were selected for multivariate analysis. Covariates were retained in the final model if they were statistical significant with a p-value of <0.05.

For the second purpose, ROC analysis with calculation of the AUC was performed to evaluate the utility of NT-proBNP for prognosis of all-cause mortality in all patients after 90 days. We identified independent predictors for 90-day mortality by Cox regression analysis and Kaplan–Meier survival curves, according to NT-proBNP quartiles, were constructed for comparison among survivors and non-survivors

We performed analyses by using the software packages SPSS 21.0 (SPSS Inc., IL, USA) and MedCalc 15.0 (MedCalc Software, Ostend, Belgium). In all tests, a two-sided p-value of <0.05 was considered significant.

We compared the plasma levels of NT-proBNP in each group of stroke by TOAST classification: small vessel disease stroke (SVo), large artery atherothrombosis stroke (LAA), cardioembolic stroke (CE) and stroke of undetermined cause (UND). As shown in Fig. 2, Kruskal–Wallis revealed a significant increased NT-proBNP plasma levels in the cardioembolic stroke group (2069±488.5) versus the large vessel (293.6±86.35; ***p=0.0001), small vessel (185.2±28.66; ***p=0.0001) and undetermined (596.9±139.3; ##p=0.0088) stroke groups.

Figure 2.

N-terminal pro-brain natriuretic peptide (NT-proBNP) plasma levels by ischaemic stroke sub-type. Data are expressed as the mean±SEM. Kruskal–Wallis test: ***p<0.001 vs. SVo and LAA; ## vs. UND stroke. Abv: SVo=small vessel occlusion stroke (n=52); LAA=large artery atherosclerosis stroke (n=38); CE=cardioembolic stroke (n=27); UND=undetermined aetiology stroke (n=39); NT-proBNP=N-terminal pro-brain natriuretic peptide.

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In supplementary material (A) is shown the area under the receiver operating characteristics curve (ROC) of NT-proBNP for diagnosis of cardioembolic stroke which was 0.853 (CI95%=0.766–0.941; p<0.001). As shown in Table 2, Youden index indicated that the optimal cut-off value of NT-proBNP was 499pg/mL (sensitivity 82%, specificity 80%).

A logistic bivariate regression analysis was used to truly establish the parameters independently associated with cardioembolic stroke. As shown in Table 3, bivariate logistic regression analysis showed that NT-proBNP plasma levels were independently associated to cardioembolic stroke (OR=1.01, CI95%=1.00–1.02, p<0.003). Furthermore, bivariate logistic regression analysis showed that NT-proBNP>499pg/mL were independently associated to cardioembolic stroke (OR=9.881, CI95%=2.831–34.489, p=0.001).

We examined the survival at 90 days in both, cardioembolic and no-cardioembolic stroke (Fig. 3A). Log rank (Mantel–Cox) showed no statistical differences (p=0.495) between cardioembolic (n=3; 17.15%, CI95%=9.35–24.6) and no-cardioembolic (n=9; 15.49%, CI95%=11.95–19.02) stroke in death, by all causes, at 90 days. Furthermore, we first obtained a NT-proBNP>1500pg/mL cut-off value (COR curve: AUC=0.885, CI95%=0.81–0.96%; p=0.001; sensitivity=70%, specificity=93%) to predict mortality at 90 days post-stroke (see supplementary material). Secondly we examined the prognostic value of a NT-proBNP>1500pg/mL. Kaplan–Meier analysis (Fig. 3B) revealed that NT-proBNP>1500pg/mL were found to significantly (p=0.001) increase the mortality at 90 days (38.0%, CI95%=32.2–53.8) after stroke versus lower plasma levels (12.5%, CI95%=10.19–14.93). In this regard, 8 of 12 deaths were in patients with NT-proBNP>1500pg/mL. In this subgroup of patients, 7 deaths were directly attributed to stroke severity and 1 was caused by traumatic car accident. The causes of death in the 4 patients with NT-proBNP<1500pg/mL were (all after hospital discharge): 2 sepsis, 1 heart attack and 1 intestinal haemorrhage in a patient anticoagulated by femoral artery occlusion.

Figure 3.

Kaplan–Meier survival curves at 90 days. (A) Kaplan–Meier curves comparing survival between cardioembolic and non-cardioembolic stroke groups. (B) Kaplan–Meier curves comparing survival of patients with a NT-proBNP>1500pg/mL. The p values were obtained from the log rank tests. Abv: CE=cardioembolic stroke, NT-proBNP=N-terminal pro-brain natriuretic peptide.

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Our results showed that NT-proBNP>499pg/mL was useful to predict cardioembolic stroke (sensitivity 82%, specificity 80%). In the last few years, different studies assessed an optimal cut-off value for discriminating the presence of a cardioembolic source. For example, Zecca et al.14 showed a level of NT-proBNP>200pg/mL and calculated a 65% sensitivity and 82% specificity 0.82 while Hajsadeghi et al.25 showed a cut-off value>342pg/mL (93% sensitivity, 73% specificity). A recent study showed that NT-proBNP≥505pg/mL distinguished AF-related from noncardiac stroke with a sensitivity of 93% and a specificity of 72%.26 Interestingly, cut-off value of NT-proBNP has been shown not only within 24h of stroke but also 7 and 90 days after (NT-proBNP>313; >181 and >174pg/mL, respectively).16 Future research and meta-analysis are needed to establish a common, accurate and reliable NT-proBNP's cut-off value.

Our results demonstrated that NT-proBNP plasma levels were higher and independently associated to cardioembolic stroke. A large-scale European prospective study showed that levels of NT-proBNP are positively associated with ischaemic stroke, independently from several other risk factors.27 In this line, a prospective study using the ARIC cohort demonstrated an association between NT-proBNP plasma levels and cardioembolic stroke but not with lacunar or haemorrhagic stroke.28 Furthermore, a recent prospective study showed that patients with cardioembolic stroke had higher NT-proBNP.26 Finally, a recent meta-analysis showed that both, BNP and NT-proBNP display closely equivalent diagnostic accuracies in distinguishing cardioembolic ischaemic stroke from non-cardioembolic, with NT-proBNP showing a superior specificity.29 Altogether, these results suggest that NT-proBNP could be a useful biomarker of cardioembolic stroke and therefore may help clinicians to select patients for further etiologic study with subcutaneous Holter monitor. Further research is needed to rule out the impact of NT-proBNP in the etiologic study in patients with undetermined cause of stroke.

Our results demonstrated no differences in mortality within stroke sub-types while a NT-proBNP>1500pg/mL showed increased mortality after 90days post-stroke. Mortality of ischaemic stroke has been widely studied in long-term. Nonetheless, short-term mortality has been scarcely studied and is about 8% after 30 days.30 According to previous studies31 we found no differences in mortality between cardioembolic and no-cardioembolic stroke, by all causes, up-to 90 days. Nonetheless, that study showed an increased mortality in cardioembolic stroke group after 1 and 5 years. Moreover, Bjerkreima et al.32 showed cardioembolic stroke had a 34% higher risk of death within 5 years while small vessel occlusion had a 48% lower risk of death. In this regard, the risk of recurrent stroke is increased in cardioembolic stroke and, as previously shown; stroke recurrence may be associated with increased inhospital mortality.33

Altogether, our data support previous findings indicating no differences in short-term mortality between subtypes of ischaemic stroke. In addition, recent evidence suggests that plasma levels of natriuretic peptides might be related to mortality after stroke. In particular, high BNP levels (>500pmol/L) have been shown to be an independent prognostic value for mortality after stroke.34 A meta-analysis showed that high NT-proBNP plasma levels (>1453pg/mL) were independently associated to mortality post-stroke with no differences between stroke sub-type. Furthermore, this study demonstrated that NT-proBNP had an added value (discrete) respect to simple clinical variables in ranking patients at high risk of death after stroke.17 As suggested by Jickling and Foerch35 the ability of NT-proBNP to predict mortality after stroke may relate to disease other than stroke. As previously showed, NT-proBNP is an independent predictor of mortality in cardiac dysfunction, in kidney disease,36 diabetes37 and cardiac surgery.38 Nonetheless, a NT-proBNP>1500pg/mL value could be useful for clinicians to inform patients’ family about a poor prognosis at 90 days. Further research is needed to assess the specific management and better treatment in that group of patients with worse prognosis after stroke.