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To assess whether circulating levels of carbohydrate antigen 125 (CA125) predict subsequent 6‐month all‐cause mortality in patients after the index hospitalisation for acute heart failure (HF).
Prospective cohort study at a single teaching centre in Spain.
529 consecutive patients with acute HF admitted in a single university centre were analysed. In addition to the traditional clinical information, CA125 (U/ml) was measured during the early course of hospitalisation. The independent association between baseline CA125 and mortality was assessed with Cox regression analysis. The follow‐up was limited to 6 months.
349 (66%) patients showed serum levels of CA125 >35 U/ml (established cut‐off point value). At a 6‐month follow‐up, 89 (16.8%) deaths were identified. A positive trend between mortality and CA125 quartiles was observed; 3.8%, 15.2%, 22% and 26.5% of deaths occurred from quartile 1 to 4 of CA125 (p<0.001). Likewise, a monotonic, ascending trend in the risk ratios was estimated from the multivariable Cox model. Compared with the first quartile of CA125, the HRs (95% CI) for the second, third and fourth quartiles were 3.25 (1.20 to 8.79), 4.91 (1.88 to 12.85) and 8.41 (3.24 to 21.79), respectively.
Serum levels of CA125 obtained in patients admitted with a diagnosis of acute HF was shown to be an independent predictor of mortality up to the 6‐month follow‐up.
Heart failure (HF) is increasingly recognised as a major public health problem in the USA and in Western countries.1,2,3 Several biomarkers, including natriuretic peptides4,5 and some inflammatory markers,6,7,8 have been shown to be valuable tools for diagnostic and risk stratification purposes. However, the availability of biomarkers in this field has been limited by an educational lag in the translation of research findings to general practice, increases in healthcare costs and a lack of consensus/guidelines for the use of appropriate biomarkers.
Carbohydrate antigen 125 (CA125) is a glycoprotein synthesised by epithelial serosal cells. It is used clinically for diagnosing and monitoring several neoplasias, especially ovarian cancer.9,10 Recently, CA125 has emerged as a potential biomarker in HF, by showing correlations with clinical, haemodynamic and echocardiographic parameters indicative of the severity of the disease.11,12,13,14,15,16 Interestingly, fluctuations in serum levels of CA125 after treatment were also found, suggesting potential utility in a serial and long‐term therapeutic intervention assessment.11,14 Astoundingly, researchers have also found that increased levels of CA125 were, in a univariate setting, predictive of mortality and rehospitalisation at 6 months since admission.11
The main objective of the present study was to assess the ability of CA125 independently to predict subsequent mortality in patients admitted to hospital with a diagnosis of acute HF. As a secondary aim, we sought to determine the optimal threshold, among the continuum of CA125 values, which best discriminate between high‐ and low‐risk populations for subsequent mortality.
Initially, we studied a cohort of 565 patients consecutively admitted to our cardiology department from 1 January 2003 to 1 January 2005, with the diagnosis of acute HF (defined as the rapid onset of symptoms and signs secondary to abnormal cardiac function, and established by trained cardiologists). Patients with a diagnosis of acute coronary syndrome, cancer, pneumonia, sepsis, severe hepatic disease or end‐stage renal disease undergoing dialysis treatment were excluded from this registry (n=25). Additionally, 11 patients were excluded from the final analysis owing to missing CA125 values, leaving a final study sample of 529 patients. Demographic, medical history, vital signs, 12‐lead ECG and laboratory tests were determined routinely. Parallel to this registry, 181 patients, with heterogeneous cardiac conditions (stable ischaemic heart disease, atrial fibrillation and hypertension), were consecutively selected from an outpatient setting, and were classified as controls. Patients were excluded from this cohort if they had a history of cancer, or when the diagnosis was made during the index hospitalisation, as well as those with evidence of HF.
A comprehensive two‐dimensional echocardiography was performed with commercially available equipment (Agilent Sonos 5500, Phillips). Chamber diameters and wall thickness were measured using two‐dimensionally guided M‐mode echocardiography. Left ventricular ejection fraction (LVEF) was calculated using the Simpson method. Serum levels of CA125 were obtained during hospitalisation (48±12 h) using a commercially available immunoassay kit (Elecsys CA125 II assay, Roche Diagnostics). The established normal range for this assay was 0–35 U/ml. Indications for other diagnostic techniques and/or treatments were individualised following established guidelines.17
Death from any cause was selected as the main end point and ascertained during hospitalisation, by telephone contact with patient/family or during routine clinic visits. A patient's follow‐up was censored if he or she had had valve replacement surgery or cardiac transplantation.
Continuous variables were expressed as mean (1 SD) or median (interquartile range) when appropriate. Discrete variables were presented as percentages. Baseline characteristics were compared among categories created by quartiles of CA125 distribution. For continuous normally distributed variables, the omnibus p value for comparison was calculated with analysis of variance; for highly skewed variables, the Kruskal–Wallis rank test was used. A test for trend among ordered categories was also performed. The χ2 test was used for the comparison of discrete variables.
Three goals were pursued:
The mean (SD) age in our sample was 73 (10) years; 52.9% were women and 66% of the sample exhibited serum levels of CA125 >35 U/ml. Table 11 shows the clinical characteristics of the study population according to quartiles of CA125 distribution. Age and gender prevalence were equally distributed among CA125 quartiles. Overall, there was a positive, monotonic association between the parameters of disease severity and increasing levels of CA125. Indeed, a higher proportion of patients in New York Heart Association (NYHA) class III/IV (measured under clinically stable conditions, before the index admission), LVEF 45% and atrial fibrillation were found among quartiles 1–4 of CA125. Likewise, lower systolic and diastolic blood pressure as well as higher uric acid concentrations, arterial pH and left atrial dimension were positively related to increased CA125. Higher levels of CA125 were more often associated with pleural effusion, peripheral oedema, acute decompensated HF and cardiogenic shock. On the contrary, an inverse association was observed in patients with acute pulmonary oedema, hypertensive acute HF, a history of hypertension, dyslipidaemia and arterial carbon dioxide partial pressure concentrations. No other significant differences were observed in other baseline characteristics (table 11).
We found significant differences between patients with and without HF. Patients with acute HF exhibited a sevenfold increase in the mean CA125 serum levels compared with controls (105.2 (SD 139) vs 14.9 (22) U/ml, respectively p<0.001).
At the 6‐month follow‐up (median 5.94, interquartile range 1.80–5.94) a total of 89 deaths were identified: 37 during the index hospitalisation and 52 at follow‐up; their distribution among quartiles of CA125 shows a positive, monotonic increase in the proportion of deaths by moving from quartiles 1 to 4 (p<0.001; table 22).). Figure 11 shows, by means of the Kaplan–Meier method, significant differences in mortality among quartiles of CA125 (Peto‐Peto–Prentice test p<0.001). In multivariate analysis, CA125 was a predictor of mortality independently of age (years), gender, diabetes and their interaction (gender×diabetes), NYHA class III/IV, valvular heart disease aetiology for HF, systolic blood pressure (mm Hg), serum creatinine (mg/dl) and haemoglobin (g/dl). Variables that were excluded from the final model owing to lack of statistical significance were LVEF (continuous as well as categorised at 45%), aetiology of ischaemic heart failure and type of acute HF presentation. The adjusted hazard ratios (HRs (95% CI)) progressively increased from quartile 1 to 4 of CA125 Q2=3.25 (1.20 to 8.79); Q3=4.91 (1.88 to 12.85); and Q4=8.41 (3.24 to 21.79). Because the functional form of CA125 within the Cox model was identified as having a parabolic shape (fig 2A2A),), the HR, when the variable was included in its continuous form, was expressed by comparing the change between the 25th and the 75th centiles. The resulting HRs expressing a change between the 25th and 75th centiles among the variable distribution were similar when tested under univariate or multivariate settings (2.76 and 2.86, respectively). Varying the threshold level when dichotomising the variable did not change the previous conclusions. CA125 was independently associated with mortality when dichotomised at values 35 and 60 U/ml, which are the cut‐off points that represent the upper normal limit accepted for this biomarker, and the prognostic‐driven cut‐off point estimated in our sample, respectively. No interactions were found between CA125 and any of the covariates included in the final model. Harrell's C statistics were calculated for each of the Cox models with results ranging from 0.596 to 0.659 for univariate models and from 0.803 to 0.816 for multivariate models (table 33).
The GAM plot depicted in fig 2A2A shows that mortality risk increased markedly as CA125 increases up to 60 U/ml, levelling off afterwards. The curve also identified a value around 60 U/ml to be the value of CA125 where the increased hazard rate for mortality begins (the point that the GAM curve crossed a hazard rate of 0). This threshold value was further supported by the finding that the best operating point derived from the receiver operating characteristic curve pointed towards a similar value (fig 2B2B).
To our knowledge, this study is the first to demonstrate that serum levels of CA125 obtained in patients hospitalised for acute HF were independently associated with increased mortality. We observed an almost threefold increase in risk for all‐cause mortality for a change between the 25th and 75th centiles across the continuum of its distribution. Similar conclusions were reached by including CA125 dichotomised by its median (60 U/ml), by using the standard cut‐off point accepted for this biomarker in trials on cancer (35 U/ml). The same result was found when the entire distribution was grouped by its quartiles. Regardless of how this biomarker is presented, it is consistently shown to be a powerful predictor for mortality in a population previously admitted for acute HF (table 33).). This association persists even after adjustments for variables traditionally accepted to be powerful predictors for mortality.
HF is associated with an excessive and increasing morbidity and mortality, generating an extreme burden on our healthcare system.23,24,25,26,27,28 In the USA, HF is the leading cause of hospital admission in the Medicare population.1,24 In Spain, there are 80000 new hospitalisations for HF per year in patients aged 65 years, being the third most common cause of cardiovascular mortality.26 Despite the high mortality after 1 year following an episode of decompensation,3,28 risk stratification is not performed routinely, owing to the limited availability of biomarkers. Therefore, searching for the optimal biomarkers constitutes a source of permanent research in the HF field, to determine diagnostic and therapeutic measures tailored to the level of risk.
To date, increases in serum levels of CA125 have been described predominantly in women with ovarian cancer, particularly in those cases with peritoneal involvement,10,29 and used as a tool for monitoring treatment.9 CA125 has also been reported to be increased, although less frequently, in other types of cancer (lung, uterine, breast and gastrointestinal tract), and in some non‐malignant diseases characterised by serosal effusions (nephrotic syndrome and hepatic cirrhosis). However, the role of CA125 as a cardiac biomarker has only emerged in recent observational studies11,12,13,14,15,16 that have found CA125 (1) to be increased in patients with HF; (2) to be associated with clinical and echocardiographic parameters indicative of disease severity; and (3) to have a potential role as a prognostic marker.
CA125 has been found to be increased in patients with left ventricular systolic dysfunction, showing a close relationship with the NYHA class, and with haemodynamic parameters (pulmonary artery wedge pressure and right atrial pressure), echocardiographic abnormalities (deceleration time of early filling on transmitral Doppler)11 and levels of brain natriuretic peptide.30 D'Aloia et al11 reported a positive (although unadjusted) association between CA125 and short‐term combined end point (total mortality and hospitalisation for worsening HF) in a cohort of 240 patients with left ventricular systolic dysfunction. In addition, recent studies have reported that serum levels of CA125 fluctuate according to clinical improvement due to medical treatment, underlying a potential role for monitoring the response to treatment.11,12,14,15,30
CA125 has been found to be increased in patients with pericardial, pleural and peritoneal effusions.31,32,33 Epiney et al31 reported that mesothelial cells from peritoneum and pleura are able to synthesise CA125. We showed an important association between the presence of radiological pleural effusion and CA125 serum concentrations at baseline (table 11).). This finding can be interpreted as indirect evidence supporting the claim that the main source of CA125 increases in HF is from serosal effusions, especially from the pleura. Similar findings were recently reported by Turk et al,16 by comparing mean values of CA125 in patients with HF with and without pleural effusion and a control group. These authors showed higher CA125 values in patients with pleural effusion, intermediate values in those with no pleural effusion and lower values in the control group, with differences reported to be statistically significant. On the basis of this preliminary evidence, we assume that the increase in CA125 that occurred in patients with HF is a reliable surrogate of the amount of serosal effusions (pleura, pericardium and peritoneum) as a consequence of the increase in systemic and pulmonary venous pressure. Other authors have speculated that mesothelial cells are able to synthesise CA125, even in the absence of fluid accumulation, and are triggered by cytokine stimulation, as occurs in ovarian cancer and lymphoma.34,35,36 However, the link between inflammatory biomarkers such as tumour necrosis factor and interleukin 6 cytokines, often found to be increased in HF, and CA125 remains unknown.
This study has several strengths. To the best of our knowledge, this is the first time that a study has shown the independent effect of CA125 on mortality after an episode of acute HF. Secondly, the patients in our registry have been followed prospectively using careful and consistent methods, including clinical chart reviews performed by specialised medical personnel and a dedicated database software for storage. Finally, owing to an observational nature, our results can be extrapolated to patients commonly seen in routine clinical practice, adding a “real‐world” picture to what is already published in the medical literature.
Likewise, some limitations need to be addressed. First, the pathophysiological basis underlying the association observed between an increase in CA125 and mortality in HF is not yet clear. Increases in CA125 could merely reflect a surrogate for the progression of the disease, or may play an active role in worsening cardiac function. Secondly, the lack of availability of the measurements of brain natriuretic peptide in our registry does not permit a comparison of diagnostic accuracy between these two biomarkers.
To our knowledge, this is the first study demonstrating the independent prognostic value of CA125 for increased mortality after an episode of acute HF. The low cost, wide availability and easy determination of this biomarker make it a potential tool for risk stratification in this population. However, our preliminary results need to be supported by further studies looking at the ability of CA125 to predict cardiovascular outcomes. Furthermore, our findings need to be extended by studies comparing the diagnostic accuracy between CA125 and the natriuretic peptides biomarker family. Only then, and by means of cost‐effective analyses, will the true role of CA125 in risk stratification and patient management be established.
CA125 - carbohydrate antigen 125
GAM - generalised additive model
HF - heart failure
LVEF - left ventricular ejection fraction
NYHA - New York Heart Association
Competing interests: None declared.