This retrospective cohort study was conducted utilizing three large and public critical care databases: the Medical Information Mart for Intensive Care (MIMIC)-Ⅲ, MIMIC-IV, and eICU Collaborative Study Database (eICU). This retrospective cohort study followed the STROBE Statement. MIMIC-Ⅲ, a single-center database, contains comprehensive and de-identified data associated with patients admitted to ICU at Beth Israel Deaconess Medical Center from 2001 to 2012.17 MIMIC-IV, in brief, is an updated version of MIMIC-III, containing data on patients admitted to the ICU from 2008 to 2019.18 eICU is a multi-center ICU database with high-granularity data, encompassing de-identified data related to more than 200,000 ICU admissions in the United States during the period spanning from 2014 to 2015.19 Since patients' information has been de-identified in all three databases and ethical approval has been obtained from both the Institutional Review Boards and the Massachusetts Institute of Technology, obtaining informed consent is not deemed necessary for this study.

All patients who met the following criteria in the MIMIC-III, MIMIC-IV, and eICU databases were included in this retrospective cohort study. Inclusion criteria: (1) Patients diagnosed with AMI; (2) Patients aged ≥18 years. Those patients who had incomplete information on AG or albumin were excluded.

The following data were recorded: (1) Demographic data: gender, age (years) and race; (2) Vital signs: Systolic Blood Pressure (SBP, mmHg), Diastolic Blood Pressure (DBP, mmHg), temperature (°C), heart rate (times/min) and pulse oximetry-derived oxygen saturation (SPO2, %); (3) Laboratory parameters: AG, ACAG, potassium (mEq/L), magnesium (mg/dL), glucose (mg/dL), creatinine (mg/dL), Blood Urea Nitrogen (BUN, mg/dL), Red Blood cell distribution Width (RDW, %), White Blood Cell (WBC, K/µL), Red Blood Cells (RBC, m/µL) and hemoglobin (g/dL); (4) Medical history: Congestive Heart Failure (CHF), Atrial Fibrillation (AF), diabetes, valval disorder, Peripheral Vascular Disease (PVD), cardiogenic shock, malignant cancer, arrhythmias, AMI type; (5) Vasopressor use, thrombolysis, Percutaneous Coronary Intervention (PCI), antiplatelet drug, statins, anticoagulant, albumin (g/dL), AG (mEq/L), and age shock index. Noticeably, only patients’ data of the first ICU experience at the first admission were analyzed; this study was analyzed using vital signs and laboratory parameters recorded within 24 hours of initial admission. AG were calculated by using the formulae: AG(mmoL/L)=plasmasodium(mmoL/L)−[plasmachloride(mmoL/L)+plasmatotalbicarbonate(mmoL/L)];ACAGwerecalculated:ACAG(mmoL/L)=AG+2.5×(4−serumalbuminlevel(g/dL).20 The authors adopted the maximally selected method to determine the optimal cut-off value of AG, albumin, and ACAG.21 The ACAG was divided into high-level (≥ 19.24 mmoL/L) and low-level groups (< 19.24 mmoL/L). The survival curves were plotted using the Kaplan-Meier (KM) method in three databases and subsequently compared between the two groups using the log-rank test (Supplemental Fig. 1). The primary outcome of the present study was in-hospital mortality occurrence in patients with AMI.

In the present study, the subjects from the MIMIC-III database were utilized as the cohort for establishing the prediction model, while those from the MIMIC-IV and eICU databases served as external validation cohorts, respectively. The authors adopted univariate and multivariable cox proportional hazards models to identify predictors associated with the mortality of AMI patients from the MIMIC-III database. The prediction model based on the predictors and ACAG (ACAG combined model) was conducted to assess the mortality risk among AMI patients. The prediction performance of the developed ACAG combined model was evaluated in the three databases by Concordance-index (C-index), and Area Under the Curve (AUC) of Receiver-Operating Characteristic (ROC) curves. A nomogram was developed to visualize the prediction model. In addition, the authors also compared the predictive value between the developed ACAG combined model and other models (ACAG and age shock index) for mortality among AMI patients.

The normality of continuous variables was assessed using skewness and kurtosis, while the homogeneity of variance was tested using Levene's test. Continuous variables with normal distribution were described as Mean ± standard deviation (Mean ± SD). Group comparisons with both normal distribution and homogeneity of variance were conducted using ANOVA. Group comparisons with normal distribution but heterogeneity of variance were performed using the One-Way test. Continuous variables with non-normal distribution were expressed as median and interquartile range M (Q1, Q3). Kruskal-Wallis H rank sum test was used for comparison between groups. Categorical variables were described as a number of cases and constituent ratio n (%), and the Chi-Squared test was used for comparison. Supplemental Table 1 shows the post hoc test.

Univariable and multivariable cox proportional hazard models were used for exploring the relationship between AG, ACAG and in-hospital mortality among AMI patients, and Hazard Ratio (HR) with a 95% Confidence Interval (95% CI) was calculated. Model 1 was a coarse model with unadjusted variables; Model 2 adjusted gender; Model 3 adjusted gender, potassium, creatinine, BUN, RDW, WBC, AF, diabetes, cardiogenic shock, vasopressor use, AMI type, antiplatelet drug, statins, and age shock index. Then, the authors compared the prediction performance of a single indicator: AG and ACAG. Additionally, the authors developed and validated an ACAG combined model to predict the in-hospital mortality risk in AMI patients. Multiple imputation was performed using R MICE for missing values (Supplemental Table 2). Comparisons between groups and multivariable analyses were performed using SAS 9.4 (SAS Institute Inc., Cary, NC, USA), and all other analyses were performed using R (version 4.2.0). The survival_ROC package was employed for the development of the prediction model; p < 0.05 was considered statistically significant.

After excluding some patients who were <18 years old and had incomplete information about AG or albumin, 3250 AMI patients from the MIMIC-III database were included as the training set in this study, 1272 AMI patients from the MIMIC-IV database, and 5245 AMI patients from the eICU database were included as the external validation cohorts (testing set) (Fig. 1). The end time of follow-up was discharge or death. The median follow-up was 7.58 (4.87, 13.17) days in the MIMIC-III database, 7.84 (5.11, 13.29) days in the MIMIC-IV database, and 3.95 (2.20, 7.81) days in the eICU database. Table 1 presents the baseline characteristics of the study population in each dataset, and the differences in characteristics in the three datasets were compared. Notably, most variables had statistical differences between the MIMIC-III, MIMIC-IV, and eICU databases (p < 0.05).

Fig. 1.

Flow chart for the selection of participants in the study.

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The authors assessed the relationship between AG, ACAG and in-hospital mortality of AMI patients from the MIMIC-III database. Importantly, the relationship between AG, ACAG, and the in-hospital mortality among AMI patients is presented in Table 2. After adjusting all covariates (Model 3), the authors found that AMI patients with an ACAG ≥ 19.24 mmoL/L exhibited a 24% elevated risk of in-hospital mortality compared to those with an ACAG < 19.24 mmoL/L, and AG was also a risk factor for in-hospital mortality among AMI patients. The authors also compared the predicting performance of AG and ACAG for predicting in-hospital mortality for AMI patients. As shown in Table 3, the C-index of ACAG is 0.606 (95% CI 0.581‒0.630), which was significantly higher than AG (C-index = 0.589, 95%CI 0.565‒0.614). The result also indicated that ACAG might be a more appropriate predictor of in-hospital mortality among AMI patients compared to AG.

Some important clinical indicators were screened by univariate and multivariate cox proportional hazards analyses and included in the prediction model (Supplemental Table 3). A nomogram incorporating ACAG and several clinical indicators was developed to predict the risk of in-hospital mortality among AMI patients. Figure 2 illustrates the fifteen indicators included in the nomogram: ACAG, gender, potassium, creatinine, BUN, RDW, WBC, AF, diabetes, cardiogenic shock, vasopressor use, AMI type, antiplatelet drug, statins, and age shock index.

Fig. 2.

The nomogram for prediction of in-hospital mortality among AMI patients. AMI, Acute Myocardial Infarction; AF, Atrial Fibrillation; RDW, Red blood cell Distribution Width; BUN, Blood Urea Nitrogen; WBC, White Blood Cell; ACAG, Albumin Corrected Anion Gap.

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The C-index of the nomogram was 0.759 (95% CI 0.738‒0.781) in the training set (MIMIC-III), 0.756 (95% CI 0.720‒0.792) (MIMIC-IV), and 0.762 (95% CI 0.740‒0.783) (eICU) in the validation cohorts (Table 4), which indicated that the nomogram had a favorable prediction ability. As shown in Figure 3, AUC of the nomogram was 0.763 (95% CI 0.732‒0.794) in the MIMIC-III cohort, 0.744 (95% CI 0.689‒0.798) in the MIMIC-IV cohort and 0.681 (95% CI 0.649‒0.713) in the eICU cohort. In addition, the authors also compared the predicting performance of the nomogram (ACAG combined model) and other models (ACAG and age shock index) in predicting the risk of in-hospital mortality for AMI patients (Table 5). The C-index of the nomogram was 0.759 (95% CI 0.738‒0.781), which is obviously higher than ACAG 0.606 (95% CI 0.581‒0.630), and age shock index 0.628 (95% CI 0.600‒0.656) in the MIMIC-III database. Simultaneously, the authors found that the C-index of the nomogram was 0.756 (95% CI 0.720‒0.792), which was also obviously higher than ACAG 0.610 (95% CI 0.569‒0.651), and age shock index 0.589 (95% CI 0.541‒0.636) in the MIMIC- IV database. Similar results were found in the eICU database.

Fig. 3.

Receiver operating characteristic curves of the nomogram in the training set and validation cohorts.

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