Epidemiology and Outcomes of Acute Renal Failure in Hospitalized Patients: A National Survey

Data Source

For this analysis, we used the 2001 NHDS database, which was acquired from the National Center for Health Statistics (14). In brief, this annual survey comprises a sample of all nonfederal acute care hospitals (with an average patient LOS of <30 d) in the United States and includes approximately 500 hospitals, with equal representation from all geographic regions (14). This survey excludes federal, military, and Department of Veterans Affairs hospitals; institutional hospital units (e.g., prison hospitals); and hospitals with fewer than six beds (14).

The database is constructed through the survey of discharge records for inpatients from each participating hospital, representing approximately 1% of all hospitalizations, or 330,210 discharges annually in the United States. The data set includes weighted frequencies, which can be generalized to the entire population. The weighted sample of approximately 1% hospital discharges projects to a national estimate of 29,039,599 discharges.

Discharge records are abstracted for demographic information (age, gender, ethnic background, geographic location, and marital status), seven diagnostic codes, four procedural codes, date of hospital admission and discharge, LOS, sources of payment, and disposition at discharge. The diagnosis and procedure codes are derived from the International Classification of Diseases, Ninth Revision, Clinical Modification (ICD-9-CM) (15).

Case Definitions

Cases were identified from discharge records in the NHDS, which included a code for ARF. ARF was defined by the presence of any of the following ICD-9-CM codes: 584.0 (ARF, unspecified), 584.5 (acute tubular necrosis), 584.6 (cortical ARF), 584.7 (medullary ARF), 584.8 (ARF with other specified pathologic lesion), and 584.9 (ARF not otherwise specified). Discharge records with an ICD-9-CM code for chronic dialysis status (V45.1, V56.0, V56.31, V56.32, or V56.8) were excluded. Requirement for acute dialysis was defined by one of two codes: 39.95 or 54.98.

Coexisting conditions were defined by the following ICD-9-CM codes: Diabetes (250 and 250.01 to 250.03), hypertension (401.0, 401.1, and 401.9), coronary artery disease (414, 414.02, 414.03, and 414.9), congestive heart failure (428), chronic kidney disease (403.11, 403.91, 404.13, 404.92, 404.93, 250.40 to 250.43, 581.0 to 581.3, 581.81, 581.89, 581.9, 582, 582.1, 582.2, 582.81, 582.89, 582.9, 583.0 to 583.6, 583.81, 583.89, 583.9, and V42.0), chronic lung disease (chronic obstructive lung disease [492.8] and emphysema [496]), cancer (colon [153.9], breast [174.9], lung [162.9], prostate [185], melanoma [172.9], myeloma [203], kidney [189], and bladder [188.9]), and HIV infection (042).

Acute hospital-related factors were defined by the following diagnosis and procedure ICD-9-CM codes: Sepsis (038, 020.0, 790.7, 117.9, 112.5, and 112.81) (11), cardiac catheterization (37.22 and 37.23), and cardiac surgery (coronary artery bypass graft surgery [36.10 to 36.16] and valve repair [35.1 to 35.2, 35.11 to 35.14, and 35.21 to 35.28]). Acute organ system dysfunction (AOSD) was defined using a previously published ICD-9-CM–based classification (11) with some minor modifications, and comprised the respiratory, cardiovascular, hepatic, hematologic, and neurologic organ systems (Appendix 1).

Validation of ARF ICD-9-CM Case Definitions

The accuracy of ICD-9-CM for ARF was validated by reviewing the records of all patients who were discharged from a tertiary medical center (Caritas St. Elizabeth’s Medical Center, Boston, MA) during 2001 (n = 13,412). The Human Investigation Review Committee approved this validation study. Admissions involving patients with ESRD (n = 175) were excluded from further analysis. We compared ARF diagnostic coding (defined by the presence or absence of ICD-9-CM codes 584.5 to 584.9) with well-established criteria for ARF that are based on changes in serum creatinine (1). Nadir and peak serum creatinine values over the course of the admission were used to establish the presence of ARF on the basis of a rise in serum creatinine level of 0.5, 1, or 1.5 mg/dl from nadir values of ≤1.9, 2.0 to 4.9, and ≥5.0 mg/dl, respectively.

Statistical Analyses

Continuous data are presented as medians with interquartile range, and nominal data are presented as percentages. All statistical analyses were performed using SAS (SAS Institute, Cary, NC) version 9.1. Following the NHDS guidelines, data with a sample size of <60 or with a relative SE >30% were not used for the analyses. Unless specified, all descriptive statistics and analyses were weighted to allow inflation to national estimates, based on the weight variable provided by the NHDS. Of note, because of this very large sample size, this study has extremely high power, and P values are expected to be significant, regardless of magnitude or clinical relevance.

Kaplan-Meier survival analysis was used to compare hospital LOS (in weeks) among patients with and without ARF. This analysis was stratified by presence or absence of other nonrenal AOSD. The log-rank statistic was used to test differences between groups. In this analysis, death was censored, and patients with missing discharge status were excluded.

Logistic regression analysis was used to explore the relationship between ARF and hospital death and patient disposition at time of hospital discharge. The analysis was adjusted in a stepwise manner for the following covariates: Demographic factors (age, gender, ethnic background, and source of payment), coexisting conditions, acute hospital-related factors, and number of AOSD. The end points were ascertained at time of hospital discharge, no censoring was required, and there was no loss of follow-up. Twenty-four percent of discharges were excluded from this analysis as a result of missing values for either the predictor or outcome variables. Most of the missing values (96%) were on the ethnicity variable. However, the results were not significantly different when missing ethnicity was included as an indicator variable.

A separate robust regression model explored the relationship of ARF and other AOSD to hospital LOS. This regression method is more appropriate than linear regression for outcome variables with a skewed distribution (16). In brief, this analysis uses the median of the squared residuals instead of the sum of the squared residuals. Admissions of <24 h were assigned a LOS of 1 d. Although records with missing data for either predictor or outcome variables were excluded from the final analysis, the results were very similar when those with missing ethnicity were included as an indicator variable.

Cohort Characteristics

Approximately 1.9% of hospitalizations in the United States included a discharge diagnosis of ARF during the study period of 2001. The characteristics of patients with and without a discharge diagnosis of ARF are summarized in Table 1. ARF was more common in older patients, men, and black patients. A discharge diagnosis of ARF was also more commonly assigned to individuals with a coexisting diagnosis of congestive heart failure, chronic lung disease, chronic kidney disease, cancer, and HIV infection but less commonly to individuals with a coexisting diagnosis of coronary artery disease, diabetes, and hypertension. Patients with a diagnosis code of ARF were also more likely to have a diagnosis of sepsis or have undergone cardiac surgery. Finally, patients with an ARF diagnosis code were more likely to have other nonrenal AOSD. A total of 7.5% of patients with a diagnosis of ARF required dialysis. Whereas overall hospital mortality was 2.6%, patients who were discharged with a diagnosis of ARF had a higher mortality rate compared with those without ARF (21.3 versus 2.3%; P < 0.0001).

ARF and Hospital LOS

As shown in Table 1, hospital LOS was significantly higher among patients with a discharge diagnosis of ARF. Table 2 displays the LOS data for different diagnostic categories and is stratified according to survivor status. Compared with other single AOSD, a discharge diagnosis of ARF per se was associated with the longest median LOS (7 d), whereas acute cardiovascular system dysfunction was associated with the shortest LOS, which might be due to a high early fatality rate (see also Figure 1). The presence of ARF coupled to single or multiple, nonrenal AOSD was associated with the longest hospital LOS (median 10 d). Of note, the presence of ARF alone and without other nonrenal AOSD was associated with longer LOS than for patients with single nonrenal AOSD (Table 2). ARF was the second most frequent AOSD (1.9%), after acute respiratory system dysfunction (2.3%).

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Figure 1.

Median hospital length of stay (LOS) stratified by single acute organ system dysfunction (AOSD), including acute renal failure (ARF).

Kaplan-Meier survival analysis demonstrated that the sole presence of ARF, as well as its addition to other nonrenal AOSD, confers the most prolonged hospital LOS (P < 0.0001 by log rank test; Figure 2). In addition, dialysis-requiring ARF was associated with a more prolonged LOS compared with hospitalization in which ARF did not require dialysis (P < 0.0001 by log rank test; Figure 3).

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Figure 2.

Kaplan-Meier analysis for the cumulative percentage of patients who remained hospitalized according to presence or absence of ARF with or without other single or multiple AOSD. (A) No ARF and no other single AOSD (hatched line), and ARF and no other single AOSD (solid line), P < 0.0001 by log rank test. (B) No ARF but presence of other single AOSD (hatched line), and ARF and no other single AOSD (solid line), P < 0.0001 by log rank test. (C) No ARF but presence of other single AOSD (hatched line), and ARF and presence of other single AOSD (solid line), P < 0.0001 by log rank test. (D) No ARF but presence of other multiple AOSD (hatched line), and ARF and presence of other multiple AOSD (solid line), P < 0.0001 by log rank test.

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Figure 3.

Kaplan-Meier analysis for the cumulative percentage of patients who had ARF and remained hospitalized according to dialysis requirement. ARF requiring dialysis (hatched line) and ARF not requiring dialysis (solid line), P < 0.0001 by log rank test.

On multivariate analysis (Table 3), a discharge diagnosis of ARF was associated with an estimated prolongation of hospital LOS by 2 d (P < 0.0001) and was surpassed only by cardiac surgery (3.9 additional days) and sepsis (2.6 additional days). Several other groups of diagnosis codes were also associated with LOS but to a lesser degree, including a discharge diagnosis of chronic kidney disease (0.2 additional day). Factors associated with a shorter LOS included a discharge diagnosis of coronary artery disease, hypertension, and cardiac catheterization.

ARF and Hospital Discharge Disposition

The characteristics of patients who had ARF and were discharged from the hospital alive are shown in Table 4 and are stratified according to disposition. Compared with patients who had ARF and were discharged home, those who were discharged to a short-term care facility were older and had a higher frequency of congestive heart failure, chronic lung disease, sepsis, and acute respiratory system dysfunction. However, compared with patients who had ARF and were discharged to a short-term care facility, those who were discharged to a long-term care facility were older by a median of 6 yr, more likely to be female, and more likely to have a coexisting diagnosis of HIV infection and acute cardiovascular or neurologic system dysfunction.

On multivariate analysis (Table 5), ARF was associated with a 2.0-fold higher odds for transfer to a short- or long-term care facility after adjustment for age, gender, ethnic background, payment source, coexisting conditions (including chronic kidney disease), acute hospital-related factors, and other AOSD.

ARF and Hospital Death

On multivariate analysis (Table 5), ARF was associated with an eight-fold higher odds for death after adjustment for age, gender, ethnic background, and payment source. This association was weakened but persisted with 4.1-fold higher odds for death after adjustment for age, gender ethnic background, payment source, coexisting conditions (including chronic kidney disease), acute hospital-related factors, and other AOSD.

ARF Coding Validation

We performed an audit of ARF coding practices by reviewing the electronic discharge records of all patients who were discharged from our tertiary medical center during the 2001 calendar year. After exclusion of the discharges of 175 patients with ESRD, 13,237 records were available for analysis. Using serum creatinine–based laboratory criteria, ARF supervened on 1584 hospital admissions (12.0%). An ICD-9-CM code for ARF was present in 347 (2.6%) discharge records during this period. Acute renal failure was confirmed by biochemical criteria in 304 of these cases, yielding a positive predictive value of 87.6%. However, the sensitivity of ARF ICD-9-CM coding was 19.2% (304 of 1584). Among the 12,890 discharge records without an ARF ICD-9-CM code, serum creatinine criteria for ARF were not met in 11,610, yielding a negative predictive value of 90.1%. The specificity of ARF coding was 99.6%.