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. 2014 May 28;472(9):2878–2886. doi: 10.1007/s11999-014-3686-7

The Elixhauser Comorbidity Method Outperforms the Charlson Index in Predicting Inpatient Death After Orthopaedic Surgery

Mariano E Menendez 1,, Valentin Neuhaus 1, C Niek van Dijk 2, David Ring 1
PMCID: PMC4117875  PMID: 24867450

Abstract

Background

Scores derived from comorbidities can help with risk adjustment of quality and safety data. The Charlson and Elixhauser comorbidity measures are well-known risk adjustment models, yet the optimal score for orthopaedic patients remains unclear.

Questions/purposes

We determined whether there was a difference in the accuracy of the Charlson and Elixhauser comorbidity-based measures in predicting (1) in-hospital mortality after major orthopaedic surgery, (2) in-hospital adverse events, and (3) nonroutine discharge.

Methods

Among an estimated 14,007,813 patients undergoing orthopaedic surgery identified in the National Hospital Discharge Survey (1990–2007), 0.80% died in the hospital. The association of each Charlson comorbidity measure and Elixhauser comorbidity measure with mortality was assessed in bivariate analysis. Two main multivariable logistic regression models were constructed, with in-hospital mortality as the dependent variable and one of the two comorbidity-based measures (and age, sex, and year of surgery) as independent variables. A base model that included only age, sex, and year of surgery also was evaluated. The discriminative ability of the models was quantified using the area under the receiver operating characteristic curve (AUC). The AUC quantifies the ability of our models to assign a high probability of mortality to patients who die. Values range from 0.50 to 1.0, with 0.50 indicating no ability to discriminate and 1.0 indicating perfect discrimination.

Results

Elixhauser comorbidity adjustment provided a better prediction of in-hospital case mortality (AUC, 0.86; 95% CI, 0.86–0.86) compared with the Charlson model (AUC, 0.83; 95% CI, 0.83–0.84) and to the base model with no comorbidities (AUC, 0.81; 95% CI, 0.81–0.81). In terms of relative improvement in predictive performance, the Elixhauser measure performed 60% better than the Charlson score in predicting mortality. The Elixhauser model discriminated inpatient morbidity better than the Charlson measure, but the discriminative ability of the model was poor and the difference in the absolute improvement in predictive power between the two models (AUC, 0.01) is of dubious clinical importance. Both comorbidity models exhibited the same degree of discrimination for estimating nonroutine discharge (AUC, 0.81; 95% CI, 0.81–0.82 for both models).

Conclusions

Provider-specific outcomes, particularly inpatient mortality, may be evaluated differently depending on the comorbidity risk adjustment model selected. Future research assessing and comparing the performance of the Charlson and Elixhauser measures in predicting long-term outcomes would be of value.

Level of Evidence

Level II, prognostic study. See the Instructions for Authors for a complete description of levels of evidence.

Introduction

Patients undergoing orthopaedic surgery often have multiple coexisting medical conditions (comorbidities) [13, 21, 24, 28, 39, 45, 58]. Preoperative risk assessment can help with decision-making and management strategies [11, 37, 50]. Several models for estimating risk based on coded comorbidities are currently in use for orthopaedic patients, but there is no consensus regarding the optimal approach [22, 37, 49, 51, 56, 57]. Selecting appropriate risk adjustment models can help hospitals contain costs while ensuring high levels of quality. Furthermore, inadequate comorbidity risk-adjustment might penalize practitioners and hospitals that care for the sickest patients [41].

Large administrative inpatient databases have been used to assess the effect of baseline comorbidity status on surgical care outcomes targeted in pay-for-performance initiatives such as mortality, morbidity, and discharge disposition [14, 22, 3234, 3739]. The Charlson Comorbidity Index [5] encompasses 19 medical conditions and is the most widely used comorbidity risk adjustment model in orthopaedic surgery. First reported in 1987 to predict 1-year mortality [5], this index subsequently was adapted for use with administrative databases [9]. The Elixhauser measure [12], a more recent model including 31 conditions, is believed to be a better predictor of mortality in patients with cardiac, gastrointestinal, hepatobiliary, and oncologic conditions [6, 18, 27, 52]. Several prevalent comorbidities such as hypertension, obesity, weight loss, and psychiatric disorders that are included in the Elixhauser model are not included in the Charlson model [12].

We therefore determined whether there was a difference in the accuracy of the Charlson and Elixhauser comorbidity-based measures in predicting (1) in-hospital mortality after major orthopaedic surgery, (2) in-hospital adverse events, and (3) nonroutine discharge.

Patients and Methods

All data were extracted from the National Hospital Discharge Survey (NHDS) database [4, 8]. The NHDS is an annual probability sample survey of discharges from nonfederal, general, and short-stay hospitals in the United States [8, 19]. Sample data then were weighted to produce annual estimates of inpatient care [8]. A maximum of seven medical diagnoses and four procedures were gathered and coded with the use of ICD-9-CM codes. Patient demographic information, hospital characteristics, and inpatient outcomes such as discharge disposition and hospital length of stay also were collected. Recognizing its utility to answer valuable clinical questions, the NHDS has been used extensively to analyze data associated with a wide range of diagnoses and procedures across different medical specialties [3, 25, 33, 34, 38, 44, 48]. Because of prior adequate data deidentification, our study was exempt from institutional review board approval.

Patients with a procedure code (ICD-9-CM) for primary TKA (81.84), primary THA (81.51), or spinal fusion (81.00 to 81.08) were included in the sample. Patients who underwent hip fracture (820.x) surgery also were included in the analysis. From a database with more than 500,000,000 patients treated between 1990 to 2007, an estimated 14,007,813 patients were identified and included in the analysis. The mean age of the patients was 66 ± 15 years, and female patients accounted for 62% of the study sample (Table 1). Overall, an estimated 0.80% of the included patients died during hospitalization. Mortality rates ranged from 0.30% for total joint arthroplasty and spinal fusion to 2.6% for operative treatment of hip fracture (Table 1).

Table 1.

Characteristics of the study cohort (n = 14,007,813)

Parameter Total cohort Mortality cohort p value
% of the total cohort 100 0.80
Age (years)* 66 ± 15 81 ± 11 < 0.001
Age group (%) < 0.001
 ≤ 50 years 15 0.10
 50–59 15 0.10
 60–69 years 22 0.20
 70–79 years 28 0.70
 80–89 years 16 2.0
 > 89 years 4.0 4.1
Sex (%) < 0.001
 Male 38 0.70
 Female 62 0.80
Procedure (%)
 Primary TKA 38 0.30 < 0.001
 Primary THA 21 0.30 < 0.001
 Spinal fusion 20 0.30 < 0.001
 Surgery for hip fracture 21 2.6 < 0.001
Number of Charlson comorbidities (%)
 0 69 0.40 < 0.001
 1 or 2 30 1.5
 ≥ 3 0.90 4.7
Number of Elixhauser comorbidities (%)
 0 32 0.30 < 0.001
 1 or 2 54 0.80
 ≥ 3 14 1.7
≥ 1 adverse events (%) 32 1.7 < 0.001
Days of care (days)* 5.5 ± 5.6 11 ± 16 < 0.001

* Values are expressed as mean ± SD.

Comorbidity burden was quantified using validated Charlson (adaptation by Deyo et al. [8]) and Elixhauser coding algorithms available for ICD-9-CM codes [9, 12, 43]. Dichotomous variables indicating the presence or absence of each Charlson and Elixhauser comorbidity were created, and their associations with mortality were assessed in bivariate analysis using chi-square tests. In addition, the original Charlson and the weighted Elixhauser scores, developed by van Walraven et al. [55], were computed and further stratified into groups (0, 1–2, 3–4, ≥ 5 and < 0, 0, 1–4, ≥ 5, respectively). The Charlson weights assigned to each comorbidity range from +1 to +6, while the Elixhauser weights range from −7 to +12 [5, 55]. Comorbidity scores then can be calculated for each patient by summing the individual weights of all comorbidities. Continuous variables (age, days of care) of the stratified Charlson and Elixhauser groups were analyzed with ANOVA, and categorical data (sex, mortality, adverse events, discharge status) were analyzed with the chi-square test (Table 2). Chronic pulmonary disease (11%) and uncomplicated diabetes mellitus (11%) were the most frequently encountered comorbidities when using the Charlson/Deyo algorithm (Table 3). Among all 31 Elixhauser comorbidities, uncomplicated hypertension (38%) was the most prevalent condition, followed by chronic pulmonary disease (11%) and uncomplicated diabetes mellitus (11%) (Table 4).

Table 2.

Charlson and Elixhauser comorbidity scores in the study cohort (n = 14,007,813)

Parameter Charlson score p value Elixhauser score (van Walraven et al. [53]) p value
0 1 or 2 3 or 4 ≥ 5 < 0 0 1 to 4 ≥ 5
Age (years)* 64 ± 16 71 ± 13 75 ± 11 70 ± 15 < 0.001 64 ± 14 64 ± 15 69 ± 14 74 ± 13 < 0.001
Sex (%) < 0.001 < 0.001
 Male 39 37 40 43 29 41 38 36
 Female 61 64 61 57 71 59 63 64
Mortality (%) 0.40 1.3 5.0 4.5 < 0.001 0.10 0.30 0.60 2.5 < 0.001
≥ 1 adverse events (%) 30 35 45 43 < 0.001 31 27 35 47 < 0.001
Days of care (days)* 5.2 ± 5.3 6.0 ± 5.7 8.1 ± 8.2 11 ± 16 < 0.001 4.9 ± 4.7 5.0 ± 4.9 5.5 ± 4.7 7.5 ±7.8 < 0.001
Discharge status (%) < 0.001 < 0.001
 Routine/discharged home 57 41 22 28 53 60 46 31
 Left against medical advice 0.10 0.10 0.20 0 0.10 0.10 0.20 0.10
 Transferred to short-term facility 7.4 9.3 9.7 11 7.9 7.2 8.5 10
 Transferred to long-term facility 20 31 48 38 23 19 28 39
 Alive, disposition not stated 13.0 15.0 14.0 17 15 13 15 15
 Died 0.40 1.3 5.0 4.5 0.10 0.30 0.60 2.5
 Not reported 1.8 2.1 1.6 2.1 1.6 1.7 2.2 2.4

* Values are expressed as mean ± SD.

Table 3.

Bivariate analysis of Charlson comorbidities in the study cohort (n = 14,007,813)

Comorbidity Total cohort (%) Mortality cohort (%) p value
Myocardial infarction 2.4 3.8 < 0.001
Congestive heart failure 4.4 4.9 < 0.001
Peripheral vascular disease 0.9 1.3 < 0.001
Cerebrovascular disease 1.7 4.2 < 0.001
Dementia 1.0 1.9 < 0.001
Chronic pulmonary disease 11 1.2 < 0.001
Rheumatic disease 2.0 0.10 < 0.001
Peptic ulcer disease 0.80 0.60 < 0.001
Mild liver disease 0.20 0.90 0.015
Moderate/severe liver disease 0 3.1 < 0.001
Diabetes (no chronic complication) 11 0.50 < 0.001
Diabetes (chronic complication) 0.80 3.4 < 0.001
Hemiplegia or paraplegia 0.30 3.7 < 0.001
Renal failure 0.60 6.3 < 0.001
Any malignancy 0.70 3.5 < 0.001
Leukemia 0.20 2.1 < 0.001
Lymphoma 0.20 0.80 0.94
Metastatic solid tumor 0.40 4.9 < 0.001
AIDS/HIV infection 0.10 0 < 0.001

Table 4.

Bivariate analysis of Elixhauser comorbidities (n = 14,007,813)

Comorbidity Total cohort (%) Mortality cohort (%) p value
Congestive heart failure 5.0 4.6 < 0.001
Cardiac arrhythmias 8.1 2.7 < 0.001
Valvular disease 3.0 1.1 < 0.001
Pulmonary circulation disorders 0.50 5.8 < 0.001
Peripheral vascular disorders 1.5 1.3 < 0.001
Hypertension (uncomplicated) 38 0.3 < 0.001
Hypertension (complicated) 1.9 2.1 < 0.001
Paralysis 0.70 2.6 < 0.001
Other neurologic disorders 1.9 1.6 < 0.001
Chronic pulmonary disease 11 1.2 < 0.001
Diabetes (uncomplicated) 11 0.50 < 0.001
Diabetes (complicated) 1.2 3.6 < 0.001
Hypothyroidism 7.6 0.30 < 0.001
Renal failure 1.3 5.0 < 0.001
Liver disease 0.60 1.2 < 0.001
Peptic ulcer disease (excluding bleeding) 0.70 0.10 < 0.001
AIDS/HIV infection 0.10 0 < 0.001
Lymphoma 0.20 0.70 0.56
Metastatic cancer 0.50 4.5 < 0.001
Solid tumor without metastasis 0.80 3.6 < 0.001
Rheumatoid arthritis/collagen vascular diseases 3.2 0.20 < 0.001
Coagulopathy 1.1 1.7 < 0.001
Obesity 4.8 0 < 0.001
Weight loss 0.70 9.0 < 0.001
Fluid and electrolyte disorders 7.6 2.2 < 0.001
Blood loss anemia 1.6 0.70 < 0.001
Deficiency anemia 0.90 0.20 < 0.001
Alcohol abuse 1.1 0.60 < 0.001
Drug abuse 0.70 0.70 0.18
Psychoses 0.70 0.50 < 0.001
Depression 4.4 0.40 < 0.001

Multivariable binary logistic regression analyses were performed to assess the contributions of the individual Charlson (Table 5) and Elixhauser (Table 6) comorbidities to predicted in-hospital mortality, our primary response variable. Charlson and Elixhauser comorbidities with a p value less than 0.10 in bivariate analysis and present in at least 0.2 % of the population were included in the logistic regression modeling. Two main models were constructed; each of these regression models encompassed one of the two comorbidity-based scores, and age, sex, and year of surgery, as independent variables. A base model that included only age, sex, and year of surgery also was evaluated [27].

Table 5.

Logistic regression analysis of relation of Charlson comorbidities (n = 14,007,813)

Comorbidity Coefficient (β) Standard error Wald chi-square Odds ratio 95% CI p value
Lower Upper
Myocardial infarction 1.4 0.010 18017 3.9 3.9 4.0 < 0.001
Congestive heart failure 1.3 0.0080 27778 3.5 3.5 3.6 < 0.001
Peripheral vascular disease 0.022 0.026 0.73 1.0 1.0 1.1 0.40
Cerebrovascular disease 1.2 0.012 9793 3.3 3.2 3.4 < 0.001
Dementia −0.34 0.020 284 0.71 0.69 0.74 < 0.001
Chronic pulmonary disease 0.35 0.0080 1723 1.4 1.4 1.4 < 0.001
Rheumatic disease −1.8 0.064 751 0.17 0.15 0.20 < 0.001
Peptic ulcer disease −0.50 0.039 162 0.61 0.56 0.66 < 0.001
Diabetes (no chronic complication) −0.49 0.012 1589 0.61 0.60 0.63 < 0.001
Diabetes (chronic complication) 1.5 0.018 6856 4.3 4.2 4.5 < 0.001
Hemiplegia or paraplegia 0.45 0.027 276 1.6 1.5 1.7 < 0.001
Renal failure 1.5 0.016 8036 4.3 4.2 4.4 < 0.001
Any malignancy 0.81 0.020 1562 2.2 2.2 2.3 < 0.001
Leukemia 0.43 0.042 107 1.5 1.4 1.7 < 0.001
Metastatic solid tumor 1.5 0.023 4369 4.5 4.3 4.7 < 0.001

Table 6.

Logistic regression analysis of Elixhauser comorbidities (n = 14,007,813)

Comorbidity Coefficient (β) Standard error Wald chi-square OR 95% CI p value
Lower Upper
Congestive heart failure 1.01 0.0080 17580 2.8 2.7 2.8 < 0.001
Cardiac arrhythmias 0.71 0.0070 9150 2.0 2.0 2.1 < 0.001
Valvular disease −0.45 0.016 827 0.64 0.62 0.66 < 0.001
Pulmonary circulation disorders 1.51 0.018 7217 4.5 4.4 4.7 < 0.001
Peripheral vascular disorders −0.013 0.021 0.38 1.0 0.95 1.0 0.54
Hypertension (uncomplicated) −0.95 0.0090 11075 0.39 0.38 0.40 < 0.001
Hypertension (complicated) −0.86 0.018 2234 0.43 0.41 0.44 < 0.001
Paralysis 1.4 0.022 3715 3.9 3.7 4.0 < 0.001
Other neurologic disorders 0.40 0.016 589 1.5 1.4 1.5 < 0.001
Chronic pulmonary disease 0.20 0.0090 548 1.2 1.2 1.2 < 0.001
Diabetes (uncomplicated) −0.16 0.012 167 0.85 0.83 0.87 < 0.001
Diabetes (complicated) 1.4 0.015 8818 3.9 3.8 4.0 < 0.001
Hypothyroidism −0.78 0.018 1801 0.46 0.44 0.48 < 0.001
Renal failure 1.5 0.016 9112 4.4 4.3 4.6 < 0.001
Liver disease 0.67 0.034 377 1.9 1.8 2.1 < 0.001
Peptic ulcer disease (excluding bleeding) −2.4 0.11 449 0.091 0.073 0.11 < 0.001
Metastatic cancer 1.1 0.023 2196 2.9 2.7 3.0 < 0.001
Solid tumor without metastasis 0.77 0.019 1587 2.2 2.1 2.2 < 0.001
Rheumatoid arthritis/collagen vascular diseases −0.73 0.034 468 0.48 0.45 0.51 < 0.001
Coagulopathy 0.18 0.021 77 1.2 1.2 1.2 < 0.001
Obesity −2.2 0.081 747 0.11 0.092 0.13 < 0.001
Weight loss 1.6 0.013 14868 5.0 4.8 5.1 < 0.001
Fluid and electrolyte disorders 0.55 0.0080 4750 1.7 1.7 1.8 < 0.001
Blood loss anemia −0.69 0.027 667 0.50 0.48 0.53 < 0.001
Deficiency anemia −2.18 0.071 955 0.11 0.10 0.13 < 0.001
Alcohol abuse −0.066 0.033 4.0 0.94 0.88 1.00 0.046
Psychoses −1.16 0.049 561 0.31 0.28 0.34 < 0.001
Depression −0.0080 0.022 0.15 1.0 1.0 1.0 0.70

To determine which model best predicted inpatient mortality, receiver operating characteristic (ROC) curves were plotted and the regression models were compared on the basis of the area under the ROC curve (AUC) and its 95% CI [20, 54]. The AUC quantifies the ability of our models to assign a high probability of mortality to the patients who died [42]. Values range from 0.50 to 1.0, with 0.50 indicating no ability to discriminate and 1.0 indicating perfect discrimination. In general, values less than 0.70 are considered to show poor discrimination, values between 0.70 and 0.80 can be considered acceptable, and between 0.80 and 0.90 excellent. In addition to the absolute improvement in predictive performance, we calculated the difference between two AUCs in percent beyond the predictive power of the base model including age, sex, and year of surgery [47]. For instance, a difference in AUC between the Charlson and Elixhauser comorbidity scores of 0.80 and 0.90, when the baseline AUC is 0.75, corresponds to a 67% relative increase in AUC: 0.90–0.75 – 0.80–0.75/0.90–0.75 = 0.67. We calculated the relative improvement in predictive performance of the Elixhauser score to the Charlson score. Global model performance also was compared using the Nagelkerke pseudo R-square measure [35]. Our secondary outcome variables, in-hospital adverse events and nonroutine discharge, were analyzed in an analogous fashion to in-hospital mortality. In-hospital adverse events were defined by ICD-9 codes (Appendix), following a coding approach used in other studies [34, 38]. A nonroutine discharge was defined as discharge to a skilled nursing facility or rehabilitation center. So as to set stricter standards owing to the large weighted sample size, a p value less than 0.001 was used to define significance in all analyses.

Results

Elixhauser comorbidity adjustment provided better prediction of in hospital case-mortality (AUC, 0.86; 95% CI, 0.86–0.86) compared with the Charlson model (AUC, 0.83; 95% CI, 0.83–0.84) and the base model with no comorbidities (AUC, 0.81; 95% CI, 0.81–0.81) (Table 7). In terms of relative improvement in predictive ability, the Elixhauser model performed 60% better than the Charlson model. The base model already showed excellent discrimination and accounted for 12% of the variation (Nagelkerke R-square = 0.12). The further addition of the Charlson comorbidity score to the base model led to a 2% increase in the amount of variation explained. The inclusion of the Elixhauser score to the base model achieved greater discrimination than the base model alone and the model incorporating the Charlson index and explained 18% of the variability (Nagelkerke R-square = 0.18). The rates of in-hospital death, together with those of adverse events and nonroutine disposition, increased steadily with the number of comorbidities and index scores In multivariable logistic regression analysis, chronic renal failure (odds ratio [OR], 4.3; 95% CI, 4.2–4.4; p < 0.001), complicated diabetes mellitus (OR, 4.3; 95% CI, 4.2–4.5; p < 0.001), and myocardial infarction (OR, 3.9; 95% CI, 3.9–4.0; p < 0.001) were the Charlson conditions associated with the greatest odds of in-hospital death (Table 5). Weight loss (OR, 5.0; 95% CI, 4.8–5.1; p < 0.001), pulmonary circulation disorders (OR, 4.5; 95% CI, 4.4–4.7; p < 0.001), and chronic renal failure (OR, 4.4; 95% CI, 4.3–4.6; p < 0.001) had the highest adjusted odds of inpatient mortality in the Elixhauser algorithm (Table 6).

Table 7.

Elixhauser and Charlson comorbidity method discrimination for inpatient outcomes after orthopaedic surgery

Model Mortality Adverse events Nonroutine discharge
AUC (95% CI) R-square AUC (95% CI) R-square AUC (95% CI) R-square
Base model (age, sex, year of surgery) 0.81 (0.81–0.81) 0.12 0.64 (0.63–0.64) 0.066 0.81 (0.81–.81) 0.35
Base model + Charlson score 0.83 (0.83–0.84) 0.14 0.64 (0.64–0.64) 0.067 0.81 (0.81–0.82) 0.36
Base model + Elixhauser score 0.86 (0.86–0.86) 0.18 0.65 (0.65–0.65) 0.077 0.81 (0.81–0.82) 0.36

AUC = area under the receiver operating characteristic curve.

Although the Elixhauser measure (AUC, 0.65; 95% CI, 0.65–0.65) was 100% more accurate than the Charlson measure (AUC, 0.64; 95% CI, 0.64–0.64) in predicting adverse events in terms of relative improvement, the discriminative ability of the model was poor and the difference in the absolute improvement in predictive power between the two models (AUC, 0.01) is of dubious clinical importance (Table 7).

The Elixhauser and Charlson models showed the same degree of discrimination for nonroutine discharge prediction after major orthopaedic surgery (AUC, 0.81; 95% CI, 0.81–0.81 for both scales) (Table 7).

Discussion

Surgical mortality and morbidity rates are important parameters of in-hospital quality of care [11, 37, 50]. Given the increasing age and complexity of patients undergoing orthopaedic surgery, it is necessary to appropriately adjust for patient risk, recognizing that the underlying nature of some patients’ conditions may make them more likely than others to experience poor outcomes. We therefore assessed and compared the two most commonly used comorbidity risk adjustment models in orthopaedic surgery, the Charlson and Elixhauser measures, regarding their ability to predict in-hospital death, adverse events, and nonroutine discharge.

Our results should be interpreted after taking into account numerous factors. Despite access to large numbers and associated power, administrative databases have several recognized limitations [14, 23, 29]. First, the NHDS dataset is based on billing data from ICD-9-CM codes, and such a coding system may not fully capture the patient population of interest [1]. In particular, it has been suggested that administrative databases tend to underreport chronic medical conditions that are considered less acute in the perioperative orthopaedic surgery setting [16, 31, 33, 34, 39]. Second, the possibility of errors in coding of the diagnoses and procedures cannot be avoided [7]; however, misclassification mistakes distribute evenly in large-scale studies [53]. Third, the NHDS database does not include data regarding the timing of diagnoses, which hinders the differentiation of baseline comorbidities from complications [36]. Analyses of risk-adjusted mortality rates should adjust mortality rates only for baseline comorbid diseases, not complications that arise from surgery [15]. The degree to which this issue influenced our results is unclear, although it has been reported that the majority of common diagnoses are comorbidities rather than adverse events [15, 30, 36]. Fourth, the NHDS enabled only ascertainment of inpatient outcomes, and thus postdischarge complications and readmissions were not captured. Fifth, we performed risk-adjustment using administrative data only; inclusion of clinically relevant variables such as the American Society of Anesthesiologists (ASA) score or the Frailty Index developed by the Canadian Study of Health and Aging may have improved model performance [24, 40, 58]. Finally, we did not perform any clinical data abstraction from medical records, which is considered the gold standard risk adjustment method in these comparisons [10]; thus, we were able to compare the Charlson and Elixhauser measures only for their relative performance.

We found that the Elixhauser comorbidity risk adjustment model performed numerically better than the Charlson model in predicting in-hospital mortality after major orthopaedic surgery. Although differences in the AUC values between the two comorbidity-based measures were small, it has been noted that even slight improvements in the AUC for such indexes can translate into quantifiable reductions in confounding bias [46]. Overall, the AUC values for inpatient mortality for the Charlson and Elixhauser comorbidity-based measures in our study were comparable to or slightly higher than those described in other patient populations [6, 18, 27, 52]. Consistent with a study by Nikkel et al. [39] in patients with hip fractures, the Elixhauser weight loss or malnutrition comorbidity was the major factor influencing mortality. We found some comorbidities (eg, hypothyroidism, obesity, uncomplicated diabetes, hypertension) to be associated with decreased odds of inpatient mortality. It is counterintuitive that these comorbidities would protect against inpatient death. It may be that these comorbidities are most common in patients with less overall infirmity compared with the average orthopaedic inpatient.

The occurrence of in-hospital adverse events after major orthopaedic surgery was slightly more accurately predicted with the Elixhauser comorbidity index. However, in line with the study by Gordon et al. [17] looking at the influence of the Elixhauser and Charlson measures on reoperations after THA, the predictive accuracy of both models to detect adverse events was poor (AUC values < 0.70). An AUC value approximating 0.70 is considered acceptable for discrimination and validation of methods for ongoing use [18]; we therefore could not validate the Charlson or Elixhauser measures in terms of predicting perioperative complications after major orthopaedic surgery. There may be something beyond measurable comorbidities that is yet unaccounted for in orthopaedic inpatient morbidity.

Both comorbidity indexes provided clinically relevant insight for estimating nonroutine discharge after orthopaedic surgery; the Elixhauser score was no better than the Charlson score. This finding suggests that the Charlson and Elixhauser indexes are valid prediction tools for healthcare resource use risk adjustment, and researchers should choose between them based more on their availability and comfort with the method [2].

The Elixhauser measure has not been introduced in orthopaedic surgery research until recently [17, 26, 39, 57, 59, 60], perhaps because of scarce reported comparisons with the Charlson model [17] and concerns regarding the inclusion of too many explanatory variables (31 variables), therefore requiring a relatively large sample size [27]. The main attractiveness of the use of large administrative databases for medical research lies in the possibility of studying rare occurrence events, such as inpatient mortality, that otherwise would be difficult to investigate in small population studies [14].

Testing comorbidity risk adjustment measure performance in orthopaedic surgery is worthy of future study. Further research comparing the Charlson and Elixhauser methods with the less accessible (costwise) risk adjustment methods of Disease Staging (Thomson Medstat Inc, Ann Arbor, MI, USA) and All Patient Refined Diagnosis Related Groups (3M Health Information Systems, Wallingford, CT, USA) is warranted [36]. In addition, we currently are testing and validating a specific comorbidity-based measure for outcome prediction after orthopaedic surgery. The Elixhauser comorbidity measure outperformed the widely used Charlson measure in predicting inpatient mortality and morbidity after major orthopaedic surgery, and its more extensive use in claims-based studies should be considered. Future research assessing and comparing the performance of these measures in predicting long-term outcomes would be of value.

Appendix

List of ICD-9 codes included to identify adverse events

Adverse events ICD-9 codes
Postoperative shock 998.0
Hematoma or seroma 998.1
Disruption of wound 998.3
Postoperative infection 998.5
Acute posthemorrhagic anemia 285.1
Complications not elsewhere classified 997
Acute renal failure 580, 584
Acute myocardial infarction 410
Ventricular arrhythmias and cardiac arrest 427.4, 427.5
Pneumonia and pulmonary congestion 482, 485, 486, 514, 5184
Iatrogenic postoperative hypotension 458.29
Pulmonary embolism 415.1
Induced mental disorders 291, 292, 293
Cerebrovascular disease 430, 431, 432, 433, 434, 435, 436
Fat embolism 958.1
Pulmonary insufficiency after trauma, surgery, transfusion, or acute respiratory distress syndrome 518.5, 518.7, 518.81
Thrombotic events 451.1, 451.2, 453.2, 453.4, 453.8, 453.9
Intubation and mechanical ventilation 96.04, 96.07
Transfusion of blood (components) 99.0
Conversion of cardiac rhythm 99.6

ICD-9 = International Classification of Diseases, 9th Revision.

Footnotes

Each author certifies that he or she, or a member of his or her immediate family, has no funding or commercial associations (eg, consultancies, stock ownership, equity interest, patent/licensing arrangements, etc) that might pose a conflict of interest in connection with the submitted article.

All ICMJE Conflict of Interest Forms for authors and Clinical Orthopaedics and Related Research ® editors and board members are on file with the publication and can be viewed on request.

Each author certifies that his or her institution waived approval for the human protocol for this investigation and that all investigations were conducted in conformity with ethical principles of research.

This work was performed at the Orthopaedic Hand and Upper Extremity Service, Massachusetts General Hospital, Boston, MA, USA.

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