Free
Education  |   April 2002
Standard versus  Fiberoptic Pulmonary Artery Catheterization for Cardiac Surgery in the Department of Veterans Affairs: A Prospective, Observational, Multicenter Analysis
Author Affiliations & Notes
  • Martin J. London, M.D.
    *
  • Thomas E. Moritz, M.S.
  • William G. Henderson, Ph.D.
  • Gulshan K. Sethi, M.D.
    §
  • Maureen M. O'Brien, Ph.D.
  • Gary K. Grunwald, Ph.D.
    #
  • Catherine B. Beckman, R.N., M.S., M.B.A
    **
  • A. Laurie Shroyer, Ph.D., M.S.H.A.
    ††
  • Frederick L. Grover, M.D.
    ‡‡
  • *Professor of Clinical Anesthesia, San Francisco Veterans Affairs Medical Center and the Department of Anesthesia and Perioperative Care, University of California–San Francisco. †Biostatistician, ‡Director, Cooperative Studies Program Coordinating Center, Hines Veterans Affairs Medical Center. §Professor of Surgery, Tucson Veterans Affairs Medical Center and University of Arizona Health Sciences Center. ∥Biostatistician, **Study Research Nurse Coordinator, Denver Veterans Affairs Medical Center. #Assistant Professor of Preventive Medicine and Biometrics, ††Assistant Professor of Medicine, ‡‡Professor of Surgery, Denver Veterans Affairs Medical Center and University of Colorado Health Sciences Center, Denver, Colorado.
  • Received from the San Francisco Veterans Affairs Medical Center and the Department of Anesthesia and Perioperative Care, University of California–San Francisco, San Francisco, California; Cooperative Studies Program Coordinating Center, Hines Veterans Affairs Medical Center, Hines, Illinois; Tucson Veterans Affairs Medical Center and University of Arizona Health Sciences Center, Tucson, Arizona; and Denver Veterans Affairs Medical Center and University of Colorado Health Sciences Center, Denver, Colorado.
Article Information
Education
Education   |   April 2002
Standard versus  Fiberoptic Pulmonary Artery Catheterization for Cardiac Surgery in the Department of Veterans Affairs: A Prospective, Observational, Multicenter Analysis
Anesthesiology 4 2002, Vol.96, 860-870. doi:
Anesthesiology 4 2002, Vol.96, 860-870. doi:
THE need for pulmonary artery catheterization (PAC) in patients undergoing cardiac surgery has been a topic of considerable clinical interest and controversy for nearly two decades. Despite earlier reports from university settings that the majority of elective coronary artery bypass grafting (CABG) could be performed safely with central venous catheterization alone 1–3 and a more recent report of only 58% PAC use in community hospitals for similar cases, PAC use remains popular in many centers and settings. 4 
The first major technological innovation to the PAC was addition of continuous measurement of mixed venous oxygen saturation (ST̄vo2) by reflectance spectrophotometry (ST̄vo2-PAC). 5,6 In the cardiac surgical setting, the ability to continuously trend ST̄vo2, which reflects the balance between whole body oxygen delivery (cardiac output, hemoglobin concentration, arterial oxygen saturation) and utilization (peripheral oxygen consumption) maybe useful as an “early warning system” for impending adverse hemodynamic and clinical events. 7,8 It can also be used to assess adequacy of oxygen delivery during ventilator weaning, potentially decreasing the number of arterial blood gases (ABG) analyses and other laboratory measurements required. Previous studies with differing experimental designs, in either the general medical surgical or cardiac surgical intensive care unit (ICU) settings, reached varying conclusions regarding the clinical utility of ST̄vo2-PAC for these purposes. 7–14 
As part of a multicenter, prospective, observational study evaluating the association of perioperative processes and structures of care with risk-adjusted patient outcomes in patients undergoing cardiac surgery with cardiopulmonary bypass in the Department of Veterans Affairs (DVA) medical system, frequency of use of standard PAC and ST̄vo2-PAC was collected. Given the large sample size and prospective data capture by trained research nurses during the hospital stay, this database affords a unique opportunity to evaluate associations of PAC type with resource consumption and clinical outcome not previously reported.
Methods
Study Protocol
Department of Veterans Affairs Cooperative Study #5, “Processes, Structures and Outcomes of Care in Cardiac Surgery” (PSOCS), was a 4.5-yr prospective, observational study conducted at 14 DVA medical centers. This study investigated the associations of processes (acts of care) and structures (environment of care) on risk-adjusted operative mortality in patients undergoing cardiac surgery requiring cardiopulmonary bypass at 14 participating centers from 1992 to 1996. 1Details of the data collection methodology have been previously reported. 15 All data, with the exception of a small number of emergent cases, were collected by direct observation by a PSOCS study research nurse. The current analysis represents a substudy from this database. Institutional review board approval for the PSOCS study was obtained from the Hines Veterans Affairs Cooperative Studies Program Coordinating Center Central Human Rights Committee and by the institutional review boards at each participating center; informed consent was obtained as required.
Mixed Venous Oxygen Saturation–Pulmonary Artery Catheterization Data Extraction and Coding
For the period of study (July 1, 1994, to December 31, 1996) with all 14 centers participating, we considered 3,582 patients undergoing CABG or valve replacement–repair with or without concurrent CABG requiring cardiopulmonary bypass enrolled in the operational phase of the PSOCS study. 2The following subgroups of patients were excluded: 18 intraoperative deaths, 137 monitored with central venous catheters alone (120 of these at one hospital), 151 missing intraoperative catheter data, and 145 missing postoperative catheter data (groups not mutually exclusive). Thus, 3,265 (91%) of enrolled PSOCS patients from the operational phase formed our study cohort.
Within these patients, PAC was coded in both the intraoperative and postoperative periods in 1,681 patients, whereas ST̄vo2-PAC was coded in both periods in 1,383 patients. One hundred forty-eight patients were coded as having ST̄vo2-PAC during the intraoperative period but with PAC only in the postoperative period, whereas 53 patients were coded as PAC only in the intraoperative period but with ST̄vo2-PAC in the postoperative period. The reasons for these differences are not recorded in the PSOCS database. Potential explanations include clinical factors (i.e.  , intraoperative PAC changed to ST̄vo2-PAC for deteriorating clinical status in the postoperative period or in the reverse situation, the additional equipment necessary to monitor ST̄vo2may not have been available in the ICU and thus the patient would be recoded as PAC only) or data coding errors. 3For the purposes of this analysis, these 201 patients were added to the ST̄vo2-PAC group to compare patients with some form of the “treatment” under consideration (i.e.  , ST̄vo2-PAC) versus  those with “no treatment” (i.e.  , PAC). Thus, the final ST̄vo2-PAC group totaled 1,584 patients versus  1,681 PAC patients.
Statistical Analysis
Logistic and Cox regression models were constructed to evaluate the association of ST̄vo2-PAC with several important clinical outcomes: (1) 30-day mortality; (2) any postoperative complication (1); (3) cardiac complications (1); (4) time to extubation; and (5) ICU length of stay. All deaths were reviewed by the PSOCS Death Review Committee. Complications were coded locally at each site by the research nurses using standardized definitions. A 30-day operative mortality risk estimate derived from population-based logistic regression models developed by the DVA's Continuous Improvement in Cardiac Surgery Program was calculated for each patient and used in each outcome model for risk-adjustment purposes. 16,17 The component risk variables used to calculate the Continuous Improvement in Cardiac Surgery Program estimate (listed in appendices B and C for CABG and Valve/Valve-CABG procedures, respectively) were not used individually in any of the models presented here to minimize colinearity. Given the controversy regarding the relative importance of preoperative risk and perioperative process variables in modulating outcome, we also included the duration of cardiopulmonary bypass in the models as an intraoperative and early postoperative surrogate for risk. 18,19 
We selected preoperative risk factors and perioperative process of care variables with strong clinical bases or evidence-based linkage to outcome. These variables were compared between PAC and ST̄vo2-PAC groups using the Wilcoxon rank sum test for continuous variables and chi-square or Kruskall-Wallis test for categorical variables. Significant variables with a P  value < 0.1 were entered into the logistic or Cox regression models using backward stepwise selection (P  < 0.05 for removal).
To adjust for hospital level effects impacting the choice of catheter, particularly the lack of availability of the ST̄vo2-PAC catheter at certain hospitals or protocol-driven effects (i.e.  , use in every patient at a particular hospital), a three-level indicator variable was also entered into each model. Hospitals in which 95% of patients were coded as having ST̄vo2-PAC were considered “always,” those with 5% or less were considered “never,” and those in between were considered as “some.” A 5% threshold was arbitrarily chosen to account for potential data coding errors in this large study in which hundreds of other variables unrelated to this analysis were also collected. In the model results, “never” is the reference category.
Patients with missing data for variables used in a specific regression model were excluded as noted in each of the tables. 4Model discrimination and goodness of fit for dichotomous outcomes were assessed using the C-index and the Hosmer-Lemeshow “goodness of fit” (H-L) statistic, respectively. A C-index of 1.0 represents perfect discrimination, and a value of 0.5 represents chance discrimination only. 20 The H-L statistic tests the null hypothesis of no difference in the average observed and predicted outcome rates across deciles of expected risk. 21 A lower H-L value (with a larger P  value) represents better model calibration. Cox proportional hazards regression analysis was used to model time to extubation and ICU length of stay. Patients who died before extubation or in whom no time to extubation was recorded were censored in the time-to-extubation model (n = 58). Deaths during the ICU stay were censored in the ICU length-of-stay model (n = 82). Odds ratios for logistic regression or hazards ratios for Cox regression with 95% confidence intervals are reported.
To evaluate the influence of catheter type on the number of ABG analyses and thermodilution cardiac outputs (TdCOs) performed in the first 24 h postoperatively, we used the mortality risk estimate to stratify patients into three groups (low risk ≤ 2.5%, moderate risk 2.6–5.0%, and higher risk > 5.0%) comparing the frequency of each respective measurement using analysis of covariance.
Data are presented as mean ± SD for normally distributed variables or median ± interquartile range for nonnormally distributed variables. Statistical significance was considered at P  < 0.05. All statistical analyses were performed using SAS software (version 6.12; SAS Institute, Cary, NC).
Results
Overall, ST̄vo2-PAC was used in 49% and standard PAC in 51% of patients. The distribution of ST̄vo2-PAC use by hospital is shown in figure 1. Four hospitals appeared to use ST̄vo2-PAC in all patients, four others in some but not all patients (including the one center in which central venous catheterization alone was the predominant clinical practice), whereas the remaining six centers never used ST̄vo2-PAC.
Fig. 1. Distribution of mixed venous oxygen saturation–pulmonary artery catheterization (ST̄vo2-PAC) use by hospital as a percentage of patients analyzed.
Fig. 1. Distribution of mixed venous oxygen saturation–pulmonary artery catheterization (ST̄vo2-PAC) use by hospital as a percentage of patients analyzed.
Fig. 1. Distribution of mixed venous oxygen saturation–pulmonary artery catheterization (ST̄vo2-PAC) use by hospital as a percentage of patients analyzed.
×
Differences in preoperative risk and intraoperative and postoperative process of care variables between the groups are presented in tables 1–3. The cohort was predominantly male undergoing elective CABG. Because of the large sample size, many variables achieved statisticalsignificance, although most differences were small and of marginal clinical relevance. In the univariateanalyses,PAC type had no effect on mortality or morbidity (aggregatecardiac complication variable or any postoperativecomplications variable), although several individualpostoperative complications were significant. There werestatistically significant but clinically small differencesbetween PAC type for time to extubation and for ICU and postoperative length of stay.
Table 1. Preoperative Variables by PAC Type
Image not available
Table 1. Preoperative Variables by PAC Type
×
Table 2. Intraoperative Variables by PAC Type
Image not available
Table 2. Intraoperative Variables by PAC Type
×
Table 3. Postoperative Variables by PAC Type
Image not available
Table 3. Postoperative Variables by PAC Type
×
The logistic and Cox regression models for perioperative mortality, one or more postoperative complications, cardiac complications, time to extubation, and ICU length of stay are presented in tables 4–8. With the exception of time to extubation, no independent associations of ST̄vo2-PAC with any of these outcomes were observed. In the cardiac-complications model, the hospital indicator for “some” use was significantly associated with a lower frequency of complications, despite the observation that the catheter variable alone was not. This suggests that an unspecified hospital level effect, independent of catheter type, may be responsible.
Table 4. Mortality Model
Image not available
Table 4. Mortality Model
×
Table 5. Any Postoperative Complication Model
Image not available
Table 5. Any Postoperative Complication Model
×
Table 6. Cardiac Complications Model
Image not available
Table 6. Cardiac Complications Model
×
Table 7. Time to Extubation Model
Image not available
Table 7. Time to Extubation Model
×
Table 8. Intensive Care Unit Duration of Stay Model
Image not available
Table 8. Intensive Care Unit Duration of Stay Model
×
In the time-to-extubation model, a more complex interaction was observed between catheter type and the hospital indicator. The “always” and “some use” hospital indicators were associated with a shorter time to extubation, but catheter type was associated with a longer time. Inspection of the survival curves for each of the possible six catheter type by hospital indicator combinations (including the null combinations of always used but no ST̄vo2-PAC and never used with yes ST̄vo2-PAC) revealed that the shortest times to extubation were noted in the some use, no ST̄vo2-PAC pair, and the always used, yes ST̄vo2-PAC pair relative to the remaining pairs. Overall, PAC patients had shorter times to extubation relative to ST̄vo2-PAC, and hospitals in which ST̄vo2-PAC was used had shorter times. The presence of a Fast Track protocol was strongly associated with shorter time to extubation (odds ratio, 2.1; 95% confidence interval, 1.9–2.3).
The C-indices and H-L P  values for the logistic models indicate acceptable model discrimination and calibration.
The mean number of ABG analyses and TdCOs performed in the first 24 h postoperatively at each hospital are presented in figure 2. These data, stratified by terciles of the Continuous Improvement in Cardiac Surgery Program risk estimate, are shown in table 9. An increase in the number of ABG analyses performed with increasing risk was observed (P  = 0.002). The rate of increase with risk was similar between PAC and ST̄vo2-PAC. However, there were fewer ABG analyses performed in the ST̄vo2-PAC group (P  = 0.001). For TdCO measurements, a risk by catheter type interaction was observed. Although the number of TdCO measurements increased in both PAC and ST̄vo2-PAC groups with increasing risk, the rate of increase was greater in the PAC group (P  = 0.027).
Fig. 2. Mean number (± SD) of arterial blood gas (ABG) and thermodilution cardiac output (CO) measurements performed in the first 24 h postoperatively. Hospital codes are same as those used in figure 1.
Fig. 2. Mean number (± SD) of arterial blood gas (ABG) and thermodilution cardiac output (CO) measurements performed in the first 24 h postoperatively. Hospital codes are same as those used in figure 1.
Fig. 2. Mean number (± SD) of arterial blood gas (ABG) and thermodilution cardiac output (CO) measurements performed in the first 24 h postoperatively. Hospital codes are same as those used in figure 1.
×
Table 9. Number of Arterial Blood Gases (ABG) and Thermodilution Cardiac Outputs (TdCO) Performed in the First 24 h Postoperatively
Image not available
Table 9. Number of Arterial Blood Gases (ABG) and Thermodilution Cardiac Outputs (TdCO) Performed in the First 24 h Postoperatively
×
Discussion
This analysis reveals that PAC use was nearly universal in the 14 hospitals participating in the PSOCS study between 1994 and 1996, and that ST̄vo2-PAC was used in nearly 50% of patients. We cannot be certain if these results were representative of the entire VA system (43 centers performing cardiac surgery during this time period), although we believe it likely given that the PSOCS study sites were selected based on predefined criteria for geographic location and risk-adjusted mortality, to obtain a representative national mix of sites. The frequent use of ST̄vo2-PAC was surprising given the additional cost over standard PAC (approximately $150–200 difference). Our findings contrast with a recent retrospective cohort study of 13,907 patients undergoing elective CABG at community hospitals in 1997, retrieved from a commercial “benchmarking” database, in which PAC (specific type and exact time of insertion not reported) was used in only 58% of patients. 4 
Our data fail to support a statistically significant independent association of ST̄vo2-PAC use with the outcomes we selected for modeling. The failure to observe an independent effect on mortality is not unexpected given the multiplicity of factors involved and the complexity of interactions, which is the basic premise of the parent PSOCS study. 22–24 We chose to use a subset of the PSOCS cohort, in which data were collected in a similar time frame at all of the 14 participating centers (operational phase from July 1, 1994, to December 31, 1996) to minimize time-related effects in adoption and use of this technology, lowering our sample size and statistical power relative to the original study's target enrollment of approximately 5,000 patients (which used fewer centers during the earlier pilot and developmental phases).
Our choice of complication models, either all aggregate complications or cardiac complications alone, was based on literature precedent for similar large observational analyses in either cardiac or noncardiac surgery in the DVA 17,25–27 (for the former) and controversies regarding the “early warning” potential for ST̄vo2-PAC to alert clinicians to impending (or manifest) hemodynamic abnormalities (for the latter). 7–13 Given the number of complications comprising our aggregate cardiac complication variable, it is possible that analysis of individual complications might have revealed significant results. However, this a posteriori  approach is likely to yield false-positive associations simply by chance. In addition, several of these complications are subject to variability in interpretation and coding. Because independent validation of complication data by a central study monitoring board was not performed (as was done for mortality), given the high frequency of these events, these results must be considered tentative. Our finding of a hospital level effect of ST̄vo2-PAC for cardiac complications, in the absence of a patient level association with catheter type, is interesting and is likely a result of either a higher-order hospital effect (i.e.  , different processes of care at an individual hospital within the three-level hospital group indicator we used that might impact on cardiac complication rates) or variability in coding of complications at different centers, issues beyond the scope of this analysis.
Evaluating resource utilization parameters (time to extubation, ICU length of stay, number of ABG and TdCO measurements performed), we noted several interesting findings. With regard to time to extubation, a complex interaction between the hospital indicator and catheter type was noted. The overriding effect of hospitals with a Fast Track protocol was the predominant factor, as would be expected. As noted in a previous DVA study from this time period, a bimodal distribution of patients is usually present in time to extubation. 19 Although the exact role of preoperative risk versus  perioperative processes in modulating postoperative outcome remains controversial, it is likely that healthier patients undergoing “successful” procedures are extubated earliest, followed by “sicker” patients undergoing “successful” procedures, followed by patients undergoing complicated or “stormy” procedures. Given the physiologic basis for ST̄vo2-PAC in evaluating the stability of weaning from mechanical ventilation, 14 it is likely that its true clinical utility may be in the latter “sicker” groups of patients. Thus, an association with a longer time to extubation may occur.
Modeling of hospital length of stay is a complex process, and it is unlikely that an isolated process variable such as ST̄vo2-PAC would have a measurable impact on it (as we have noted). As noted previously, reduction in time to extubation is unlikely to significantly reduce postoperative length of stay, except in hospitals with “aggressive” fast-tracking protocols. 28,29 
Finally, we noted a highly significant but clinically modest reduction in the number of ABG and TdCO measurements performed in hospitals with ST̄vo2-PAC. As expected, higher-risk patients were subjected to more measurements, but at all levels fewer measurements were made in the ST̄vo2-PAC group. Although we have not and are unable to perform a cost analysis, it is unlikely that the small difference (based on the entire cohort data) would offset the cost of the more expensive catheter. However, we cannot completely discount the possibility that, at a particular center, such an offset might have occurred.
We do not know the current prevalence of ST̄vo2-PAC use in this population and to what extent the wider institution of “fast tracking” in the DVA system has impacted on it. 19,28 It is likely that fast tracking, with its emphasis on efficiency and curtailing excessive resource consumption, may have significantly decreased ST̄vo2-PAC use. However, shortly after this study concluded, a “continuous” cardiac output PAC was introduced clinically and has been found to have acceptable accuracy and correlation with bolus TdCO in this setting. 30,31 This catheter is marketed with or without continuous ST̄vo2capability, and the price of a “dual” catheter is only marginally greater than continuous cardiac output PAC alone. Thus, it is possible that some centers continue to use these catheters over standard PAC, given the additional information provided at a similar cost to ST̄vo2-PAC alone.
An additional factor likely to influence the use of ST̄vo2-PAC is the increasing use of off-pump and minimally invasive coronary artery bypass procedures. Avoidance of cardiopulmonary bypass in the vast majority of these cases is likely to lead the clinician to curtail use of the more costly ST̄vo2-PAC. However, there is still controversy regarding reduction of adverse outcomes after off-pump or minimally invasive coronary artery bypass and the extent of perioperative resource utilization relative to cardiopulmonary bypass procedures. 32 The risk profile of patients undergoing off-pump coronary artery bypass may vary significantly between centers, with some reserving them for the sickest patients and others performing them routinely on the healthiest patients, a factor that could influence choice of monitoring in either direction. 33 
The continuing clinical controversy regarding the value of “goal-oriented hemodynamic therapy,” in which oxygen delivery is maintained at a supranormal level (as manifested by increased cardiac output and ST̄vo2), may also influence choice of PAC. 34–36 Although predominantly studied in medical ICU patients (with conflicting results), a recent randomized study of 403 cardiac surgical patients reported a significant reduction in the frequency of organ dysfunction at the time of discharge in the protocol group (1.0 vs.  5.6% control, P  < 0.01). 37 Thus, the capability to continually monitor ST̄vo2may be advantageous, although further confirmatory studies are required.
Given the observational nature of our study, the statistical methodology to assess the impact of ST̄vo2-PAC is considerably more controversial than what would be used in a randomized controlled trial. 38 Our models must be considered exploratory as they were constructed solely to evaluate associations of ST̄vo2-PAC with a small group of variables (especially relative to the much larger parent PSOCS study). We considered risk and process covariates modulating outcome and decision-making related to choice of catheter, entering into the regression models a core set of risk variables and other risk–process variables with statistically significant differences between catheter groups, allowing us to adjust for these imbalances. Those that appear significant in the output of the models may or may not be clinically relevant if the analysis was performed with a variable other than PAC–ST̄vo2-PAC as the “primary” variable because it is likely that different covariates would be considered in the regression model. Thus, interesting and controversial findings (i.e.  , transesophageal echocardiography use, differences in blood transfusion, etc.  ) may suggest other analyses but are not necessarily relevant findings of this analysis. It must be emphasized that, with such a large sample size, highly statistically significance differences in the absence of clinical significance is a common finding. The clinician must carefully inspect actual percentage differences and not rely on small P  values. Although we present basic model calibration and discrimination statistics (C-index and H-L test), we have not performed additional diagnostics (i.e.  , bootstrapping, etc.  ) required for validation of prediction models. In addition, the PSOCS study analysis makes extensive use of complex data reduction and variable weighting techniques to deal with hundreds of clinical variables collected, before entry into the primary outcome mortality logistic model, which we have not performed. Thus, our limited modeling approach should be interpreted cautiously.
Other statistical techniques such as subclassification on propensity scores can be used along with logistic regression and case-matching to evaluate treatment bias related to treatment choice (in this case catheter type). 39 However, each has different exclusion criteria and might yield different results. With propensity scoring, patients in the PAC-only hospitals would be excluded from consideration because of the absence of ST̄vo2-PAC at those hospitals. Inclusion of a catheter-related hospital indicator variable (never, some, always) serves a somewhat similar role, allowing inclusion of a substantially larger number of patients.
Using data from a large prospective cohort of patients undergoing cardiac surgery with cardiopulmonary bypass, we failed to note any independent association of ST̄vo2-PAC use with a variety of important clinical outcomes. A small reduction in resource utilization as measured by ABG and TdCO measurements was observed. Given development of new technology (continuous cardiac output) and changes in surgical practice (off-pump and minimally invasive coronary artery bypass), the clinical implications of these findings are uncertain. Further study of the effectiveness of sophisticated PACs using a variety of data sources and experimental designs, especially in light of ongoing controversy regarding PAC use, 40 appears worthy of further research.
Appendix A: Complication Variables Definitions
  • Low cardiac output: cardiac index < 2.0 l · min−1· m−2or peripheral manifestations (e.g.  , oliguria, hypotension, obtundation), or both for 6 h or longer postoperatively requiring inotropic or intraaortic balloon pump support.
  • Perioperative myocardial infarction: new Q waves or widening of Q waves by 0.02 s on the electrocardiogram within 30 days postoperatively.
  • Perioperative myocardial injury: (1) electrocardiogram changes consistent with a non-Q myocardial infarction (new ST segment depression ≥ 2 mm in two or more adjacent leads, deep [≥ 5 mm] inverted T waves, or new left bundle branch block (LBBB); (2) CK-MB (creatine kinase MB isoenzyme) isoenzyme changes ≥ twice the upper limit of normal; or (3) a technetium pyrophosphate scan showing myocardial damage.
  • Cardiac arrest: external or open cardiopulmonary resuscitation occurring in the ICU, ward, or out of hospital after the chest has been completely closed and within 30 days of surgery.
  • Ventricular arrhythmias: ventricular tachycardia or ventricular fibrillation requiring cardioversion or defibrillation (with or without cardiopulmonary resuscitation).
  • Heart block: second- or third-degree heart block documented by electrocardiogram requiring the insertion or activation of a temporary or permanent pacemaker.
  • CHF symptoms: New York Heart Association functional class III or class IV congestive heart failure throughout the postoperative hospital stay.
  • Atrial fibrillation: one or more episodes of atrial fibrillation (documented by electrocardiogram) postoperatively.
  • Coma: Decreased level of consciousness (exclude transient disorientation or psychosis) for ≥ 24 h during postoperative hospitalization as evidence by lack of response to deep, painful stimuli.
  • Stroke: new objective neurologic deficit lasting ≥ 30 min with onset intraoperatively or during the postoperative hospital stay.
  • Respiratory failure: total duration of ventilator-assisted respiration during postoperative hospitalization ≥ 48 h.
  • Reintubation: reintubation for postoperative respiratory failure.
  • Pulmonary embolus: a ventilation–perfusion scan interpreted as a high probability of pulmonary embolism or positive pulmonary arteriogram.
  • Mediastinitis: a bacterial infection below the sternum requiring drainage and antimicrobial therapy diagnosed during the postoperative hospitalization or within 30 days after surgery.
  • Endocarditis: two or more positive blood cultures with the same organism, or development of vegetations and valve destruction seen by echo or repeat surgery, or histologic evidence of infection at repeat surgery or autopsy, or any combination.
  • Pneumonia: clinical signs and symptoms and infiltrate on chest radiograph.
  • Vein harvest infection: a vein harvest site (usually saphenous) infection manifested by draining pus with positive cultures that may require or be relieved by antibiotic therapy.
  • Chest wound infection: a bacterial infection of the sternotomy incision not involving the sternum but requiring antibiotic therapy and prolonging the hospital stay.
  • Renal failure: new renal failure requiring dialysis or an exacerbation of renal failure requiring the initiation of dialysis (not on dialysis preoperatively).
  • GI bleed: gastrointestinal bleed that requires a transfusion of more than three units of erythrocytes, that results in hematocrit decreasing more than 20%, or that requires an operative procedure during postoperative hospitalization.
  • Hepatic failure: severe liver dysfunction manifested by visible jaundice, serum total bilirubin greater than 5.0 mg/dl, serum albumin less than 3.0 g/dl, or INR (prothrombin time) greater than 3.0 (not on warfarin).
  • Coagulopathy: a diagnosis of disseminated intravascular coagulation manifested by diffuse bleeding with a serum fibrinogen less than 100 mg/dl and a platelet count less than 100,000/μl.
Appendix B: Variables Included in the Continuous Improvement in Cardiac Surgery Program Coronary Artery Bypass Grafting Mortality Risk Estimate
Definitions of the following variables are available at :
  • Serum creatinine
  • Ejection fraction
  • Prior myocardial infarction
  • Surgical priority
  • CHF functional class
  • Preoperative PTCA
  • Age
  • Prior heart surgery
  • Hx cerebrovascular disease
  • Hx COPD
  • Preoperative ST segment depression on 12-lead electrocardiogram
  • ASA class
  • Hx peripheral vascular disease
  • Preoperative IABP
Appendix C: Variables Included in the Continuous Improvement in Cardiac Surgery Program Valve Surgery Mortality Risk Estimate
Definitions of the following variables are available at :
  • Serum creatinine
  • Ejection fraction
  • Prior myocardial infarction
  • Surgical priority
  • Angina functional class
  • Procedure type
  • Age
  • Prior heart surgery
  • Current smoker
  • Functional status
  • Gender
  • Endocarditis
  • Rales on physical examination
  • ASA class
References
Bashein G, Johnson PW, Davis KB, Ivey TD: Elective coronary bypass surgery without pulmonary artery catheter monitoring. A nesthesiology 1985; 63: 451–4Bashein, G Johnson, PW Davis, KB Ivey, TD
Tuman KJ, McCarthy RJ, Spiess BD, DaValle M, Hompland SJ, Dabir R, Ivankovich AD: Effect of pulmonary artery catheterization on outcome in patients undergoing coronary artery surgery. A nesthesiology 1989; 70: 199–206Tuman, KJ McCarthy, RJ Spiess, BD DaValle, M Hompland, SJ Dabir, R Ivankovich, AD
Stewart RD, Psyhojos T, Lahey SJ, Levitsky S, Campos CT: Central venous catheter use in low-risk coronary artery bypass grafting. Ann Thorac Surg 1998; 66: 1306–11Stewart, RD Psyhojos, T Lahey, SJ Levitsky, S Campos, CT
Ramsey SD, Saint S, Sullivan SD, Dey L, Kelley K, Bowdle A: Clinical and economic effects of pulmonary artery catheterization in nonemergent coronary artery bypass graft surgery. J Cardiothorac Vasc Anesth 2000; 14: 113–8Ramsey, SD Saint, S Sullivan, SD Dey, L Kelley, K Bowdle, A
Gómez CM, Palazzo MG: Pulmonary artery catheterization in anaesthesia and intensive care. Br J Anaesth 1998; 81: 945–56Gómez, CM Palazzo, MG
Hines R, Griffin M: Pulmonary artery catheterization, Clinical Monitoring: Practical Applications for Anesthesia and Critical Care. Edited by Lake CL, Hines RL, Blitt CD. Philadelphia, Saunders, 2001, pp 204–36
Jastremski MS, Chelluri L, Beney KM, Bailly RT: Analysis of the effects of continuous on-line monitoring of mixed venous oxygen saturation on patient outcome and cost-effectiveness. Crit Care Med 1989; 17: 148–53Jastremski, MS Chelluri, L Beney, KM Bailly, RT
Vedrinne C, Bastien O, De Varax R, Blanc P, Durand PG, Du Gres B, Bouvier H, Saroul C, Lehot JJ: Predictive factors for usefulness of fiberoptic pulmonary artery catheter for continuous oxygen saturation in mixed venous blood monitoring in cardiac surgery. Anesth Analg 1997; 85: 2–10Vedrinne, C Bastien, O De Varax, R Blanc, P Durand, PG Du Gres, B Bouvier, H Saroul, C Lehot, JJ
Orlando R 3rd: Continuous mixed venous oximetry in critically ill surgical patients:“High-tech” cost-effectiveness. Arch Surg 1986; 121: 470–1Orlando, R
Larson LO, Kyff JV: The cost-effectiveness of Oximetrix pulmonary artery catheters in the postoperative care of coronary artery bypass graft patients. J Cardiothorac Anesth 1989; 3: 276–9Larson, LO Kyff, JV
Pearson KS, Gomez MN, Moyers JR, Carter JG, Tinker JH: A cost/benefit analysis of randomized invasive monitoring for patients undergoing cardiac surgery. Anesth Analg 1989; 69: 336–41Pearson, KS Gomez, MN Moyers, JR Carter, JG Tinker, JH
Cernaianu AC, DelRossi AJ, Boatman GA, Moore MW, Posner MA, Cilley JH Jr, Baldino WA, Santos ZL: Continuous venous oximetry for hemodynamic and oxygen transport stability post cardiac surgery. J Cardiovasc Surg (Torino) 1992; 33: 14–20Cernaianu, AC DelRossi, AJ Boatman, GA Moore, MW Posner, MA Cilley, JH Baldino, WA Santos, ZL
Colonna-Romano P, Horrow JC: Dissociation of mixed venous oxygen saturation and cardiac index during opioid induction. J Clin Anesth 1994; 6: 95–8Colonna-Romano, P Horrow, JC
Jubran A, Mathru M, Dries D, Tobin MJ: Continuous recordings of mixed venous oxygen saturation during weaning from mechanical ventilation and the ramifications thereof. Am J Respir Crit Care Med 1998; 158: 1763–9Jubran, A Mathru, M Dries, D Tobin, MJ
Shroyer AL, London MJ, VillaNueva CB, Sethi GK, Marshall G, Moritz TE, Henderson WG, McCarthy MJ Jr, Grover FL, Hammermeister KE: The Processes, Structures, and Outcomes of Care in Cardiac Surgery study protocol. Med Care 1995; 33: OS17–25Shroyer, AL London, MJ VillaNueva, CB Sethi, GK Marshall, G Moritz, TE Henderson, WG McCarthy, MJ Grover, FL Hammermeister, KE
Grover FL, Shroyer AL, Hammermeister KE: Calculating risk and outcome: The Veterans Affairs database. Ann Thorac Surg 1996; 62: S6–11Grover, FL Shroyer, AL Hammermeister, KE
Daley J, Henderson WG, Khuri SF: Risk-adjusted surgical outcomes. Annu Rev Med 2001; 52: 275–87Daley, J Henderson, WG Khuri, SF
Higgins TL, Estafanous FG, Loop FD, Beck GJ, Lee JC, Starr NJ, Knaus WA, Cosgrove DMR: ICU admission score for predicting morbidity and mortality risk after coronary artery bypass grafting. Ann Thorac Surg 1997; 64: 1050–8Higgins, TL Estafanous, FG Loop, FD Beck, GJ Lee, JC Starr, NJ Knaus, WA Cosgrove, DMR
London MJ, Shroyer AL, Coll JR, MaWhinney S, Fullerton DA, Hammermeister KE, Grover FL: Early extubation following cardiac surgery in a veterans population. A nesthesiology 1998; 88: 1447–58London, MJ Shroyer, AL Coll, JR MaWhinney, S Fullerton, DA Hammermeister, KE Grover, FL
Hanley JA, McNeil BJ: The meaning and use of the area under a receiver operating characteristic (ROC) curve. Radiology 1982; 143: 29–36Hanley, JA McNeil, BJ
Hosmer DW, Taber S, Lemeshow S: The importance of assessing the fit of logistic regression models: A case study. Am J Public Health 1991; 81: 1630–5Hosmer, DW Taber, S Lemeshow, S
Shroyer AL, London MJ, Sethi GK, Marshall G, Grover FL, Hammermeister KE: Relationships between patient-related risk factors, processes, structures, and outcomes of cardiac surgical care: Conceptual models. Med Care 1995; 33: OS26–34Shroyer, AL London, MJ Sethi, GK Marshall, G Grover, FL Hammermeister, KE
London MJ, Shroyer AL, Grover FL, Sethi GK, Moritz TE, Henderson WG, VillaNueva CB, Tobler HG, McCarthy MJJ, Hammermeister KE: Evaluating anesthesia health care delivery for cardiac surgery: The role of process and structure variables. Med Care 1995; 33: OS66–75London, MJ Shroyer, AL Grover, FL Sethi, GK Moritz, TE Henderson, WG VillaNueva, CB Tobler, HG McCarthy, MJJ Hammermeister, KE
Hammermeister KE, Shroyer AL, Sethi GK, Grover FL: Why it is important to demonstrate linkages between outcomes of care and processes and structures of care. Med Care 1995; 33: OS5–16Hammermeister, KE Shroyer, AL Sethi, GK Grover, FL
Hammermeister KE, Burchfiel C, Johnson R, Grover FL: Identification of patients at greatest risk for developing major complications at cardiac surgery. Circulation 1990; 82: IV380–9Hammermeister, KE Burchfiel, C Johnson, R Grover, FL
Daley J, Khuri SF, Henderson W, Hur K, Gibbs JO, Barbour G, Demakis J, Irvin GR, Stremple JF, Grover F, McDonald G, Passaro E Jr, Fabri PJ, Spencer J, Hammermeister K, Aust JB, Oprian C: Risk adjustment of the postoperative morbidity rate for the comparative assessment of the quality of surgical care: Results of the National Veterans Affairs Surgical Risk Study. J Am Coll Surg 1997; 185: 328–40Daley, J Khuri, SF Henderson, W Hur, K Gibbs, JO Barbour, G Demakis, J Irvin, GR Stremple, JF Grover, F McDonald, G Passaro, E Fabri, PJ Spencer, J Hammermeister, K Aust, JB Oprian, C
Gibbs J, Cull W, Henderson W, Daley J, Hur K, Khuri SF: Preoperative serum albumin level as a predictor of operative mortality and morbidity: Results from the National VA Surgical Risk Study. Arch Surg 1999; 134: 36–42Gibbs, J Cull, W Henderson, W Daley, J Hur, K Khuri, SF
London MJ, Shroyer ALW, Grover FL: Fast tracking into the new millenium: An evolving paradigm (editorial). A nesthesiology 1999; 91: 936–44London, MJ Shroyer, ALW Grover, FL
Butterworth J, James R, Prielipp RC, Cerese J, Livingston J, Burnett DA: Do shorter-acting neuromuscular blocking drugs or opioids associate with reduced intensive care unit or hospital lengths of stay after coronary artery bypass grafting? CABG clinical benchmarking data base participants. A nesthesiology 1998; 88: 1437–46Butterworth, J James, R Prielipp, RC Cerese, J Livingston, J Burnett, DA
Seguin P, Colcanap O, Le Rouzo A, Tanguy M, Guillou YM, Malledant Y: Evaluation of a new semi-continuous cardiac output system in the intensive care unit. Can J Anaesth 1998; 45: 578–83Seguin, P Colcanap, O Le Rouzo, A Tanguy, M Guillou, YM Malledant, Y
Zollner C, Polasek J, Kilger E, Pichler B, Jaenicke U, Briegel J, Vetter HO, Haller M: Evaluation of a new continuous thermodilution cardiac output monitor in cardiac surgical patients: A prospective criterion standard study. Crit Care Med 1999; 27: 293–8Zollner, C Polasek, J Kilger, E Pichler, B Jaenicke, U Briegel, J Vetter, HO Haller, M
Chaney MA, Durazo-Arvizu RA, Fluder EM, Sawicki KJ, Nikolov MP, Blakeman BP, Bakhos M: Port-access minimally invasive cardiac surgery increases surgical complexity, increases operating room time, and facilitates early postoperative hospital discharge. A nesthesiology 2000; 92: 1637–45Chaney, MA Durazo-Arvizu, RA Fluder, EM Sawicki, KJ Nikolov, MP Blakeman, BP Bakhos, M
Plomondon ME, Cleveland JC, Ludwig ST, Grunwald GK, Kiefe CI, Grover FL, Shroyer AL: Off-pump coronary artery bypass is associated with improved risk-adjusted outcomes. Ann Thorac Surg 2001; 72: 114–9Plomondon, ME Cleveland, JC Ludwig, ST Grunwald, GK Kiefe, CI Grover, FL Shroyer, AL
Hayes MA, Timmins AC, Yau EH, Palazzo M, Hinds CJ, Watson D: Elevation of systemic oxygen delivery in the treatment of critically ill patients. N Engl J Med 1994; 330: 1717–22Hayes, MA Timmins, AC Yau, EH Palazzo, M Hinds, CJ Watson, D
Gattinoni L, Brazzi L, Pelosi P, Latini R, Tognoni G, Pesenti A, Fumagalli R: A trial of goal-oriented hemodynamic therapy in critically ill patients. SvO2 Collaborative Group. N Engl J Med 1995; 333: 1025–32Gattinoni, L Brazzi, L Pelosi, P Latini, R Tognoni, G Pesenti, A Fumagalli, R
Heyland DK, Cook DJ, King D, Kernerman P, Brun-Buisson C: Maximizing oxygen delivery in critically ill patients: A methodologic appraisal of the evidence. Crit Care Med 1996; 24: 517–24Heyland, DK Cook, DJ King, D Kernerman, P Brun-Buisson, C
Polonen P, Ruokonen E, Hippelainen M, Poyhonen M, Takala J: A prospective, randomized study of goal-oriented hemodynamic therapy in cardiac surgical patients. Anesth Analg 2000; 90: 1052–9Polonen, P Ruokonen, E Hippelainen, M Poyhonen, M Takala, J
Concato J, Shah N, Horwitz RI: Randomized, controlled trials, observational studies, and the hierarchy of research designs. N Engl J Med 2000; 342: 1887–92Concato, J Shah, N Horwitz, RI
Joffe MM, Rosenbaum PR: Invited commentary: Propensity scores. Am J Epidemiol 1999; 150: 327–33Joffe, MM Rosenbaum, PR
Dalen JE: The pulmonary artery catheter-friend, foe or accomplice? (editorial). JAMA 2001; 286: 348–50Dalen, JE
Fig. 1. Distribution of mixed venous oxygen saturation–pulmonary artery catheterization (ST̄vo2-PAC) use by hospital as a percentage of patients analyzed.
Fig. 1. Distribution of mixed venous oxygen saturation–pulmonary artery catheterization (ST̄vo2-PAC) use by hospital as a percentage of patients analyzed.
Fig. 1. Distribution of mixed venous oxygen saturation–pulmonary artery catheterization (ST̄vo2-PAC) use by hospital as a percentage of patients analyzed.
×
Fig. 2. Mean number (± SD) of arterial blood gas (ABG) and thermodilution cardiac output (CO) measurements performed in the first 24 h postoperatively. Hospital codes are same as those used in figure 1.
Fig. 2. Mean number (± SD) of arterial blood gas (ABG) and thermodilution cardiac output (CO) measurements performed in the first 24 h postoperatively. Hospital codes are same as those used in figure 1.
Fig. 2. Mean number (± SD) of arterial blood gas (ABG) and thermodilution cardiac output (CO) measurements performed in the first 24 h postoperatively. Hospital codes are same as those used in figure 1.
×
Table 1. Preoperative Variables by PAC Type
Image not available
Table 1. Preoperative Variables by PAC Type
×
Table 2. Intraoperative Variables by PAC Type
Image not available
Table 2. Intraoperative Variables by PAC Type
×
Table 3. Postoperative Variables by PAC Type
Image not available
Table 3. Postoperative Variables by PAC Type
×
Table 4. Mortality Model
Image not available
Table 4. Mortality Model
×
Table 5. Any Postoperative Complication Model
Image not available
Table 5. Any Postoperative Complication Model
×
Table 6. Cardiac Complications Model
Image not available
Table 6. Cardiac Complications Model
×
Table 7. Time to Extubation Model
Image not available
Table 7. Time to Extubation Model
×
Table 8. Intensive Care Unit Duration of Stay Model
Image not available
Table 8. Intensive Care Unit Duration of Stay Model
×
Table 9. Number of Arterial Blood Gases (ABG) and Thermodilution Cardiac Outputs (TdCO) Performed in the First 24 h Postoperatively
Image not available
Table 9. Number of Arterial Blood Gases (ABG) and Thermodilution Cardiac Outputs (TdCO) Performed in the First 24 h Postoperatively
×