Coronary Angiography and Angioplasty after Acute Myocardial Infarction

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Articles in PubMed by Author:

	Bates, D. W.

	Leape, L. L.

REVIEW

Coronary Angiography and Angioplasty after Acute Myocardial Infarction

David W. Bates, MD, MSc; Elizabeth Miller, BS; Steven J. Bernstein, MD; Paul J. Hauptman, MD; and Lucian L. Leape, MD

1 April 1997 | Volume 126 Issue 7 | Pages 539-550

Purpose: To assess the data that support the use of coronaryangiography and angioplasty after acute myocardial infarction,that identify the risks of these procedures, and that analyzetheir use and costs.

Data Sources: English-language articles published between 1970and June 1995 identified through a search of the MEDLINE database.

Study Selection: Studies that contained information about benefits,risks, use, and costs of coronary angiography and angioplastyafter acute myocardial infarction.

Data Extraction: Descriptive and analytic data from each studywere collected.

Data Synthesis: The outcome for patients who have complicationsof myocardial infarction (such as shock) is poor. Such patientsusually undergo angiography, although the evidence that supportsthis practice is weak. Preliminary data suggest that patientswho immediately have angiography and angioplasty after acutemyocardial infarction have better outcomes than do patientswho receive thrombolytic therapy with angioplasty only for specificindications in experienced centers. After the acute phase ofmyocardial infarction, patients who have noninvasive evidenceof persistent or recurrent ischemia are believed to benefitfrom angiography. In the remaining patients, however, angiographyafter myocardial infarction has not been shown to be beneficial.Coronary angiography is done in 30% to 81% of patients afteracute myocardial infarction in different settings and regions;for many of these patients, the benefit is questionable. Betteroutcomes are not always associated with more frequent use ofthe procedure. In the United States, catheterizations aftermyocardial infarction cost approximately $1 billion per year.

Conclusions: Although many patients benefit from angiographyand angioplasty after myocardial infarction, others probablydo not. Substantial resources are at stake.

Coronary angiography may be done during or after myocardialinfarction for diagnostic or therapeutic purposes. The proceduresare usually done to identify coronary disease that is amenableto coronary revascularization. Therefore, the randomized trialsthat have evaluated the benefit of coronary angiography aftermyocardial infarction have focused on percutaneous transluminalcoronary angioplasty or coronary artery bypass graft surgeryrather than on whether to do angiography [1].

Nevertheless, it may be equally important to evaluate the diagnosticprocess [2] because interventions closely follow diagnostictests in what has been called a "clinical cascade" [3]. Verrilliand Welch [2] found strong correlations between rates of diagnostictests and subsequent use of therapeutic procedures. For example,the correlation between cardiac catheterization and coronaryrevascularization was 0.91, which suggests that decisions aboutdiagnostic tests may be as important as decisions about coronarytherapeutic procedures.

Whether angiography after myocardial infarction is appropriatedepends on the efficacy of subsequent interventions. Studieshave evaluated the use of angioplasty as an alternative to thrombolytictherapy (primary angioplasty) or in conjunction with thrombolytictherapy at various times: immediately (as soon as possible afteronset of symptoms), early (within several hours after myocardialinfarction to any time before discharge), or delayed (afterdischarge but within 12 weeks of myocardial infarction) [4].In the period immediately after myocardial infarction, angiographycan be done routinely (that is, on patients in whom revascularizationis not contraindicated) or after the development of such specificcomplications as recurrent chest pain or shock. After discharge,angiography can also be done routinely, in subsets of symptomaticpatients, or when results of noninvasive tests are positive.Strategies in which angiography and, if feasible, angioplastywere done immediately have usually been compared with strategiesin which they were done before discharge, within the next severalweeks, or not routinely.

The appropriateness of angiography also depends on whether thrombolyticagents have been or can be given and the length of time thathas elapsed since the onset of symptoms (Table 1). Althoughthrombolytic therapy has been shown to be effective for thetreatment of myocardial infarction in several clinical situations,it is contraindicated in some patients and its effectivenessdepends on how soon it is given after myocardial infarction[41, 42]. Thrombolytic therapy is most effective if it is administeredwithin 0 to 6 hours after the onset of symptoms [42]. Althoughthe benefit of thrombolytic therapy decreases over time, thistherapy remains effective for at least 12 hours [42-44].

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Table 1. Structure of Review*

We analyze data on the use of coronary angiography after acutemyocardial infarction; we also assess the use of angioplasty.The report is structured on the basis of the timing of the proceduresafter myocardial infarction and whether thrombolytic agentshave been or can be given. We also include information on therisks, costs, and use of angiography and angioplasty.

Methods

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Methods
Author & Article Info
References

We included information from articles that were published from1970 through June 1995. For the period from 1970 to 1989, werelied heavily on a literature review that had been preparedfor an expert panel on coronary angiography [45]. We focusedon studies that contained information on benefits, risks, use,and costs of coronary angiography and angioplasty after acutemyocardial infarction. Studies were categorized by whether thrombolyticagents had been given and by the amount of time that had elapsedafter myocardial infarction (0 to 6 hours, 6 to 12 hours, morethan 12 hours but before discharge, and after discharge butbefore 12 weeks). Because the effectiveness of angiography inpatients who have had myocardial infarction is largely determinedby the effectiveness of reestablishing coronary patency, wealso reviewed information on the efficacy of thrombolytic therapyand coronary artery bypass graft surgery.

We identified the articles by searching MEDLINE. The searchincluded only English-language articles that had been publishedfrom 1970 through June 1995. To identify other articles, thebibliographies of all articles that were identified in the MEDLINEsearch were evaluated. The members of an expert panel on coronaryangiography evaluated the bibliography and literature reviewfor accuracy and completeness. The panel, which was part ofthe Acute Myocardial Infarction Patient Outcome Research Team(PORT) study, had convened to update the ratings of appropriatenessfor angiography in patients who had had acute myocardial infarction.Our search terms included the following Medical Subject Headings:myocardial infarction, indications; angiography; angioplasty;angioplasty, transluminal, percutaneous coronary; thrombolytictherapy; coronary artery bypass; and randomized controlled.

Data Synthesis

Timing of Angiography and Angioplasty and Relation to Thrombolytic Therapy

Within 6 Hours of Myocardial Infarction, No Thrombolytic Therapy

Through 1995, seven randomized trials had compared immediateangiography and angioplasty without thrombolytic therapy (primaryangioplasty) with thrombolytic therapy in acute myocardial infarction[5-12]. In a multicenter study, Grines and colleagues [5] foundthat in-hospital mortality rates for patients who had primaryangioplasty (2.6%) were lower than those for patients who receivedthrombolytic therapy (6.5%); however, this difference was notstatistically significant. The difference in survival was largestin the group that was at highest risk. After 6 months, 8.5%of the group receiving primary angioplasty and 16.8% of thegroup receiving thrombolytic therapy had had reinfarction orhad died. In a smaller, single-center study, Zijlstra and colleagues[6] found that primary angioplasty resulted in a higher infarct-relatedartery patency rate, better left ventricular function, and lessrecurrent ischemia and myocardial infarction than did intravenousstreptokinase. In preliminary results of the angioplasty substudyof the GUSTO (Global Use of Strategies to Open Occluded CoronaryArteries) study [46], patients who had had angioplasty had alower rate for the end points of death, disabling stroke, orreinfarction (9.6%) than did patients who had received the mosteffective thrombolytic therapy regimen (13.1%) (P = 0.06).

In a meta-analysis that included all seven trials that comparedprimary angioplasty with thrombolytic therapy (except the recentGUSTO study), Michels and Yusuf [4] reported lower 6-week mortalityrates in patients who were treated with angioplasty (odds ratio,0.56 [95% CI, 0.33 to 0.94]) but no significant difference in1-year mortality rates (odds ratio, 0.91 [CI, 0.42 to 2.00]).The results of trials in which death or nonfatal reinfarctionwas the outcome were similar (Figure 1, top left). Data fromlonger follow-up periods are not yet available. Despite thesepromising results, access to primary angioplasty is logisticallydifficult; only about 15% of hospitals have rapidly available,experienced angioplasty teams [47]. Moreover, in a recent observationalstudy that was done in a community setting and compared theoutcome of 1050 patients who received primary angioplasty withthat of 2095 patients who received thrombolytic therapy, Everyand coworkers [48] found no difference in mortality rates duringhospitalization or during long-term follow-up. These researchersalso noted that costs were lower and that angioplasty was doneless frequently in the thrombolytic therapy group at dischargeand after 3 years of follow-up.

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Figure 1. Summary odds ratios and 95% Cls for outcomes after percutaneous transluminal coronary angioplasty (PTCA) compared with other therapies. Lower odds ratios show a benefit for using the first strategy compared with the second. Only odds ratios that do not include 1 are statistically significant; this was the case for the 6-week end points for immediate PTCA compared with thrombolysis only. Outcome category 1 is death at 6 weeks, outcome category 2 is death or nonfatal infarction at 6 weeks, outcome category 3 is death at 1 year, and outcome category 4 is death or nonfatal reinfarction at 1 year. Immediate PTCA includes trials that compare immediate PTCA (primary angioplasty) with thrombolytic agents. Aggressive PTCA includes trials of immediate, early, delayed, and rescue angioplasty compared with no angioplasty. Routine means that angioplasty was done on almost all patients as a routine strategy. Elective means that PTCA was done late as an elective procedure. Adapted from Michels and Yusuf [4]. MI = myocardial infarction.

Thrombolytic therapy is strongly contraindicated in as manyas 20% of patients who have had acute myocardial infarction[14]. No randomized trials have compared angioplasty with noninvasivetherapy in patients who have strong contraindications to thrombolyticagents; however, several case series report good primary successrates for angioplasty in such patients [13-15]. Two studiesalso report good 1-year survival rates [14, 15].

Two controlled trials of early coronary artery bypass graftsurgery from the pre-thrombolytic era found that patients whowere treated surgically had a lower 30-day in-hospital mortalityrate (2.2%) than did those who were treated medically (11.1%)[49, 50]. As with angioplasty, however, few hospitals can provideimmediate bypass surgery.

Within 6 Hours of Myocardial Infarction, after Thrombolytic Therapy

Most studies of angiography and angioplasty after myocardialinfarction have focused on the use of these procedures afterthrombolysis [16-2427-29, 37]. Many studies have shown thatthrombolytic therapy can preserve myocardium and improve survivalrates [42-44, 51-54]. Overall, the evidence suggests that aftermyocardial infarction has been treated with thrombolytic agents,routine immediate angiography and routine angioplasty are associatedwith no significant benefit and may be harmful. However, immediateangiography and angioplasty may be useful in specific subgroupsthat have such complications as angina and shock after myocardialinfarction.

The TIMI (Thrombolysis in Myocardial Infarction) II-A study[32, 33] addressed the use of angiography after thrombolytictherapy in patients who had had myocardial infarction. Thisstudy compared three treatment strategies: immediate invasive,delayed invasive, and conservative. With the immediate invasivestrategy, angiography and angioplasty (if indicated) were doneas early as possible. With the delayed invasive strategy, routineangiography was done between 18 and 48 hours after thrombolytictherapy. With the conservative strategy, angiography and angioplasty(if it was indicated) were done only if the patient developedspontaneous or exercise-induced ischemia. The 24-hour complicationrate for patients who received the immediate invasive strategywas significantly higher (8.5%) than that for patients who receivedthe delayed invasive strategy (4.6%); no benefit for other majorend points was shown. Patients who received the conservativestrategy had outcomes that were equal to those for patientswho received the delayed invasive strategy for major outcomes:6-week survival (95.3% in the conservative group compared with94.8% in the delayed invasive group), absence of reinfarction(93.5% in the conservative group compared with 93.1% in thedelayed invasive group), and ejection fraction at discharge(49.9% in the conservative group compared with 50.5% in thedelayed invasive group); therapy for patients in the conservativegroup was also less expensive.

The SWIFT (Should We Intervene Following Thrombolysis) trial[29] compared an invasive strategy with a conservative approachafter thrombolytic therapy. The invasive strategy was earlyelective angioplasty (within 48 hours). Patients in the conservativegroup had angiography only if they had recurrent ischemic symptomsor positive results on exercise tests. At 3 months, mortalityrates were similar between the conservative group (3.2%) andthe invasive group (4.8%); ejection fraction was also similar.Thus, the results of the SWIFT trial confirmed those of theTIMI II-A study [32, 33].

In the first TAMI (Thrombolysis and Angioplasty in MyocardialInfarction) trial [20], patients who were randomly assignedto receive immediate angioplasty had a higher mortality rate(4%) than patients who were assigned to the delayed strategy(1%). However, the TAMI-5 study showed that an aggressive strategyof catheterization and selective angioplasty had good results[34, 35]. The aggressive strategy was associated with improvedregional wall motion in the infarct region (P = 0.004) and feweradverse outcomes (P = 0.004).

Two small trials of rescue angioplasty have been reported [30, 31].In these trials, patients who had persistent occlusionof the infarction-related artery after thrombolytic therapywere randomly assigned to angioplasty or continued medical management.When Michels and Yusuf [4] combined the data from these trials,trends reflecting improved 6-week mortality rates (odds ratio,0.38 [CI, 0.13 to 1.06]) and 1-year mortality rates (odds ratio,0.17 [CI, 0.02 to 1.15]) were seen.

Thus, the data suggest that routine, immediate angioplasty doneafter thrombolytic therapy has little benefit and may be harmful.Rescue angioplasty seems promising, but not many patients havebeen studied.

Six to 12 Hours after Myocardial Infarction, No Thrombolytic Therapy

No randomized trials of angiography or angioplasty have focusedspecifically on this period.

Six to 12 Hours after Myocardial Infarction, Thrombolytic Therapy

Two trials [43, 44] reported an advantage for thrombolytic therapywhen it is administered 6 to 12 hours after myocardial infarction,but the benefit is smaller than if this therapy is administered0 to 6 hours after myocardial infarction. No trials examiningangiography or angioplasty have focused specifically on thisperiod.

More Than 12 Hours after Myocardial Infarction but before Discharge, No Thrombolytic Therapy

No recent randomized trials on angiography or angioplasty specificallyaddress this group.

More Than 12 Hours after Myocardial Infarction but before Discharge, after Thrombolytic Therapy

Five trials have examined angioplasty [22-2427-29, 37] donemore than 12 hours after myocardial infarction in patients whoreceived thrombolytic therapy. As noted earlier, the TIMI II-Aand SWIFT trials (in which such patients constituted a majority)found that the clinical outcomes of conservative strategiesin which angiography was reserved for patients who had recurrentsymptoms or positive results on exercise tests were similarto the outcomes of aggressive strategies but were less expensive[29, 32, 33]. Efforts to identify subgroups that are at highrisk have met with only limited success [35, 55]. When Michelsand Yusuf [4] combined the data from all five trials, conservativeand invasive strategies did not differ in 1) mortality rateor 2) nonfatal reinfarction or mortality rate at either 6 weeksor 1 year.

After Discharge from the Hospital but before 12 Weeks

Three trials [38-40] compared a strategy of routine catheterization(catheterization in all patients) and angioplasty (if feasible)done 2 to 14 days after thrombolytic therapy with a strategyof thrombolytic therapy alone [39, 40] followed by angioplastythat was done only in patients who had ischemia and stenosisof 50% or greater [38]. Some of the patients had not been discharged.Michels and Yusuf [4] combined the results of these trials.Compared with the conservative group, the invasive group showeda trend toward increased mortality rates at 6 weeks (odds ratio,1.33 [CI, 0.49 to 3.63]) and significantly increased mortalityrates at 1 year (odds ratio, 6.79 [CI, 1.32 to 35.03]).

After a patient is discharged from the hospital, reasons fordoing angiography change. Factors that predict higher morbidityand mortality rates are the presence of recurrent or persistentchest pain, extent of coronary disease, results of such noninvasivetests as exercise tests and nuclear imaging studies, and leftventricular ejection fraction [56-74].

No trials have addressed the efficacy of routine angiographyand angioplasty after discharge from the hospital for patientswho did not receive thrombolytic therapy. Although some evidencesupports the efficacy of angiography and angioplasty in patientswho have angina or myocardial ischemia after myocardial infarction,no data suggest that angiography and angioplasty are effectivein patients who do not have these conditions [45].

Results of Trials of Percutaneous Transluminal Angioplasty after Thrombolytic Therapy

To ascertain whether individual trials of angioplasty lack thepower to determine the effectiveness of angioplasty, Michelsand Yusuf [4] did a metaanalysis of trials of angioplasty thathad been done for acute myocardial infarction at various timesafter thrombolytic therapy [16-2427-29, 37]. When the resultsfor immediate, early, delayed, and rescue angioplasty were comparedwith those for no angioplasty, 6-week mortality rates, 1-yearmortality rates, and 6-week and 1-year mortality or nonfatalreinfarction rates were similar (aggressive angioplasty, Figure 1,top left). Comparisons between routine angioplasty (regardlessof the presence of ischemia) or elective angioplasty (angioplastydone if it was medically indicated, such as for ischemia) withoutangioplasty also showed no difference in 6-week and 1-year mortalityrates and mortality or nonfatal reinfarction rates (Figure 1,bottom). The few data that are currently available show no 5-yearsurvival benefit from angioplasty done after thrombolytic therapy[4].

Angiography in Patients Who Have Complications of Myocardial Infarction

Complications of myocardial infarction that may increase thebenefit of angiography and revascularization include persistentchest pain, mitral regurgitation, ventricular septal defect,shock, and persistent pulmonary edema.

Persistent Chest Pain

Patients who develop persistent chest pain after myocardialinfarction have a greater risk for extension of the infarctionand death than other patients [75-77]. In major randomized trials,patients with chest pain have usually had angiography. Althoughno data from randomized trials have proven its efficacy, angiographyis probably effective in this setting [78].

Noninvasive Evidence of Mitral Regurgitation or Ventricular Septal Defect

Cardiac catheterization is useful for assessing the severityof mitral regurgitation or ventricular septal defect if surgeryis being considered [78, 79], and angiography is almost alwaysdone at the same time to assess the severity of coronary disease.No randomized trials have addressed the efficacy of angiographyin patients who have these complications.

Shock or Persistent Pulmonary Edema

Mortality rates are high in patients who have been in shockor have had persistent pulmonary edema after myocardial infarction[26, 32, 33, 80]. Because these patients often have poor outcomesand represent a small proportion of all patients, their ratesof complication are often reported together. Patients with shockhave been excluded from many trials [34]. Patients with shockor pulmonary edema were included in the TIMI-II trial, but thepercentages of patients were low: One percent of patients hadhad pulmonary edema, and 1.5% had been in shock [26]. Outcomesfor such patients did not differ from those for other patientsin the TIMI-II trial, regardless of the management strategy.However, the power of these results was limited. The outcomeswith conventional and thrombolytic therapy are often poor inpatients with shock or pulmonary edema. If direct angioplastyis done, however, survival rates for these patients are betterthan those for historical controls [81].

Other Factors That Affect the Decision To Do Angiography

Many factors are associated with worse outcomes after myocardialinfarction. These factors include worse left ventricular function,increased age, presence of three-vessel coronary disease, previousmyocardial infarction, non-Q-wave infarction, female sex, historyof smoking, and presence of diabetes [82]. Whether to do angiographypartly depends on the factors that are present in a given patient.However, no widely used scale similar to the Parsonnet Index(a validated index that summarizes risk factors to predict theoutcome of coronary artery bypass surgery) is available to summarizerisk factors and to predict complications of angiography orbenefits of revascularization [83]. Kimmel and associates [84]developed and validated an index to predict major complicationsof angioplasty (emergency coronary bypass surgery, myocardialinfarction, or death). Risk factors in the index include multivesseldisease, unstable angina, myocardial infarction within 24 hours(odds ratio, 2.2), type C lesion or left main angioplasty, shock,age, and aortic valve disease. The index stratifies patientsinto groups with low (complication rate, 1.3%), moderate (2.8%),high (12.7%), and very high (29.7%) risk. We present data onhow factors associated with poor postinfarction prognosis affectoutcomes after myocardial infarction. Patients whose outcomesare predicted to be worse can generally be expected to respondbetter to aggressive intervention.

Severe Left Ventricular Dysfunction

Ejection fraction is a strong predictor of early and long-termoutcome after myocardial infarction [70, 85-87]. Ejection fractionindependently predicted in-hospital mortality in the TAMI study[86]. As shown in a study by the European Cooperative StudyGroup [87], the 1-year mortality rate was 8.2% in patients whohad an ejection fraction less than 40% but was only 1.8% inthe group with an ejection fraction greater than 40%. Angiographyis often done to identify patients who have decreased left ventricularfunction and three-vessel disease because such patients wereshown to have improved survival rates after coronary arterybypass grafting in the Coronary Artery Surgery Study [88]. However,this study did not specifically address patients who had recentlyhad myocardial infarction.

Age

Increased age was associated with higher mortality rates aftermyocardial infarction in the TIMI-II and TAMI trials as wellas several other studies [86, 89, 90]. Udvarhelyi and colleagues[91] found that 30-day mortality rates increased from 19% forthe group of patients who were 65 to 74 years of age to 38%for patients who were 85 years of age or older. Elderly patientshave often been excluded from trials of thrombolytic therapybecause they are presumed to have a greater risk for bleeding[81]. Several age cutoffs have been used, but 70 or 75 yearsof age is the most frequently used cutoff. However, elderlypatients probably benefit from thrombolytic therapy even thoughtheir risk is greater. In the primary angioplasty trials, benefitsthat were seen as a result of angioplasty were more marked inelderly patients [5]. Compared with thrombolytic therapy, directangioplasty has not been associated with a greater risk forbleeding complications in elderly patients, although death associatedwith angioplasty is increased [81].

Stress-Induced Myocardial Ischemia

The TIMI-II and SWIFT trials found that when patients were stratifiedby risk according to the results of noninvasive studies, outcomeswere equally good in conservative and invasive treatment groups.However, functional testing in patients who have received thrombolysismay not be as sensitive for identifying a myocardium with reversibleinjury as it is in patients who have not received thrombolysis[79]. This concern is supported by studies that found that functionaltesting after thrombolysis did not predict reinfarction or death[18, 79, 92].

Non-Q-wave Myocardial Infarction

Studies from the pre-thrombolytic era showed that patients whohad had non-Q-wave infarctions had high rates of recurrent myocardialinfarction [93]. In the TIMI-II study [93], 29% of patientshad had non-Q-wave infarctions, and no differences were seenin death or reinfarction rates between the aggressive and conservativepost-thrombolytic strategies. A main goal of the TIMI-IIIB study[94] was to compare an early invasive strategy with a more conservativestrategy in patients who had had non-Q-wave myocardial infarctionor unstable angina. At 1 year, no difference in death or nonfatalinfarction was seen between groups. However, angioplasty wasdone more frequently in the early invasive group (39%) thanin the conservative group (32%) (P < 0.001), and more patientsfrom the conservative group were subsequently hospitalized (33%)than were those from the early invasive group (26%) (P <0.05). Outcomes for the patients who had had non-Q-wave infarctionswere generally similar in the invasive and conservative groups.However, 73% of patients in the conservative group had angiographywithin 1 year. Taken together, these data suggest that eithera conservative or an aggressive approach may be acceptable,depending on the preference of the patient.

Previous Myocardial Infarction

In the TIMI-II trial [26], patients who had previously had myocardialinfarction had a higher 42-day mortality rate (8.8%) than thosewho had not previously had infarction (4.3%) (P < 0.001).However, this trial was a subgroup analysis; much of this differencemay have been the result of a lower ejection fraction in patientswho had previously had myocardial infarction (42%) than in thosewho had not (48%) (P < 0.001) and a higher prevalence ofmultivessel coronary disease in patients who had previouslyhad myocardial infarction (60%) than in those who had not (28%).

Complications of Coronary Angiography and Angioplasty

Complications of coronary angiography include death, myocardialinfarction, stroke, ventricular arrhythmia, vascular complications,and contrast reactions. When Bernstein and colleagues [45] combinedthe results of reports about complications for patients whohave had angiography, they found rates of 0.1% for death, 0.07%for myocardial infarction and stroke, 0.47% for ventriculararrhythmia, and 0.59% for vascular complications.

For angioplasty, the usual definition of major complicationsincludes myocardial infarction, coronary complications leadingto bypass surgery, and death [95]. Combining data from reportspublished in the late 1980s, Hilborne and coworkers [95] reportedmyocardial infarction rates of 3% to 5% (with transmural infarctionrates of 1% to 2%), mortality rates of approximately 1%, andemergency surgery rates of 2% to 4%. These rates have tendedto decrease over time [96]; recent rates reported from largeseries are 0.9% to 1% for death, 1.5% to 5.2% for myocardialinfarction, and 1.0% to 2.7% for emergency bypass surgery [97, 98].

Patients who have angioplasty or angiography soon after myocardialinfarction have a higher risk for complications than do otherpatients. For angioplasty, Kimmel and associates [84] foundthe multivariate odds ratio for myocardial infarction within24 hours to be 2.2 (CI, 1.25 to 3.86). However, for myocardialinfarction within the previous 1 to 14 days, the odds ratiowas only 0.73 (CI, 0.46 to 1.16). For angiography (Table 2),all available estimates have wide CIs because few studies havereported each outcome of angiography [45]. Five studies haveexamined angiography that was done soon after myocardial infarction(generally 24 to 72 hours); most of these studies were donein the early 1980s and reported complications after angiography[18, 99-102]. The mortality rate related to angiography was0.97%, 10 times that for all patients; the rate of ventriculararrhythmia was 9.3%, 20 times that for all patients. For angiographythat was done 1 to 8 weeks after myocardial infarction, themortality rate was 0.22%, the myocardial infarction rate was0.83%, the stroke rate was 0.53%, and the ventricular arrhythmiarate was 1.06%. However, these data were obtained from fewerthan 1000 patients. The rates are higher than those reportedfor catheterizations in general; the mortality rate was twiceas high, the myocardial infarction rate was eight times higher,and the stroke rate was five times higher. However, most ofthese data are now more than 10 years old. Because catheterizationtechniques have improved, absolute rates of complications maycurrently be lower. However, differences between risk afterrecent myocardial infarction and risk after routine catheterizationprobably persist.

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Table 2. Complications in Patients Who Had Coronary Angiography after Myocardial Infarction*

Use of Coronary Angiography and Angioplasty

In 1992, 1 084 000 inpatient cardiac catheterizations were donein the United States, making this the second most frequent surgicalprocedure done in patients who were discharged after short hospitalstays [103]. In 1992, 369 000 angioplasties were done in thisgroup [103]. In 1994, about 10% of catheterizations were donein patients who had a Diagnosis-Related Group code for acutemyocardial infarction [104]. Among patients who had angioplastyin New York in 1990, 2.5% had the procedure done within 6 hoursof myocardial infarction and 24% had it done 6 hours to 21 daysafter myocardial infarction [105].

Rates of angiography and revascularization after myocardialinfarction seem to be increasing in the elderly. Between 1987and 1990, the percentage of patients older than 65 years ofage who had angiography after myocardial infarction increasedfrom 24% to 33%, the bypass surgery rate increased from 8% to11%, and the angioplasty rate doubled from 5% to 10% [106].

Geographic variation in the use of angiography and revascularizationhas been seen in the United States and abroad. In the SAVE (Survivaland Ventricular Enlargement) trial [107], 68% of patients inthe United States who had had myocardial infarction subsequentlyhad angiography compared with 35% of patients in Canada. Revascularizationprocedures were also used more often in the United States. Thesedifferences were not associated with any difference in mortalityor reinfarction rates, but the incidence of activity-limitingangina was higher in Canada (33%) than in the United States(27%). In the GUSTO trial [108] (which also compared use ofangiography in the United States and Canada), Canadian patientshad a lower rate of angiography (25%) than did U.S. patients(72%), were less likely to have angioplasty (11%) than wereU.S. patients (29%), and were less likely to have coronary arterybypass graft surgery (3%) than were U.S. patients (14%). Inthis study, Canadian patients also had worse functional statusand more symptoms at 1 year than did U.S. patients: The prevalenceof chest pain was 34% in Canadian patients and 21% in U.S. patients,and the prevalence of dyspnea was 45% in Canadian patients and29% in U.S. patients.

Rates of cardiac catheterization and revascularization alsovary among different areas of the United States. In 1987, thecatheterization rate was 323 per 100 000 patients in the Midwestcompared with 173 per 100 000 patients in the West [45]. Piloteand associates [109] used the GUSTO-1 data to evaluate variationin the management of patients who had had acute myocardial infarctionand found that the proportion of patients who had various cardiacprocedures substantially differed among regions. Angiographywas done in 52% to 81% of patients, angioplasty was done in22% to 35% of patients, and coronary artery bypass graft surgerywas done in 9% to 17% of patients. Among eight regions, theuse of these procedures was lowest in New England. In everyregion but New England, the use of procedures was closely relatedto their availability. Procedure rates did not seem to be relatedto rates of recurrent myocardial infarction or mortality at30 days or 1 year. The study did not evaluate whether increaseduse of angiography and revascularization resulted in a betterquality of life.

To address quality-of-life issues and rates of reinfarctionand mortality, Guadagnoli and colleagues [110] compared theuse of cardiac procedures after acute myocardial infarctionin the Medicare populations in New York and Texas. Coronaryangiography was done 50% more often in Texas (45% of patients)than in New York (30% of patients). However, the adjusted mortalityrate for a period of 2 years was significantly lower in NewYork (hazard ratio, 0.87 [CI, 0.78 to 0.98]), and patients inTexas were 41% more likely to report angina and 62% more likelyto say they that could not do activities that required 5 ormore metabolic equivalents at 2 years than were patients inNew York. The lower rate of angiography in New York probablyreflects tighter regulatory control exercised by the state'sDepartment of Health certificate of need process and supervisionby its Cardiac Advisory Committee. Guadagnoli and colleagues[110] suggest that differences in long-term results may be aneffect of different patterns of care after myocardial infarction,such as the greater use of ß-blockers in New York.

Cost of Coronary Angiography and Angioplasty

The cost of coronary angiography includes the cardiac catheterizationlaboratory fee, professional fees, room charges, cost of repeatinginadequate studies, and cost of complications [45]. MetropolitanLife reported that in 1992, the mean charge for inpatient cardiaccatheterization for their beneficiaries was $10 880 [111]; totalcharges varied from $6400 in Maryland to $17 600 in California.Assuming a figure of $10 000, total annual charges for cardiaccatheterization in the United States would be $10 billion, andcharges after myocardial infarction would be approximately $1billion. These figures reflect the assumption that coronaryangiography would be done as an inpatient procedure. Althoughit can be done safely as an outpatient procedure at lower cost[112-116], angiography is associated with greater risk whenit is done after myocardial infarction. Thus, the procedureis usually done on an inpatient basis.

A 1993 study estimated that charges of angioplasty were approximately$15 000 [117]. Assuming that about 400 000 such procedures aredone per year, the charges in the United States would be $6billion; about 25%, or $1.5 billion of the total amount, wouldbe for care of patients after myocardial infarction. Using datafrom 1992 to 1993, one study [97] estimated that the medianin-hospital cost of angioplasty was $9176.

Different strategies for the use of angiography after myocardialinfarction may have a substantial effect on costs. The TIMI-IIstudy compared the costs of the conservative strategy with thoseof the invasive strategy. The conservative strategy avoided50% of coronary angiograms, and the investigators estimatedthe potential savings to be more than $700 million per year[79]. The actual cost data showed that the average total costsper hospital admission were $10 496 for the invasive strategyand $8826 for the conservative strategy [118].

Conclusions

Decisions about how to use coronary angiography after myocardialinfarction have substantial implications for clinical factorsand use of resources because they are closely linked with coronaryrevascularization procedures. Expert panels support the useof angiography after myocardial infarction in patients who havecomplications and in patients who have recurrent symptoms ornoninvasive evidence of ischemia. The data that support thisapproach vary by indication and are often equivocal; however,outcomes are poor without revascularization, and angiographyis probably beneficial. The potential benefits of primary angioplastyover thrombolytic therapy in patients who have had acute myocardialinfarction are being vigorously debated [119, 120]. Small randomizedtrials suggest that short-term outcomes after angioplasty arebetter in centers that have substantial experience with theprocedure, but a recent large observational study did not finda similar benefit [48]. This may partly be because rapid thrombolytictherapy is easier to administer than immediate angioplasty.Recent data suggest that outcomes vary substantially, particularlywithin the first 2 hours, depending on the amount of time thathas elapsed before the artery opens [121].

Use of angiography and angioplasty varies substantially acrossregions. The findings from the TIMI-II study (that the conservativestrategy reduced the number of angiographies by 50% withoutan increase in mortality rates) suggest that coronary angiographyis currently done in many patients whose outcome is unlikelyto be improved as a result of the procedure. Substantial resourcesare at stake: The total charges for catheterization after myocardialinfarction are approximately $1 billion per year; this figuredoes not include the cost of the coronary revascularizationprocedures that follow.

Dr. Bernstein: University of Michigan Medical Center, Divisionof General Medicine, 3116 Taubman Center, Ann Arbor, MI 48109.

Dr. Hauptman: Division of Cardiology, Brigham and Women's Hospital,75 Francis Street, Boston, MA 02115.

Dr. Leape: Department of Health Policy and Management, HarvardSchool of Public Health, 677 Huntington Avenue, Boston, MA 02115.

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From Brigham and Women's Hospital and Harvard School of Public Health, Boston, Massachusetts; and University of Michigan Medical Center, Ann Arbor, Michigan.
Acknowledgments: The authors thank George Beller, MD, Gottlieb C. Friesinger, MD, Spencer B. King 3d, MD, Thomas J. Ryan, MD, and Eric J. Topol, MD, for their comments on an earlier version of this manuscript.
Grant Support: By research grant R01-HS08071-02 from the Agency for Health Care Policy and Research.
Requests for Reprints: David W. Bates, MD, MSc, Division of General Medicine and Primary Care, Brigham and Women's Hospital, 75 Francis Street, Boston, MA 02115.
Current Author Addresses: Dr. Bates and Ms. Miller: Division of General Medicine and Primary Care, Brigham and Women's Hospital, 75 Francis Street, Boston, MA 02115.

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