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Routine invasive strategies versus selective invasive strategies for unstable angina and non‐ST elevation myocardial infarction in the stent era

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Background

People with unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI) are managed with a combination of medical therapy, invasive angiography and revascularisation. Specifically, two approaches have evolved: either a 'routine invasive' strategy whereby all patients undergo coronary angiography shortly after admission and, if indicated, coronary revascularisation; or a 'selective invasive' (also referred to as 'conservative') strategy in which medical therapy alone is used initially, with a selection of patients for angiography based upon evidence of persistent myocardial ischaemia. Uncertainty exists as to which strategy provides the best outcomes for these patients. This Cochrane review is an update of a Cochrane review originally published in 2006, to provide a robust comparison of these two strategies in the early management of patients with UA/NSTEMI.

Objectives

To determine the benefits and harms associated with the following.
1. A routine invasive versus a conservative or 'selective invasive' strategy for the management of UA/NSTEMI in the stent era.
2. A routine invasive strategy with and without glycoprotein IIb/IIIa receptor antagonists versus a conservative strategy for the management of UA/NSTEMI in the stent era.

Search methods

We searched the following databases and additional resources up to 25 August 2015: the Cochrane Central Register of Controlled Trials (CENTRAL) on the Cochrane Library, MEDLINE and EMBASE, with no language restrictions.

Selection criteria

We included prospective randomised controlled trials (RCTs) that compared invasive with conservative or 'selective invasive' strategies in participants with acute UA/NSTEMI.

Data collection and analysis

Two review authors screened the records and extracted data in duplicate. Using intention‐to‐treat analysis with random‐effects models, we calculated summary estimates of the risk ratio (RR) with 95% confidence intervals (CIs) for the primary endpoints of all‐cause death, fatal and non‐fatal myocardial infarction (MI), combined all‐cause death or non‐fatal MI, refractory angina and re‐hospitalisation. We performed further analysis of included studies based on whether glycoprotein IIb/IIIa receptor antagonists were used routinely. We assessed the heterogeneity of included trials using Pearson χ² (Chi² test) and variance (I² statistic) analysis. Using the Grading of Recommendations Assessment, Development and Evaluation (GRADE) approach, we assessed the quality of the evidence and the GRADE profiler (GRADEPRO) was used to import data from Review Manager 5.3 (Review Manager) to create Summary of findings (SoF) tables.

Main results

Eight RCTs with a total of 8915 participants (4545 invasive strategies, 4370 conservative strategies) were eligible for inclusion. We included three new studies and 1099 additional participants in this review update. In the all‐study analysis, evidence did not show appreciable risk reductions in all‐cause mortality (RR 0.87, 95% CI 0.64 to 1.18; eight studies, 8915 participants; low quality evidence) and death or non‐fatal MI (RR 0.93, 95% CI 0.71 to 1.2; seven studies, 7715 participants; low quality evidence) with invasive strategies compared to conservative (selective invasive) strategies at six to 12 months follow‐up. There was appreciable risk reduction in MI (RR 0.79, 95% CI 0.63 to 1.00; eight studies, 8915 participants; moderate quality evidence), refractory angina (RR 0.64, 95% CI 0.52 to 0.79; five studies, 8287 participants; moderate quality evidence) and re‐hospitalisation (RR 0.77, 95% CI 0.63 to 0.94; six studies, 6921 participants; moderate quality evidence) with routine invasive strategies compared to conservative (selective invasive) strategies also at six to 12 months follow‐up.

Evidence also showed increased risks in bleeding (RR 1.73, 95% CI 1.30 to 2.31; six studies, 7584 participants; moderate quality evidence) and procedure‐related MI (RR 1.87, 95% CI 1.47 to 2.37; five studies, 6380 participants; moderate quality evidence) with routine invasive strategies compared to conservative (selective invasive) strategies.

The low quality evidence were as a result of serious risk of bias and imprecision in the estimate of effect while moderate quality evidence was only due to serious risk of bias.

Authors' conclusions

In the all‐study analysis, the evidence failed to show appreciable benefit with routine invasive strategies for unstable angina and non‐ST elevation MI compared to conservative strategies in all‐cause mortality and death or non‐fatal MI at six to 12 months. There was evidence of risk reduction in MI, refractory angina and re‐hospitalisation with routine invasive strategies compared to conservative (selective invasive) strategies at six to 12 months follow‐up. However, routine invasive strategies were associated with a relatively high risk (almost double the risk) of procedure‐related MI, and increased risk of bleeding complications. This systematic analysis of published RCTs supports the conclusion that, in patients with UA/NSTEMI, a selectively invasive (conservative) strategy based on clinical risk for recurrent events is the preferred management strategy.

PICOs

Population
Intervention
Comparison
Outcome

The PICO model is widely used and taught in evidence-based health care as a strategy for formulating questions and search strategies and for characterizing clinical studies or meta-analyses. PICO stands for four different potential components of a clinical question: Patient, Population or Problem; Intervention; Comparison; Outcome.

See more on using PICO in the Cochrane Handbook.

Plain language summary

Routine invasive versus conservative strategies for unstable angina and non‐ST elevation myocardial infarction in the stent era

Background

People with prolonged or recurrent chest pain may have a condition called unstable angina (UA) or suffer a certain type of heart attack called non‐ST elevation myocardial infarction (NSTEMI). People with either of these two conditions may be managed by either one of two treatment strategies: the routine invasive strategy, or the conservative or 'selective invasive strategy'. With the first approach, patients have a catheter (a long, patent tube) inserted into the arteries that bring blood to the heart muscle itself, called the coronary arteries. The main objective behind inserting this catheter (in other words, to perform a procedure called coronary angiography) is to look for thickening and hardening of the vessel. If a significant narrowing or a complicated plaque is found, then the artery may be dilated by inserting a balloon catheter that can be inflated wherever the vessel is particularly narrow, so as to open the vessel and improve blood flow. The vessel is held open by inserting a metallic stent. In some cases, the region of vessel narrowing is not amenable to this approach and surgery to bypass it is required. With the other, conservative or 'selective invasive' strategy, patients are initially treated with drugs, and only those who continue to suffer further chest pain or who demonstrate evidence of ongoing coronary artery narrowing via other non‐invasive tests, such as stress testing or imaging, undergo coronary angiography and revascularisation if indicated. In this Cochrane review, researchers examined the available evidence to determine which strategy is better.

Study characteristics

We included randomised controlled trials that compared routine invasive strategies to conservative strategies in patients with UA and NSTEMI in the stent era. We searched the available literature up to 25 August 2015.

Key results

We included eight studies with 8915 participants: five trials were in the review version published in 2010, and three were new trials. Of the included participants with UA and NSTEMI, there were 4545 in the invasive strategy arm and 4370 in the conservative strategy arm. Evidence failed to show appreciable risk reduction in all‐cause mortality and death or non‐fatal myocardial infarction (MI) with routine invasive management strategy compared to conservative strategies. There was appreciable risk reduction in MI, refractory angina and re‐hospitalisation with routine invasive strategies compared to conservative strategies, but this was associated with an increased risk of procedure‐related MI and bleeding complications.

Quality of evidence for primary outcomes

The quality of the evidence in this review update ranged from low quality to moderate quality. Low quality evidence was as a result of serious risk of bias and uncertainty surrounding the effect, while moderate quality evidence was only due to serious risk of bias.

Conclusions

The debate continues as to which strategy is better. The invasive strategy reduces the incidence of further chest pain or re‐hospitalisation. Also, long‐term follow‐up from three studies suggests that it lowers the risk of a heart attack over the next three to five years. However, the invasive strategy also is associated with double the risk of heart attack during or soon after initial treatment, as well as an increased risk of bleeding. In summary, the published scientific research suggests that the invasive strategy may have particular benefit in those patients who are at high risk for recurrent events, and that patients at low risk for a recurrent event may even suffer harm from such an approach.

Authors' conclusions

Implications for practice

The most important new finding of this Cochrane review update is the identification of a significantly increased risk of index death with a routine invasive approach. Conversely, consistent with previous versions of this review (Hoenig 2006; Hoenig 2010), adopting a routine invasive strategy for the management of UA/NSTEMI patients results in a significant reduction in risk, from six to 12 months of follow‐up, for the two endpoints of refractory angina and rehospitalisation. While the invasive strategy is associated with an almost two‐fold increase in the risk of peri‐procedural myocardial infarction (MI), the data also suggest a significant risk reduction in the rate of MI assessed at three to five years. The importance of peri‐procedural infarction continues to be a subject of dispute, with recent suggestions that this endpoint lacks prognostic significance. Hence, the early risks associated with a routine invasive strategy must be weighed against potential long‐term benefits in clinical endpoints. However, longer term follow‐up of more contemporary trials may find this benefit to be attenuated with more optimal use of medical therapies, the deployment of more rigorous risk stratification protocols in the days immediately following onset of the acute event, and a more conservative/selective invasive approach with high invasive percentages. The benefits of a routine invasive strategy may be more meaningful in higher‐risk patients, among whom the number needed to treat for an additional beneficial outcome (NNTB) should be less.

The increased risk of index death noted with the inclusion of the Italian Elderly ACS and the LIPSIA‐NSTEMI trials in this review update must be interpreted in the context of the disproportionate representation of populations with known adverse predictors. Increased mortality risk has been associated with both elderly populations (Italian Elderly ACS) and routine glycoprotein IIb/IIIa inhibitor use (LIPSIA‐NSTEMI), both of which contribute to excess event rates among people treated using a routinely invasive strategy. A more considered approach in the elderly population and a selective use of glycoprotein IIb/IIIa inhibitors is now recommended in most international guidelines (Hamm 2011; Jneid 2012). The finding that inclusion of two such populations resulted in an overall increase in index mortality rate associated with an invasive strategy strengthens the current recommendations. Due to the attendant bleeding risk and subsequent increased morbidity/mortality, glycoprotein IIb/IIIa inhibitors should only be used selectively in people undergoing invasive treatment. Similarly, in elderly populations, a selective invasive approach is appropriate, as invasive interventions carry increased risk, with decisions based upon markers of risk — in particular, troponin status.

In the all‐study analysis, evidence incorporating intermediate endpoints with all included studies (or most of the studies) failed to show appreciable benefit with invasive strategies for unstable angina and non‐ST elevation MI compared to conservative strategies in all‐cause mortality and death or non‐fatal MI at six to 12 months. Evidence showed risk reduction in MI, refractory angina and rehospitalisation with routine invasive strategies compared to conservative (selective invasive) strategies at six to 12 months follow‐up. However, routine invasive strategies were seen to be associated with a relatively high risk (almost double the risk) of procedure‐related MI, and increased risk of bleeding complications. This systematic analysis of published RCTs supports the conclusion that, in people with unstable angina and non‐ST elevation MI (UA/NSTEMI), a selectively invasive (conservative) strategy based on clinical risk for recurrent events is the preferred management strategy.

Implications for research

This Cochrane review highlights the need for further research on treatment strategies for UA/NSTEMI. To date, published trials have enrolled heterogeneous populations of patients with variable levels of risk and event rates, subjected to a variety of co‐interventions, and used outcome measures subject to variable definition and timing. Risk stratification of the participants in each trial based upon a validated risk system (e.g. the TIMI risk score) would allow for more meaningful meta‐analyses of available data, and provide a risk score or an absolute event rate above which an invasive strategy is expected to significantly improve outcomes. Clearly as medical therapies for UA/NSTEMI improve, progressively less absolute benefit is likely to be gained via aggressive interventions. Hence, the level of baseline risk at which an invasive intervention becomes warranted is likely to be a moving target. Another major limitation to the analyses undertaken in this review is the under‐powering of trials in terms of assessing the effects of an invasive strategy on all‐cause mortality, due to the short length of follow‐up. Inadequate numbers also hinder the interpretation of subgroup analyses. This could be addressed in future clinical trials by ensuring that sufficient events accrue by way of larger sample sizes, the enrolment of higher‐risk participants, and longer durations of follow‐up. Finally, further research is required to better define the benefits and hazards of an invasive strategy in females.

Given the support for a routine invasive strategy in the management of non‐ST‐elevation ACS, it has become difficult to justify the inclusion of a selectively invasive (conservative) arm when designing RCTs, and this is reflected in the paucity of recent research comparing a selective versus routine invasive approach. However, our findings suggest that including a selectively invasive arm is required. Using a routine invasive strategy amongst the elderly requires particular investigation. In light of the results of the ACUITY and EARLY ACS 2009 studies, studies responsible for discrediting the routine use of glycoprotein IIb/IIIa inhibitors as part of an invasive strategy, it is also prudent to re‐evaluate conservative and invasive management strategies in light of the significant potential confounding effect observed in a number of influential studies. Indeed, these studies warrant repeating, albeit employing a highly‐selective glycoprotein IIb/IIIa inhibitor strategy.

Summary of findings

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Summary of findings for the main comparison. Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial (UA/NSTEMI) infarction in the stent era

Routine invasive strategies versus selective invasive strategies (conservative) for UA/NSTEMI infarction in the stent era

Participant or population: participants with UA/NSTEMI in the stent era
Settings: hospital setting
Intervention: routine invasive strategies
Comparison: selective invasive strategies (conservative)

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

Number of participants
(studies)

Quality of the evidence
(GRADE)

Assumed risk

Corresponding risk

Selective invasive strategies (conservative)

Routine invasive strategies

Death
Follow‐up: 6 to 12 months1

Study population

RR 0.87
(0.64 to 1.18)

8915
(8 studies)

⊕⊕⊝⊝
low2,3

42 per 1000

36 per 1000
(27 to 49)

Moderate risk population

39 per 1000

34 per 1000
(25 to 46)

Myocardial infarction
Follow‐up: 6 to 12 months1

Study population

RR 0.79
(0.63 to 1)

8915
(8 studies)

⊕⊕⊕⊝
moderate2

78 per 1000

62 per 1000
(49 to 78)

Moderate risk population

89 per 1000

70 per 1000
(56 to 89)

Death or non‐fatal Myocardial infarction
Follow‐up: 6 to 12 months1

Study population

RR 0.93
(0.71 to 1.2)

7715
(7 studies)

⊕⊕⊝⊝
low2,3

113 per 1000

105 per 1000
(80 to 135)

Moderate risk population

109 per 1000

101 per 1000
(77 to 131)

Refractory angina
Follow‐up: 6 to 12 months1

Study population

RR 0.64
(0.52 to 0.79)

8287
(5 studies)

⊕⊕⊕⊝
moderate2

325 per 1000

208 per 1000
(169 to 257)

Moderate risk population

129 per 1000

83 per 1000
(67 to 102)

Rehospitalisation
Follow‐up: 6 to 12 months1

Study population

RR 0.77
(0.63 to 0.94)

6921
(6 studies)

⊕⊕⊕⊝
moderate2

286 per 1000

220 per 1000
(180 to 269)

Moderate risk population

122 per 1000

94 per 1000
(77 to 115)

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% CI) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
Abbreviations: CI: confidence interval; RR: risk ratio; UA: unstable angina; NSTEMI: non ST segment myocardial infarction.

GRADE Working Group grades of evidence
High quality: further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: we are very uncertain about the estimate.

1 Intermediate end points.
2 Downgraded by one due to possible risk of bias due to lack of blinding.
3 Downgraded by one due to imprecision with effect size overlapping the line of no effect and appreciable benefit or harm.

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Summary of findings 2. Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI) in the stent era

Routine invasive strategies versus selective invasive strategies (conservative) for UA/NSTEMI in the stent era

Participant or population: participants with UA/NSTEMI in the stent era
Settings: hospital setting
Intervention: routine invasive strategies
Comparison: selective invasive strategies (conservative)

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

Number of participants
(studies)

Quality of the evidence
(GRADE)

Assumed risk

Corresponding risk

Selective invasive strategies (conservative)

Routine invasive strategies

Complications of angiography or revascularization
Bleeding

Study population

RR 1.73
(1.3 to 2.31)

7584
(6 studies)

⊕⊕⊕⊝
moderate1

42 per 1000

72 per 1000
(54 to 96)

Moderate risk population

27 per 1000

47 per 1000
(35 to 62)

Complications of angiography or revascularization
Procedure‐related myocardial infarction

Study population

RR 1.87
(1.47 to 2.37)

6380
(5 studies)

⊕⊕⊕⊝
moderate1

30 per 1000

57 per 1000
(45 to 72)

Moderate risk population

29 per 1000

54 per 1000
(43 to 69)

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% CI) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
Abbreviations: CI: confidence interval; RR: risk ratio; UA: unstable angina; NSTEMI: non ST segment myocardial infarction.

GRADE Working Group grades of evidence
High quality: further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: we are very uncertain about the estimate.

1 Downgraded by one due to possible risk of bias due to lack of blinding.

Background

Diagnosis of acute coronary syndromes

Acute coronary syndrome (ACS) encompasses three disorders of related aetiology: ST‐elevation myocardial infarction (STEMI); non‐STEMI (NSTEMI); and unstable angina (UA). Management of STEMI differs from that for UA and NSTEMI, which can be considered a single clinical entity (UA/NSTEMI). The pathogenesis of UA/NSTEMI involves five non‐exclusive causative factors: non‐occlusive thrombus on pre‐existing plaque; dynamic obstruction; progressive mechanical obstruction; inflammation; and secondary UA associated with increased cardiac workload (Braunwald 1998). Of these factors, thrombus formation on pre‐existing plaque, which is an acute plaque change, is the most common. Indeed, most patients with ACS have an acute change in coronary atherosclerotic plaques, with STEMI usually associated with complete occlusion of the involved vessel(s) (DeWood 1980) and UA/NSTEMI usually associated with subtotal occlusion (DeWood 1986; TIMI‐IIIA 1993). The distinction between UA and NSTEMI depends on the presence of myocardial infarction (MI), as determined by markers of myocardial damage such as troponin I (TnI), troponin T (TnT) and creatine kinase‐myocardial band (CK‐MB).

Compared to STEMI, NSTEMI has a lower 30‐day mortality rate, but more recurrent ischaemia and a similar one‐year mortality rate (Armstrong 1998). UA/NSTEMI is much more common than STEMI; in the USA, for example, 1.4 million patients per year are admitted to hospital with ACS, approximately 70% of them with UA/NSTEMI (Rosamond 2008). Whereas emergency percutaneous coronary revascularisation is now a commonly‐used therapy for treating STEMI (Antman 2004; Cucherat 2003), the role of angiography and possible subsequent revascularisation is less clear in UA/NSTEMI patients. Treatment of UA/NSTEMI initially involves medical therapy followed by one of two variations on the management strategy, which results in differing rates of angiography and revascularisation. In this Cochrane review update we review the medical therapies for UA/NSTEMI briefly before we focus on the management strategies of patients with UA/NSTEMI.

Initial medical management of UA/NSTEMI

Medical treatments, as outlined in the American College of Cardiology Foundation (ACCF) and American Heart Association (AHA) (Anderson 2007; Jneid 2012) and European Society of Cardiology (ESC) guidelines (Hamm 2011), fall into the two major categories: anti‐ischaemic and anti‐platelet/anti‐coagulation. Anti‐ischaemic therapies include bed rest, nitroglycerin, beta blockers (or certain non‐dihydropyridine calcium antagonist if beta blockers are contraindicated) and angiotensin‐converting enzyme (ACE) inhibitors. Anti‐platelet or anti‐coagulation therapies include aspirin, P2Y12 receptor inhibitor treatment (clopidogrel, prasugrel and ticagrelor), heparin and glycoprotein IIb/IIIa receptor antagonists. Published randomised clinical trials support the use of most of these specific therapies. Among the anti‐ischaemic treatments, beta blockers have proven efficacy in patients with evolving MI (Hjalmarson 1982; Yusuf 1988), as well as in patients with UA/NSTEMI (Gottlieb 1986; Muller 1984; Théroux 1985). Non‐dihydropyridine calcium channel antagonists have proven efficacy in ACS (Boden 1991; Gibson 1986; Pepine 1998; Tijssen 1987), and are particularly useful in patients with contraindications to beta‐blockers. Both the early and late administration of ACE inhibitors can be beneficial for MI (EUROPA 2003; HOPE 2000; Rodrigues 2003). Of the anti‐platelet or anti‐coagulation treatments, aspirin exhibits a consistent benefit for UA/NSTEMI as demonstrated in several clinical trials (Cairns 1985; Lewis 1983; RISC 1990; Theroux 1988). Similarly, clopidogrel is a beneficial adjunct to aspirin (CURE 2001). Subsequently, prasugrel, TRITON‐TIMI 38, and ticagrelor, PLATO, have been identified as alternatives to clopidogrel. Heparin, in its various forms, or fondaparinux are also beneficial in UA/NSTEMI (Gurfinkel 1995; Mehta 2008; Neri Serneri 1990; RISC 1990; Theroux 1993). The glycoprotein IIb/IIIa receptor antagonists have proven efficacy in the medical treatment of UA/NSTEMI (Boersma 2002; PRISM‐PLUS Trial; PURSUIT 1998; Roffi 2002; Topol 1999). However, this class of drugs appears to have differential effects depending on the patients' risk level and bleeding propensity, and high‐risk patients obtain the greatest benefit; consequently, their use should be highly‐selective (ACUITY; EARLY ACS 2009). The glycoprotein IIb/IIIa receptor antagonists warrant special mention regarding their use in invasive procedures. We expand upon this concept later in this review update.

Management following initial medical treatment: what is the role of early coronary angiography and revascularization?

Two different treatment strategies may be adopted after the initial medical treatment of UA/NSTEMI.

  1. A routine invasive strategy of coronary angi ography and, if indicated, revascularisation in most or all patients who have no contraindication to such an approach.

  2. A 'selective invasive' or 'ischaemia guided' (conservative) strategy, in which patients undergo coronary angiography and revascularisation only if there is evidence of recurrent ischaemia. Examples are recurrent infarction, angina at rest, dynamic ST changes on electrocardiograph (ECG), and definitive inducible ischaemia on provocative testing.

Proponents of the routine invasive strategy argue that the early determination of coronary anatomy can be used to tailor revascularisation therapy, avoid lengthy hospital stays and prevent further events. Those with significant coronary disease evident on angiography can be treated expeditiously according to their angiographic findings, which may include revascularisation via percutaneous coronary intervention (PCI) comprised of coronary angioplasty and coronary stenting, or coronary artery bypass grafting (CABG). Proponents of the conservative or 'selective invasive' strategy argue that medical therapy can stabilise patients. Stress testing can identify patients at risk for future events and who would therefore benefit most from an invasive intervention. This strategy may also limit the costs and complications of invasive procedures. The evidence for the relative advantages and disadvantages of these two approaches is the subject of this Cochrane review.

Interpretation of the evidence from trials: changes in contemporary clinical practice

In routine clinical practice, the outcomes of invasive coronary procedures vary depending upon a number of factors, including clinical expertise (Singh 2000), volume of procedures performed (Magid 2000), and methods and protocols used, especially regarding pharmacological and procedural co‐interventions. Of particular importance in contemporary practice is the use of coronary artery stents (Al Suwaidi 2004), which improves outcomes and reduces complications when used with invasive procedures. Stenting is associated with fewer major adverse cardiovascular events and a reduced need for emergency cardiac surgery (Al Suwaidi 2004). Specifically, the reduction in target vessel revascularisation associated with stenting is of particular relevance to trials with longer durations of follow‐up.

Upstream glycoprotein IIb/IIIa receptor antagonist use is controversial. Though these drugs initially seemed beneficial (EPIC 1994; EPILOG 1997; EPISTENT 1998; Karvouni 2003; Simoons 1997), their routine application has been associated with an increased risk of non‐life‐threatening bleeding (ACUITY; EARLY ACS 2009), which has resulted in a paradigm shift from routine to highly‐selective use. In the ACUITY study, patients with UA/NSTEMI treated with an early invasive strategy, bivalirudin without routine glycoprotein IIb/IIIa receptor antagonists, demonstrated significantly reduced rates of major bleeding with non‐inferior outcomes in ischaemia endpoints compared to standard heparin or bivalirudin with mandatory glycoprotein IIb/IIIa receptor antagonists (Stone 2006; Stone 2007). However, the substitution of bivalirudin for heparin with glycoprotein IIb/IIIa receptor antagonists probably should not be undertaken unless patients have been pretreated with a thienopyridine prior to angiography (Stone 2006).

Why it is important to do this review

UA/NSTEMI is a common hospital presentation and carries a significant risk of mortality and recurrent ischaemic events. Older landmark meta‐analyses (Bavry 2006; Mehta 2005) include pre‐stent era trials and do not consider more recently published studies, and thus limit their application to contemporary management of this serious disease. This Cochrane review evaluates the relative merits of the two above‐noted strategies in the modern era with relevance to patients, physicians and healthcare systems.

Objectives

To determine the benefits and harms associated with the following.

  1. A routine invasive versus a conservative or 'selective invasive' strategy for the management of UA/NSTEMI in the stent era.

  2. A routine invasive strategy with and without glycoprotein IIb/IIIa receptor antagonists versus a conservative strategy for the management of UA/NSTEMI in the stent era.

Methods

Criteria for considering studies for this review

Types of studies

We only considered studies undertaken in the stent era for inclusion. If we had included non‐stent studies, the analysis would underestimate the benefits of a routine invasive strategy on endpoints such as recurrent angina and rehospitalisation (e.g. due to chest pain). We included randomised controlled trials (RCTs) that compared invasive and selectively invasive strategies in participants with unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI), and measured at least one of this review's outcomes. The revascularisation approaches in the included studies were percutaneous coronary intervention (PCI) or coronary artery bypass grafting (CABG), as required. We investigated the effect of glycoprotein IIb/IIIa receptor antagonist use on outcomes further by undertaking two separate analyses on trials according to routine versus selective use of glycoprotein IIb/IIIa receptor antagonists during PCI. Thus, the analyses we undertook were as follows.

  1. All studies that deployed stents routinely in revascularisation procedures using PCI, regardless of glycoprotein IIb/IIIa receptor antagonist use.

  2. Stents and glycoprotein IIb/IIIa receptor antagonists deployed routinely in revascularisation procedures using PCI.

  3. Stents deployed routinely in revascularisation procedures using PCI with selective glycoprotein IIb/IIIa receptor antagonists use.

It is important to note that, in recent years, a number of studies have focused on the optimal timing of an invasive strategy. While these studies fulfil many of the criteria for inclusion, often they did not randomise patients to a medically‐managed conservative or 'selective invasive' strategy. Consequently, we have generally excluded these studies from the current analysis.

Types of participants

Men and women, at least 18 years of age, who had an episode of angina with an accelerating pattern of pain at rest. The index episode of pain must have occurred within 72 hours of randomisation. Furthermore, the patients must have exhibited at least one of the following.

  1. New ST depression.

  2. Transient (< 20 minute) ST elevation.

  3. Ischaemic T‐wave inversion or T‐wave inversion in at least two contiguous leads.

  4. Elevated levels of cardiac markers; e.g. troponin's or creatine kinase‐myocardial band (CK‐MB).

  5. Coronary artery disease (CAD), as determined by a history of catheterisation, revascularisation, or acute coronary syndromes (ACS).

The included studies generally excluded patients if they had any of the following.

  1. Persistent ST elevation (i.e. > 20 minutes).

  2. Secondary causes of acute myocardial ischaemia (e.g. anaemia, thyrotoxicosis, acute pulmonary infection, fever, tachyarrhythmias, uncontrolled hypertension).

  3. Secondary causes of cardiac biomarker elevation or altered kinetics (e.g. renal insufficiency, acute non‐cardiac disease etc.).

  4. Serious systemic disease or major co‐morbidities that would preclude an invasive approach.

  5. Severe congestive heart failure or cardiogenic shock.

  6. Arrhythmias that required immediate catheterisation.

  7. Refractory symptoms.

  8. Intolerance of anticoagulation and anti‐platelet therapy.

  9. Coronary revascularization procedure within the previous 30 days.

Types of interventions

All patients with UA/NSTEMI were initially treated with some or all of the medical therapies we discussed in the 'Background' section; we have summarised these in Table 1. Following initial medical therapy, patients were randomised to either routine or selective invasive treatment. The two treatment strategies differed with regard to the use of angiography and subsequent revascularisation rates.

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Table 1. Detailed characteristics of included studies, rates of angiography and revascularisation

Study characteristic

TACTICS‐TIMI 18

ICTUS

RITA‐3

FRISC‐II

VINO

Italian Elderly ACS

LIPSIA‐NSTEMI

OASIS 5

Year of publication

2001

2005

2002

1999

2001

2012

2012

2012

Total number of participants

2220

1200

1810

2457

131

313

602

184

Stent use in invasive arm %

83

88

88

61

47

50

73

52

Men %

66

74

62

70

80

50

67

0

Mean age

62

62

63

65

66

82

70

68

Trial duration

6 months

4 years

5 years

5 years

6 months

1 year

6 months

2 years

Diabetes mellitus %

28

14

13

13

25

36

38

25

Myocardial infarction (MI) on trial enrolment %

54

100

75

58

100

100

100

67

Previous MI %

29

23

28

23

26

31

20

22

ST depression %

39

48

37

46

47

NA

62

47

Mortality in conservatively managed participants at end of follow‐up % (note different trial durations)

3.5

7.7

14

10.1

13.4

13.8

6.5

2.2

Mortality in conservatively managed participants expressed as an average mortality per year of follow‐up %/year

7.0

1.9

2.8

2.0

26.8

13.8

13

1.1

MI rate in conservatively managed participants at end of follow‐up % (note different trial durations)

6.9

12.3 (as per trial definition)

6.2

17.7

14.9

10.7

11.5

13.3

Glycoprotein 2b/3a receptor antagonist use in invasive arm %

94

94

9

10

0

17

99

12

Revascularization at end of follow‐up invasive/conservative %

61/44

81/58

61/38

80/52

78/39

58/31

84/70

64/49

Difference in revascularization rates at end of follow‐up between the 2 strategies %

17

23

23

28

39

27

14

15

Percentage of revascularization procedures in the invasive group being CABG %

22

24

42

41

35

7

10

21

Medical co‐interventions (% of participants enrolled)

Aspirin: 98; unfractionated heparin: 99; beta‐blocker: 82; statin: 52; clopidogrel: 0 (this was a criterion for exclusion)

Aspirin: 100 as per protocol, enoxaparin: 100 as per protocol, statin: 92, clopidogrel: 55

Aspirin: 92; enoxaparin: 84; unfractionated heparin: 11; beta‐blocker: 72; calcium channel antagonist: 35; ACE inhibitor: 18; statin: 45

Aspirin: 93; dalteparin 50; unfractionated heparin: 50; beta‐blocker: 79; calcium channel antagonist: 20; statin: 56

Aspirin: 100 as per protocol, heparin: 100 as per protocol; beta‐blocker: 76; calcium channel antagonist: 9; ACE inhibitor: 47; statin: 43

During index admission: aspirin: 96; ticlopidine: 3.2; clopidogrel: 90; unfractionated heparin: 24; enoxaparin: 50; bivalirudin: 2.5; fondaparinux: 7; at discharge: aspirin: 91; ticlopidine: 2; clopidogrel: 76; beta‐blockers: 60; ACEi: 80; statins: 80

Beta‐blockers: 99; ACEi/ARB: 99; Asprin: 100; clopidogrel/prasugrel: 99; statins: 98; tirofiban: 99

Aspirin: 99; clopidogrel: or ticlopedin: 81; dual antiplatelet therapy: 80; UFH: 10; enoxaparin: 50; fondaparinux: 50; ACE inhibitor or ARB: 76; beta‐blocker: 94; lipid‐lowering drug: 87

The two management strategies compared were as follows.

  1. Routine invasive strategy: routine angiography with or without revascularisation in all patients. This was performed in all eligible patients unless they had contraindications to angiography.

  2. Conservative or 'selective invasive' strategy: angiography with or without revascularisation only in eligible patients with evidence of cardiac ischaemia; e.g. recurrent ischaemia, dynamic electrocardiograph (ECG) changes or a positive stress test.

Revascularisation modalities included PCI or CABG, depending on the angiographic findings. CABG is indicated in lieu of PCI when any one of the following criteria is met.

  • Three vessel disease and an ejection fraction (EF) of less than 0.50.

  • Two vessel disease with proximal left anterior descending involvement and EF of less than 0.50 or ischaemia.

  • Left main CAD.

Types of outcome measures

Primary outcomes

  1. Death: all causes.

  2. Myocardial infarction (MI) (this endpoint only included non‐fatal MI in the review protocol, but the review includes fatal and non‐fatal MI).

  3. Death (all causes) or non‐fatal MI.

  4. Refractory angina.

Secondary outcomes

  1. Rehospitalisation for ACS.

  2. Complications of angiography or revascularisation (e.g. bleeding, procedure‐related MI, stroke).

Differentiating peri‐PCI cardiac biomarker leaks from the outcome measure 'non‐fatal myocardial infarction' warrants further comment. A universal definition of MI, including peri‐procedural MI, has only recently been adopted and defines peri‐procedural MI as a biomarker increase to three times the upper reference limit (Thygesen 2007). Unfortunately, as summarised in Table 2, the included studies inconsistently defined peri‐procedural MI and this limited the interpretation of this outcome data across the included trials. The TACTICS‐TIMI 18, OASIS 5 and Italian Elderly ACS definitions most closely match the current universal definition. Furthermore, not all included studies involved the routine measurement of cardiac biomarkers following PCI. We have discussed this point further under the heading 'Outcomes'.

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Table 2. Definitions of myocardial infarction in the included studies

Study name

Definition for non‐procedural myocardial infarction (MI)

Definition of procedural MI

More than one definition of MI?

Definition of MI used in this review

RITA‐3

Clinical symptoms, ECG changes and CK‐MB or Toponin > 2 x upper limit of normal > 24 hours postrandomisation

Clinical symptoms, ECG changes and CK‐MB or Toponin > 2 x upper limit of normal > 24 hours postrandomisation

Yes

As per trial definition

ICTUS

CK‐MB > upper limit of normal or a 50% decline from a peak value followed by subsequent rise to a value greater than the upper limit of normal. An increased troponin above the upper limit of normal was also used beyond one year of follow‐up

CK‐MB > upper limit of normal or a 50% decline from a peak value followed by subsequent rise to a value greater than the upper limit of normal. New Q waves on the electrocardiogram were used to define MI associated with coronary artery bypass grafting

Yes

In various publications, the trial authors report the MI end point as the following.

  1. Total MI.

  2. Spontaneous MI.

  3. Procedural MI.

We utilized spontaneous MI for our MI endpoint, death/spontaneous MI for our death or MI composite and procedural MI is reported as a safety endpoint. Since the prognostic value of peri‐procedural infarctions is still debated, 'spontaneous' MI is our preferred endpoint since this allows for consistency with the other trials

TACTICS‐TIMI 18

CK‐MB > upper limit of normal or > 50% over previous

CK‐MB > 3 times upper limit of normal or > 50% over previous

No

As per trial definition

Italian Elderly ACS

Cardiac ischaemic symptoms at rest within 42 hours before randomisation, together with Ischemic ECG changes (transient or persistent ST‐segment elevation or depression > 0.5mm but < 1 mm in the case of ST‐elevation, or persistent and definite T‐wave inversion > 1 mm in at least 2 contiguous leads) and/or any elevation of CK‐MB or cTn (> upper limit of normal)

Recurrent infarction within first 72 hours: Ischemic ECG changes (new Q‐waves > 0.04 s in 2 or more contiguous leads which is not an ambiguous change from baseline) CK‐MB > upper limit of normal and increased > 50% over previous value

Following PCI: CK‐MB elevation > 3 times upper limit of normal and increased by at least 50% over the previous value.

In 72 hours following CABG: both biomarker and ECG criteria if the CK‐MB is > 5 times upper limit of normal but < 10 times upper limit of normal; if the cardiac markers are > 10 times upper limit of normal, ECH criteria are not required.

No

As per trial definition

LIPSIA‐NSTEMI

Ischaemic symptoms that were increasing or occurred at rest, with the last episode < 24 hours before randomisation plus elevated troponin T level ≥ 0.1 ng/mL

In‐hospital re‐MI was defined by the occurrence of any of the following: new Q waves in ≥ 2 contiguous leads plus ischaemic symptoms > 20 mins; or new ST‐segment elevation in ≥ 2 contiguous leads plus ischaemic symptoms > 20 mins; or elevation of CK‐MB > 5 upper limit of normal in those with CK‐MB > 5 times upper limit of normal at randomisation an increase > 50% was required for re‐MI definition

No

As per trial definition

VINO

Recurrent ischaemic chest pain lasting > 20 minutes, new ECG changes and CK‐MB > 1.5 times the upper limit of normal after 72 hours postrandomisation

Recurrent ischaemic chest pain lasting > 20 minutes, new ECG changes and CK‐MB > 1.5 times the upper limit of normal after 72 hours postrandomisation

No

As per trial definition

FRISC‐II

Two or three of the following criteria: chest pain, ECG changes or elevated markers of myocardial damage. Marker definitions: CK‐MB mass > upper limit of normal or CK, CK‐B, CK‐MB activity > 2 times upper limit of normal in 1 sample of CK‐MB activity > upper limit of normal in 2 samples

Either 2 or 3 of the following criteria: chest pain, ECG changes or elevated markers of myocardial damage. Marker definitions: CK‐MB mass > 1.5 times upper limit of normal or CK, CK‐B, CK‐MB activity > 3 times upper limit of normal in 1 sample of CK‐MB activity > 2 times upper limit of normal in 2 samples

No

As per trial definition

OASIS 5

Typical rise and fall of biochemical marker of myocardial necrosis (including troponin, CK‐MB, CK) to greater than 2 x ULN (if markers were already elevated, > 50% of the lowest recovery biomarker level from the index infarction) and at least one of the following.

  1. Ischaemic symptoms.

  2. Development of pathological Q waves on ECG.

  3. ECG changes indicative of ischaemia (ST‐segment elevation or depression).

  4. Coronary artery intervention.

  5. Findings of an acute MI at autopsy.

Typical rise and fall of biochemical marker of myocardial necrosis (including troponin, CK‐MB, CK) to greater than 3 x ULN if within 48 hours of PCI or 5 x ULN if within 48 hours of CABG and at least one of the following.

  1. Ischaemic symptoms.

  2. Development of pathological Q waves on ECG.

  3. ECG changes indicative of ischaemia (ST‐segment elevation or depression).

  4. Coronary artery intervention.

  5. Findings of an acute MI at autopsy.

No

As per trial definition

MI = myocardial infarction

Search methods for identification of studies

The previous version of this review (Hoenig 2010) included: the Cochrane Central Register of Controlled Trials (CENTRAL) (Issue 1 of 12, 2008) on the Cochrane Library, MEDLINE (1996 to February 2008) and EMBASE (1996 to February 2008). The review applied a restriction of 1996 onwards because of low rates of stent use prior to that year (see Appendix 1 for search strategies).

This review update utilised similar search strategies for CENTRAL (Issue 7 of 12, 2015) on the Cochrane Library, MEDLINE (OVID, 1946 to August week 3, 2015) and EMBASE (OVID, 1980 to 2015 week 33), restricted from 2008 through to the date of the searches, 25 August 2015 (see Appendix 2 for search strategies). We searched the reference lists of all retrieved articles and contacted experts in the field to identify additional potentially‐eligible studies. We did not apply any language restrictions.

Data collection and analysis

Selection of studies

Two review authors of a previous version of this review (Hoenig 2010)(MRH, JAD) identified and independently selected studies published between 1996 and 2008 for inclusion. Two authors of this review update (JPF, DLW) identified studies published between 2008 and 2015. We considered a study to be eligible for inclusion if it prospectively enrolled eligible participants with an acute presentation of UA/NSTEMI and randomised their management to either a routine invasive strategy or conservative/'selective invasive' strategy in patients with an acute presentation of UA/NSTEMI. We have mentioned specific exclusion criteria in the 'Types of studies' section.

Data extraction and management

Two of the original review authors (MRH, JAD) extracted data from the 1996 to 2008 searches independently onto data extraction sheets. They resolved any disagreements first by consensus and then by consultation with CNA and IAS. We updated the literature searches for the period 2008 to 2015. Two review authors (JPF, DLW) independently extracted relevant data using double data entry.

'Risk of bias' assessment

Two review authors independently assessed the risk of bias in all included studies. Please refer to the 'Characteristics of included studies' tables for the quality assessment guidelines for the included studies.

Statistical considerations

We analysed data on an ITT basis. Where appropriate, we combined data from all trials using the meta‐analysis software in Review Manager (RevMan) (RevMan 2014). All outcome measures of this Cochrane review were dichotomous. We combined data using a random‐effects model to determine a summary estimate of the risk ratio (RR) with a 95% confidence interval (CI). We assessed heterogeneity using the Pearson χ² (Chi²) test (P < 0.10) for all endpoints and the I² statistic for selected endpoints (Higgins 2003). We displayed the I² statistic on the forest plots for all analyses. Furthermore, we performed sensitivity analysis for various prespecified variables that may present sources of inter‐study heterogeneity. Since this meta‐analysis contained a small number of included studies and we previously identified many potential sources of heterogeneity (Hoenig 2010), we did not undertake meta‐regression. As such, we felt that individual patient data meta‐analysis would be more appropriate (Thompson 2005). This also would avoid aggregation bias. Given the discrepant definitions of MI between the included studies (Table 2), we used mortality at end of follow‐up when we assessed publication bias or heterogeneity via sensitivity analysis. As stated under the 'Types of studies' section, we analysed all included studies further by assigning them to one of two analyses, depending on the routine use of glycoprotein IIb/IIIa receptor antagonists. We compared the invasive strategy versus the conservative strategy within each analysis.

Summary of findings

The GRADE approach was employed to interpret findings and the GRADE profiler (GRADEPRO) allowed us to import data from Review Manager 5.3 (Review Manager) to create 'Summary of findings' tables.

Results

Description of studies

The original literature search performed for this review (1996 to 2008) yielded 2221 hits (Hoenig 2010). Of these, we selected 31 papers that reported on 14 studies for closer attention. We excluded one study because it was based on a registry and hence contained observational data (MITI 2000). We excluded another study because it was a post‐hoc analysis of a trial that compared hirudin to heparin in acute coronary syndrome (ACS) patients (GUSTO2b 2003). We excluded four trials because they were undertaken in the pre‐stent era or did not encourage the routine use of stents in the invasive strategy (MATE 1998; TIMI‐3b; VANQWISH 1998; Zhao 2005). Moreover, some studies included patients with ST elevation myocardial infarction (STEMI) but did not report outcomes separately for unstable angina (UA)/non‐ST elevation myocardial infarction (NSTEMI) (Eisenberg 2005; MATE 1998). As stated earlier, studies from the pre‐stent era underestimate the value of the invasive strategy and are irrelevant to current practice. Also, we excluded two studies because of inappropriate participant selection or trial design (ISAR‐COOL; TRUCS 2000). More details on the excluded studies can be found in the 'Characteristics of excluded studies' table. We deemed five studies appropriate for inclusion and we have described these in the 'Characteristics of included studies' table. We analysed these five studies together in Analysis 1. Two studies used a glycoprotein IIb/IIIa antagonist routinely in the routine invasive arm (ICTUS; TACTICS‐TIMI 18), and we analysed these two studies together via the prespecified Analysis 2 (see the 'Types of studies' section). The three remaining studies satisfied this Cochrane review's stent requirement but did not routinely use glycoprotein IIb/IIIa antagonists in participants randomised to the routine invasive strategy. We analysed these together as Analysis 3 (FRISC‐II; RITA‐3; VINO).

The literature search update (2008 to 2015) yielded 1929 hits, of which 27 were potentially relevant articles. Of these, we added five articles, which related to three studies (Italian Elderly ACS; LIPSIA‐NSTEMI; OASIS 5), to the previous analysis. The Italian Elderly ACS and OASIS 5 studies were also relevant to Analysis 2, and the LIPSIA‐NSTEMI trial was relevant to Analysis 3. We excluded a number of important randomised controlled trials (RCTs) from the update due to the absence of randomisation to a management arm consistent with the 'selective invasive' strategy as defined in this Cochrane review. These studies generally focused on the optimal timing of an invasive strategy (e.g. ABOARD; ELISA; ISAR‐COOL; OPTIMA; TIMACS; Zhang 2010), or optimal use of antithrombotic medication (e.g. ACUITY; EARLYACS; PLATO; TRITON‐TIMI 38). A published conference abstract, Dimitrov 2013, eluded to a potentially relevant study. However, as the full text publication was unavailable at the time of the literature search, we classified this study as 'ongoing' and excluded it from the analyses (see the 'Characteristics of ongoing studies' section).

Design

All included studies were RCTs. Due to the procedural nature of the intervention, we presumed that the participants and treating clinicians were not blinded to the intervention. However, a blinded committee could assess outcomes. The 'Characteristics of included studies' table describes the trial design features and includes information on intention‐to treat (ITT) analysis and losses to follow‐up.

Populations

The included studies were heterogeneous in their participant selection criteria. The inclusion criteria were comprised of different combinations of the following core criteria: chest pain, electrocardiograph (ECG) changes, increased level(s) of cardiac marker(s) or a documented history of coronary artery disease (CAD). We have outlined the specific criteria for each included study in the 'Characteristics of included studies' table. Clearly, since the included studies used different criteria, the trials randomised participants at different levels of risk. Elevated troponin levels (Antman 1996; Galvani 1997; Lindahl 1996) or ECG changes (Cannon 1997) forebode a worse prognosis for unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI). As such, trials that recruited these participants could be expected to exhibit higher event rates. For example, the VINO study, which had the highest mortality rate (26.8% per year of follow‐up) and the Italian Elderly ACS study, which had the second highest mortality rate (13.8% per year follow‐up), randomised participants who had chest pain, ECG changes and elevated cardiac markers; whereas in TACTICS‐TIMI 18, 27% of the trial participants had accelerating or prolonged chest pain with a history of CAD as the sole entry criteria. Additionally, the Italian Elderly ACS only included participants who were 65 years of age or older, with the attendant increased morbidity and mortality that comes with aging. In contrast, the entry criteria for the RITA‐3 study were explicitly aimed at intermediate‐risk participants and the OASIS 5 substudy exclusively recruited female participants.

Interventions

Within the routine invasive strategy, all participants were randomised to receive angiography, regardless of symptom status. In contrast, with the conservative/'selective invasive' strategy, angiography only was performed in participants with clinical or investigational evidence of ischaemia. It is important to note that angiography is a component of both strategies, and that angiography in the conservative arm did not represent a 'cross‐over', as long as it was preceded by myocardial ischaemia or evidence of CAD.

Time to interventions

The times to angiography after randomisation in the routine invasive arms were: mean 6.2 hours in VINO, median 22 hours in TACTICS‐TIMI 18, median 23 hours in ICTUS, mean 24 hours in the Italian Elderly ACS, median two days in RITA‐3, median 51 hours in OASIS 5 and mean four days in FRISC‐II. The invasive strategy in the LIPSIA‐NSTEMI trial included both an immediate invasive strategy and an early invasive strategy with respective mean randomisation to sheath insertion times of 1.1 and 18.3 hours.

The FRISC‐II trial authors cited observational data to justify delayed angiography and postulated that a period of "plaque passivation" prior to angiography would be beneficial. However, the ISAR‐COOL trial subsequently compared an 'early invasive' (angiography within six hours of randomisation) to 'delayed invasive' (angiography in three to five days) strategy in UA/NSTEMI patients and found that early angiography produced superior outcomes. Since that time, a number of RCTs have evaluated the optimal timing of an invasive approach (ABOARD; ELISA; LIPSIA‐NSTEMI; OPTIMA; TIMACS; Zhang 2010). However, at present, there is insufficient evidence to indicate the optimal time for invasive management in general populations and such a discussion is beyond the scope of this Cochrane review.

Criteria for ischaemia

There were important differences between the included trials in the criteria for ischaemia that mandated angiography within the selectively invasive arm. In particular, the FRISC‐II criteria were widely criticised for being more stringent than those of the other studies, thereby exaggerating any benefit conferred by the invasive strategy. Furthermore, FRISC‐II did not utilise nuclear imaging or pharmacologic stress testing in its selectively invasive strategy arm. Indeed, application of the FRISC‐II criteria to the VANQWISH 1998 study, which recruited similar participants, suggests that significant CAD was under‐detected in the selectively invasive arm of the FRISC‐II study (Goyal 2002). Similarly, the LIPSIA‐NSTEMI trial applied strict criteria for intervention in the conservative arm, including evidence of refractory ischaemia by clinical, ECG and stress testing, and an ejection fraction (EF) via echocardiography of less than 45%. Consequently, 70% of those randomised to the selectively invasive arm underwent an invasive strategy (versus 84% amongst those randomised to receive an invasive strategy). Conversely, the Italian Elderly ACS did not require an objective ischaemia measure and relied on symptoms alone. This resulted in lower rates of invasive management in the conservative arm (31% versus 58% amongst those randomised to an invasive strategy).

Outcomes

Commonly reported outcomes included death, myocardial infarction (MI) and recurrent angina. Death was reported as all‐cause mortality. The definition of MI varied between the included studies, but included a combination of chest pain, ECG changes and elevated cardiac biomarkers. Not all studies reported peri‐percutaneous coronary intervention (peri‐PCI) cardiac biomarker leaks without other criteria as an endpoint, but were included as a safety outcome where data were available. We have summarised the variable definitions of MI in Table 2, which show that some studies required clinical or ECG changes, or both, for MI endpoints, whereas others only required an increased cardiac marker. Importantly, the ICTUS and LIPSIA‐NSTEMI trial protocols mandated the routine measurement of creatine kinase‐myocardial band (CK‐MB) after PCI, and peak levels constituted the endpoint of MI for both and the primary outcome for the LIPSIA‐NSTEMI trial. Such an assessment has the benefit of allowing quantification of overall myocardial necrosis, including that associated with the intervention itself. However, the significance of peri‐PCI biomarker leaks is a subject of considerable debate (Bhatt 2005; Cutlip 2005).

The other included trials did not specify the routine measurement of CK‐MB after PCI per protocol. Fortunately the ICTUS trial authors reported 'spontaneous' and 'peri‐procedural' MI as separate endpoints (de Winter 2005; Hirsch 2007; Windhausen 2007b). Extraction of data from ICTUS, which combined spontaneous and procedural MI into a single MI endpoint, caused significant heterogeneity in a previous version of this meta‐analysis (Hoenig 2010). Hence, to maximize consistency between trials, we analysed 'spontaneous' MI from the ICTUS trial with our MI endpoint and reported peri‐procedural MI as a safety endpoint. This minimised heterogeneity during meta‐analysis and also is justifiable since the significance of peri‐procedural biomarker leaks is still a subject of contention. Fortunately, endpoints such as death are indisputable. Follow‐up was six months in TACTICS‐TIMI 18, VINO and LIPSIA‐NSTEMI; one year in the Italian Elderly ACS; two years in the OASIS 5 substudy; three years for MI but four years for mortality in ICTUS; five years in FRISC‐II; and five years in RITA‐3. We have summarised the characteristics of the included studies in the 'Characteristics of included studies' table and in Table 1.

Risk of bias in included studies

We summarised the risk of bias of the included studies in the 'Characteristics of included studies' table, Figure 1 and Figure 2.


Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.


Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Allocation

We judged six of the included studies to be of low risk of bias as they generated the random sequence adequately (FRISC‐II; ICTUS; Italian Elderly ACS; LIPSIA‐NSTEMI; OASIS 5; VINO). Two trials are of unclear risk of bias for random sequence generation (RITA‐3; TACTICS‐TIMI 18) as they did not provide details on the method of randomisation.

All trials were judged to be of low risk of allocation concealment.

Blinding

All included studies were judged to be of high risk of performance bias. The blinding of outcome assessors was done in three trials (ICTUS; Italian Elderly ACS; OASIS 5) and they were therefore judged to be of low risk detection bias. One trial (TACTICS‐TIMI 18) was of unclear risk of bias in this domain and four trials (FRISC‐II; LIPSIA‐NSTEMI; RITA‐3; VINO) were judged to be of high risk of bias as outcome assessors were not blinded.

Incomplete outcome data

All trials were judged to be of low risk of attrition bias.

Other potential sources of bias

We judged four of the studies (FRISC‐II; Italian Elderly ACS; RITA‐3; VINO) to be at low risk of other biases and the other four studies (ICTUS; LIPSIA‐NSTEMI; OASIS 5; TACTICS‐TIMI 18) at unclear risk of bias.

Effects of interventions

See: Summary of findings for the main comparison Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial (UA/NSTEMI) infarction in the stent era; Summary of findings 2 Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI) in the stent era

The baseline participant characteristics were equivalent between the two randomised groups across all included studies. We analysed TACTICS‐TIMI 18, ICTUS and LIPSIA‐NSTEMI together in Analysis 2, since they involved the routine use of both glycoprotein IIb/IIIa receptor antagonists and stents. Analysis 3 included studies that only used stenting routinely, and included RITA‐3, FRISC‐II, the Italian Elderly ACS, the OASIS 5 substudy and VINO. Since the trials reported outcomes after different durations of follow‐up, we categorised the endpoints for meta‐analysis as being index, early, intermediate or late. 'Index' endpoints indicate follow‐up over the course of the initial hospitalisation. 'Early' endpoints indicate a follow‐up of up to four months. 'Intermediate' endpoints indicate a follow‐up from six to 12 months. 'Late' endpoints indicate a follow‐up greater than or equal to two years. In studies that supplied endpoints at various time points within a given category, we used the latest follow‐up outcomes. For example, if a trial provided outcomes at six and 12 months of follow‐up, we used the 12‐month data for intermediate analysis. In the 'Summary of findings' table, we reported an all‐study analysis that involved all included studies for each outcome. This all‐study analysis was seen in studies that reported six to 12 months follow‐up period (i.e. intermediate endpoints).

Analysis 1: studies that deployed stents routinely in revascularisation procedures using PCI, regardless of glycoprotein IIb/IIIa receptor antagonist use

This analysis included all eight studies undertaken in the stent era, regardless of glycoprotein IIb/IIIa receptor antagonist use (FRISC‐II; ICTUS; Italian Elderly ACS; LIPSIA‐NSTEMI; OASIS 5 substudy; TACTICS‐TIMI 18; RITA‐3; VINO). The commonly reported outcomes for this analysis are presented in Summary of findings' table 1 (summary of findings Table for the main comparison) and complications of angiography or revascularization in Summary of findings' table 2 (summary of findings Table 2).

Death: all causes (index, early, intermediate, late)

Risk of index death significantly increased with a routine invasive versus conservative or selective invasive strategy (risk ratio (RR) 1.54, 95% confidence interval (CI) 1.02 to 2.34; six trials, 8094 participants; Analysis 1.1). Early (RR 1.18, 95% CI 0.70 to 2.00; four trials, 4345 participants; Analysis 1.2), intermediate (RR 0.87, 95% CI 0.64 to 1.18; eight trials, 8915 participants; Analysis 1.3) and late (RR 0.90, 95% CI 0.76 to 1.08; three trials, 5467 participants; Analysis 1.4) death were not significantly affected by an invasive strategy. There was no evidence of any heterogeneity in inter‐study effect sizes across all time points for this endpoint.

The death rates standardised to years of study duration, shown in Table 1, were 1.1% to 2.8% per year for the OASIS 5 substudy, RITA‐3, FRISC‐II and ICTUS; whereas TACTICS‐TIMI 18 had a rate of 7%; the Italian Elderly ACS study and LIPSIA‐NSTEMI trial 13% to 14%; and VINO had a rate of 27%. For the most part, the levels of risk were concordant with the inclusion criteria employed by each study, as described in the 'Characteristics of included studies' table, with the exception of ICTUS. As already discussed, mortality increases as troponin concentrations increase in patients with ACS (Antman 1996). The ICTUS trial exclusively enrolled participants with a troponin T (TnT) greater than 0.03 ng/mL and, as such, would be expected to observe a higher mortality rate. Indeed, in TACTICS‐TIMI 18, the six‐month mortality rate for participants with a TnT greater than 0.01 ng/mL was 4% (Morrow 2001). Since the ICTUS trial recruited participants with a TnT greater than 0.03 ng/mL and had a longer duration of 12 months, the standardised mortality would be expected to be greater than 4%. Indeed, in FRISC‐II, participants with a TnT value greater than 0.03 ng/mL had a 12‐month mortality rate of 4.2% (Diderholm 2002). Hence, the ICTUS participants appear to have experienced a lower than expected event rate, based upon the event rates reported for other included trials. Differences between trials in baseline medical therapy do not appear to explain why mortality in the ICTUS trial was less than the other trials.High rates of background medical therapy seen in both ICTUS and TACTICS‐TIMI 18. This observation highlights the importance of global risk stratification over the selection of a single high‐risk characteristic when predicting the risk of future events.

MI (index, early, intermediate, late)

The incidence of MIs during the index hospitalisation was not significantly affected by an invasive strategy (RR 1.08, 95% CI 0.65 to 1.80; seven trials, 8694 participants; Analysis 1.5), though significant heterogeneity was identified at this time point (P = 0.003, I² statistic = 70%). Possible reasons for this heterogeneity include the use of glycoprotein IIb/IIIa receptor antagonists in TACTICS‐TIMI 18 and the unique definition of MI the VINO trial authors used, which excluded any events within the first 72 hours of randomisation (Table 2). Both early (RR 0.68, 95% CI 0.43 to 1.08; four trials, 4345 participants; Analysis 1.6) and intermediate (RR 0.79, 95% CI 0.63 to 1.00; eight trials, 8915 participants; Analysis 1.7) MI endpoints revealed a non‐significant trend towards reduction with an invasive strategy. Interestingly, the previous version of this review, Hoenig 2010. identified statistically significant reductions at the early and intermediate endpoints associated with an invasive versus conservative strategy, so that the current analysis represents a reduced effect. Late MI rates were drawn from three studies with these data — FRISC‐II (five years), RITA‐3 (five years) and ICTUS (three years) — and as in the previous meta‐analysis, they remained significantly decreased in those treated invasively (RR 0.78, 95% CI 0.67 to 0.92; three trials, 5467 participants; Analysis 1.8).

Death (all causes) or non‐fatal MI (index, early, intermediate, late)

Index death or non‐fatal MI, as a composite outcome, was not decreased in those treated via a routine invasive approach (RR 1.14, 95% CI 0.59 to 2.21; four trials, 6618 participants; Analysis 1.9); however, we noted significant heterogeneity (P = 0.001, I² statistic = 81%) and possible reasons include those already discussed for components of the composite outcome. Early death or non‐fatal MI, based on 30‐day TACTICS‐TIMI 18 data and VINO data, was significantly decreased with an invasive strategy (RR 0.64, 95% CI 0.45 to 0.92; two trials, 2351 participants; Analysis 1.10). We observed a trend towards a decreased incidence of intermediate death or non‐fatal MI, again as a composite outcome, with the routine invasive strategy and included data from all included studies except for ICTUS (RR 0.93, 95% CI 0.71 to 1.20; seven trials, 7715 participants; Analysis 1.11). Again, as was the case for the intermediate MI component of this composite outcome, we noted heterogeneity (P = 0.007, I² statistic = 66%). As with intermediate MI alone (see the previous paragraph), this represents a loss of significance relative to the previous version of this review (Hoenig 2010), due to the influence of the OASIS 5 substudy and LIPSIA‐NSTEMI studies. Late death or non‐fatal MI was not significantly decreased (RR 0.89, 95% CI 0.73 to 1.08; three trials, 5467 participants; Analysis 1.13). The late follow‐up for this composite endpoint was perhaps less important, given the independent benefit observed for the MI endpoint at late follow‐up and the 'dilution' of this effect observed with incorporation of mortality into a composite outcome.

Four included studies reported gender‐specific data for males and five studies reported it for females, and subanalysis of intermediate death or non‐fatal MI demonstrated a statistically‐significant benefit of a routine invasive strategy only in males (male: RR 0.73, 95% CI 0.62 to 0.87; four trials, 4454 participants; female: RR 0.87, 95% CI 0.65 to 1.16; five trials, 2521 participants; Analysis 1.12). Late (five‐year) follow‐up from the FRISC‐II trial also showed that the invasive strategy only significantly benefited males (RR 0.70, 95% CI 0.59 to 0.86). These subgroup analyses should be interpreted with caution, and we have explored them further in the Discussion.

Refractory angina (early, intermediate)

An invasive strategy decreased early refractory angina, based upon four‐month data from RITA‐3 (RR 0.47, 95% CI 0.32 to 0.68). Intermediate refractory angina was significantly decreased using a routine invasive strategy (RR 0.64, 95% CI 0.52 to 0.79; five trials, 8287 participants; Analysis 1.14), although we found significant heterogeneity at this time point (P < 0.0003, I² statistic = 81%), which was driven by the ICTUS results. The null effect for this endpoint in ICTUS was surprising, given that this study recruited only troponin‐positive participants. Indeed, retrospective analysis of troponin‐positive participants from the TACTICS‐TIMI 18 trial revealed that 94% of troponin‐positive participants had significant angiographic CAD, 79% of whom were revascularised (PCI or coronary artery bypass grafting (CABG)) during the index hospitalisation (Dokainish 2005). Hence, the trial participants in ICTUS would be expected to exhibit high rates of angiographic CAD and to experience considerable symptomatic improvement with an invasive strategy. One possible explanation for this difference in outcomes is that 20% of the participants enrolled in ICTUS underwent PCI or CABG prior to randomisation, which potentially resulted in artificially‐improved outcomes in the conservative arm as these participants likely had the most to gain from a routine invasive strategy.

Rehospitalisation for ACS (early, intermediate, late)

The invasive strategy was associated with a significantly decreased rate of rehospitalisation at the intermediate time point (RR of 0.77, 95% CI 0.63 to 0.94; six trials, 6921 participants; Analysis 1.15), albeit with significant heterogeneity (P = 0.05, I² statistic = 54%). ICTUS provided late follow‐up on rehospitalisation at three years, at which point no significant benefit persisted (RR 0.79, 95% CI 0.56 to 1.12). This attenuation of earlier significance was unsurprising, when we considered the narrowing in the difference in revascularisation rates between the two strategies in ICTUS, from a 36% difference at initial hospitalisation between revascularisation in the routine invasive versus conservative or selective invasive strategies, to only 23% at the termination of follow‐up.

Analysis 2: routine use of both stents and glycoprotein IIb/IIIa receptor antagonists in revascularisation procedures using PCI

This analysis examined routine use of both stents and glycoprotein IIb/IIIa receptor antagonists, and included three trials (ICTUS; LIPSIA‐NSTEMI; TACTICS‐TIMI 18).

Death: all causes (index, early, intermediate, late)

There was no difference between the treatment strategies at any of the time points assessed. Data from TACTICS‐TIMI 18 and ICTUS at hospitalisation (for index death) and from TACTICS‐TIMI 18 at 30 days (for early death) exhibited a trend toward increased index death (RR 1.67, 95% CI 0.84 to 3.31; two trials, 3383 participants; Analysis 1.1) and early death (RR 1.38, 95% CI 0.76 to 2.51; one trial, 2220 participants; Analysis 1.2) in the invasive arm, but this did not reach statistical significance. Intermediate death was no different between the treatment strategies when we combined six‐month data from the LIPSIA‐NSTEMI trial and TACTICS‐TIMI 18 and 12‐month data from ICTUS (RR 0.92, 95% CI 0.66 to 1.27; three trials, 4020 participants; Analysis 1.3). In TACTICS‐TIMI 18, a routine invasive strategy did not reduce the risk of death, even in higher‐risk participants with troponin I (TnI) levels greater than 0.1 ng/mL. Late follow‐up from ICTUS (four years) revealed no benefit of a routine invasive strategy on the death endpoint at late follow‐up (RR 1.11, 95% CI 0.74 to 1.67; one trial, 1200 participants; Analysis 1.4).

MI (index, early, intermediate, late)

Based on the LIPSIA‐NSTEMI, TACTICS‐TIMI 18 and ICTUS data, the routine invasive strategy exhibited no significant difference in MI rate during the index hospitalisation (RR 0.96, 95% CI 0.51 to 1.83; three trials, 3983 participants; Analysis 1.5). Hence, there did not appear to be an early hazard to an invasive strategy when glycoprotein IIb/IIIa receptor antagonists were used upstream of PCI. Early MI was reduced by an invasive strategy, based on TACTICS‐TIMI 18 data at 30 days (RR 0.53, 95% CI 0.35 to 0.79; one trial, 2220 participants; Analysis 1.6). Intermediate MI was unaffected by an invasive strategy using data for spontaneous MI from LIPSIA‐NSTEMI, ICTUS and TACTICS‐TIMI 18 (RR 0.95, 95% CI 0.56 to 1.60; three trials, 4020 participants; Analysis 1.7). As already discussed, the TACTICS‐TIMI 18 trial authors did not routinely measure CK‐MB post‐PCI (Table 2). Late follow‐up from ICTUS (three years) demonstrated no benefit of an early invasive strategy on the rate of spontaneous MI (RR 1.01, 95% CI 0.66 to 1.55; one trial, 1200 participants; Analysis 1.8).

Death (all causes) or non‐fatal MI (index, early, intermediate, late)

Data for this composite endpoint at index and early (30‐day) time points were only available from TACTICS‐TIMI 18. There was no difference between the treatment strategies at index admission (RR 0.77, 95% CI 0.51 to 1.17; one trial, 2220 participants; Analysis 1.9). However, the invasive strategy was associated with significant early benefit (RR 0.67, 95% CI 0.48 to 0.94; one trial, 2220 participants; Analysis 1.10). Baseline troponin levels were available from 1826 of 2220 trial participants, and these data formed the basis for the prespecified subgroup analysis based on TnT levels greater than (troponin positive) or less than (troponin negative) 0.01 ng/mL. Upon subgroup analysis, the early (30 day) benefit of a routine invasive strategy only achieved statistical significance in troponin‐positive participants (RR 0.50, 95% CI 0.32 to 0.79). Troponin‐negative participants received no significant benefit at 30‐days follow‐up (RR 0.95, 95% CI 0.44 to 2.06), although this CI overlapped with those of troponin‐positive participants. Although the TACTICS‐TIMI 18 trial authors prespecified this subgroup analysis based on troponin, it should nevertheless be interpreted with caution.

Contrary to the early results, at intermediate (six‐month) follow‐up, adoption of a routine invasive strategy yielded no benefit (RR 0.97, 95% CI 0.59 to 1.60; two trials, 2820 participants; Analysis 1.11). The results of this subgroup analysis changed when the TACTICS‐TIMI 18 authors used a different cardiac biomarker. With subgroup analysis based on a TnI cut‐off of 0.1 ng/mL, troponin‐positive participants showed early (30 day) and intermediate (six month) benefits of an invasive strategy, with a RR of 0.47 (95% CI 0.30 to 0.73) and a RR of 0.67 (95% CI 0.47 to 0.96) respectively. The TACTICS‐TIMI 18 authors prespecified such subgroup analysis based on troponin, but should nevertheless be interpreted with caution. The ICTUS trial suggested no benefit of a routine invasive strategy at late follow‐up regardless of baseline risk (RR 1.19, 95% CI 0.87 to 1.63; one trial, 1200 participants; Analysis 1.13); we have explored this further in the Discussion.

Analysis 3: routine stent use in revascularisation procedures using PCI with selective glycoprotein IIb/IIIa receptor antagonist use

This analysis included five trials (FRISC‐II; Italian Elderly ACS; the OASIS 5 substudy; RITA‐3, VINO).

Death: all causes (index, early, intermediate, late)

There was a non‐significant trend towards increased death rate at index hospitalisation (RR 1.48, 95% CI 0.88 to 2.48; four trials, 4711 participants; Analysis 1.1) and no effect on early death (RR 1.01, 95% CI 0.31 to 3.33; three trials, 2125 participants; Analysis 1.2) in the invasive strategy group. Intermediate death at six to 12 months was not significantly improved by an invasive strategy (RR 0.85, 95% CI 0.48 to 1.49; five trials, 4895 participants; Analysis 1.3). However, we noted significant heterogeneity was noted (P=0.02, I² statistic = 68%). This may have been driven by the stringent criteria set by the FRISC‐II group to define failure of conservative therapy; and by the large benefit of an invasive strategy observed in the small VINO study, which randomised patients with the highest death rates of all five studies (Table 1). The FRISC‐II trial authors undertook subgroup analysis based on the presence of TnT greater than or less than 0.03 ng/mL and the presence of ST depression on the admission ECG. Mortality assessed at one year was not affected by an invasive strategy in this retrospective analysis, even in the group of participants with both TnT greater than 0.03 ng/mL and ST depression, although the numbers of participants may have been too small to detect any difference. Only FRISC‐II and RITA‐3 provided follow‐up data for late death at five years, and was not significantly improved by an invasive strategy (RR 0.87, 95% CI 0.72 to 1.04; two trials, 4267 participants; Analysis 1.4).

MI (index, early, intermediate, late)

There were no differences in index MI rates between the two strategies (RR 1.22, 95% CI 0.59 to 2.55; four trials, 4711 participants; Analysis 1.5), although we found significant heterogeneity (P = 0.06, I² statistic = 59%). The FRISC‐II data show a significant hazard for this endpoint in the routine invasive group (RR 2.22, 95% CI 1.46 to 3.36). Importantly, the four studies in this analysis did not undertake routine cardiac biomarkers measurements post‐PCI, as the ICTUS and LIPSIA‐NSTEMI did, and used clinical symptoms as a diagnostic criterion (Table 2). Significant heterogeneity may be due to the distinct VINO definition of MI, which excluded events within 72 hours of randomisation when calculating this endpoint. Early MI, based on 30‐day VINO and OASIS 5 data, and four‐month RITA‐3 data, was not significantly altered by a routine invasive strategy (RR 0.87, 95% CI 0.52 to 1.44; three trials, 2125 participants; Analysis 1.6). Intermediate (six‐month data from VINO and 12‐month data from the Italian Elderly ACS, FRISC‐II, OASIS 5 and RITA‐3 studies) and late MI (five‐year FRISC‐II and RITA‐3 data) significantly decreased with a routine invasive strategy (RR 0.73, 95% CI 0.60 to 0.89; five trials, 4895 participants; Analysis 1.7; and RR 0.75, 95% CI 0.63 to 0.90; two trials, 4267 participants; Analysis 1.8, respectively).

Death (all causes) or non‐fatal MI (index, early, intermediate, late)

Death or non‐fatal MI at index hospitalisation did not differ between strategies (RR 1.46, 95% CI 0.75 to 2.86; three trials, 4398 participants; Analysis 1.9). Notably, this contrasts with the FRISC‐II data, from which a significant hazard of the routine invasive strategy was identified for this endpoint (RR 2.07, 95% CI 1.42 to 3.03). There was no significant benefit with a routine invasive strategy with respect to early death or non‐fatal MI based on 30‐day VINO data (RR 0.30, 95% CI 0.06 to 1.39; one trial, 131 participants; Analysis 1.10). Similarly, there was no difference between strategies at the intermediate time point (RR 0.91, 95% CI 0.62 to 1.32; five trials, 4895 participants; Analysis 1.11) with analysis of data from FRISC‐II, RITA‐3, OASIS 5 and Italian Elderly ACS, in addition to VINO. However, drawing on five‐year results from FRISC‐II and RITA‐3, we noted a significant benefit for this composite outcome with a routine invasive strategy (RR 0.81, 95% CI 0.72 to 0.92; two trials, 4267 participants; Analysis 1.13).

The FRISC‐II data revealed that the intermediate (six to 12‐month) benefit of a routine invasive strategy was only significant in participants with ST depression at entry, who exhibited a RR of 0.66 (95% CI 0.50 to 0.88). There was no benefit from a routine invasive strategy in participants without ST depression, although such retrospective subgroup analysis should be interpreted with caution. Furthermore, FRISC‐II troponin subgroup analysis identified a RR of 0.71 (95% CI 0.53 to 0.93) at 12 months in troponin‐positive participants (TnT greater than 0.1 ng/mL), whereas participants with a TnT of less than 0.1 ng/mL only trended towards benefit with a RR of 0.77 (95% CI 0.53 to 1.11). Again, the CIs of these subgroup analyses overlap and the results should be regarded with caution. In a separate report, the FRISC‐II trial authors undertook subgroup analysis based on the presence of TnT greater than versus less than 0.03 ng/mL and the presence of ST depression on admission ECG. The intermediate (one‐year) death or non‐fatal MI endpoint was only significantly decreased in the group of participants with both TnT greater than 0.03 ng/mL and ST depression greater than 0.1 mV (RR 0.60, 95% CI 0.43 to 0.82). Likewise, the FRISC‐II trial authors stratified participants by FRISC score when they reported late (five‐year) outcomes for this endpoint. We have explored these findings in the Discussion.

Safety endpoints

Procedure‐related MI

Analysis of data from FRISC‐II, RITA‐3, ICTUS,Italian Elderly ACS and LIPSIA‐NSTEMI showed that the invasive strategy was associated with an increased risk of procedure‐related MI (RR 1.87, 95% CI 1.47 to 2.37; five trials, 6380 participants; Analysis 2.1). We did not identify any heterogeneity, despite the different diagnostic criteria used for MI: routine measurement of CK‐MB post‐PCI in ICTUS and LIPSIA‐NSTEMI; and the FRISC‐II, RITA‐3 and Italian Elderly ACS studies also included either clinical or ECG criteria, or both, to define MI (Table 2). As already discussed, the significance of a peri‐procedural cardiac biomarker leak is the subject of considerable debate, but can be modified by background medications, including use of glycoprotein IIb/IIIa receptor antagonists (Cutlip 2005). Notably, the increased rate of procedure‐related MI seen in participants subjected to a routine invasive strategy did not translate into any increased long‐term mortality.

Bleeding

The invasive strategy was associated with an increased risk of bleeding (RR 1.73, 95% CI 1.30 to 2.31; six trials, 7584 participants; Analysis 2.2), although we noted considerable variability in bleeding definitions between the included studies that reported this endpoint (FRISC‐II; ICTUS,Italian Elderly ACS; LIPSIA‐NSTEMI; OASIS 5; RITA‐3). Numerous studies of people with UA/NSTEMI have identified major bleeding as a harbinger of a poor ultimate outcome. The ICTUS trial authors reported major bleeding, which was defined as: fatal bleeding, intracranial bleeding, need for transfusion, a decrease in haemoglobin by 4.8 g/dL, or bleeding causing haemodynamic compromise. Major bleeding occurred in 3.1% and 1.7% (P = not significant) of participants randomised to a routine invasive versus conservative strategy, respectively, during the initial hospitalisation. On four‐year follow‐up, mortality was 18.6% in the 29 participants with major bleeding during initial hospitalisation, versus just 7.5% in the 1171 participants without an in‐hospital major bleed (RR 2.68, 95% CI 1.08 to 6.61).

Stroke

Data from five trials revealed no statistically‐significant hazard for stroke with a routine invasive strategy (RR 0.84, 95% CI 0.38 to 1.86) (ICTUS; Italian Elderly ACS; LIPSIA‐NSTEMI; OASIS 5; TACTICS‐TIMI 18).

Contrast reactions

Typically, 1% of participants assigned to an invasive strategy experienced a contrast allergy. The rate in the conservative strategy depended on the proportion that underwent subsequent angiography, and this depended upon the population risk level. Contrast‐induced renal failure was not reported; however, this outcome can be modified by the patient's baseline renal function, hydration status and administration of sodium bicarbonate.

Sensitivity analysis

We chose a random‐effects model to analyse the results, as it provides a more conservative estimate of effect size in the presence of a small number of studies and variable risk levels among randomised participants. Table 1 highlights important differences between the included studies, which guided our choice of sensitivity analysis based on the exclusion of certain studies. We did not subject recurrent angina and rehospitalisation endpoints to sensitivity analysis, because RR estimates were the most consistent and robust findings of this meta‐analysis and, in general, were not associated with significant heterogeneity.

Time to angiography

As previously discussed, time to angiography in the invasive arm could influence outcomes, and optimal timing remains unclear (Navarese 2013). Indeed, the ISAR‐COOL study found that, in participants with UA/NSTEMI, a 'delayed invasive' strategy with angiography three to five days postrandomisation approximately doubled the risk of death or non‐fatal MI over that observed in participants with an 'early invasive' strategy in whom angiography was performed within six hours of randomisation. The excess events in the late invasive arm occurred prior to angiography; this was observed despite background anti‐thrombotic therapy which included aspirin, clopidogrel, tirofiban and heparin. Notably, this study randomised a high risk population with roughly two thirds of participants positive for troponin and ST depression on ECG (ISAR‐COOL). We have presented the times to angiography in the 'Characteristics of included studies' table and can be categorised into an 'immediate invasive', 'early invasive' or 'delayed invasive' strategy. The ICTUS, TACTICS‐TIMI 18, VINO and Italian Elderly ACS studies generally employed angiography within 24 hours of randomisation; whereas in the FRISC‐II, OASIS 5 and RITA‐3 studies, angiography was typically delayed for at least two days.

The increasing interest in timing of invasive strategies has resulted in more considered comparisons of timing to determine optimal management. The most recently performed study of the included clinical trials, the LIPSIA‐NSTEMI trial, randomised participants to immediate, early and selective invasive approaches with median times from randomisation to angiography of 1.1, 18.6 and 67.2 hours respectively.

Mortality rates In the conservative arm

We have presented mortality rates in Table 1 as the mortality rate in the conservative arm divided by the number of years of follow‐up. The OASIS 5 substudy, ICTUS, FRISC‐II and RITA‐3 had mortality rates of 1.1% to 2.8% per year of follow‐up, while TACTICS‐TIMI 18 had a rate of 7%, the Italian Elderly ACS and LIPSIA‐NSTEMI trials had rates between 13% and 14%, and VINO had a rate of 27%. Hence, we analysed the data for OASIS 5, ICTUS, FRISC‐II and RITA‐3 separately, and the data for TACTICS‐TIMI 18, the Italian Elderly ACS, LIPSIA‐NSTEMI and VINO. When we analysed the high‐mortality and low‐mortality rate studies separately, the previously‐reported findings were significantly different, which is likely due to the inclusion of the more recent Italian Elderly ACS and LIPSIA‐NSTEMI studies. These studies, as we will discuss below, included participant cohorts of high‐risk for interventional complications.

Percentage of trial participants with a positive troponin

Findings on subgroup analysis suggest that a positive troponin may identify high‐risk patients likely to experience a particular benefit with a routine invasive strategy. While the VINO, ICTUS and LIPSIA‐NSTEMI trials only recruited participants with positive cardiac biomarkers, the percentage of biomarker‐positive participants in the Italian Elderly ACS, OASIS 5 substudy, FRISC‐II, RITA‐3 and TACTICS‐TIMI 18 studies ranged between 50% and 80% (Table 1). We analysed the studies that only randomised biomarker‐positive participants separately (ICTUS; LIPSIA‐NSTEMI; VINO) and exhibited a null effect for mortality at all time points. However, this finding should not undermine the potential hazards of a routine invasive strategy and the importance of risk stratification to select high‐risk patients who may experience meaningful benefits that outweigh any potential harm.

CABG as a mode of revascularization in the invasive arm

We have described the rates of CABG as a mode of revascularisation in the invasive arms in Table 1. The OASIS 5 substudy, ICTUS and TACTICS‐TIMI 18 identified rates of approximately 20%, while RITA‐3, FRISC‐II and VINO had rates of approximately 40%. Consistent with international UA/NSTEMI management guidelines (Hamm 2011; Jneid 2012) and subsequent increasing use of PCI, we observed the lowest CABG rates in the two studies with the most recent recruitment of participants, Italian Elderly ACS and LIPSIA‐NSTEMI, with rates of 7% and 10% respectively. Performing a sensitivity analysis on the basis of high or low rates of CABG in the invasive arm used the same data already utilised in Analyses 2 and 3; hence, the findings were identical to those already described.

Difference in revascularisation rates between the treatment arms

We have presented the absolute percentage differences in revascularisation rate between the routine invasive and conservative arms of each trial in Table 1. The Italian Elderly ACS, FRISC‐II and VINO exhibited higher absolute differences in revascularisation rate (27% to 39%) relative to the other trials (14% to 23%). When we pooled the former trials, we noted a non‐significant trend towards benefit with a routine invasive strategy at all time points except the index hospitalisation. Conversely, as the difference between rates of revascularisation narrows — as is seen for instance in the LIPSIA‐NSTEMI study, which had the highest invasive rate reported to date amongst participants randomised to a conservative management strategy (70%) — any benefit derived from a routine invasive strategy may diminish.

Discussion

Summary of findings

Eight randomised controlled trials (RCTs) with a total of 8915 participants (4545 invasive strategies, 4370 conservative strategies) were eligible for inclusion.

In the all‐study analysis, evidence did not show appreciable risk reductions in all‐cause mortality (RR 0.87, 95% CI 0.64 to 1.18; eight studies, 8915 participants; low quality evidence) and death or non‐fatal myocardial infarction (MI) (RR 0.93, 95% CI 0.71 to 1.2; seven studies, 7715 participants; low quality evidence) with routine invasive strategies compared to conservative (selective invasive) strategies at six to 12 months follow‐up. There was appreciable risk reduction in MI (RR 0.79, 95% CI 0.63 to 1; eight studies, 8915 participants; moderate quality evidence), refractory angina (RR 0.64, 95% CI 0.52 to 0.79; five studies, 8287 participants; moderate quality evidence) and rehospitalisation (RR 0.77, 95% CI 0.63 to 0.94; six studies, 6921 participants; moderate quality evidence) with routine invasive strategies compared to conservative (selective invasive) strategies also at six to 12 months follow‐up.

There were increased risks in bleeding (RR 1.73, 95% CI 1.3 to 2.31; six studies, 7584 participants; moderate quality evidence) and procedure‐related MI (RR 1.87, 95% CI 1.47 to 2.37; five studies, 6380 participants; moderate quality evidence) with routine invasive strategies compared to conservative (selective invasive) strategies. Low quality evidence was as a result of serious risk of bias and imprecision in the estimate of effect, while moderate quality evidence was only due to serious risk of bias.

The risk of index death (during the initial hospitalisation for unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI)) was high when an invasive strategy was adopted from the outset, with a RR of 1.54 (95% CI 1.02 to 2.34). However, early death (less than four months), intermediate death (six to 12 months) and late death (four to five years) were not influenced by management strategy. Though index MI was not significantly improved with an invasive strategy, we identified significant heterogeneity within this analysis, possibly driven by the different levels of risk, different rates of background medical therapies and different criteria for ischaemia in the studies included in the analysis. Early MI data from trials that routinely used glycoprotein IIb/IIIa receptor antagonists revealed a significant benefit of a routine invasive strategy (RR 0.53, 95% CI 0.35 to 0.79), though in the all‐study combined analysis, this failed to achieve statistical significance (RR 0.68, 95% CI 0.43 to 1.08).

In comparison to previous versions of this Cochrane review (Hoenig 2006; Hoenig 2010), the inclusion of OASIS 5, Italian Elderly ACS and LIPSIA‐NSTEMI studies resulted in the loss of significant benefit in the all‐study analysis of a routine invasive approach at the intermediate MI endpoint (RR 0.79, 95% CI 0.63 to 1.00). However, we observed a significant difference between strategies at the endpoint with the exclusion of the studies employing routine glycoprotein IIb/IIIa (RR 0.73, 95% CI 0.60 to 0.89). With a routine invasive strategy, the significant reduction observed in late MI remained unchanged (RR 0.78, 95% CI 0.67 to 0.92), driven by studies that did not employ routine glycoprotein IIb/IIIa strategy (RR 0.75, 95% CI 0.63 to 0.90).

Regarding the composite endpoint of death or non‐fatal MI, although a routine invasive approach was not beneficial at the time of index hospitalisation, we observed a significant benefit at the early time point (RR 0.64, 95% CI 0.45 to 0.92). The all‐study analysis of the this endpoint at the intermediate time point lost significance (RR 0.93, 95% CI 0.71 to 1.20). However, an unchanged benefit remained significant amongst males (RR 0.73, 95% CI 0.62 to 0.87). Late death or non‐fatal MI was unaffected by management strategy (RR 0.89, 95% CI 0.73 to 1.08). The studies that reported the death or MI endpoint suggest that any benefits of a routine invasive strategy were significant only in trial participants with high‐risk characteristics, primarily positive troponin or dynamic ischaemic electrocardiograph (ECG) changes on admission or secondary diabetes mellitus, renal insufficiency, reduced EF to less than 40%, early postinfarction angina, recent percutaneous coronary intervention (PCI), prior coronary artery bypass grafting (CABG), or intermediate to high Global Registry of Acute Coronary Events (GRACE) risk score (Hamm 2011). These markers of risk may have identified populations with higher event rates and, hence, enhanced the power to detect differences between the two strategies. The CIs between subgroups overlapped, and these findings from post‐hoc analyses should be interpreted with appropriate caution.

We observed a statistically‐significant benefit for both refractory angina and rehospitalisation (RR 0.64, 95% CI 0.52 to 0.79; and RR 0.77, 95% CI 0.63 to 0.94, respectively) at the intermediate time point, both driven by the benefit of an invasive strategy in studies that did not use routine glycoprotein IIb/IIIa inhibitors. However, the narrowing difference in revascularisation rates between the two strategies over time reduces the hospitalisation benefit longer term.

Regarding safety endpoints, the invasive strategy was associated with a 1.9‐fold increase in the RR of the variably defined procedurally‐related MI endpoint, as well as a 1.8‐fold increase in the RR of bleeding. This bleeding was mainly due to wound site bleeding, but was difficult to grade due to inter‐trial differences in the definition of bleeds and reporting of data. No increase risk of stroke was noted (RR 0.84, 95% CI 0.38 to 1.86).

Discussion of findings on subgroup analysis

Cardiac troponin status of participants

The baseline cardiac biomarker status of the patient serves as an important tool for risk stratification, though the ideal marker and definitions remain unclear and have evolved over time with advances in technology ( creatine kinase‐myocardial band (CK‐MB) versus troponin versus high‐sensitivity troponin). The TACTICS‐TIMI 18 trial had the prespecified intention of testing the 'troponin hypothesis': that is, to test whether benefit from an invasive strategy was limited to troponin‐positive participants. Data for the death or non‐fatal MI endpoint from TACTICS‐TIMI 18 and FRISC‐II suggest that only high‐risk participants with a positive troponin benefited from a routine invasive strategy with respect to this endpoint. However, the CI for this subgroup analysis showed overlap with that of troponin‐negative participants. The Italian Elderly ACS reinforced the importance of baseline troponin status on treatment effect, and identified a significant reduction in the primary endpoint (composite of death, MI, disabling stroke and repeat hospital stay for cardiovascular causes or severe bleeding within one year) amongst participants with an elevated troponin on admission (hazard ratio (HR) 0.43, 95% CI 0.23 to 0.80) but not in those with normal troponin (HR 1.67, 95% CI 0.75 to 3.70). Data from VINO, which only included participants with clinical symptoms, ECG changes and positive cardiac biomarkers, revealed a significant 72% risk ratio reduction in this endpoint at six months. However, the ICTUS trial, which also exclusively enrolled troponin‐positive participants, had an unexpectedly low baseline mortality rate relative to the other included studies (Table 1). This may be partly due to optimal medical therapy in the ICTUS trial versus other included trials wherein, in both trial arms, early use of clopidogrel and intensive lipid‐lowering therapy was recommended to treating clinicians. Alternatively, this may be a statistical outlier given the large CIs for mortality in these studies. Disparate event rates in participants with positive troponin highlights the importance of global risk stratification as opposed to using cardiac biomarkers as a single risk index. Indeed, in a retrospective analysis of the FRISC‐II data (Diderholm 2002), death or non‐fatal MI experienced a significant 40% risk ratio reduction only in participants with both troponin T (TnT) greater than 0.03 ng/mL and ST depression on admission ECG. Hence, although ICTUS participants all had a TnT of greater than 0.03 ng/mL, this sole criterion did not necessarily identify a risk level that might benefit from invasive treatment. The risk associated with troponin elevation has been shown to be a continuous variable and therefore classification as a dichotomous variable may dilute its predictive power.

Though some have argued that the prognostic value of troponin is greater than that of CK‐MB (Montalescot 2009; Saenger 2008; Thompson 1979), troponin may be overly sensitive for the detection of re‐infarction and only elevated CK‐MB has been correlated with evidence of myocardial necrosis (Lim 2011). Retrospective analysis performed by the TACTICS‐TIMI 18 trial authors highlights the limitations of purely using a positive troponin to predict event rates. Analysis of the invasive arm revealed that 6% of the participants with a positive troponin test did not have significant angiographic coronary artery disease (CAD), defined as greater than 50% stenosis of any coronary artery (Dokainish 2005). At six months, these participants had a 3.1% rate of death or re‐infarction, compared to 0% among those with a negative troponin and no angiographic CAD. As would be expected, troponin‐positive participants with angiographic CAD had a high rate of death or re‐infarction (8.6%) at six months. Interestingly, participants with angiographic CAD who had a negative troponin had a 5.8% rate of death or re‐infarction at six months, which is clearly higher than that for troponin‐positive participants without angiographic CAD. Hence, troponin alone cannot be used to risk stratify patients. Moreover, this analysis highlights the limitations of angiography in the assessment of plaque burden. In general in unstable angina studies, positive troponin status has been shown to correlate with complex coronary lesions on angiography and reduced coronary flow (Benamer 1999; Heeschen 1999a; Hochman 1999), but should not be used alone to identify those at high‐risk. However, absolute values of troponin exhibit a linear relationship with subsequent risk of coronary events. Troponin positivity has also been shown to predict benefit from glycoprotein IIb/IIIa receptor antagonists (Hamm 1999; Heeschen 1999b), an early invasive strategy in the elderly (Italian Elderly ACS), and remains a critical element of risk stratification.

ST depression on admission

As previously mentioned, ECG changes on admission forebode a worse prognosis in UA/NSTEMI patients. Indeed, data from the TIMI III Registry shows that patients with ST depression on admission ECG have a 2.5‐fold increased risk of death or MI within one year (Cannon 1997). In the ICTUS and TACTICS‐TIMI 18 trials, ST depression was an independent predictor of failure of medical therapy with the conservative strategy (Sabatine 2006; Windhausen 2007b). As discussed above, on post‐hoc analysis of FRISC‐II data, the benefit of a routine invasive strategy on the endpoint of death or non‐fatal MI only achieved statistical significance in participants with ST depression on admission ECG. In FRISC‐II and the TIMI III Registry, the prevalence rates for triple‐vessel and left main artery disease were approximately 50% and 66%, respectively, in participants who had ST depression on admission ECG. Similarly, the TACTICS‐TIMI 18 study identified an odds ratio for three‐vessel disease of 1.79 in participants with ST deviation of 0.05 to 0.09 mV, and an odds ratio of 1.91 in those with a ST deviation greater than 0.10 mV versus those with a ST deviation less than 0.05 mV. Hence, the ECG can be used as a tool to identify patients who are likely to benefit from revascularisation. Analysis of the FRISC‐II data demonstrated that ST depression was still a predictor of benefit from an invasive strategy, even after baseline differences were accounted for (Holmvang 2003). Furthermore, this analysis also suggested that the benefits of a routine invasive strategy were further amplified with increasing amplitude of ST depression in an increasing number of ECG leads.

Data from TACTICS‐TIMI 18 confirms the utility of ST segment changes in identifying a higher‐risk population that may benefit from an invasive strategy. Unfortunately, we could not obtain data for the composite endpoint of death or non‐fatal MI, but the study includes data for the endpoint of death or non‐fatal MI or rehospitalisation for ACS. Using this endpoint, the RR was 0.62 (95% CI 0.53 to 0.74) in participants with baseline ST changes, while no effect was observed in those without such changes. The ICTUS data show a trend towards decreased rates of (spontaneous) MI at one year in those randomised to a routine invasive strategy, with a risk ratio of 0.74 (95% CI 0.40 to 1.38). However, the events were few and CIs were wide. In light of the potential implications of ST‐depression on treatment effect, we have provided the percentages of trial participants with ST depression on index ECG in Table 1, with the highest rates of 62% reported in the LIPSIA‐NSTEMI study. In general the studies eligible for analysis did not provide data for subgroup analysis of ST depression and troponin status. While subgroup analyses may identify populations with increased risk, and hence provide increased power to detect statistical significance, such post‐hoc analyses should be interpreted with caution.

Gender

Disparate outcomes of a routine invasive strategy based on gender has been a source of controversy. The all‐study (Analysis 1) gender subanalysis for intermediate death or non‐fatal MI revealed a benefit of routine invasive strategy confined to males. However, the number of women in the studies was lower than the number of men, and the decreased power to detect any advantage of routine invasive strategy is highlighted by the comparatively wide CIs. TACTICS‐TIMI 18 identified no significant interaction between gender and outcomes based on treatment strategy. Conversely, the FRISC‐II and RITA‐3 trials found significant benefit of a routine invasive strategy for death or MI amongst men, but not women. Supporting this, the OASIS 5 substudy, which randomly assigned 184 women to a routine or selective invasive strategy, identified significantly more deaths after one year (HR 9.01, 95% CI 1.11 to 72.90) and higher rates of major bleeding at 30 days (HR 11.45, 95% CI 1.43 to 91.96) with a routine invasive strategy.

Confounding comparison and interpretation of these results, women had less severe CAD across the studies analysed, and were less likely to have an elevated troponin level than men (Clayton 2004; Glaser 2002; Lagerqvist 2001). Moreover, in FRISC‐II and RITA‐3, women in the conservative arm had a better prognosis than men in the conservative arm. A retrospective analysis of TACTICS‐TIMI 18 data suggests that, after adjusting for differences in baseline characteristics, the benefits of an early invasive strategy in women were the same as those seen in men (Glaser 2002). In contrast, similar analyses undertaken by FRISC‐II and RITA‐3 trial authors failed to demonstrate any benefit of an invasive strategy in women, even after they adjusted for baseline characteristics. The RITA‐3 analysis suggested that women had better outcomes than men when managed conservatively and did not benefit from an invasive strategy, even when those with high‐risk features were analysed separately (Clayton 2004). Women in TACTICS‐TIMI 18 and RITA‐3 were less likely than men to undergo CABG, even when trials adjusted for the presence of three‐vessel or left anterior descending artery disease (Clayton 2004; Glaser 2002). Notably in FRISC‐II, where the rates of CABG were similar in both men and women, the one‐year mortality rate in participants undergoing CABG was 9.9% in women versus just 1.2% in men (Lagerqvist 2001). Higher operative CABG mortality has been observed in women enrolled in observational studies and this discrepancy could not be accounted for by age, co‐morbidities or smaller body surface area (Blankstein 2005). These retrospective analyses should be interpreted with appropriate caution. They highlight the importance of further research to determine the optimal treatment strategy in women, and the importance of risk stratification, especially in women who are less likely to have angiographic CAD when compared to their male counterparts, and requisite caution extrapolating results from men to women.

Other subgroups

We have discussed other subgroups of interest that we did not prespecify in our protocol, Hoenig 2004, as a narrative review in this section.

Elderly

The elderly (aged over 65 years) comprise the majority of hospital admissions for UA/NSTEMI. Given the higher risk of recurrent events in this group compared to counterparts who are younger, increased absolute risk may translate into a greater absolute risk reduction with improved understanding of the relative benefits of invasive versus conservative management (Alexander 2007). Despite this, there is a deficit of knowledge regarding the management of elderly patients, since the included studies in this Cochrane review generally excluded participants over 75 years of age.

The Italian Elderly ACS was the only RCT to specifically compare treatment strategies in elderly participants with non‐ST‐elevation ACS. Here, we did not identify any statistical difference between early aggressive and initially‐conservative groups for the primary endpoint of composite death, MI, disabling stroke and repeat hospital stay for cardiovascular or bleeding causes (HR 0.80, 95% CI 0.53 to 1.19) or for mortality (HR 0.87; 95% CI 0.49 to 1.56), MI (HR 0.67, 95% CI 0.33 to 1.36) or repeat hospitalisation (HR 0.81, 95% CI 0.45 to 1.46) when examined alone. However, stratification of participants dependent on baseline troponin revealed a significant reduction in the primary endpoint amongst troponin‐positive (HR 0.43, 95% CI 0.23 to 0.80) versus troponin‐negative participants (HR 1.67, 95% CI 0.75 to 3.70; P = 0.03). Implicit in this is the lost advantage of an early invasive strategy in troponin‐negative elderly, who can be safely managed conservatively. These findings are supported by the collaborative analysis of individual data from the FRISC II‐ICTUS‐RITA 3 (FIR) trials (Damman 2012), where a 29% reduction in cardiovascular death or MI was reported with a routine invasive strategy in participant greater than or equal to 75 years old, with sustained benefit still demonstrated at long‐term follow‐up.

A retrospective analysis of the TACTICS‐TIMI 18 trial showed that those over 65 years of age were more likely to have high‐risk features, such as elevated troponin levels, ST‐deviation, diabetes and congestive heart failure (Bach 2004). Indeed, 90% of those over 65 years old had intermediate to high‐risk TIMI scores (score greater than or equal to three), versus just 63% of those under 65 years of age. Overall, the routine invasive strategy reduced early and intermediate death or MI when compared to conservative management amongst those over 65 years of age, with risk ratios of 0.58 (95% CI 0.37 to 0.92) and 0.64 (95% CI 0.45 to 0.93), respectively. The invasive strategy did not significantly benefit those under 65 years old, which suggests that benefit increases with age, though the CIs were wide and overlapped. However, major bleeding was higher with the invasive strategy in those over 65 (RR 1.74, 95% CI 1.12 to 2.70), while no such hazard was observed in those under 65 years of age.

Reassuringly, in both the Italian Elderly ACS and the retrospective analysis of the TACTICS‐TIMI 18 trial, stroke was not increased with an invasive strategy in the elderly, and in fact demonstrated a trend towards decreased events with the routine invasive strategy adopted in TACTICS‐TIMI 18. The results of this type of analysis are unsurprising, given that the elderly are at increased risk of events. Therefore, retrospective analysis should have greater power to identify benefits of an intervention with absolute event rates.

The FRISC‐II trial authors also published risk ratio estimates for participants based on age; and while the risk estimate was only significant in those over 65 years old, the risk estimate for those under 65 years of age was similar and the CIs overlapped (Lagerqvist 2006). However, the results from TACTICS‐TIMI 18 and FRISC‐II differ from older excluded studies such as TIMI‐3b, which showed a significant hazard of intervention in younger trial participants. This point again reinforces the reasoning behind only including studies that were undertaken in the stent era, since older studies are irrelevant to contemporary practice.

The 2012 American College of Cardiology Foundation/American Heart Associate (ACCF/AHA) focused update, Jneid 2012, and the 2011 European Society of Cardiology (ESC) guidelines, Hamm 2011, on the management of UA/NSTEMI endorse an early invasive strategy (Level B evidence) for elderly patients, despite increased early procedural risks. Moreover, since elderly patients recruited into clinical trials generally have fewer cardiovascular risk factors, fewer co‐morbidities, and better haemodynamics and renal function than community‐dwelling elderly, event rates and benefits from a routine invasive strategy might be even greater in the 'real world'. Registry data support the use of the routine invasive strategy in the elderly, and there is no stroke hazard as a consequence of routine intervention reported in contemporary registries (Bauer 2007).

However, in the real world, acute coronary care for the elderly is provided within the context of the health and co‐morbid status of the patient. These factors also need to be considered for therapeutic decision‐making. Despite the lack of any statistically‐significant benefit with an invasive strategy in younger age groups, this is not to say that younger patients with high‐risk features would not benefit from a routine invasive approach. Age is included in the TIMI risk score, which integrates several prognostic variables readily available from the clinical history and first‐line investigations (Antman 2000). Similarly, retrospective analyses from the included studies have suggested that diabetes, peripheral arterial disease and a history of previous coronary artery bypass grafting are co‐morbid conditions associated with an increased risk of events and, hence, the potential for enhanced benefit from an early invasive strategy, as well as a more favourable risk‐benefit ratio (Januzzi 2005; Kugelmass 2006; Norhammar 2004). However, as with age, there is co‐variation with other indicators of high‐risk. Consequently, while retrospective analyses that focus on a single indicator of higher risk are interesting, a universal and easily‐applied method of risk stratification that can be utilised by the practicing physician would be of greater interest.

Diabetics

The relative benefit of adopting a routine invasive strategy has been a contentious issue amongst people with diabetes, who have both an increased risk of recurrent cardiovascular events and an increased risk of intervention due to co‐morbid conditions. A collaborative meta‐analysis of RCTs, which incorporated 9904 participants, compared conservative verse invasive treatment strategies between diabetic and non‐diabetic patients (O'Donoghue 2012). Although an invasive strategy yielded similar reductions in diabetic and non‐diabetic participants in overall cardiovascular events, the reduction in recurrent non‐fatal MI was greater in diabetic participants. The data presented by O'Donoghue 2012 support the 2012 ACCF/AHA focused update (Jneid 2012; Level B evidence) and the 2011 ESC guidelines (Hamm 2011; Level A evidence), which recommend use of an invasive strategy for people with diabetes who present with UA/NSTEMI.

The importance of global risk stratification

As the above discussion highlights, and as subgroup analyses have illustrated, risk stratification is an integral component of managing patients with UA/NSTEMI. The goal of risk stratification is to identify patients with a high likelihood of complicated CAD who are at increased risk of recurrent coronary events or premature death, and to offer such patients the benefits of revascularisation. However, the clinical distinction between UA and NSTEMI does not adequately stratify high‐risk patients (Zaacks 1999). Consequently, the current 2012 ACCF/AHA focused update, Jneid 2012, and the 2011 ESC guidelines, Hamm 2011, recommend using several parameters for risk stratification; as occurs with the application of risk scoring tools, for example the TIMI risk score (Antman 2000). To underscore this point, in a post‐hoc analysis of the FRISC‐II data, participants with troponin T of greater than 0.03 ng/mL and ST depression experienced a statistically‐significant benefit with a routine invasive strategy, whereas participants with only one of these variables did not (Diderholm 2002). Only TACTICS‐TIMI 18 undertook subgroup analyses based on TIMI risk scores, and stratified the participants into three categories based on their TIMI risk score: low‐, intermediate‐ or high‐risk. In this study, only intermediate‐ and high‐risk participants benefited from the invasive strategy, regarding the primary composite endpoint of death or non‐fatal MI or rehospitalisation for ACS. Unfortunately, data for the composite endpoint of death or non‐fatal MI were unavailable and therefore we could not incorporate them into this Cochrane review.

The TIMI score was extracted from the unfractionated heparin arm of the TIMI 11B trial (TIMI 11B 1999). It was validated in the enoxaparin arm of TIMI 11B and in both arms of the ESSENCE 1997 trial. The risk score was shown to be a valid predictor of the composite endpoint encompassing all‐cause mortality, MI and urgent revascularisation within 14 days of randomisation. Importantly, the TIMI score also predicted each of the components of this composite endpoint (Antman 2000). The TIMI risk score was subsequently validated in the TIMI III Registryof unselected UA/NSTEMI patients and was shown to predict the endpoint of death, MI or recurrent ischaemia and the components of the composite outcome at both six weeks and one year (Scirica 2002). Further, the TIMI risk score was validated for the death, MI or recurrent ischaemia composite endpoint for up to six months in the PRISM‐PLUS Trial; and it was shown to predict benefit from tirofiban, even in participants with a negative CK‐MB (Morrow 2002). Hence, this versatile risk score is able to identify patients with high event rates who may also benefit from an invasive strategy. Intuitively, one would expect that patients with higher TIMI scores, and therefore a higher risk for mortality and recurrent events, have more extensive CAD on angiography. This has been confirmed in a retrospective analysis of patients with UA/NSTEMI (Garcia 2004). The PRISM‐PLUS Trial authors also confirmed these findings by a retrospective analysis, and found the TIMI score to correlate with impaired epicardial artery blood flow and the presence of visible thrombus on angiography (Mega 2005). Although there are other published risk scores for UA/NSTEMI (de Araújo Gonçalves 2005), the TIMI risk score is perhaps the most widely used. In addition, the low event rates in ICTUS, which exclusively enrolled troponin‐positive participants, highlight the importance of considering multiple variables in risk stratification. Indeed, on five‐year follow‐up by the RITA‐3 trial authors, nine factors other than treatment group emerged as multi‐variate predictors of death or non‐fatal MI (Fox 2005). When the logistic coefficients for the risk factors were added and the study population divided into quartiles based upon risk score, participants in the highest quartile of risk score experienced substantially greater benefit from an invasive strategy. Similarly, the FRISC‐II trial authors developed a FRISC score, ranging from zero to seven, with one point alloted for each of seven factors: age of over 70 years, male sex, diabetes, previous MI, ST depression, increased troponin, and increased interleukin‐6 or C‐reactive protein (Lagerqvist 2005). Having a medium to high‐risk (score of three to seven) predicted benefit from an early invasive strategy, with risk ratios of 0.64 (95% CI 0.51 to 0.80) at two years and 0.75 (95% CI 0.64 to 0.89) at five years for the composite endpoint of death or non‐fatal MI (FRISC‐II). Low‐risk patients (score zero to two) did not benefit and had a trend towards harm for the composite endpoint of death or non‐fatal MI, with a RR of 1.62 (95% CI 0.71 to 3.69) at two years and 1.26 (95% CI 0.66 to 2.40) at five years (FRISC‐II). In contrast, the ICTUS trial authors confirmed the prognostic utility of the FRISC score, but were unable to predict benefit from an early invasive strategy in this trial; even participants with the highest FRISC scores (five to seven) derived no benefit from an early invasive approach (RR 1.30, 95% CI 0.69 to 2.47), in terms of the late death or MI endpoint.

Current 'real world' event rates in patients with UA/NSTEMI compared to rates observed in the included trials

The largest multinational registry, the GRACE registry, which collects data from 30 countries, has reported mortality rates in patients hospitalised with various forms of acute coronary syndrome (ACS). Entry criteria for this registry include a history of chest pain and one of the following: ischaemic ECG changes, increased cardiac biomarkers or a documented history of CAD. The in‐hospital mortality rates for patients recruited between 1999 and 2002 were 5.9% for patients with NSTEMI and 2.7% for patients with unstable angina. Also, the six‐month post‐discharge mortality rates were 6.2% and 3.6% for NSTEMI and unstable angina, respectively (Goldberg 2004). Furthermore, rehospitalisation rates six months post‐discharge were roughly 20%. Another report from the GRACE registry, which included patients recruited between 1999 and 2003, reported the six‐month post‐discharge mortality rates as 11.6% for NSTEMI and 6.8% for unstable angina (Van de Werf 2005). Clearly, the mortality rates from this real‐world registry are higher than those observed in the studies included in our meta‐analysis, as shown in Table 1. However, these patients did not receive optimal medical management in that only approximately 50% of NSTEMI patients received ACE inhibitors, heparin or statins (Goldberg 2004). While over 90% of patients received aspirin and over 80% received beta blockers, it is unlikely that many would have received clopidogrel as the patients studied were entered into the registry prior to publication of the CURE trial (CURE 2001); that is, before use of clopidogrel for UA/NSTEMI became accepted as standard therapy. Similarly, participants enrolled in the UA/NSTEMI trials received higher rates of medical therapy than participants enrolled in the CRUSADE registry (Kandzari 2005). However, the discrepancy in mortality rates between the participants in the included studies of this Cochrane review and registry‐reported mortality rates is arguably too high to be explained by advances in the medical management of UA/NSTEMI alone. Another explanation may be that selection and recruitment protocols may bias trials towards enrolling participants with a risk lower than that seen in unselected participants entered into registries. While analysis of available data suggests that high‐risk patients may benefit from an invasive strategy, this absolute benefit is likely to narrow as early medical therapies and risk stratification procedures for UA/NSTEMI improve, combined with the appropriate use of deferred coronary angiography and revascularisation. Novel medical therapies, such as prasugrel (TRITON‐TIMI 38) and ticagrelor (PLATO) instead of clopidogrel, continue to decrease absolute event rates in patients with UA/NSTEMI. Consequently, future trials of invasive versus conservative management for UA/NSETMI will be required as novel medical therapies are adopted. It is likely that only progressively higher‐risk patients will continue to benefit from routine invasive intervention in the future. A report from the GRACE registry has shown that increasing use of evidence‐based therapies has translated into reduced event rates over time (Fox 2007b). However, the lack of benefit observed for several endpoints in this review may be due to lower‐risk patients having been selected for trial enrolment.

The general paucity of enrolment of participants with cardiogenic shock or an advanced Killip class in the included studies may mean that the results of this systematic review are not applicable to this high‐risk subset. Advanced Killip class has been identified as an independent predictor of mortality in patients with NSTEMI (Khot 2003), while Killip class and congestive heart failure (development of or history of) were shown to predict death and the composite of death or MI in the GRACE registry (Fox 2006). Indeed, the current ACCF/AHA guidelines for UA/NSTEMI recommend using signs of heart failure as markers of increased risk (Jneid 2012). However, most of the included studies did not report Killip class, EF or brain natriuretic peptides among their baseline characteristics; and the event rates in the included studies indicate that participants with cardiogenic shock were excluded. Two exceptions to this are the FRISC‐II trial, in which 13% of participants were reported to have an EF of less than 45% at baseline, and the VINO trial, in which 53% of the sample were reported to be Killip class of II or III at baseline. This high percentage of participants with pulmonary oedema in VINO may explain why this trial had the highest standardised mortality rates of the included studies (Table 1); and, while being a small trial, identified a robust benefit for routine invasive strategy. Observational data have revealed that Killip class II and III patients enjoyed a significant mortality benefit (at 30 days and six months) from an invasive strategy, while Killip class I patients did not benefit (Rott 2001). The SHOCK 1999 trial (302 participants), which recruited STEMI patients with cardiogenic shock, uncovered a significant mortality benefit for a routine invasive versus conservative strategy at six months, with mortality rates of 50.3% and 63.1% (P = 0.027), respectively (SHOCK 1999). These are consistent with observations from the GRACE registry (Dauerman 2002). Similarly, elevated N‐terminal pro‐brain natriuretic peptide (NT‐proBNP) has been shown to predict a poor prognosis in patients with UA/NSTEMI, independently of age, Killip class or left ventricular EF (Jernberg 2004). In a retrospective subgroup analyses from FRISC‐II (2017 participants), NT‐proBNP measured at median of 39 hours after symptom presentation correlated (correlation coefficient, r) with TnT (r = 0.53, P < 0.001), interleukin‐6 (r = 0.29, P < 0.001) and the severity of coronary disease on angiography (Jernberg 2003). A relationship between higher brain natriuretic peptide (BNP) and more severe angiographic coronary disease was also evident in a small retrospective analysis from the TACTICS‐TIMI 18 trial, which also demonstrated higher BNP to be associated with higher TIMI frame counts, consistent with reduced myocardial perfusion (Sadanandan 2004). In FRISC‐II, NT‐proBNP predicted two‐year mortality independently of TnT, interleukin‐6 and left ventricular EF, but failed to predict the incidence of MI. Importantly, this retrospective subgroup analysis from the FRISC‐II trial authors suggested that the early invasive strategy only improved two‐year mortality in participants within the highest tertile for NT‐proBNP (greater than 906 ng/L for men, greater than 1345 ng/L for women) and with an interleukin‐6 concentration greater than 5 ng/mL (absolute risk reduction of 7.3%; RR 0.46, 95% CI 0.21 to 1.00). Such retrospective analyses are hypothesis‐generating and by no means definitive. A similar analysis from TACTICS‐TIMI 18 (1676 participants) measured BNP instead of NT‐proBNP, and dichotomised participants at a BNP of greater than 80 ng/L. The analysis found that participants with an elevated BNP exhibited greater seven‐day and six‐month mortality (2.5% versus 0.7%, P < 0.01; and 8.4% versus 1.8%, P < 0.01 respectively). However, BNP was not shown to predict any benefit from invasive management (Morrow 2003). This may be due to the relatively short follow‐up performed in the TACTICS‐TIMI 18 study, which was only six months (Table 1). The ICTUS trial authors also examined the prognostic influence of NT‐proBNP measured a median of 13 hours after presentation in a 1141‐participant subgroup extracted from the main trial (Windhausen 2007a). In the highest quartile (greater than 1170 ng/L for men, greater than 2150 ng/L for women), one‐year mortality was 7.3%, compared to just 1.1% among participants in the lower three quartiles. However, as with the retrospective analyses from the FRISC‐II and TACTICS‐TIMI 18 trials, NT‐proBNP failed to predict MI and, in contrast to FRISC‐II, elevated NT‐proBNP did not predict any benefit from an early invasive strategy in the ICTUS cohort (Windhausen 2007a). Hence, the role of natriuretic peptides and the assessment of patients for clinical features of congestive heart failure in UA/NSTEMI need to be further elucidated. In the interim, patients with features of congestive heart failure need to be considered at high‐risk for death and managed aggressively.

The GRACE investigators identified predictors of a poor prognosis that were derived from and validated in cohorts enrolled in GRACE from 1999 to 2002 and 2002 to 2003, respectively (Eagle 2004). The investigators identified nine variables — older age, history of MI, history of heart failure, increased heart rate, lower systolic blood pressure, elevated serum creatinine, elevated cardiac biomarkers, ST depression and not undergoing PCI — as independent predictors of increased six‐month mortality across the ACS spectrum. Of particular note is that the GRACE risk score incorporates renal function, which is an important, practical risk prognosticator in UA/NSTEMI that was not considered when the TIMI risk score was derived (Antman 2000). In a retrospective subgroup analysis of the FRISC‐II trial, creatinine clearance was estimated from serum creatinine using the Cockcroft‐Gault formula (Johnston 2006). In conservatively‐managed patients, the rates of death or MI for creatinine clearances of less than 69 mL/min, 69 to 90 mL/min and greater than 90 mL/min were 22.4%, 14.6% and 11.6%, respectively. The corresponding event rates in the invasive group were 14.6% (P < 0.01 versus conservative treatment), 9.9% (P = 0.048) and 11.2% (P = not significant), respectively. Indeed, there was a significant interaction between treatment strategy and outcomes in patients with a creatinine clearance of less than 90 mL/min. These data are indeed sobering, since patients with renal dysfunction are often denied aggressive therapy in the real world, possibly because of clinician concerns about bleeding risk and a poor prognosis regardless of therapy. These data are particularly relevant to clinicians practicing in countries where an estimate of glomerular filtration rate is mandatory on adult electrolyte panels, as is standard in the USA and Australia. Hence, risk stratification is an integral part of the management of patients with UA/NSTEMI and needs to be considered carefully in future prospective RCTs on the topic. Moreover, the roles of estimated glomerular filtration rate and NT‐proBNP as risk prognosticators over and above established markers such as the TIMI risk score need to be further evaluated.

Current 'real world' management of patients with UA/NSTEMI, emphasising the relationship between patient risk and subsequent management

Despite the extensive literature that exists on risk stratification, real‐world data from the GRACE registry has shown that high‐risk patients are no more likely to receive enoxaparin or glycoprotein IIb/IIIa receptor antagonists or to undergo catheterisation and PCI than low‐risk patients (Oliveira 2007). In a different analysis from the GRACE registry that only included participants recruited with direct access to a catheterisation laboratory, there was an inverse relationship between the level of patient risk (measured as a GRACE risk score) and the frequency of angiography and PCI (Fox 2007a; Ranasinghe 2011). Indeed, the rates of cardiac catheterisation in low‐, medium‐ and high‐risk patients with UA/NSTEMI were 72%, 68% and 51%, respectively, while the rates of PCI were 40%, 35% and 25%, respectively (Fox 2007a). In addition, thienopyridines and glycoprotein IIb/IIIa receptor antagonists were more commonly used in low‐risk patients than medium‐ or high‐risk patients with similar findings in a Canadian registry (Yan 2007). Likewise, diabetics with UA/NSTEMI, despite their higher risk, are not treated more aggressively than non‐diabetics (Franklin 2004). The reasons for the discrepancy between patient risk and treatment have been unclear, but recent data from a Canadian registry suggest that the most common reason for under‐utilization of an invasive strategy in high‐risk patients is the treating physician's underestimation of patient risk (Lee 2008). In this regard, a focused initiative to educate physicians on risk stratification could enhance quality of care in patients with UA/NSTEMI. It is also important to recognise that access and distance to cardiac catheterisation services are established predictors of treatment strategy.

Quality of life endpoints

Although not an initial outcome of this systematic review, this section provides a narrative discussion of health‐related quality of life (HRQOL) outcomes. Four studies (Eisenberg 2005; RITA‐3; FRISC‐II; TACTICS‐TIMI 18) specifically compared HRQOL and functional status following invasive versus non‐invasive management for NSTEMI. One trial (Eisenberg 2005) selected change in QOL as a primary endpoint, and the other three (RITA‐3; FRISC‐II; TACTICS‐TIMI 18) had HRQOL measures as secondary endpoints. In the primary endpoint trial, which included only 88 participants (Eisenberg 2005), there was no difference between the two groups at 12 months in terms of the level of peak exercise reached on an endurance exercise treadmill (7.8 versus 6.7 metabolic equivalents). Functional status was improved in the invasive group (Duke Activity Status Index scores 4.3 versus −3.5, P = 0.04), as was angina‐specific quality of life, assessed using the Seattle Angina Questionnaire measure of anginal stability (21.6 versus −5.3, P = 0.020), anginal frequency (22.9 versus 2.3, P = 0.02) and treatment satisfaction (11.2 versus −10.3, P = 0.02).

In the RITA‐3 trial, Kim 2005 assessed HRQOL was assessed with the Short Form‐36 (SF‐36), Seattle Angina Questionnaire (SAQ), EuroQOL Visual Analogue Scale (EQ‐VAS) and EuroQOL 5‐Dimensional Classification (EQ‐5D) scale at baseline, four months and one year follow‐up. Mean changes from baseline EQ‐VAS scores were better for the invasive versus non‐invasive strategy at four months (treatment difference of 3.0, P < 0.001) and one year (2.3, P < 0.01). The EQ‐5D utility scores were also higher in the invasive group at four months (treatment difference 0.036, P < 0.01) but not at one year (0.016, P = 0.20). For the SF‐36, the invasive strategy group scored significantly better at four months for physical function, physical role function, emotional role function, social function, vitality and general health. The SAQ scores for exertional capacity, anginal stability and frequency, treatment satisfaction and disease perception were significantly better for the invasive strategy group at both four months and one year, though attenuated at the last follow‐up. The study authors concluded that improvements in HRQOL associated with the invasive strategy were most likely due to improved in anginal symptoms.

In theFRISC‐II trial, Janzon 2004 measured HRQOL was measured using the generic Medical Outcomes Study SF‐36 and the disease‐specific Angina Pectoris Quality of Life Questionnaire (APQLQ) at baseline and three, six and 12 months follow‐up. The invasively‐treated group reported a significantly better quality of life in all eight scales and both component scores (physical and mental) of the SF‐36 at three and six months of follow‐up (P < 0.01) relative to the non‐invasively treated group. These differences remained at 12 months follow‐up, with significance in seven of the scales and in the physical component score. The invasive group scored significantly higher on all five subscales of the APQLQ scores at three months (P < 0.01), and on four subscales at six months (P < 0.05), but only on one subscale at one year.

Regarding the TACTICS‐TIMI 18 trial, Weintraub 1999 planned to assess health status using some measure of utility in order to perform cost‐effectiveness evaluations of invasive versus non‐invasive strategy, but subsequent publications failed to disclose HRQOL data (Mahoney 2002). From the available evidence, it would appear that improvements in HRQOL as a result of an invasive strategy are modest and last on average no more than 12 months, with anginal relief likely the key determinant of improved HRQOL.

Findings from studies in the pre‐stent era and other reviews on this topic

We excluded two large trials that were undertaken during the pre‐stent era (TIMI‐3b; VANQWISH 1998). The early invasive arm of TIMI‐3b involved cardiac catheterisation an average of 36 hours after randomisation and coronary revascularisation by coronary angioplasty or CABG. The early invasive strategy had no effect on the hard clinical endpoints of death, MI, stroke or the composite of death or MI. As is consistent with more recent clinical trials, the early invasive strategy reduced recurrent hospitalisation at both six weeks and one year, with RRs of 0.54 (95% CI 0.40 to 0.74) and 0.79 (95% CI 0.68 to 0.93), respectively (TIMI‐3b). In TIMI‐3b, a routine invasive strategy did not reduce the need for anti‐angina medications at one year. In contrast, the VANQWISH 1998 study demonstrated increased risk associated with the early invasive strategy, which involved cardiac catheterisation an average of 48 hours after randomisation. In fact, the early invasive strategy was associated with an increased risk ratio of mortality prior to hospital discharge, and at one month and one year (RR 3.47 (95% CI 1.41 to 8.52); RR 2.53, 95% CI 1.19 to 5.42; and RR 1.60, 95% CI 1.08 to 2.37, respectively) (VANQWISH 1998). Similarly, increased risk was associated with the early invasive strategy for the composite endpoint of death or non‐fatal MI. The hazard of an early invasive strategy on these endpoints ceased to be significant by the end of the study (average 23 months). Forty‐four percent of participants in the invasive arm of this trial underwent a revascularisation procedure, of which 47% involved CABG. The mortality associated with CABG in the invasive arm was 11.6%, compared to 3.4% in the conservative arm. Braunwald 2003 has cited this discrepancy as an explanation for the increased mortality in the early invasive arm of the VANQWISH 1998 trial. Unsurprisingly, rates of background medical therapy were low by contemporary standards.

Two older meta‐analyses on this topic that included the aforementioned pre‐stent era trials, plus trials that we excluded for reasons other than low stent use, reached different conclusions than the ones presented here (Choudhry 2005; Mehta 2005). These reviews did not include the most recent trials, including the OASIS 5 substudy, LIPSIA‐NSTEMI, Italian Elderly ACS and ICTUS studies. A subsequent meta‐analysis included the early trials and the one‐year results from ICTUS (Bavry 2006). The review by Mehta 2005 associated an invasive strategy with an increased risk of mortality during the period from randomisation to hospital discharge (RR 1.61, 95% CI 1.14 to 2.27). When Mehta 2005 analysed the outcomes from hospital discharge to end of follow‐up, the early invasive strategy was associated with reductions in death and non‐fatal MI (RR 0.78, 95% CI 0.64 to 0.94; and RR 0.56, 95% CI 0.47 to 0.68, respectively). When they analysed trial data from randomisation to the end of follow‐up, the invasive strategy exhibited no effect on mortality, but induced a reduction in non‐fatal MI (RR 0.77, 95% CI 0.67 to 0.89). This Cochrane review analysed the endpoints at certain time points, since we felt that combining outcomes collected from studies of short duration (six months) with those of longer duration (five years) would not provide a meaningful point estimate (see the 'Characteristics of included studies' table). All reviews consistently found a significant reduction in recurrent angina and rehospitalisation with an invasive strategy (Bavry 2006; Choudhry 2005; Mehta 2005). More recently, a meta‐regression analysis that included the earlier studies but excluded VANQWISH 1998 revealed the benefit of an invasive strategy — with respect to the endpoint of death or the composite of death or MI — to be related to the comparator odds ratio for events in the conservative group (Tarantini 2007). This implies that the benefit of an invasive strategy relates to the level of baseline risk in the comparator group. One meta‐analysis has been published since the publication of late follow‐up data from the ICTUS trial. This report, which included the older studies, identified no benefit of an invasive strategy on the endpoints of death, MI, or the composite of death or MI (Qayyum 2008). The findings from our analysis differ, because we excluded older studies and utilised the reported 'spontaneous' MI endpoint for our analysis, in light of the controversy surrounding the routine peri‐procedural biomarker assessment undertaken by the ICTUS trial authors.

Relevant international guidelines for management of UA/NSTEMI

Both the current AHA (Anderson 2007; Jneid 2012) and ESC (Hamm 2011) guidelines make class 1 recommendations for an invasive strategy in patients who are symptomatic or are considered (Level A evidence). The AHA guidelines also endorse the option of treating stabilised but high‐risk (for example troponin‐positive) patients conservatively, however with only Class IIb recommendation.

Limitations

We have limited the included studies in this Cochrane review to those from the post‐stent era. However, a number of changes in practice have occurred over this time which limit the applicability of findings from this meta‐analysis to contemporary practice. Of greatest significance, during the post‐stent era, is that the routine use of glycoprotein IIb/IIIa inhibitors gained acceptance (Boersma 2002). Subsequently, however this practice has been discredited due to the association with increased bleeding (EARLY ACS 2009). As such, we have presented analyses of studies in which glycoprotein IIb/IIIa use was routine (Analyses 1 and 2) as of historical interest, with Analysis 3 being the most relevant to contemporary practice. Additionally, across this time period there has been controversy regarding access site efficacy. In particular, the prospective randomised RIFLE‐STEACS study reported significant benefit for a transradial verse transfemoral approach for major adverse cardiac and cerebrovascular events (MACCE), non‐CABG‐related bleeding and overall net adverse clinical event (NACE) rate among STEMI patients. Subsequently, the transradial access approach has emerged as the preferred strategy for PCI and has been adopted as routine practice for invasive strategies in ACSs. Despite this, a transfemoral strategy was predominant amongst the included studies in this meta‐analysis, which potentially resulted in increased adverse events in the routine invasive strategy compared with contemporary practice. Additionally, improved outcomes have also resulted from refinement in stent design with second‐generation drug‐eluting stents forming the cornerstone of modern PCI practice (Sarno 2012). Both the predominance of a transfemoral approach and use of earlier generation stents amongst the included studies in this meta‐analysis potentially and differentially diminish outcomes in the routine invasive arm compared with contemporary practice, thus obscuring any comparison with selective invasive strategies.

These limitations of the current body of evidence form important considerations for future trials designed to compare a routine verse selective invasive strategy in UA/NSTEMI. We recommend that such studies employ a transradial access route, an antithrombotic regime consisting of aspirin and ticagrelor across all study participants and second generation drug‐eluting stents to most accurately reflect current practice and difference between routine and selective invasive strategies. Finally, where possible, analyses should allow for the discrete assessment of outcome measures for NSTEMI and UA as the heterogeneity of combined UA/NSTEMI may mask important intervention risk‐benefit differences between the two entities.

Quality of the evidence

The GRADE approach was employed to interpret findings and the GRADE profiler (GRADEPRO) allowed us to import data from Review Manager 5.3 (Review Manager) to create 'Summary of findings' tables. The quality of evidence for routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial (UA/NSTEMI) infarction in the stent era (summary of findings Table for the main comparison and summary of findings Table 2) ranged from
moderate to low across the different outcomes. This was mainly due to risk of bias and imprecise results.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.
Figures and Tables -
Figure 1

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.
Figures and Tables -
Figure 2

Risk of bias summary: review authors' judgements about each risk of bias item for each included study.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 1 Index death.
Figures and Tables -
Analysis 1.1

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 1 Index death.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 2 Early death.
Figures and Tables -
Analysis 1.2

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 2 Early death.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 3 Intermediate death.
Figures and Tables -
Analysis 1.3

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 3 Intermediate death.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 4 Late death.
Figures and Tables -
Analysis 1.4

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 4 Late death.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 5 Index myocardial infarction.
Figures and Tables -
Analysis 1.5

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 5 Index myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 6 Early myocardial infarction.
Figures and Tables -
Analysis 1.6

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 6 Early myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 7 Intermediate myocardial infarction.
Figures and Tables -
Analysis 1.7

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 7 Intermediate myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 8 Late myocardial infarction.
Figures and Tables -
Analysis 1.8

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 8 Late myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 9 Index death or non‐fatal myocardial infarction.
Figures and Tables -
Analysis 1.9

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 9 Index death or non‐fatal myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 10 Early death or non‐fatal myocardial infarction.
Figures and Tables -
Analysis 1.10

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 10 Early death or non‐fatal myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 11 Intermediate death or non‐fatal myocardial infarction.
Figures and Tables -
Analysis 1.11

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 11 Intermediate death or non‐fatal myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 12 Intermediate death or non‐fatal myocardial infarction; gender subanalysis.
Figures and Tables -
Analysis 1.12

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 12 Intermediate death or non‐fatal myocardial infarction; gender subanalysis.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 13 Late death or non‐fatal myocardial infarction.
Figures and Tables -
Analysis 1.13

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 13 Late death or non‐fatal myocardial infarction.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 14 Intermediate refractory angina.
Figures and Tables -
Analysis 1.14

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 14 Intermediate refractory angina.

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 15 Intermediate rehospitalisation.
Figures and Tables -
Analysis 1.15

Comparison 1 All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use, Outcome 15 Intermediate rehospitalisation.

Comparison 2 Safety endpoints, Outcome 1 Procedure‐related myocardial infarction.
Figures and Tables -
Analysis 2.1

Comparison 2 Safety endpoints, Outcome 1 Procedure‐related myocardial infarction.

Comparison 2 Safety endpoints, Outcome 2 Bleeding.
Figures and Tables -
Analysis 2.2

Comparison 2 Safety endpoints, Outcome 2 Bleeding.

Summary of findings for the main comparison. Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial (UA/NSTEMI) infarction in the stent era

Routine invasive strategies versus selective invasive strategies (conservative) for UA/NSTEMI infarction in the stent era

Participant or population: participants with UA/NSTEMI in the stent era
Settings: hospital setting
Intervention: routine invasive strategies
Comparison: selective invasive strategies (conservative)

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

Number of participants
(studies)

Quality of the evidence
(GRADE)

Assumed risk

Corresponding risk

Selective invasive strategies (conservative)

Routine invasive strategies

Death
Follow‐up: 6 to 12 months1

Study population

RR 0.87
(0.64 to 1.18)

8915
(8 studies)

⊕⊕⊝⊝
low2,3

42 per 1000

36 per 1000
(27 to 49)

Moderate risk population

39 per 1000

34 per 1000
(25 to 46)

Myocardial infarction
Follow‐up: 6 to 12 months1

Study population

RR 0.79
(0.63 to 1)

8915
(8 studies)

⊕⊕⊕⊝
moderate2

78 per 1000

62 per 1000
(49 to 78)

Moderate risk population

89 per 1000

70 per 1000
(56 to 89)

Death or non‐fatal Myocardial infarction
Follow‐up: 6 to 12 months1

Study population

RR 0.93
(0.71 to 1.2)

7715
(7 studies)

⊕⊕⊝⊝
low2,3

113 per 1000

105 per 1000
(80 to 135)

Moderate risk population

109 per 1000

101 per 1000
(77 to 131)

Refractory angina
Follow‐up: 6 to 12 months1

Study population

RR 0.64
(0.52 to 0.79)

8287
(5 studies)

⊕⊕⊕⊝
moderate2

325 per 1000

208 per 1000
(169 to 257)

Moderate risk population

129 per 1000

83 per 1000
(67 to 102)

Rehospitalisation
Follow‐up: 6 to 12 months1

Study population

RR 0.77
(0.63 to 0.94)

6921
(6 studies)

⊕⊕⊕⊝
moderate2

286 per 1000

220 per 1000
(180 to 269)

Moderate risk population

122 per 1000

94 per 1000
(77 to 115)

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% CI) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
Abbreviations: CI: confidence interval; RR: risk ratio; UA: unstable angina; NSTEMI: non ST segment myocardial infarction.

GRADE Working Group grades of evidence
High quality: further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: we are very uncertain about the estimate.

1 Intermediate end points.
2 Downgraded by one due to possible risk of bias due to lack of blinding.
3 Downgraded by one due to imprecision with effect size overlapping the line of no effect and appreciable benefit or harm.

Figures and Tables -
Summary of findings for the main comparison. Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial (UA/NSTEMI) infarction in the stent era
Summary of findings 2. Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI) in the stent era

Routine invasive strategies versus selective invasive strategies (conservative) for UA/NSTEMI in the stent era

Participant or population: participants with UA/NSTEMI in the stent era
Settings: hospital setting
Intervention: routine invasive strategies
Comparison: selective invasive strategies (conservative)

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

Number of participants
(studies)

Quality of the evidence
(GRADE)

Assumed risk

Corresponding risk

Selective invasive strategies (conservative)

Routine invasive strategies

Complications of angiography or revascularization
Bleeding

Study population

RR 1.73
(1.3 to 2.31)

7584
(6 studies)

⊕⊕⊕⊝
moderate1

42 per 1000

72 per 1000
(54 to 96)

Moderate risk population

27 per 1000

47 per 1000
(35 to 62)

Complications of angiography or revascularization
Procedure‐related myocardial infarction

Study population

RR 1.87
(1.47 to 2.37)

6380
(5 studies)

⊕⊕⊕⊝
moderate1

30 per 1000

57 per 1000
(45 to 72)

Moderate risk population

29 per 1000

54 per 1000
(43 to 69)

*The basis for the assumed risk (e.g. the median control group risk across studies) is provided in footnotes. The corresponding risk (and its 95% CI) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI).
Abbreviations: CI: confidence interval; RR: risk ratio; UA: unstable angina; NSTEMI: non ST segment myocardial infarction.

GRADE Working Group grades of evidence
High quality: further research is very unlikely to change our confidence in the estimate of effect.
Moderate quality: further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
Low quality: further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate.
Very low quality: we are very uncertain about the estimate.

1 Downgraded by one due to possible risk of bias due to lack of blinding.

Figures and Tables -
Summary of findings 2. Routine invasive strategies versus selective invasive strategies (conservative) for unstable angina and non‐ST elevation myocardial infarction (UA/NSTEMI) in the stent era
Table 1. Detailed characteristics of included studies, rates of angiography and revascularisation

Study characteristic

TACTICS‐TIMI 18

ICTUS

RITA‐3

FRISC‐II

VINO

Italian Elderly ACS

LIPSIA‐NSTEMI

OASIS 5

Year of publication

2001

2005

2002

1999

2001

2012

2012

2012

Total number of participants

2220

1200

1810

2457

131

313

602

184

Stent use in invasive arm %

83

88

88

61

47

50

73

52

Men %

66

74

62

70

80

50

67

0

Mean age

62

62

63

65

66

82

70

68

Trial duration

6 months

4 years

5 years

5 years

6 months

1 year

6 months

2 years

Diabetes mellitus %

28

14

13

13

25

36

38

25

Myocardial infarction (MI) on trial enrolment %

54

100

75

58

100

100

100

67

Previous MI %

29

23

28

23

26

31

20

22

ST depression %

39

48

37

46

47

NA

62

47

Mortality in conservatively managed participants at end of follow‐up % (note different trial durations)

3.5

7.7

14

10.1

13.4

13.8

6.5

2.2

Mortality in conservatively managed participants expressed as an average mortality per year of follow‐up %/year

7.0

1.9

2.8

2.0

26.8

13.8

13

1.1

MI rate in conservatively managed participants at end of follow‐up % (note different trial durations)

6.9

12.3 (as per trial definition)

6.2

17.7

14.9

10.7

11.5

13.3

Glycoprotein 2b/3a receptor antagonist use in invasive arm %

94

94

9

10

0

17

99

12

Revascularization at end of follow‐up invasive/conservative %

61/44

81/58

61/38

80/52

78/39

58/31

84/70

64/49

Difference in revascularization rates at end of follow‐up between the 2 strategies %

17

23

23

28

39

27

14

15

Percentage of revascularization procedures in the invasive group being CABG %

22

24

42

41

35

7

10

21

Medical co‐interventions (% of participants enrolled)

Aspirin: 98; unfractionated heparin: 99; beta‐blocker: 82; statin: 52; clopidogrel: 0 (this was a criterion for exclusion)

Aspirin: 100 as per protocol, enoxaparin: 100 as per protocol, statin: 92, clopidogrel: 55

Aspirin: 92; enoxaparin: 84; unfractionated heparin: 11; beta‐blocker: 72; calcium channel antagonist: 35; ACE inhibitor: 18; statin: 45

Aspirin: 93; dalteparin 50; unfractionated heparin: 50; beta‐blocker: 79; calcium channel antagonist: 20; statin: 56

Aspirin: 100 as per protocol, heparin: 100 as per protocol; beta‐blocker: 76; calcium channel antagonist: 9; ACE inhibitor: 47; statin: 43

During index admission: aspirin: 96; ticlopidine: 3.2; clopidogrel: 90; unfractionated heparin: 24; enoxaparin: 50; bivalirudin: 2.5; fondaparinux: 7; at discharge: aspirin: 91; ticlopidine: 2; clopidogrel: 76; beta‐blockers: 60; ACEi: 80; statins: 80

Beta‐blockers: 99; ACEi/ARB: 99; Asprin: 100; clopidogrel/prasugrel: 99; statins: 98; tirofiban: 99

Aspirin: 99; clopidogrel: or ticlopedin: 81; dual antiplatelet therapy: 80; UFH: 10; enoxaparin: 50; fondaparinux: 50; ACE inhibitor or ARB: 76; beta‐blocker: 94; lipid‐lowering drug: 87

Figures and Tables -
Table 1. Detailed characteristics of included studies, rates of angiography and revascularisation
Table 2. Definitions of myocardial infarction in the included studies

Study name

Definition for non‐procedural myocardial infarction (MI)

Definition of procedural MI

More than one definition of MI?

Definition of MI used in this review

RITA‐3

Clinical symptoms, ECG changes and CK‐MB or Toponin > 2 x upper limit of normal > 24 hours postrandomisation

Clinical symptoms, ECG changes and CK‐MB or Toponin > 2 x upper limit of normal > 24 hours postrandomisation

Yes

As per trial definition

ICTUS

CK‐MB > upper limit of normal or a 50% decline from a peak value followed by subsequent rise to a value greater than the upper limit of normal. An increased troponin above the upper limit of normal was also used beyond one year of follow‐up

CK‐MB > upper limit of normal or a 50% decline from a peak value followed by subsequent rise to a value greater than the upper limit of normal. New Q waves on the electrocardiogram were used to define MI associated with coronary artery bypass grafting

Yes

In various publications, the trial authors report the MI end point as the following.

  1. Total MI.

  2. Spontaneous MI.

  3. Procedural MI.

We utilized spontaneous MI for our MI endpoint, death/spontaneous MI for our death or MI composite and procedural MI is reported as a safety endpoint. Since the prognostic value of peri‐procedural infarctions is still debated, 'spontaneous' MI is our preferred endpoint since this allows for consistency with the other trials

TACTICS‐TIMI 18

CK‐MB > upper limit of normal or > 50% over previous

CK‐MB > 3 times upper limit of normal or > 50% over previous

No

As per trial definition

Italian Elderly ACS

Cardiac ischaemic symptoms at rest within 42 hours before randomisation, together with Ischemic ECG changes (transient or persistent ST‐segment elevation or depression > 0.5mm but < 1 mm in the case of ST‐elevation, or persistent and definite T‐wave inversion > 1 mm in at least 2 contiguous leads) and/or any elevation of CK‐MB or cTn (> upper limit of normal)

Recurrent infarction within first 72 hours: Ischemic ECG changes (new Q‐waves > 0.04 s in 2 or more contiguous leads which is not an ambiguous change from baseline) CK‐MB > upper limit of normal and increased > 50% over previous value

Following PCI: CK‐MB elevation > 3 times upper limit of normal and increased by at least 50% over the previous value.

In 72 hours following CABG: both biomarker and ECG criteria if the CK‐MB is > 5 times upper limit of normal but < 10 times upper limit of normal; if the cardiac markers are > 10 times upper limit of normal, ECH criteria are not required.

No

As per trial definition

LIPSIA‐NSTEMI

Ischaemic symptoms that were increasing or occurred at rest, with the last episode < 24 hours before randomisation plus elevated troponin T level ≥ 0.1 ng/mL

In‐hospital re‐MI was defined by the occurrence of any of the following: new Q waves in ≥ 2 contiguous leads plus ischaemic symptoms > 20 mins; or new ST‐segment elevation in ≥ 2 contiguous leads plus ischaemic symptoms > 20 mins; or elevation of CK‐MB > 5 upper limit of normal in those with CK‐MB > 5 times upper limit of normal at randomisation an increase > 50% was required for re‐MI definition

No

As per trial definition

VINO

Recurrent ischaemic chest pain lasting > 20 minutes, new ECG changes and CK‐MB > 1.5 times the upper limit of normal after 72 hours postrandomisation

Recurrent ischaemic chest pain lasting > 20 minutes, new ECG changes and CK‐MB > 1.5 times the upper limit of normal after 72 hours postrandomisation

No

As per trial definition

FRISC‐II

Two or three of the following criteria: chest pain, ECG changes or elevated markers of myocardial damage. Marker definitions: CK‐MB mass > upper limit of normal or CK, CK‐B, CK‐MB activity > 2 times upper limit of normal in 1 sample of CK‐MB activity > upper limit of normal in 2 samples

Either 2 or 3 of the following criteria: chest pain, ECG changes or elevated markers of myocardial damage. Marker definitions: CK‐MB mass > 1.5 times upper limit of normal or CK, CK‐B, CK‐MB activity > 3 times upper limit of normal in 1 sample of CK‐MB activity > 2 times upper limit of normal in 2 samples

No

As per trial definition

OASIS 5

Typical rise and fall of biochemical marker of myocardial necrosis (including troponin, CK‐MB, CK) to greater than 2 x ULN (if markers were already elevated, > 50% of the lowest recovery biomarker level from the index infarction) and at least one of the following.

  1. Ischaemic symptoms.

  2. Development of pathological Q waves on ECG.

  3. ECG changes indicative of ischaemia (ST‐segment elevation or depression).

  4. Coronary artery intervention.

  5. Findings of an acute MI at autopsy.

Typical rise and fall of biochemical marker of myocardial necrosis (including troponin, CK‐MB, CK) to greater than 3 x ULN if within 48 hours of PCI or 5 x ULN if within 48 hours of CABG and at least one of the following.

  1. Ischaemic symptoms.

  2. Development of pathological Q waves on ECG.

  3. ECG changes indicative of ischaemia (ST‐segment elevation or depression).

  4. Coronary artery intervention.

  5. Findings of an acute MI at autopsy.

No

As per trial definition

MI = myocardial infarction

Figures and Tables -
Table 2. Definitions of myocardial infarction in the included studies
Comparison 1. All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Index death Show forest plot

6

8094

Risk Ratio (M‐H, Random, 95% CI)

1.54 [1.02, 2.34]

1.1 Routine glycoprotein IIb/IIIa receptor antagonist use

2

3383

Risk Ratio (M‐H, Random, 95% CI)

1.67 [0.84, 3.31]

1.2 No routine glycoprotein IIb/IIIa receptor antagonist use

4

4711

Risk Ratio (M‐H, Random, 95% CI)

1.48 [0.88, 2.48]

2 Early death Show forest plot

4

4345

Risk Ratio (M‐H, Random, 95% CI)

1.18 [0.70, 2.00]

2.1 Routine glycoprotein IIb/IIIa receptor antagonist use

1

2220

Risk Ratio (M‐H, Random, 95% CI)

1.38 [0.76, 2.51]

2.2 No routine glycoprotein IIb/IIIa receptor antagonist use

3

2125

Risk Ratio (M‐H, Random, 95% CI)

1.01 [0.31, 3.33]

3 Intermediate death Show forest plot

8

8915

Risk Ratio (M‐H, Random, 95% CI)

0.87 [0.64, 1.18]

3.1 Routine glycoprotein IIb/IIIa receptor antagonist use

3

4020

Risk Ratio (M‐H, Random, 95% CI)

0.92 [0.66, 1.27]

3.2 No routine glycoprotein IIb/IIIa receptor antagonist use

5

4895

Risk Ratio (M‐H, Random, 95% CI)

0.85 [0.48, 1.49]

4 Late death Show forest plot

3

5467

Risk Ratio (M‐H, Random, 95% CI)

0.90 [0.76, 1.08]

4.1 Routine glycoprotein IIb/IIIa receptor antagonist use

1

1200

Risk Ratio (M‐H, Random, 95% CI)

1.11 [0.74, 1.67]

4.2 No routine glycoprotein IIb/IIIa receptor antagonist use

2

4267

Risk Ratio (M‐H, Random, 95% CI)

0.87 [0.72, 1.04]

5 Index myocardial infarction Show forest plot

7

8694

Risk Ratio (M‐H, Random, 95% CI)

1.08 [0.65, 1.80]

5.1 Routine glycoprotein IIb/IIIa receptor antagonist use

3

3983

Risk Ratio (M‐H, Random, 95% CI)

0.96 [0.51, 1.83]

5.2 No routine glycoprotein IIb/IIIa receptor antagonist use

4

4711

Risk Ratio (M‐H, Random, 95% CI)

1.22 [0.59, 2.55]

6 Early myocardial infarction Show forest plot

4

4345

Risk Ratio (M‐H, Random, 95% CI)

0.68 [0.43, 1.08]

6.1 Routine glycoprotein IIb/IIIa receptor antagonist use

1

2220

Risk Ratio (M‐H, Random, 95% CI)

0.53 [0.35, 0.79]

6.2 No routine glycoprotein IIb/IIIa receptor antagonist use

3

2125

Risk Ratio (M‐H, Random, 95% CI)

0.87 [0.52, 1.44]

7 Intermediate myocardial infarction Show forest plot

8

8915

Risk Ratio (M‐H, Random, 95% CI)

0.79 [0.63, 1.00]

7.1 Routine glycoprotein IIb/IIIa receptor antagonist use

3

4020

Risk Ratio (M‐H, Random, 95% CI)

0.95 [0.56, 1.60]

7.2 No routine glycoprotein IIb/IIIa receptor antagonist use

5

4895

Risk Ratio (M‐H, Random, 95% CI)

0.73 [0.60, 0.89]

8 Late myocardial infarction Show forest plot

3

5467

Risk Ratio (M‐H, Random, 95% CI)

0.78 [0.67, 0.92]

8.1 Routine glycoprotein IIb/IIIa receptor antagonist use

1

1200

Risk Ratio (M‐H, Random, 95% CI)

1.01 [0.66, 1.55]

8.2 No routine glycoprotein IIb/IIIa receptor antagonist use

2

4267

Risk Ratio (M‐H, Random, 95% CI)

0.75 [0.63, 0.90]

9 Index death or non‐fatal myocardial infarction Show forest plot

4

6618

Risk Ratio (M‐H, Random, 95% CI)

1.14 [0.59, 2.21]

9.1 Routine glycoprotein IIb/IIIa receptor antagonist use

1

2220

Risk Ratio (M‐H, Random, 95% CI)

0.77 [0.51, 1.17]

9.2 No routine glycoprotein IIb/IIIa receptor antagonist use

3

4398

Risk Ratio (M‐H, Random, 95% CI)

1.46 [0.75, 2.86]

10 Early death or non‐fatal myocardial infarction Show forest plot

2

2351

Risk Ratio (M‐H, Random, 95% CI)

0.64 [0.45, 0.92]

10.1 Routine glycoprotein IIb/IIIa receptor antagonist use

1

2220

Risk Ratio (M‐H, Random, 95% CI)

0.67 [0.48, 0.94]

10.2 No routine glycoprotein IIb/IIIa receptor antagonist use

1

131

Risk Ratio (M‐H, Random, 95% CI)

0.30 [0.06, 1.39]

11 Intermediate death or non‐fatal myocardial infarction Show forest plot

7

7715

Risk Ratio (M‐H, Random, 95% CI)

0.93 [0.71, 1.20]

11.1 Routine glycoprotein IIb/IIIa receptor antagonist use

2

2820

Risk Ratio (M‐H, Random, 95% CI)

0.97 [0.59, 1.60]

11.2 No routine glycoprotein IIb/IIIa receptor antagonist use

5

4895

Risk Ratio (M‐H, Random, 95% CI)

0.91 [0.62, 1.32]

12 Intermediate death or non‐fatal myocardial infarction; gender subanalysis Show forest plot

5

6975

Risk Ratio (M‐H, Random, 95% CI)

0.78 [0.67, 0.91]

12.1 Male

4

4454

Risk Ratio (M‐H, Random, 95% CI)

0.73 [0.62, 0.87]

12.2 Female

5

2521

Risk Ratio (M‐H, Random, 95% CI)

0.87 [0.65, 1.16]

13 Late death or non‐fatal myocardial infarction Show forest plot

3

5467

Risk Ratio (M‐H, Random, 95% CI)

0.89 [0.73, 1.08]

13.1 Routine glycoprotein IIb/IIIa receptor antagonist use

1

1200

Risk Ratio (M‐H, Random, 95% CI)

1.19 [0.87, 1.63]

13.2 No routine glycoprotein IIb/IIIa receptor antagonist use

2

4267

Risk Ratio (M‐H, Random, 95% CI)

0.81 [0.72, 0.92]

14 Intermediate refractory angina Show forest plot

5

8287

Risk Ratio (M‐H, Random, 95% CI)

0.64 [0.52, 0.79]

14.1 Routine glycoprotein IIb/IIIa receptor antagonist use

3

4020

Risk Ratio (M‐H, Random, 95% CI)

0.67 [0.42, 1.08]

14.2 No routine glycoprotein IIb/IIIa receptor antagonist use

2

4267

Risk Ratio (M‐H, Random, 95% CI)

0.57 [0.50, 0.64]

15 Intermediate rehospitalisation Show forest plot

6

6921

Risk Ratio (M‐H, Random, 95% CI)

0.77 [0.63, 0.94]

15.1 Routine glycoprotein IIb/IIIa receptor antagonist use

3

4020

Risk Ratio (M‐H, Random, 95% CI)

0.83 [0.61, 1.14]

15.2 No routine glycoprotein IIb/IIIa receptor antagonist use

3

2901

Risk Ratio (M‐H, Random, 95% CI)

0.71 [0.54, 0.94]

Figures and Tables -
Comparison 1. All studies undertaken in the stent era regardless of glycoprotein IIb/IIIa receptor use
Comparison 2. Safety endpoints

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Procedure‐related myocardial infarction Show forest plot

5

6380

Risk Ratio (M‐H, Random, 95% CI)

1.87 [1.47, 2.37]

2 Bleeding Show forest plot

6

7584

Risk Ratio (M‐H, Random, 95% CI)

1.73 [1.30, 2.31]

Figures and Tables -
Comparison 2. Safety endpoints