Bivalirudin versus heparin in primary PCI: clinical outcomes and cost analysis.

Background: The evidence for benefits of bivalirudin over heparin has recently been challenged. We aimed to analyse the safety and cost-effectiveness following reintroduction of heparin instead of bivalirudin as the standard anticoagulation for primary percutaneous coronary intervention (PPCI) in a high-volume centre. Methods and results: This analysis was an open-label, prospective registry including all patients admitted to our centre for PPCI from April 2014 to April 2016. Heparin was reintroduced as standard anticoagulant in April 2015. During the 2 years, 1291 patients underwent a PPCI, 662 in the Bivalirudin protocol period (Cohort B) and 629 in the Heparin protocol period (Cohort H). Baseline and procedural characteristics were not significantly different, except for a higher use of thromboaspiration and femoral access in the earlier Cohort B. Glycoprotein 2b3a (Gp2b3a) antagonists were used in 24% of the patients in Cohort B versus 28% in Cohort H (P<0.01). We did not observe any differences in death at 180 days (11.03% in Cohort B vs 11.29% in Cohort H)(HR 95% CI 0.98 (0.72 to 1.33), P=0.88). The incidence of any bleeding complications at 30 days did not differ between the two periods (21.9% vs 21.9%, P=0.99). The cost related to the anticoagulants amounted to £246 236 in Cohort B versus £4483 in Cohort H (£324 406 vs £102 347 when adding Gp2b3a antagonists).
Conclusion: We did not find clinically relevant changes in patient outcomes, including bleeding complications with reintroduction of heparin in our PPCI protocol. However, the use of heparin was associated with a major reduction in treatment costs.

Bivalirudin is associated with reduction in the risk of bleeding events during primary percutaneous coronary intervention (PPCI) for ST elevation myocardial infarction (STEMI) in comparison with heparin versus Gp2b3a inhibitors.

Recently, similar outcomes between bivalirudin and heparin has been showed in randomized trials, with higher risk of stent thrombosis with bivalirudin.

The present analysis showed that the reintroduction of heparin instead of bivalirudin as standard anticoagulant for PPCI did not lead to significant differences in efficacy or safety outcomes, but was associated with a significant cost saving.

The use of heparin should be the first line anticoagulant during the management of STEMI with PPCI.

Introduction

European and American guidelines recommend intravenous anticoagulation in all patients undergoing primary percutaneous coronary intervention (PPCI).1 2 Bivalirudin is a specific, reversible, direct thrombin inhibitor, characterised by a quick onset of action and short half-life, overcoming the limitations of heparin, with a more predictable antithrombotic response. Harmonizing Outcomes with Revascularization and Stents in Acute Myocardial Infarction (HORIZONS-AMI) and most recently the European Ambulance Acute Coronary Syndrome Angiography (EUROMAX) trial suggested the superiority of bivalirudin versus the combination of heparin plus glycoprotein 2b3a (Gp2b3a) antagonists in patients undergoing PPCI. The benefit was in net adverse clinical events, driven mainly by the reduction of bleeding complications, despite a higher rate of stent thrombosis (ST).3 4

Bivalirudin use in PPCI has recently been challenged by the results of the Unfractionated heparin versus bivalirudin in primary percutaneous coronary intervention (HEAT-PPCI) trial. This single-centre randomised trial compared bivalirudin and unfractionated heparin (UFH) with bailout Gp2b3a and favoured heparin with respect to ischaemic and bleeding outcomes.5 This trial used contemporary methods, including radial arterial access and more potent P2Y12 blockers (ie, prasugrel and ticagrelor). as the default strategy. As a result, the most recent guidelines of the European Society of Cardiology (ESC) downgraded the recommendation to use bivalirudin from IB to IIA.1 Following this, Bivalirudin or unfractionated heparin in patients with acute coronary syndromes managed invasively with and without ST elevation (MATRIX) trial showed in the largest and most contemporary cohort, similar outcomes between heparin and bivalirudin.6

Prior to publication of the HEAT-PPCI results, the standard of care at our institution was to use bivalirudin as the anticoagulant of choice for PPCI, unless contraindicated. Due to the changes in the ESC guidance plus the geographical and procedural similarities between our centre and the HEAT-PPCI study centre, we switched to heparin as our default antithrombotic agent. We prospectively assessed clinical outcomes, including bleeding complications and treatment costs.

The objective of the present study was to investigate the differences in clinical outcomes and financial costs following the reintroduction of heparin as the standard anticoagulant in patients treated for PPCI in our high-volume centre.

Materials and methods

Study design and patients

This analysis was an open-label, single-centre, prospective registry undertaken at the Bristol Heart Institute, Bristol, UK. All patients undergoing PPCI from April 2014 to April 2016 were prospectively enrolled.

Two periods were defined: Cohort B encompassed all PPCI patients admitted from 1 April 2014 to 30 March 2015. During this period, bivalirudin was used as the standard for anticoagulation in PPCI, unless contraindicated. Cohort H included patients treated by PPCI between 1 April 2015 and 1 April 2016 following an institutional protocol amendment resulting in the use of UFH as the standard periprocedural anticoagulant.

The indication for PPCI was based on the current guidance from the ESC.1 All patients, including out-of-hospital cardiac arrest, intubated patients and cardiogenic shock, were included in the main analysis. A prespecified analysis was planned in the cohort of non-ventilated patients.

Treatment

Bivalirudin was started as soon as possible during the PPCI and was given as a bolus of 0.75 mg per kg of body weight, followed by an infusion of 1.75 mg per kg per hour for 4 hours following the procedure.1 Heparin was given at a dosage of 70–100 IU per kg (operator preference) and then guided by activated clotting time (ACT) results, aiming to maintain an ACT of >250 s.

Bailout use of a Gp2b3a inhibitor was allowed in the event of high thrombus burden or microvascular obstruction (no reflow), as recommended in ESC guidelines.1 Any Gp2b3a inhibitor could be used at the approved doses and regimens.

During the index admission, a 300 mg loading dose of aspirin was given to patients who were treatment naïve before the study. All patients were pretreated with a loading dose of clopidogrel 600 mg, ticagrelor 180 mg or prasugrel 60 mg before or during the PPCI. The use of prasugrel and ticagrelor was recommended over clopidogrel unless contraindicated, but the choice was left to the treating physician. Other cardiac medications were given according to ESC guidelines.1

Follow-up and endpoint assessments

We aimed to assess the incidence of death, cerebrovascular accident (CVA), target lesion failure (TLF), definite ST and bleeding at 30 days. Additionally, the mortality rate was evaluated again at 6 months.

TLF was defined as any unexpected coronary revascularisation procedure (PCI or coronary artery bypass graft surgery) or reinfarction of the target lesion during the follow-up period. A diagnosis of CVA was made by a treating neurologist. CT or MRI was used to distinguish ischaemic from haemorrhagic strokes. Definite ST was classified according to the Academic Research Consortium criteria.7 Bleeding episodes were classified according to the Bleeding Academic Research Consortium (BARC) classification.8

All data were collected prospectively using standardised questionnaire and were entered into a central database. Follow-up was planned for 6 months after inclusion or until the time of death, whichever came first.

All events were adjudicated by a local research committee that was unaware of treatment allocations. All thrombotic and bleeding events requiring medical attention were verified by research nurses who were blinded to the patient’s study group by use of medical records obtained from referring family doctors and hospitals.

Cost analysis

All costs were expressed in Great British Pound. The exact dosages of anticoagulants and Gp2b3a inhibitors administrated during the hospitalisation were reported, for each patient and procedure, by analysis of the medical and drug charts. We used the drug cost at our institution as primary base-case estimate: a 20 mL heparin phial costs £4.20, a bivalirudin 250 mg/5 mL phial costs £372, a 12.5 mg/50 mL tirofiban phial costs £146.10 and a 10 mg/5 mL abciximab phial costs £265.60. The other antithrombotic costs were assumed to be negligible and equal for all agents. We aimed to define the cost of antithrombotic agents associated with the PPCI index procedure.

Statistical analysis

All calculations were performed using SPSS software (version 20.00) and GraphPad prism (version 7.0). Continuous variables were reported as means and SD or as medians and range (according to their distribution), and categorical variables were reported as count and percentages. Standard two-sided tests were used to compare continuous characteristics (Student’s t-tests or Mann-Whitney U-tests) or categorical characteristics (χ2 or Fisher’s exact tests) among patient groups. As a measure of strength of the treatment effect, we calculated HR and 95% CI for ‘Cohort B’ versus ‘Cohort H’ by means of Cox’s proportional hazards regression analysis.

Results

Baseline

Between April 2014 and April 2016, we enrolled 1291 patients, of whom 662 were included in Cohort B and 629 in Cohort H. Baseline and procedural characteristics are presented in tables 1 and 2. In Cohort B, 75.2% of the patients were treated with bivalirudin while 24.8% received heparin. In Cohort H, 99.2% of patients had heparin and 0.8% received bivalirudin. One thousand one hundred and seventy-five (91.0%) patients were enrolled in the non-ventilated cohort, corresponding to 603 in Cohort B and 572 in Cohort H.

Regarding the antiplatelet strategy, we observed that clopidogrel was less frequently used in Cohort H (11.9% vs 20.2%, P<0.01). The use of Gp2b3a inhibitors was higher in Cohort H (28.1% vs 22.3%, P=0.05), mostly driven by more frequent use of abciximab (24.6% vs 17.5%, P<0.01).

Regarding the procedural characteristics, the femoral access was less frequently used in Cohort H (12.6% vs 19.8%, P<0.01). We observed significant difference in the use of mechanical thrombus aspiration with a significant drop in the later Cohort H (44.9% vs 12.4%, P<0.01).

Endpoints

At 30 days, any ischaemic endpoint occurred in 72 (10.9%) patients in Cohort B and in 67 (10.7%) in Cohort H (HR 95% CI 1.02 (0.72 to 1.46), P=0.90).

At 30 days, 62 (9.4%) patients died in Cohort B versus 56 (8.9%) in Cohort H (HR 95% CI 1.05 (0.75 to 1.49), P=0.77) (table 3, figure 1). At 180 days, 73 (11.03%) patients died in Cohort B versus 71 (11.3%) in Cohort H (HR 95% CI 0.98 (0.72 to 1.33), P=0.88) (table 3, figure 1).

Table 3

Endpoints at 30 and 180 days in the whole cohort

	Cohort B	Cohort H	P value
Death 30 days	62 (9.4%)	56 (8.9%)	0.77
Death 180 days	73 (11.0%)	71 (11.3%)	0.88
CVA 30 days	5 (0.8%)	3 (0.5%)	0.52
TLF 30 days	12 (1.8%)	11 (1.8%)	0.93
Definite ST 30 days	3 (0.5%)	2 (0.3%)	0.70
Bleeding all 30 days	145 (21.9%)	138 (21.9%)	0.99
Bleeding BARC≥2 30 days	102 (15.4%)	115 (18.3%)	0.17
Bleeding BARC 2 30 days	82 (12.4%)	99 (15.7%)	0.09
Bleeding BARC 3 30 days	17 (2.6%)	15 (2.4%)	0.83
Bleeding BARC 4 30 days	1	0	–
Bleeding BARC 5 30 days	2	1	–

CVA, cerebrovascular accident; ST, stent thrombosis; TLF, target lesion failure.

Figure 1

Incidence of ischaemic endpoints at 30 and 180 days. CVA, cerebrovascular accident; ST, stent thrombosis; TVF, target vessel failure.

TLF was observed at 30 days in 12 (1.8%) patients in Cohort B and 11 (1.8%) in Cohort H (HR 95% CI 1.03. (0.46 to 2.33), P=0.93); a CVA event at 30 days was observed in five (0.8%) patients in Cohort B and three (0.5%) patients in Cohort H (HR 95% CI 1.58 (0.38 to 6.60), P=0.52) (table 3, figure 1). The rate of definite ST at 30 days was low and not different between the two groups (three (0.5%) patients in Cohort B vs two (0.3%) in Cohort H, P=0.70).

Bleeding events defined as all BARC occurred in 145 (21.9%) patients in Cohort B and in 138 (21.9%) in Cohort H (HR 95% CI 0.99 (0.91 to 1.23), P=0.99) (table 3, figure 2). Bleeding events defined as BARC ≥2 occurred in 102 (15.4%) patients in Cohort B and in 115 patients (18.3%) in Cohort H (HR 95% CI 0.84 (0.66 to 1.08), P=0.17).

Figure 2

Incidence of bleeding endpoints at 30 days.

When we directly compare heparin versus bivalirudin during the whole period, any ischaemic endpoint occurred in 89 (11.2%) patients on heparin and in 50 (9.9%) on bivalirudin (HR 95% CI 1.14 (0.82 to 1.56), P=0.44) at 30 days. Bleeding all BARC was observed in 180 patients (22.8%) on heparin versus 103 (20.5%) on bivalirudin (HR 95% CI 1.12 (0.90 to 1.38), P=0.32), while bleeding BARC 2–5 was observed in 150 (19.0%) versus 67 (13.3%) patients (HR 95% CI 1.43 (1.10 to 1.86), P=0.001).

When the analysis was restricted to non-ventilated patients, we observed that at 30 days 36 (6.0%) patients died in Cohort B versus 30 (5.2%) in Cohort H (HR 95% CI 1.14 (0.71 to 1.82), P=0.59). At 180 days, 44 (7.3%) patients died in Cohort B versus 43 (7.5%) in Cohort H (HR 95% CI 0.97 (0.65 to 1.46), P=0.89) (table 4).

Table 4

Endpoints at 30 and 180 days in the non-ventilated cohort

	Cohort B	Cohort H	P value
Death 30 days	36 (6.0%)	30 (5.2%)	0.59
Death 180 days	44 (7.3%)	43 (7.5%)	0.89
CVA 30 days	1 (0.2%)	2 (0.4%)	0.53
TLF 30 days	12 (2.0%)	9 (1.6%)	0.59
Definite ST 30 days	3 (0.5%)	1 (0.2%)	0.34
Bleeding all 30 days	132 (21.9%)	114 (17.9%)	0.10
Bleeding BARC≥2 30 days	91 (15.1%)	92 (16.1%)	0.64
Bleeding BARC 2 30 days	78 (12.9%)	83 (14.5%)	0.09
Bleeding BARC 3 30 days	10 (1.7%)	9 (1.6%)	0.83
Bleeding BARC 4 30 days	1	0	–
Bleeding BARC 5 30 days	2	0	–

CVA, cerebrovascular accident; ST, stent thrombosis; TLF, target lesion failure.

TLF at 30 days was observed in 12 (2.0%) patients in Cohort B and 9 (1.6%) in Cohort H (HR 95% CI 1.27 (0.53 to 2.98), P=0.59); a CVA event at 30 days was observed in one (0.2%) patient in Cohort B and two (0.4%) patients in Cohort H (HR 95% CI 0.47 (0.04 to 5.22), P=0.53.). Definite ST at 30 days was reported in three patients in Cohort B versus one in Cohort H (P=0.34). Bleeding events defined as all BARC occurred in 132 (21.9%) patients in Cohort B and in 114 (19.9%) in Cohort H (HR 95% CI 1.21 (0.97 to 1.69), P=0.10) (table 4). Bleeding events defined as BARC ≥2 occurred in 91 (15.1%) patients in Cohort B and in 92 patients (16.1%) in Cohort H (HR 95% CI 0.94 (0.72 to 1.23), P=0.64).

The total costs related to the anticoagulants used for the index procedure in Cohort B were £2 46 236.0 versus £4483.0 in Cohort H (P<0.01), corresponding to £372.0 per patient versus £7.1 per patient (figure 3A). When we added the cost of Gp2b3a inhibitors, the difference remained significant with £324 406.0 in Cohort B versus £102 347.0 in Cohort H (P<0.01), corresponding to £490.0 per patient versus £162.7 per patient (figure 3B).

Figure 3

(A) Procedural anticoagulant cost analysis. (B) Procedural anticoagulants and glycoprotein 2b3a (Gp2b3a) inhibitors cost analysis.

Discussion

We report ‘real-world’ adoption of the latest evidence in acute antithrombotic therapy in PPCI and have demonstrated significant cost savings through the reintroduction of UFH use with comparable ischaemic and bleeding outcomes.

HORIZONS-AMI was the first randomised trial to show the superiority of bivalirudin (administered without a post-PPCI infusion) versus heparin plus Gp2b3a, in patients undergoing PPCI, on net adverse clinical events, driven mostly by the reduction of bleeding complications.3 More recently, EUROMAX confirmed the reduction in the composite endpoint of bleeding plus death with bivalirudin (administered with a post-PPCI infusion) versus heparin plus optional Gp2b3a antagonists (11.5% vs 69% of patients had Gp2b3a inhibitors, respectively).4 A higher rate of ST was observed with use of bivalirudin in both trials.3 4 HORIZONS-AMI demonstrated a mortality benefit with bivalirudin use, which was not confirmed in EUROMAX. In contrast, HEAT-PPCI, a single- centre randomised trial, investigated bivalirudin (without post-procedure infusion) versus low-dose heparin (70 IU per kg), limiting Gp2b3a use to bailout in both groups (13% in each group).5 The incidence of the primary ischaemic endpoint (all-cause mortality, stroke, recurrent infarction and unplanned target lesion revascularisation) was higher in the bivalirudin group. Interestingly, bivalirudin failed to prove a significant reduction in bleeding complications (12.5% vs 13.5%, P=0.54).

Since then, Bavarian Reperfusion Alternatives Evaluation 4 trial compared prasugrel plus bivalirudin versus clopidogrel plus heparin in PPCI and was stopped prematurely due to slow recruitment and failure to demonstrate differences in outcome.9 The BivaliRudin in Acute Myocardial Infarction vs Glycoprotein IIb/IIIa and Heparin: a Randomised Controlled Trial, a Chinese randomised trial, compared bivalirudin versus heparin plus Gp2b3a in PPCI, with a reduction of net adverse clinical events with bivalirudin.10 Most recently, the MATRIX randomised trial showed in 7213 patients with acute coronary syndrome (ACS) (of whom 55.6% underwent PPCI) no differences between bivalirudin and heparin regarding the ischaemic outcomes, while bivalirudin significantly reduced the bleeding complication rates.6

The conflicting results of these studies, complexity of study designs, with mandatory/discretionary use of Gp2b3a inhibitors, variations in bivalirudin protocols and geographical differences in clinical practice (particularly radial access use) have led to confusion surrounding the optimal antithrombotic regime for PPCI. However, the results of HEAT-PPCI were embraced by UK interventional cardiologists and have resulted in significant reductions in the use of bivalirudin for PPCI. Our results support the results observed by the HEAT-PPCI investigators with no observed differences in ischaemic or bleeding endpoints with use of heparin versus bivalirudin. However, we noticed that the reintroduction of UFH was associated with an increased use of bailout Gp2b3a inhibitors compared with routine use of bivalirudin with a post-PCI infusion. This finding may have been accentuated by the significant reduction in the use of thromboaspiration catheters and potential increased presence of thrombus between cohorts, precipitated by the reporting of the findings of the The Trial of Routine Aspiration Thrombectomy with PCI versus PCI Alone in Patients with STEMI (TOTAL) study11 contributing to the increase of bailout Gp2b3a antagonists use.

The increase in ST incidence observed in HORIZONS-AMI and EUROMAX was confirmed in HEAT-PPCI (3, 4 and 5). Our local approach of administering bivalirudin as a bolus followed by a prolonged post-PPCI infusion was associated with very low levels of definite ST, with no significant difference observed in comparison with UFH. Interestingly, in the prespecified analysis of the MATRIX cohort including 55.6% of PPCI, the prolonged infusion did not impact the ST risk in comparison with no post-PPCI infusion.6

Nowadays, prasugrel and ticagrelor are the recommended first-line antiplatelet agents in PPCI, in association with aspirin and intravenous anticoagulants.1 Trial to Assess Improvement in Therapeutic Outcomes by Optimizing Platelet Inhibition with Prasugrel –Thrombolysis in Myocardial Infarction and PLATelet inhibition and patient Outcomes trials proved their superiority over clopidogrel in reducing ischaemic complications.12 13 However, enhanced potency of antiplatelet effect is associated with an increase in bleeding risk.12 13 The initial benefit of bivalirudin was proved mostly in clopidogrel-treated patients.3 4 Our modern cohort used preferentially the newer P2Y12 inhibitors in PPCI and confirmed that even if numerically lower rate of bleeding complications was observed in the bivalirudin period, no significant difference was shown between both protocols despite a very high use of prasugrel and ticagrelor.

Nowadays, cost-effectivenes of the procedures has to be considered. The incidence of STEMI requiring PPCI remains stable and remains a significant challenge in health systems.1 2 Bivalirudin has been proved to be cost-effective in comparison with heparin plus systematic Gp2b3a antagonist in PPCI setting.14 Recent changes in PPCI treatment, including high rate of radial access and bailout Gp2b3a use, have highlighted the need to re-evaluate the cost-effectiveness of these strategies. We confirmed that the reintroduction of heparin as standard anticoagulant for PPCI was associated with significant cost saving that was maintained despite a slightly higher rate of Gp2b3a antagonist use. Additionally, clinical outcomes were not influenced by the anticoagulant strategy.

Limitations

The present study has some limitations. First, the intrinsic limitations of this study result from the observational character of a prospective registry, with unadjusted baseline differences existing between the two cohorts. The two groups compared were treated at different time points, with the Heparin group H the year after the Bivalirudin group B. In the group B, a significant proportion of patients were treated with heparin as per individual treatment choice in higher risk patients. Secondarily, we observed higher rates of radial access and newer P2Y12 blockers use in the later cohort, likely related to progressive adoption of PPCI recommendations.1 2 Vascular closure systems being largely used nowadays when femoral access is needed and the decrease in terms of use of femoral route may have impacted the cost of the procedure. However, this cost is not dependent on the subject of interest for this analysis (ie, periprocedural antithrombotic strategy). Similarly, the decrease in the use of clopidogrel and parallel increase in the use of ticagrelor have an obvious impact in terms of cost but only when extrapolated to 1-year treatment cost. When focusing on the procedure, it does not appear to be relevant. Therefore, we decided not to include those prices in the analysis. Third, we included all PPCI patients referred to our centre, which include a substantial number of patients with cardiogenic shock and comatose patients. This explains the high rates of death at 6 months, compared with clinical trials. Fourth, major changes in PPCI techniques occurred during the planned follow-up period. TOTAL results confirmed the lack of benefit associated with manual thromboaspiration devices in PPCI, explaining the significant differences in use of this technique between the two cohorts. Finally, we were not able to provide exact duration of bivalirudin infusion for each patient. The recommended protocol was an infusion of 3 –4 hours post PPCI.

Conclusion

In conclusion, in the present analysis, we observed that the reintroduction of heparin instead of bivalirudin as standard anticoagulant for PPCI did not lead to significant differences in efficacy or safety outcomes, but was associated with a significant cost saving.

Table 1

Clinical characteristics and treatment at baseline

	Cohort B (n=662)	Cohort H (n=629)	P value
Age, mean (SD), years	65.6±12.9	64.6±13.3	0.15
Body mass index, mean (SD)	28.6±21.7	28.5±17.3	0.93
Male gender, n (%)	473 (71.5%)	483 (76.8%)	0.03
Medical history, n (%)
Coronary artery disease	152 (23.0%)	134 (21.3%)	0.47
Myocardial infarction	113 (17.1%)	92 (14.6%)	0.23
CABG	23 (3.5%)	20 (3.2%)	0.77
Coronary revascularisation	88 (13.3%)	74 (11.8%)	0.41
Stroke/TIA >1 year	29 (4.4%)	16 (2.5%)	0.07
Peripheral arterial disease	31 (4.7%)	25 (4.0%)	0.21
Congestive heart failure	6 (0.9%)	7 (1.1%)	0.71
Hypertension	354 (53.5%)	303 (48.2%)	0.06
Hypercholesterolaemia	307 (46.4%)	294 (46.7%)	0.90
Diabetes	101 (15.3%)	83 (13.2%)	0.29
Current smoker	216 (32.6%)	248 (39.4%)	0.01
Long-term antiplatelet therapy, n (%)
Aspirin	256 (38.7%)	243 (38.6%)	0.99
EKG presentation, n (%)
ST elevation	640 (96.7%)	608 (96.7%)	0.99
LBBB	10 (1.5%)	7 (1.1%)	0.53
EKG territory of infarction, n (%)
Anterior	223 (33.7%)	229 (36.4%)	0.31
Cardiogenic shock, n (%)	82 (12.4%)	77 (12.2%)	0.94
Ventilated patients, n (%)	59 (8.9%)	57 (9.1%)	0.93
Out-of-hospital cardiac arrest, n (%)	69 (10.4%)	66 (10.5%)	0.97
Anticoagulation, n (%)
Bivalirudin	498 (75.2%)	5 (0.8%)	<0.01
Heparin	164 (24.8%)	624 (99.2%)	<0.01
Recent lysis, n (%)	1 (0.2%)	0 (0%)
Gp2b3a agent, n (%)	154 (22.3%)	177 (28.1%)	0.05
Tirofiban	38 (5.7%)	22 (3.5%)	0.06
Abciximab	116 (17.5%)	155 (24.6%)	<0.01
Loading dose of antiplatelet, n (%)	633 (95.6%)	611 (97.1%)	0.15
Antiplatelet therapy received between randomisation and discharge, n (%)
Aspirin	652 (98.5%)	617 (98.1%)	0.58
Oral P2Y12 blocker, n (%)
Clopidogrel	134 (20.2%)	75 (11.9%)	<0.01
Prasugrel	411 (62.1%)	362 (57.6%)	0.10
Ticagrelor	117 (17.7%)	192 (30.5%)	<0.01

CABG, coronary artery bypass graft; Gp2b3a, glycoprotein 2b3a; LBBB, left bundle branch block.; TIA, transient ischaemic attack.

Table 2

Baseline procedural characteristics

	Cohort B (n=662)	Cohort H (n=629)	P value
Access site, n (%)
Femoral	131 (19.8%)	79 (12.6%)	<0.01
Culprit lesion, n (%)			0.60
LMS	16 (2.2%)	24 (3.4%)	0.18
LAD	270 (37.8%)	272 (38.9%)	0.91
LCx	127 (17.8%)	126 (18.0%)	0.92
RCA	289 (40.5%)	264 (37.7%)	0.29
Graft	12 (1.7%)	14 (2.0%)	0.66
Number of bystander lesions (n %)*	390 (35.3%)	308 (30.6%)	0.02
Number of lesions attempted (n %)*	822 (74.5%)	834 (82.7%)	<0.01
Number of stents per patient, mean (SD)	1.3±0.8	1.4±0.9	0.01
Drug eluting stent, (n %)†	815 (95.5%)	866 (97.6%)	0.02
Stent diameter, mean (SD)	3.3±0.7	3.4±1.5	0.11
Stent length, mean (SD)	27.1±10.2	27.8±11.2	0.09
TIMI flow in the culprit artery at the end of the procedure, n (%)‡:			0.17
0–1	20 (2.8%)	12 (1.7%)
2–3	694 (97.2%)	688 (98.3%)
Number of lesions successful, n (%)§:	793 (96.5%)	799 (95.8%)	0.48
Use of a thrombus extraction catheter, n (%):	297 (44.9%)	78 (12.4%)	<0.01
Use of a vascular closure device system, n (%)¶:	107 (81.7%)	76 (96.2%)	<0.01
Thrombotic procedural complications, n (%):	21 (3.17%)	13 (2.07%)	0.22

If more than one stent is used, the stent length denotes the sum of all stent lengths.

LAD, left anterior descending coronary artery; LCx, left circumflex coronary artery; LMS, left main stem; RCA, right coronary artery.