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Dual Antiplatelet Therapy Versus Aspirin Monotherapy in Diabetics With Multivessel Disease Undergoing CABG
JOURNAL OF THE AMERICAN COLLEGE OF CARDIOLOGY
VOL. 69, NO. 2, 2017
ª 2017 BY THE AMERICAN COLLEGE OF CARDIOLOGY FOUNDATION PUBLISHED BY ELSEVIER
ISSN 0735-1097/$36.00 http://dx.doi.org/10.1016/j.jacc.2016.10.043
ORIGINAL INVESTIGATIONS
Dual Antiplatelet Therapy Versus Aspirin Monotherapy in Diabetics With Multivessel Disease Undergoing CABG FREEDOM Insights Sean van Diepen, MD, MSC,a,b Valentin Fuster, MD, PHD,c Subodh Verma, MD, PHD,d Taye H. Hamza, PHD,e F. Sandra Siami, MPH,e Shaun G. Goodman, MD, MSC,b,f Michael E. Farkouh, MD, MSCg
ABSTRACT BACKGROUND Clinical practice guidelines recommend post-operative dual antiplatelet therapy (DAPT) in patients who undergo coronary artery bypass grafting (CABG) following acute coronary syndromes (ACS). OBJECTIVES The authors have evaluated DAPT utilization rates and associated outcomes among post-CABG patients with diabetes. METHODS In a post hoc, nonrandomized analysis from the FREEDOM (Future REvascularization Evaluation in patients with Diabetes mellitus: Optimal management of Multivessel disease) trial, we compared patients receiving DAPT (aspirin plus thienopyridine) and aspirin monotherapy at 30 days post-operatively. The primary outcome was the risk adjusted 5-year FREEDOM composite of all-cause mortality, nonfatal myocardial infarction, or stroke. Safety outcomes included major bleeding, blood transfusion, and hospitalization for bleeding. RESULTS At 30 days post-CABG, 544 (68.4%) patients received DAPT and 251 (31.6%) patients received aspirin alone. The median (25th, 75th percentile) duration of clopidogrel therapy was 0.98 (0.23 to 1.91) years. There was no significant difference in the 5-year primary composite outcome between DAPT- and aspirin-treated patients (12.6% vs. 16.0%; adjusted hazard ratio [HR]: 0.83; 95% confidence interval [CI]: 0.54 to 1.27; p ¼ 0.39). The 5-year primary composite outcomes were similar for patients receiving DAPT versus aspirin monotherapy respectively, in subgroups with pre-CABG ACSs (15.2% vs. 16.5%; HR: 1.06; 95% CI: 0.53 to 2.10; p ¼ 0.88) and those with stable angina (11.6% vs. 15.8%; HR: 0.82; 95% CI: 0.50 to 1.343; p ¼ 0.42). The composite outcomes of both treatment groups were also similar by SYNTAX score, duration of DAPT therapy, completeness of revascularization, and in off-pump CABG. No treatment-related differences in major bleeding (5.6% vs. 5.7%; HR: 1.00; 95% CI: 0.50 to 1.99; p ¼ 0.99), blood transfusions (4.8% vs. 4.5%; HR: 1.09; 95% CI: 0.51 to 2.34; p ¼ 0.82), or hospitalization for bleeding (2.6% vs. 3.3%; HR: 0.85; 95% CI: 0.34 to 2.17; p ¼ 0.74) were observed between aspirin- and DAPT-treated patients, respectively. CONCLUSIONS The use of DAPT in patients with diabetes post-CABG in our cohort was high. Compared with aspirin monotherapy, no associated differences were observed in cardiovascular or bleeding outcomes, suggesting that routine use of DAPT may not be clinically warranted. (Future REvascularization Evaluation in patients with Diabetes mellitus: Optimal management of Multivessel disease [FREEDOM]; NCT00086450) (J Am Coll Cardiol 2017;69:119–27) Listen to this manuscript’s
© 2017 by the American College of Cardiology Foundation.
audio summary by JACC Editor-in-Chief Dr. Valentin Fuster. From the aDepartment of Critical Care and Division of Cardiology, University of Alberta, Edmonton, Alberta, Canada; bCanadian VIGOUR Centre, University of Alberta, Edmonton, Alberta, Canada; cIcahn School of Medicine at Mount Sinai, New York, New York; dDivision of Cardiac Surgery, St. Michael’s Hospital, University of Toronto, Toronto, Ontario, Canada; eNew England Research Institutes, Inc., Watertown, Massachusetts; fTerrence Donnelly Heart Centre, Division of Cardiology, St. Michael’s Hospital, University of Toronto, Toronto, Ontario, Canada; and the gPeter Munk Cardiac Centre and the Heart and Stroke Richard
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JACC VOL. 69, NO. 2, 2017 JANUARY 17, 2017:119–27
Dual Antiplatelet Therapy in Diabetics After CABG
C
ABBREVIATIONS AND ACRONYMS CABG = coronary artery bypass
oronary
artery
bypass
surgery
(CABG) reduces long-term morbidity and mortality in patients with
multivessel disease with or without diabetes
surgery
(1–3). Aspirin alone has been reported to
CI = confidence interval
improve vein graft patency and mortality
DAPT = dual antiplatelet
(4,5). Dual antiplatelet therapy (DAPT) with
therapy
aspirin and a thienopyridine is a theoretically
HR = hazard ratio
attractive secondary prevention therapy,
MI = myocardial infarction
given that bypass graft thrombosis and sys-
NSAID = nonsteroidal anti-
temic hypercoagulability are potential causes
inflammatory drug
of saphenous vein graft failure (6). In addi-
PPI = proton pump inhibitor
tion, native coronary artery atherothrombotic risk for plaque rupture, ulceration, or erosion remains post-CABG (7,8). Clinical practice guidelines currently recommend DAPT in patients who undergo CABG for
drug-eluting stents. All study participants provided written consent. STUDY POPULATION AND DEFINITIONS. This anal-
ysis included all patients who underwent primary revascularization with CABG (per-protocol analysis) and were taking aspirin 30 days post-operatively. Patients undergoing DAPT were defined as all patients who were receiving aspirin and a thienopyridine (clopidogrel or ticlopidine) at 30 days post-operatively. The aspirin cohort was defined as those receiving aspirin monotherapy at 30 days. Patients receiving warfarin at 30 days were excluded. The primary analysis compared 5-year outcomes in patients treated with DAPT versus aspirin alone at 30-days post-CABG. The secondary analysis examined 1-year outcomes.
an acute coronary syndrome; however, the efficacy
OUTCOMES. The primary outcome was the FREEDOM
of DAPT reported in observational studies, subgroup
trial primary endpoint of 5-year all-cause mortality,
analyses, and small randomized trials that underpin
nonfatal myocardial infarction (MI), or stroke. Second-
these recommendations is uncertain, and DAPT may
ary outcomes included the individual components of
be associated with a higher risk of bleeding (9–16).
the composite outcomes: vascular death, MI, and cardiovascular
SEE PAGE 128
Diabetes
is
independently
hospitalization
(defined
as
unstable
angina, MI, heart failure, chest pain, arrhythmia, with
peripheral vascular disease, or stroke or transient
increased perioperative and long-term mortality in
associated
ischemic attack). Safety outcomes were major bleeding,
CABG patients, and may be a clinical risk factor for
blood transfusions, and bleeding hospitalization. All
vein graft failure (17–20). Hence, diabetics may be a
events were adjudicated by a clinical events committee.
unique high-risk subgroup that may benefit from
In a priori analysis, we also explored the primary
DAPT secondary prevention therapy, but little evi-
outcome and major bleeding in the following sub-
dence is available to support this hypothesis. The
groups: 1) patients revascularized following an acute
purpose of this analysis is to compare the long-term
coronary syndrome event versus stable angina; 2)
clinical and bleeding outcomes associated with
SYNTAX score (<22, 22 to 32, $32); 3) complete versus
DAPT versus aspirin monotherapy in post-bypass di-
incomplete revascularization; 4) patients with an
abetics with multivessel coronary artery disease from
endarterectomy or vein graft patching; 5) on- and off-
the FREEDOM (Future REvascularization Evaluation
pump CABG; 6) patients who maintained DAPT for a
in patients with Diabetes mellitus: Optimal manage-
minimum of 1 year; and 7) post-operative glomerular
ment of Multivessel disease) trial (1).
filtration rate.
METHODS
STATISTICAL METHODS. Categorical baseline char-
acteristics were summarized as number of subjects DATA SOURCE. The methods and results of the
and percentages. The difference between the 2 treat-
FREEDOM trial have been published (1,21). Briefly,
ment groups was tested using Fisher exact test.
this
enrolled
Continuous baseline characteristics were summarized
patients $ 18 years of age with diabetes mellitus (DM)
as median and quartiles. The differences between the 2
and with $70% stenosis of 2 or more major epi-
treatment groups were tested using Kruskal-Wallis
cardial vessels. Patients were randomized to either
test statistics. The times to primary, secondary, and
CABG or percutaneous coronary intervention with
safety outcomes were analyzed using Cox proportional
international
multicenter
study
Lewar Centre, University of Toronto, Toronto, Ontario, Canada. Dr. van Diepen has received honoraria and/or grant support from AstraZeneca, Bayer, Boehringer Ingelheim, Lilly, Pfizer, Merck, Novartis, Amgen, Sorin, Abbott, and Janssen. Dr. Goodman has received research grant support and speaker/consulting honoraria from AstraZeneca, Bayer, Bristol-Myers Squibb, Daiichi-Sankyo, Eli Lilly, and Sanofi. All other authors have reported that they have no relationships relevant to the contents for this paper to disclose. Faisal Bakaeen, MD, served as Guest Editor for this paper. Manuscript received September 29, 2016; accepted October 12, 2016.
van Diepen et al.
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Dual Antiplatelet Therapy in Diabetics After CABG
hazard regression. Cumulative event rate curves were compared using log-rank test statistics. Whenever
T A B L E 1 Baseline Characteristics By Treatment Groups
DAPT (n ¼ 544)
Aspirin Monotherapy (n ¼ 251)
p Value
61.2 (54.8, 68.5)
63.7 (59.4, 71.2)
<0.001
392 (72.1)
176 (70.1)
possible, the Cox models were adjusted for EuroSCORE (European System for Cardiac Operative Risk Evaluation), region of enrollment (North America, Europe,
Age, yrs
South America, and others), number of grafts, right
Male
internal thoracic artery graft use, endarterectomy,
Race
endoscopic vein harvesting, and beta-blocker, non-
White
388 (71.3)
228 (90.8)
steroidal anti-inflammatory drugs (NSAID), and proton
Black or African American
38 (7.0)
8 (3.2)
Asian
57 (10.5)
7 (2.8)
Other
61 (11.2)
8 (3.2)
80.9 (69.0, 95.0)
82.0 (73.0, 93.5)
pump inhibitor (PPI) medication use at the 1 month post-CABG visit whenever possible. All analyses were
Body weight, kg
0.61 <0.001
0.32
performed using SAS (Statistical Analysis Systems,
Medical history
Cary, North Carolina) version 9.4 and R (RStudio,
Hypertension
458 (84.2)
213 (84.9)
0.83
Boston, Massachusetts) version 3.1.1.
Dyslipidemia
455 (83.6)
217 (86.5)
0.34
Type 1
20 (3.7)
16 (6.4)
Type 2
524 (96.3)
235 (93.6)
Diabetes mellitus
RESULTS
0.10
Seven hundred and ninety-five patients (83.9%) of
Current tobacco use
98 (18.0)
35 (13.9)
947 patients from the FREEDOM trial who were
MI
149 (27.4)
56 (22.3)
0.14
randomized to CABG were included in this analysis.
PCI or PTCA in previous 12 months
5 (0.9)
4 (1.6)
0.47
History of arrhythmia
18 (3.3)
7 (2.8)
0.83
Stroke or transient ischemic attack
12 (2.2)
9 (3.6)
0.34
Peripheral vascular disease
49 (9.0)
31 (12.4)
0.16
COPD
23 (4.2)
16 (6.4)
0.22
no revascularization (n ¼ 36), deceased within in the
Chronic kidney disease
22 (4.0)
19 (7.6)
0.06
first 30 days from the date of procedure (n ¼ 15), no
Indication for coronary angiography 0.13
Patients were excluded for the following reasons: randomized to CABG but underwent percutaneous coronary intervention revascularization (n ¼ 18),
aspirin therapy at 30 days (n ¼ 52), and warfarin ther-
Stable angina
398 (73.2)
170 (67.7)
apy at 30 days (n ¼ 31). At 30-days post-CABG,
Acute coronary syndrome
146 (26.8)
81 (32.3)
544 (68.4%) patients received DAPT and 251 (31.6%) patients received aspirin. The median (25th, 75th percentile) duration of thienopyridine therapy was
Physical examination and laboratory variables Heart rate, beats/min Systolic blood pressure, mm Hg LVEF, %
0.98 (0.23 to 1.91) years. Baseline differences between
Hemoglobin, g/l
aspirin- and DAPT-treated patients are provided in
Creatinine, mmol/l
Table 1. Participants who received DAPT were more
Hemoglobin A1c, %
frequently younger, non-Caucasian, and had surgery
Region of enrollment
performed in North America, South America, India, or Israel. Surgical variables, in-hospital complications, length of stay, and pharmacotherapy at 30 days stratified by
0.18
72.0 (64.0, 79.0)
70.0 (62.0, 77.0)
0.02
130.0 (120.0, 140.0)
130.0 (120.0, 145.0)
0.12 0.26
60.0 (53.0, 66.0)
60.0 (50.0, 65.0)
139.0 (128.5, 148.0)
137.0 (126.0, 147.0)
0.13
88.4 (74.0, 106.1)
88.4 (74.5, 106.1)
0.94
7.4 (6.6, 8.7)
7.2 (6.5, 8.1)
North America
0.94 <0.001
233 (42.8)
86 (34.3)
Europe
74 (13.6)
113 (45.0)
South America
167 (30.7)
36 (14.3)
Australia/New Zealand
32 (5.9)
15 (6.0)
India/Israel
38 (7.0)
1 (0.4)
treatment cohort are presented in Table 2. Patients who received DAPT had lower median EuroSCORE,
Values are median (25th, 75th percentile) or n (%).
less frequently underwent right internal mammary
COPD ¼ chronic obstructive pulmonary disease; DAPT ¼ dual antiplatelet therapy; LVEF ¼ left ventricular ejection fraction; MI ¼ myocardial infarction; PCI ¼ percutaneous coronary intervention; PTCA ¼ percutaneous transluminal coronary angioplasty or atherectomy.
artery grafting and transmyocardial revascularization, had a higher mean number of bypass grafts, and more frequently underwent endoscopic vein harvesting. No differences in in-hospital complications or lengths of stay were observed. NSAID use was less frequent in the DAPT cohort.
the secondary outcomes of all-cause mortality, vascular mortality, MI, stroke, or cardiovascular hospitalizations between DAPT- and aspirin-treated patients. There were no differences in the 5-year
CLINICAL OUTCOMES. The primary and secondary
safety outcomes of major bleeding (5.6% vs. 5.7%;
outcomes are described in Table 3 and shown in
HR: 1.00; 95% CI: 0.50 to 1.99; p ¼ 0.99), blood
the
differ-
transfusions (4.8% vs. 4.5%; HR: 1.09; 95% CI: 0.51 to
ences were observed in the 5-year primary composite
2.34; p ¼ 0.82), and bleeding hospitalizations (2.6%
Central
Illustration.
No
significant
outcome of all-cause death, MI, or stroke (12.5% vs.
vs. 3.3%; HR: 0.80; 95% CI: 0.31 to 2.04; p ¼ 0.64)
16.0%; adjusted hazard ratio [HR]: 0.83; 95% confi-
between DAPT- and aspirin-treated patients. Point
dence interval [CI]: 0.54 to 1.27; p ¼ 0.39) (Figure 1) or
estimates were similar at 1 year.
van Diepen et al.
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Dual Antiplatelet Therapy in Diabetics After CABG
SUBGROUP ANALYSES. The primary FREEDOM trial
T A B L E 2 Surgical Variables and Discharge Medications By Treatment Group
outcome and major bleeding in subgroups of interest
DAPT (n ¼ 544)
Aspirin Monotherapy (n ¼ 251)
p Value
differences in the incidence of the composite of
1.7 (1.2, 3.0)
2.1 (1.4, 3.7)
<0.001
all-cause death, MI, or stroke were observed by
26.0 (19.0, 31.5)
26.0 (19.3, 32.0)
0.35
surgical indication (stable angina or acute coronary
Number of lesions $70%
543 (99.8)
251 (100.0)
>0.99
syndrome), SYNTAX score, complete or incomplete
3-vessel disease
451 (82.9)
216 (86.1)
0.25
revascularization, duration of DAPT, or by on- or
85.0 (66.0, 108.0)
88.0 (64.5, 109.0)
0.88
59.0 (41.0, 77.0)
60.0 (42.0, 80.0)
0.99
108 (19.9)
43 (17.1)
EuroSCORE SYNTAX score
are presented in Table 4. No treatment-related
Surgical variables Cardiopulmonary bypass time, min
off-pump bypass at 5 years. The primary outcome was
Cross-clamp time, min Off-pump bypass Number of grafts
lower among DAPT-treated patients who had a
0.38
reduced glomerular filtration rate. No differences in
0.02
5-year major bleeding were observed across the
1
8 (1.5)
2 (0.8)
subgroups of interest. In a post hoc sensitivity anal-
2
135 (24.8)
88 (35.1)
ysis restricted to events occurring 30 days after sur-
3
278 (51.1)
123 (49.0)
gery, no differences in outcomes were observed
4
106 (19.5)
34 (13.5)
(Online Tables 1 and 2). In a post hoc analysis, the
17 (3.1)
4 (1.6)
Left internal thoracic artery graft
512 (94.1)
239 (95.2)
0.62
Right internal thoracic artery graft
54 (9.9)
51 (20.3)
<0.001
Radial artery graft
56 (10.3)
23 (9.2)
0.70
Endarterectomy
34 (6.3)
9 (3.6)
0.13
$5
Transmyocardial revascularization
were age, country, race, transmyocardial revascularization, and right internal thoracic artery graft use (Online Table 3).
4 (0.7)
10 (4.0)
96 (17.6)
30 (12.0)
0.05
Graft patching
9 (1.7)
7 (2.8)
0.29
Intra-aortic balloon pump use
3 (0.6)
1 (0.4)
>0.99
Antifibrinolytics given
296 (54.4)
150 (59.8)
0.17
Aspirin post-operative day 0/1
461 (84.7)
202 (80.5)
0.15
Thienopyridine post-operative day 0/1
159 (29.2)
9 (3.6)
<0.001
Any
105 (19.3)
59 (23.5)
0.19
received DAPT for a median duration of 1 year post-
MI
29 (5.3)
9 (3.6)
0.37
CABG. Second, no significant differences in either the
Stroke
18 (3.3)
10 (4.0)
0.68
primary composite outcome (all-cause death, MI, or
Atrial fibrillation
26 (4.8)
18 (7.2)
0.46
stroke) or bleeding outcomes were observed between
Repeat sternotomy for bleeding
13 (2.4)
7 (2.8)
>0.99
aspirin- and DAPT-treated patients. Third, results
Gastrointestinal bleeding
4 (0.7)
0 (0.0)
0.30
were similar across clinically important subgroups in
Renal failure
12 (2.2)
10 (4.0)
0.35
10.0 (7.0, 16.0)
11.0 (7.0, 18.0)
0.46
2.0 (1.0, 4.0)
2.0 (1.0, 4.0)
0.86
tion of DAPT.
Beta-blockers
462 (84.9)
205 (81.7)
0.08
DAPT prescription rates range from 22.0% to 53.8%
Statins
486 (89.3)
218 (86.9)
0.44
(14,22–24). The reasons underpinning this wide range
19 (3.5)
10 (4.0)
0.69
are unclear, but they may reflect differences in case
283 (52.0)
128 (51.0)
0.41
Aldosterone antagonists
77 (14.2)
41 (16.3)
0.45
mix, regional practices patterns, or variations in
Antiarrhythmics
45 (8.3)
22 (8.8)
0.89
Thiazide diuretics
49 (9.0)
26 (10.4)
0.69
DAPT post-CABG (9,10,15). In this analysis, approxi-
Endoscopic vein harvesting
0.002
variables identified associated with DAPT therapy
Perioperative medications
Length of stay Intensive care days
ACE or ARB
pared aspirin monotherapy with DAPT post-CABG in patients with diabetes. We observed 3 important findings. First, approximately two-thirds of patients
including pre-operative acute coronary syndrome, SYNTAX score, complete revascularization, and duraIn retrospective observational studies, post-CABG
Medications at 30 days
Ezetimibe
This post hoc secondary analysis of the FREEDOM trial with centrally adjudicated clinical outcomes com-
Post-operative complications
Hospital days
DISCUSSION
practice guideline recommendation weighting of
108 (19.9)
65 (25.9)
0.09
mately two-thirds of all trial participants were pre-
6 (1.1)
1 (0.4)
0.44
scribed thienopyridines in addition to aspirin. We
107 (19.7)
44 (17.5)
0.49
hypothesize that the higher rates of DAPT prescrip-
PPIs
23 (4.2)
17 (6.8)
0.08
tion observed in this analysis may have been influ-
NSAIDs
17 (3.1)
16 (6.4)
0.05
enced by the FREEDOM study protocol, which
Loop diuretics Digoxin Calcium-channel blockers
Values are median (25th, 75th percentile) or n (%). ACE ¼ angiotensin-converting enzyme inhibitors; ARB ¼ angiotensin receptor blockers; DAPT ¼ dual antiplatelet therapy; EuroSCORE ¼ European System for Cardiac Operative Risk Evaluation; NSAIDs ¼ nonsteroidal anti-inflammatory drugs; PPIs ¼ proton pump inhibitors.
provided participants with up to 1 year of thienopyridine drug coverage at the discretion of their treating physician regardless of study randomization. This may also reflect the perceived benefit of DAPT after
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Dual Antiplatelet Therapy in Diabetics After CABG
T A B L E 3 Outcomes in Patients on DAPT and Aspirin Monotherapy
1-Yr Outcomes
Outcome*
DAPT
Aspirin Monotherapy
HR (95% CI)
534 (6.7)
244 (6.6)
1.08 (0.56–2.06)
5-Yr Outcomes
DAPT
Aspirin Monotherapy
HR (95% CI)
0.82
534 (12.5)
244 (16.0)
0.83 (0.54–1.27)
0.39
p Value
p Value
Primary FREEDOM outcome All-cause mortality, MI, or stroke Secondary outcomes All-cause mortality
538 (1.9)
244 (3.7)
0.54 (0.20–1.45)
0.22†
538 (5.8)
244 (9.4)
0.62 (0.34–1.13)
0.12
Vascular mortality
538 (1.3)
244 (1.6)
0.80 (0.23–2.83)
0.73‡
538 (3.5)
244 (3.3)
1.17 (0.50–2.72)
0.72§
MI
534 (3.9)
244 (2.0)
1.87 (0.65–5.36)
0.25
534 (5.2)
244 (3.7)
1.42 (0.63–3.21)
0.40
Stroke
538 (1.1)
244 (1.6)
0.89 (0.21–3.69)
0.87k
538 (3.2)
244 (4.1)
0.85 (0.36–1.99)
0.71k
Cardiovascular hospitalizations
533 (9.9)
243 (10.7)
0.99 (0.59–1.65)
0.97
533 (19.5)
243 (18.1)
1.10 (0.75–1.61)
0.62
Major bleeding
538 (4.3)
244 (4.5)
1.05 (0.48–2.30)
0.91
538 (5.6)
244 (5.7)
1.00 (0.50–1.99)
0.99
Blood transfusions
538 (4.3)
244 (3.7)
1.28 (0.55–2.96)
0.57
538 (4.8)
244 (4.5)
1.09 (0.51–2.34)
0.82
Bleeding hospitalization
538 (1.7)
244 (2.5)
0.73 (0.24–2.25)
0.58¶
538 (2.6)
244 (3.3)
0.85 (0.34–2.17)
0.74¶
Primary safety outcomes
Values are n (%) unless otherwise indicated. *All unadjusted outcomes presented as valid n (event %). Because of 0 events in 1 or more covariate categories, some covariates were excluded from specific time to event analysis as follows: †adjusted for EuroSCORE, region of enrollment, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and PPI or beta-blocker use at 1 month; ‡adjusted for EuroSCORE, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and PPI or beta-blocker use at 1-month visit; §adjusted for EuroSCORE, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and PPI, NSAID, or beta-blocker use at 1-month visit; kadjusted for EuroSCORE, region of enrollment, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and NSAID or beta-blocker use at 1-month visit; ¶adjusted for EuroSCORE, region of enrollment, number of grafts, endoscopic vein harvesting, and PPI or beta-blocker use at 1 month. CI ¼ confidence internal; HR ¼ hazard ratio; other abbreviations as in Tables 1 and 2.
C ENTR AL I LL U STRA T I O N Dual Antiplatelet Therapy in Diabetics After CABG: Adjusted Hazard Ratio Plot of Clinical and Safety Outcomes
van Diepen, S. et al. J Am Coll Cardiol. 2017;69(2):119–27.
No differences were observed in the 5-year incidence the primary FREEDOM outcome (all-cause death, myocardial infarction, or stroke), secondary outcomes, or primary safety outcomes in diabetic patients with multivessel coronary artery disease who underwent CABG treated with dual antiplatelet therapy or aspirin monotherapy. CABG ¼ coronary artery bypass surgery; CI ¼ confidence interval; DAPT ¼ dual antiplatelet therapy; FREEDOM ¼ Future REvascularization Evaluation in patients with Diabetes mellitus: Optimal management of Multivessel disease; MI ¼ myocardial infarction.
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Dual Antiplatelet Therapy in Diabetics After CABG
includes those with antecedent acute coronary syn-
F I G U R E 1 Kaplan-Meier Plot of the 5-Year Primary FREEDOM Outcome
dromes and incomplete revascularization and high SYNTAX
40
log-rank P = 0.377 DAPT
35
(31,32).
Although
our
scientific
post-CABG population is incomplete, observational
Aspirin alone Cumulative Event Rate, %
scores
understanding of the effectiveness of DAPT in the studies suggest a reduced efficacy of DAPT among
30
diabetic patients. A recent DAPT trial secondary 25
analysis reported that patients with diabetes mellitus had a higher long-term risk of cardiovascular events
20
but a significantly attenuated benefit of prolonged
15
DAPT after percutaneous coronary intervention (33). The authors suggested the potential for other ischemic
10
pathophysiological process including greater plaque
5
burden, inflammation, and/or a reduced response to antiplatelet therapies.
0 1
0
2
3
4
5
Time to FREEDOM Outcome , Years
The lack of an observed difference in major bleeding by treatment assignment in this analysis was an un-
DAPT (Yes/No) / Number of patients at risk Yes
540
492
449
349
233
111
No
251
231
207
166
107
43
expected finding. Prior meta-analyses have reported point estimates for bleeding were nonsignificantly higher in DAPT CABG patients (28). We hypothesize this finding may be due to inadequate power because
No differences were observed in the incidence of all-cause mortality, myocardial
of a small number of events or differential treatment
infarction, or stroke in diabetic coronary artery bypass patients treated with dual antiplatelet therapy or aspirin monotherapy. DAPT ¼ dual antiplatelet therapy;
strategies. Prior studies have primarily evaluated
FREEDOM ¼ Future REvascularization Evaluation in patients with Diabetes mellitus:
bleeding outcomes among CABG patients initiated on
Optimal management of Multivessel disease.
early post-operative DAPT, a period when the antithrombotic-related treatment bleeding is potentially highest. In the present study, only 29% of
CABG among cardiovascular physicians when finan-
DAPT-treated patients were initiated on therapy on
cial barriers to drug prescription are removed.
post-operative day 0 or 1 and the DAPT cohort was
Guideline recommendations for DAPT in patients
defined according to DAPT therapy at 30 days.
who underwent a CABG for an acute coronary syn-
The results of this large international cohort anal-
drome are only supported by observational cohorts
ysis add to the limited body of research of DAPT in
and
trials
diabetic post-CABG patients. The observational design
(13–16,25,26). Importantly, all randomized studies of
precludes causal inferences and we recognize the
DAPT after on-pump CABG have failed to demonstrate
modest sample size; however, no benefit was observed
clinical benefits compared to aspirin monotherapy.
with the routine use of DAPT in diabetic patients post-
Select meta-analyses that reported lower mortality in
CABG. These results can potentially be incorporated
DAPT-treated patients have been driven primarily by
into
the inclusion of observational analysis and/or off-
studies evaluating the efficacy of DAPT in post-CABG
pump CABG (15,27–29). The lack of observed differ-
patients; however, future randomized controlled tri-
ences in the primary composite outcome between
als powered for both mortality and graft patency are
subgroup
analyses
of
controlled
meta-analyses
of
primarily
nonrandomized
aspirin- and DAPT-treated patients in the overall
required to evaluate the efficacy and safety of DAPT
cohort is in line with previous randomized studies.
versus aspirin monotherapy. The results of the
However, a subgroup analysis of patients with acute
ongoing TiCAB (Ticagrelor in CABG) trial may also help
coronary syndrome undergoing CABG <7 days from
improve our knowledge of the optimal post-CABG
the PLATO (Platelet Inhibition and Patient Outcomes)
antiplatelet treatment strategy (34).
trial demonstrated benefits of ticagrelor over clopidogrel in aspirin-treated patients that were consistent
STUDY LIMITATIONS. Our findings should be inter-
with the overall trial results, including a statistically
preted in the context of its limitations. First, out-
significant mortality reduction (30). The current
comes were derived from prescription rates at 30 days
analysis builds on prior research by extending these
post-CABG; thus, clinical and bleeding outcomes
findings into a higher risk diabetic population and into
associated with early post-operative use cannot be
clinically important subgroups with a higher long-
inferred from this analysis. Second, this study was
term risk of post-CABG cardiovascular events; this
conducted before the approval of
novel P2Y12
van Diepen et al.
JACC VOL. 69, NO. 2, 2017 JANUARY 17, 2017:119–27
Dual Antiplatelet Therapy in Diabetics After CABG
T A B L E 4 Outcomes in Clinically Important Subgroups
1-Yr Outcomes
DAPT
Aspirin Monotherapy
Stable angina
389 (6.4)
165 (7.9)
Acute coronary syndrome
145 (7.6)
79 (3.8)
Outcome*
5-Yr Outcomes
p Value
DAPT
Aspirin Monotherapy
0.89 (0.45–1.76)
0.74
389 (11.6)
165 (15.8)
0.82 (0.50–1.34)
0.42
2.28 (0.62–8.39)
0.21†
145 (15.2)
79 (16.5)
1.06 (0.53–2.10)
0.88†
HR (95% CI)
HR (95% CI)
p Value
FREEDOM endpoint Surgical indication
SYNTAX score <22
174 (5.2)
72 (6.9)
0.91 (0.30–2.81)
0.87*
174 (11.5)
72 (18.1)
0.69 (0.34–1.40)
0.30
22-32
228 (7.9)
106 (6.6)
1.20 (0.50–2.89)
0.68
228 (12.7)
106 (17.0)
0.77 (0.43–1.38)
0.38
$32
129 (7.0)
63 (6.3)
1.19 (0.36–3.91)
0.77‡
129 (14.0)
63 (12.7)
1.18 (0.51–2.72)
0.71‡
Revascularization Incomplete Complete
50 (10.0) 484 (6.4)
26 (3.8)
3.24 (0.33–31.97)
218 (6.9)
1.00 (0.54–1.87)
0.31† >0.99
50 (22.0) 484 (11.6)
26 (11.5)
1.92 (0.53–7.00)
0.32†
218 (16.5)
0.75 (0.49–1.15)
0.19
Endarterectomy or vein patching Yes None
41 (17.1)
15 (6.7)
493 (5.9)
229 (6.6)
2.76 (0.34–22.52)
0.34§
0.98 (0.52–1.85)
0.96
493 (11.8)
41 (22.0)
15 (20.0) 229 (15.7)
1.30 (0.35–4.85) 0.80 (0.53–1.22)
0.69§ 0.31
DAPT $1 yr Yes
403 (4.2)
-
-
-
403 (10.4)
-
-
No
135 (14.1)
244 (6.6)
2.45 (1.24–4.83)
0.01
135 (19.3)
244 (16.0)
1.60 (0.96–2.66)
-
On pump
428 (7.2)
203 (5.9)
1.27 (0.65–2.48)
0.49
428 (13.1)
203 (16.3)
0.84 (0.55–1.30)
0.44
Off pump
106 (4.7)
41 (9.8)
0.75 (0.18–3.16)
0.70†
106 (10.4)
41 (14.6)
0.89 (0.30–2.58)
0.83
150 (5.3)
76 (9.2)
0.72 (0.25–2.10)
0.54
150 (10.7)
76 (23.7)
0.47 (0.24–0.95)
0.04
Stable angina
393 (4.3)
165 (4.8)
0.93 (0.40–2.18)
0.87‡
393 (5.6)
165 (6.7)
0.85 (0.41–1.76)
0.66‡
Acute coronary syndrome
145 (4.1)
79 (3.8)
1.02 (0.25–4.11)
0.95†
145 (5.5)
79 (3.8)
1.43 (0.38–5.40)
0.60† 0.69†
0.07
Cardiopulmonary bypass
Renal function GFR <60, per 10 ml/min/1.73 m2 Bleeding outcomes Surgical indication
SYNTAX score <22
175 (6.3)
72 (4.2)
1.59 (0.44–5.79)
0.48†
175 (8.6)
72 (6.9)
1.23 (0.44–3.41)
22-32
229 (3.1)
106 (5.7)
0.55 (0.19–1.66)
0.29‡
229 (3.5)
106 (5.7)
0.63 (0.22–1.83)
0.40‡
131 (3.1)
63 (3.2)
1.05 (0.19–5.88)
0.96§
131 (4.6)
63 (4.8)
1.12 (0.28–4.54)
0.87§
$32 Revascularization Incomplete Complete
50 (0.0)
26 (0.0)
-
-
488 (4.7)
218 (5.0)
0.93 (0.45–1.92)
0.84
50 (4.0)
26 (0.0)
-
-
488 (5.7)
218 (6.4)
0.87 (0.46–1.67)
0.68
Endarterectomy or vein patching Yes None
41 (2.4)
15 (0.0)
497 (4.4)
229 (4.8)
-
-
0.91 (0.44–1.89)
0.80
497 (5.8)
41 (2.4)
15 (0.0)
-
407 (5.7)
0.74§
135 (5.2)
244 (5.7)
229 (6.1)
0.93 (0.49–1.78)
0.83
DAPT $1 yr Yes
407 (3.9)
-
No
135 (5.2)
244 (4.5)
1.17 (0.45–3.04)
-
-
-
0.96 (0.39–2.40)
0.94§
On pump
430 (4.2)
203 (4.4)
0.93 (0.42–2.09)
0.87
430 (5.3)
203 (5.4)
0.98 (0.48–2.03)
0.96
Off pump
108 (4.6)
41 (4.9)
1.06 (0.20–5.55)
0.95§
108 (6.5)
41 (7.3)
0.90 (0.23–3.52)
0.88§
152 (5.9)
76 (5.3)
1.07 (0.32–3.59)
0.91†
152 (7.9)
76 (7.9)
0.92 (0.34–2.52)
0.88†
Cardiopulmonary bypass
Renal function GFR <60, per 10 ml/min/1.73 m2
Values are n (%) unless otherwise indicated. *All unadjusted outcomes presented as valid n (event %). Because of 0 events in 1 or more covariate categories, some covariates were excluded from specific time to event analysis as follows: †adjusted only for EuroSCORE and known PPI at 1-month visit; ‡adjusted only for EuroSCORE and NSAIDs at 1-month visit; §adjusted only for EuroSCORE. GFR ¼ glomerular filtration rate; other abbreviations as in Tables 1 to 3.
inhibitors (ticagrelor and prasugrel); thus, results
dosing was available in the case report form. Finally,
cannot be extrapolated to these agents. Third, a mi-
the analysis was nonrandomized and may not have
nority of patients in this analysis underwent off-
been adequately powered to detect a clinically sig-
pump CABG in whom DAPT post-CABG is recom-
nificant difference; thus, the results should be
mended (15,28). Fourth, no information of DAPT
considered hypothesis-generating.
125
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van Diepen et al.
JACC VOL. 69, NO. 2, 2017 JANUARY 17, 2017:119–27
Dual Antiplatelet Therapy in Diabetics After CABG
CONCLUSIONS
PERSPECTIVES
In a secondary analysis of the FREEDOM trial, we observed that use of DAPT in patients with diabetes post-CABG was high, and, compared with aspirin monotherapy,
no
significant
associations
were
observed with all-cause mortality, MI, or stroke. Additionally,
no
differences
in
outcomes
were
observed in bleeding, clinical indication for revascularization, complexity of coronary artery disease, completeness
of
revascularization,
or
treatment
duration. Collectively, our findings suggest that the routine use of DAPT in post-CABG diabetic patients warrants an adequately powered, prospective randomized clinical outcome trial. REPRINT REQUESTS AND CORRESPONDENCE: Dr.
Sean van Diepen, Department of Critical Care and Division of Cardiology, 2C2 Cardiology Walter MacKenzie Center, University of Alberta Hospital, 8440-11 Street, Edmonton, Alberta T6G 2B7, Canada. E-mail:
COMPETENCY IN MEDICAL KNOWLEDGE: In a nonrandomized, post hoc analysis of patients with diabetes and multivessel coronary artery disease undergoing CABG surgery in the FREEDOM trial, there were no differences in rates of recurrent ischemia or bleeding with DAPT compared with aspirin monotherapy. Results were similar when results were stratified by pre-operative coronary syndrome acuity, SYNTAX score, completeness of revascularization, or use of off-pump bypass. Outcomes were lower among DAPT-treated patients with impaired renal function. TRANSLATIONAL OUTLOOK: Adequately powered randomized trials are needed to more accurately compare the efficacy and safety of DAPT versus aspirin monotherapy in patients with diabetes undergoing CABG surgery.
[email protected].
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24. Kim DH, Daskalakis C, Silvestry SC, et al. Aspirin and clopidogrel use in the early postoperative period following on-pump and off-pump coronary artery bypass grafting. J Thorac Cardiovasc Surg 2009;138:1377–84. 25. Gao G, Zheng Z, Pi Y, Lu B, Lu J, Hu S. Aspirin plus clopidogrel therapy increases early venous graft patency after coronary artery bypass surgery a single-center, randomized, controlled trial. J Am Coll Cardiol 2010;56:1639–43. 26. Sun JC, Teoh KH, Lamy A, et al. Randomized trial of aspirin and clopidogrel versus aspirin alone for the prevention of coronary artery bypass graft occlusion: the Preoperative Aspirin and Postoperative Antiplatelets in Coronary Artery Bypass Grafting study. Am Heart J 2010;160:1178–84. 27. de Leon N, Jackevicius CA. Use of aspirin and clopidogrel after coronary artery bypass graft surgery. Ann Pharmacother 2012;46:678–87. 28. Deo SV, Dunlay SM, Shah IK, et al. Dual antiplatelet therapy after coronary artery bypass
Dual Antiplatelet Therapy in Diabetics After CABG
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33. Meredith IT, Tanguay J-F, Kereiakes DJ, et al. Diabetes mellitus and prevention of late myocardial infarction after coronary stenting in the Randomized Dual Antiplatelet Therapy study.
30. Held C, Åsenblad N, Bassand JP, et al. Ticagrelor versus clopidogrel in patients with acute coronary syndromes undergoing coronary artery bypass surgery: results from the PLATO (Platelet Inhibition and Patient Outcomes) trial. J Am Coll Cardiol 2011;57:672–84. 31. Cho Y, Shimura S, Aki A, Furuya H, Okada K, Ueda T. The SYNTAX score is correlated with longterm outcomes of coronary artery bypass grafting for complex coronary artery lesions. Interact Cardiovasc Thorac Surg 2016;23:125–32. 32. Garcia S, Sandoval Y, Roukoz H, et al. Outcomes after complete versus incomplete revascularization of patients with multivessel coronary artery disease: a meta-analysis of 89,883 patients enrolled in randomized clinical trials and
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KEY WORDS antiplatelet therapy, aspirin, clopidogrel, coronary artery bypass grafting
A PP END IX For supplemental tables, please see the online version of this article.
127
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ª 2017 BY THE AMERICAN COLLEGE OF CARDIOLOGY FOUNDATION PUBLISHED BY ELSEVIER
ISSN 0735-1097/$36.00 http://dx.doi.org/10.1016/j.jacc.2016.10.043
ORIGINAL INVESTIGATIONS
Dual Antiplatelet Therapy Versus Aspirin Monotherapy in Diabetics With Multivessel Disease Undergoing CABG FREEDOM Insights Sean van Diepen, MD, MSC,a,b Valentin Fuster, MD, PHD,c Subodh Verma, MD, PHD,d Taye H. Hamza, PHD,e F. Sandra Siami, MPH,e Shaun G. Goodman, MD, MSC,b,f Michael E. Farkouh, MD, MSCg
ABSTRACT BACKGROUND Clinical practice guidelines recommend post-operative dual antiplatelet therapy (DAPT) in patients who undergo coronary artery bypass grafting (CABG) following acute coronary syndromes (ACS). OBJECTIVES The authors have evaluated DAPT utilization rates and associated outcomes among post-CABG patients with diabetes. METHODS In a post hoc, nonrandomized analysis from the FREEDOM (Future REvascularization Evaluation in patients with Diabetes mellitus: Optimal management of Multivessel disease) trial, we compared patients receiving DAPT (aspirin plus thienopyridine) and aspirin monotherapy at 30 days post-operatively. The primary outcome was the risk adjusted 5-year FREEDOM composite of all-cause mortality, nonfatal myocardial infarction, or stroke. Safety outcomes included major bleeding, blood transfusion, and hospitalization for bleeding. RESULTS At 30 days post-CABG, 544 (68.4%) patients received DAPT and 251 (31.6%) patients received aspirin alone. The median (25th, 75th percentile) duration of clopidogrel therapy was 0.98 (0.23 to 1.91) years. There was no significant difference in the 5-year primary composite outcome between DAPT- and aspirin-treated patients (12.6% vs. 16.0%; adjusted hazard ratio [HR]: 0.83; 95% confidence interval [CI]: 0.54 to 1.27; p ¼ 0.39). The 5-year primary composite outcomes were similar for patients receiving DAPT versus aspirin monotherapy respectively, in subgroups with pre-CABG ACSs (15.2% vs. 16.5%; HR: 1.06; 95% CI: 0.53 to 2.10; p ¼ 0.88) and those with stable angina (11.6% vs. 15.8%; HR: 0.82; 95% CI: 0.50 to 1.343; p ¼ 0.42). The composite outcomes of both treatment groups were also similar by SYNTAX score, duration of DAPT therapy, completeness of revascularization, and in off-pump CABG. No treatment-related differences in major bleeding (5.6% vs. 5.7%; HR: 1.00; 95% CI: 0.50 to 1.99; p ¼ 0.99), blood transfusions (4.8% vs. 4.5%; HR: 1.09; 95% CI: 0.51 to 2.34; p ¼ 0.82), or hospitalization for bleeding (2.6% vs. 3.3%; HR: 0.85; 95% CI: 0.34 to 2.17; p ¼ 0.74) were observed between aspirin- and DAPT-treated patients, respectively. CONCLUSIONS The use of DAPT in patients with diabetes post-CABG in our cohort was high. Compared with aspirin monotherapy, no associated differences were observed in cardiovascular or bleeding outcomes, suggesting that routine use of DAPT may not be clinically warranted. (Future REvascularization Evaluation in patients with Diabetes mellitus: Optimal management of Multivessel disease [FREEDOM]; NCT00086450) (J Am Coll Cardiol 2017;69:119–27) Listen to this manuscript’s
© 2017 by the American College of Cardiology Foundation.
audio summary by JACC Editor-in-Chief Dr. Valentin Fuster. From the aDepartment of Critical Care and Division of Cardiology, University of Alberta, Edmonton, Alberta, Canada; bCanadian VIGOUR Centre, University of Alberta, Edmonton, Alberta, Canada; cIcahn School of Medicine at Mount Sinai, New York, New York; dDivision of Cardiac Surgery, St. Michael’s Hospital, University of Toronto, Toronto, Ontario, Canada; eNew England Research Institutes, Inc., Watertown, Massachusetts; fTerrence Donnelly Heart Centre, Division of Cardiology, St. Michael’s Hospital, University of Toronto, Toronto, Ontario, Canada; and the gPeter Munk Cardiac Centre and the Heart and Stroke Richard
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JACC VOL. 69, NO. 2, 2017 JANUARY 17, 2017:119–27
Dual Antiplatelet Therapy in Diabetics After CABG
C
ABBREVIATIONS AND ACRONYMS CABG = coronary artery bypass
oronary
artery
bypass
surgery
(CABG) reduces long-term morbidity and mortality in patients with
multivessel disease with or without diabetes
surgery
(1–3). Aspirin alone has been reported to
CI = confidence interval
improve vein graft patency and mortality
DAPT = dual antiplatelet
(4,5). Dual antiplatelet therapy (DAPT) with
therapy
aspirin and a thienopyridine is a theoretically
HR = hazard ratio
attractive secondary prevention therapy,
MI = myocardial infarction
given that bypass graft thrombosis and sys-
NSAID = nonsteroidal anti-
temic hypercoagulability are potential causes
inflammatory drug
of saphenous vein graft failure (6). In addi-
PPI = proton pump inhibitor
tion, native coronary artery atherothrombotic risk for plaque rupture, ulceration, or erosion remains post-CABG (7,8). Clinical practice guidelines currently recommend DAPT in patients who undergo CABG for
drug-eluting stents. All study participants provided written consent. STUDY POPULATION AND DEFINITIONS. This anal-
ysis included all patients who underwent primary revascularization with CABG (per-protocol analysis) and were taking aspirin 30 days post-operatively. Patients undergoing DAPT were defined as all patients who were receiving aspirin and a thienopyridine (clopidogrel or ticlopidine) at 30 days post-operatively. The aspirin cohort was defined as those receiving aspirin monotherapy at 30 days. Patients receiving warfarin at 30 days were excluded. The primary analysis compared 5-year outcomes in patients treated with DAPT versus aspirin alone at 30-days post-CABG. The secondary analysis examined 1-year outcomes.
an acute coronary syndrome; however, the efficacy
OUTCOMES. The primary outcome was the FREEDOM
of DAPT reported in observational studies, subgroup
trial primary endpoint of 5-year all-cause mortality,
analyses, and small randomized trials that underpin
nonfatal myocardial infarction (MI), or stroke. Second-
these recommendations is uncertain, and DAPT may
ary outcomes included the individual components of
be associated with a higher risk of bleeding (9–16).
the composite outcomes: vascular death, MI, and cardiovascular
SEE PAGE 128
Diabetes
is
independently
hospitalization
(defined
as
unstable
angina, MI, heart failure, chest pain, arrhythmia, with
peripheral vascular disease, or stroke or transient
increased perioperative and long-term mortality in
associated
ischemic attack). Safety outcomes were major bleeding,
CABG patients, and may be a clinical risk factor for
blood transfusions, and bleeding hospitalization. All
vein graft failure (17–20). Hence, diabetics may be a
events were adjudicated by a clinical events committee.
unique high-risk subgroup that may benefit from
In a priori analysis, we also explored the primary
DAPT secondary prevention therapy, but little evi-
outcome and major bleeding in the following sub-
dence is available to support this hypothesis. The
groups: 1) patients revascularized following an acute
purpose of this analysis is to compare the long-term
coronary syndrome event versus stable angina; 2)
clinical and bleeding outcomes associated with
SYNTAX score (<22, 22 to 32, $32); 3) complete versus
DAPT versus aspirin monotherapy in post-bypass di-
incomplete revascularization; 4) patients with an
abetics with multivessel coronary artery disease from
endarterectomy or vein graft patching; 5) on- and off-
the FREEDOM (Future REvascularization Evaluation
pump CABG; 6) patients who maintained DAPT for a
in patients with Diabetes mellitus: Optimal manage-
minimum of 1 year; and 7) post-operative glomerular
ment of Multivessel disease) trial (1).
filtration rate.
METHODS
STATISTICAL METHODS. Categorical baseline char-
acteristics were summarized as number of subjects DATA SOURCE. The methods and results of the
and percentages. The difference between the 2 treat-
FREEDOM trial have been published (1,21). Briefly,
ment groups was tested using Fisher exact test.
this
enrolled
Continuous baseline characteristics were summarized
patients $ 18 years of age with diabetes mellitus (DM)
as median and quartiles. The differences between the 2
and with $70% stenosis of 2 or more major epi-
treatment groups were tested using Kruskal-Wallis
cardial vessels. Patients were randomized to either
test statistics. The times to primary, secondary, and
CABG or percutaneous coronary intervention with
safety outcomes were analyzed using Cox proportional
international
multicenter
study
Lewar Centre, University of Toronto, Toronto, Ontario, Canada. Dr. van Diepen has received honoraria and/or grant support from AstraZeneca, Bayer, Boehringer Ingelheim, Lilly, Pfizer, Merck, Novartis, Amgen, Sorin, Abbott, and Janssen. Dr. Goodman has received research grant support and speaker/consulting honoraria from AstraZeneca, Bayer, Bristol-Myers Squibb, Daiichi-Sankyo, Eli Lilly, and Sanofi. All other authors have reported that they have no relationships relevant to the contents for this paper to disclose. Faisal Bakaeen, MD, served as Guest Editor for this paper. Manuscript received September 29, 2016; accepted October 12, 2016.
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Dual Antiplatelet Therapy in Diabetics After CABG
hazard regression. Cumulative event rate curves were compared using log-rank test statistics. Whenever
T A B L E 1 Baseline Characteristics By Treatment Groups
DAPT (n ¼ 544)
Aspirin Monotherapy (n ¼ 251)
p Value
61.2 (54.8, 68.5)
63.7 (59.4, 71.2)
<0.001
392 (72.1)
176 (70.1)
possible, the Cox models were adjusted for EuroSCORE (European System for Cardiac Operative Risk Evaluation), region of enrollment (North America, Europe,
Age, yrs
South America, and others), number of grafts, right
Male
internal thoracic artery graft use, endarterectomy,
Race
endoscopic vein harvesting, and beta-blocker, non-
White
388 (71.3)
228 (90.8)
steroidal anti-inflammatory drugs (NSAID), and proton
Black or African American
38 (7.0)
8 (3.2)
Asian
57 (10.5)
7 (2.8)
Other
61 (11.2)
8 (3.2)
80.9 (69.0, 95.0)
82.0 (73.0, 93.5)
pump inhibitor (PPI) medication use at the 1 month post-CABG visit whenever possible. All analyses were
Body weight, kg
0.61 <0.001
0.32
performed using SAS (Statistical Analysis Systems,
Medical history
Cary, North Carolina) version 9.4 and R (RStudio,
Hypertension
458 (84.2)
213 (84.9)
0.83
Boston, Massachusetts) version 3.1.1.
Dyslipidemia
455 (83.6)
217 (86.5)
0.34
Type 1
20 (3.7)
16 (6.4)
Type 2
524 (96.3)
235 (93.6)
Diabetes mellitus
RESULTS
0.10
Seven hundred and ninety-five patients (83.9%) of
Current tobacco use
98 (18.0)
35 (13.9)
947 patients from the FREEDOM trial who were
MI
149 (27.4)
56 (22.3)
0.14
randomized to CABG were included in this analysis.
PCI or PTCA in previous 12 months
5 (0.9)
4 (1.6)
0.47
History of arrhythmia
18 (3.3)
7 (2.8)
0.83
Stroke or transient ischemic attack
12 (2.2)
9 (3.6)
0.34
Peripheral vascular disease
49 (9.0)
31 (12.4)
0.16
COPD
23 (4.2)
16 (6.4)
0.22
no revascularization (n ¼ 36), deceased within in the
Chronic kidney disease
22 (4.0)
19 (7.6)
0.06
first 30 days from the date of procedure (n ¼ 15), no
Indication for coronary angiography 0.13
Patients were excluded for the following reasons: randomized to CABG but underwent percutaneous coronary intervention revascularization (n ¼ 18),
aspirin therapy at 30 days (n ¼ 52), and warfarin ther-
Stable angina
398 (73.2)
170 (67.7)
apy at 30 days (n ¼ 31). At 30-days post-CABG,
Acute coronary syndrome
146 (26.8)
81 (32.3)
544 (68.4%) patients received DAPT and 251 (31.6%) patients received aspirin. The median (25th, 75th percentile) duration of thienopyridine therapy was
Physical examination and laboratory variables Heart rate, beats/min Systolic blood pressure, mm Hg LVEF, %
0.98 (0.23 to 1.91) years. Baseline differences between
Hemoglobin, g/l
aspirin- and DAPT-treated patients are provided in
Creatinine, mmol/l
Table 1. Participants who received DAPT were more
Hemoglobin A1c, %
frequently younger, non-Caucasian, and had surgery
Region of enrollment
performed in North America, South America, India, or Israel. Surgical variables, in-hospital complications, length of stay, and pharmacotherapy at 30 days stratified by
0.18
72.0 (64.0, 79.0)
70.0 (62.0, 77.0)
0.02
130.0 (120.0, 140.0)
130.0 (120.0, 145.0)
0.12 0.26
60.0 (53.0, 66.0)
60.0 (50.0, 65.0)
139.0 (128.5, 148.0)
137.0 (126.0, 147.0)
0.13
88.4 (74.0, 106.1)
88.4 (74.5, 106.1)
0.94
7.4 (6.6, 8.7)
7.2 (6.5, 8.1)
North America
0.94 <0.001
233 (42.8)
86 (34.3)
Europe
74 (13.6)
113 (45.0)
South America
167 (30.7)
36 (14.3)
Australia/New Zealand
32 (5.9)
15 (6.0)
India/Israel
38 (7.0)
1 (0.4)
treatment cohort are presented in Table 2. Patients who received DAPT had lower median EuroSCORE,
Values are median (25th, 75th percentile) or n (%).
less frequently underwent right internal mammary
COPD ¼ chronic obstructive pulmonary disease; DAPT ¼ dual antiplatelet therapy; LVEF ¼ left ventricular ejection fraction; MI ¼ myocardial infarction; PCI ¼ percutaneous coronary intervention; PTCA ¼ percutaneous transluminal coronary angioplasty or atherectomy.
artery grafting and transmyocardial revascularization, had a higher mean number of bypass grafts, and more frequently underwent endoscopic vein harvesting. No differences in in-hospital complications or lengths of stay were observed. NSAID use was less frequent in the DAPT cohort.
the secondary outcomes of all-cause mortality, vascular mortality, MI, stroke, or cardiovascular hospitalizations between DAPT- and aspirin-treated patients. There were no differences in the 5-year
CLINICAL OUTCOMES. The primary and secondary
safety outcomes of major bleeding (5.6% vs. 5.7%;
outcomes are described in Table 3 and shown in
HR: 1.00; 95% CI: 0.50 to 1.99; p ¼ 0.99), blood
the
differ-
transfusions (4.8% vs. 4.5%; HR: 1.09; 95% CI: 0.51 to
ences were observed in the 5-year primary composite
2.34; p ¼ 0.82), and bleeding hospitalizations (2.6%
Central
Illustration.
No
significant
outcome of all-cause death, MI, or stroke (12.5% vs.
vs. 3.3%; HR: 0.80; 95% CI: 0.31 to 2.04; p ¼ 0.64)
16.0%; adjusted hazard ratio [HR]: 0.83; 95% confi-
between DAPT- and aspirin-treated patients. Point
dence interval [CI]: 0.54 to 1.27; p ¼ 0.39) (Figure 1) or
estimates were similar at 1 year.
van Diepen et al.
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Dual Antiplatelet Therapy in Diabetics After CABG
SUBGROUP ANALYSES. The primary FREEDOM trial
T A B L E 2 Surgical Variables and Discharge Medications By Treatment Group
outcome and major bleeding in subgroups of interest
DAPT (n ¼ 544)
Aspirin Monotherapy (n ¼ 251)
p Value
differences in the incidence of the composite of
1.7 (1.2, 3.0)
2.1 (1.4, 3.7)
<0.001
all-cause death, MI, or stroke were observed by
26.0 (19.0, 31.5)
26.0 (19.3, 32.0)
0.35
surgical indication (stable angina or acute coronary
Number of lesions $70%
543 (99.8)
251 (100.0)
>0.99
syndrome), SYNTAX score, complete or incomplete
3-vessel disease
451 (82.9)
216 (86.1)
0.25
revascularization, duration of DAPT, or by on- or
85.0 (66.0, 108.0)
88.0 (64.5, 109.0)
0.88
59.0 (41.0, 77.0)
60.0 (42.0, 80.0)
0.99
108 (19.9)
43 (17.1)
EuroSCORE SYNTAX score
are presented in Table 4. No treatment-related
Surgical variables Cardiopulmonary bypass time, min
off-pump bypass at 5 years. The primary outcome was
Cross-clamp time, min Off-pump bypass Number of grafts
lower among DAPT-treated patients who had a
0.38
reduced glomerular filtration rate. No differences in
0.02
5-year major bleeding were observed across the
1
8 (1.5)
2 (0.8)
subgroups of interest. In a post hoc sensitivity anal-
2
135 (24.8)
88 (35.1)
ysis restricted to events occurring 30 days after sur-
3
278 (51.1)
123 (49.0)
gery, no differences in outcomes were observed
4
106 (19.5)
34 (13.5)
(Online Tables 1 and 2). In a post hoc analysis, the
17 (3.1)
4 (1.6)
Left internal thoracic artery graft
512 (94.1)
239 (95.2)
0.62
Right internal thoracic artery graft
54 (9.9)
51 (20.3)
<0.001
Radial artery graft
56 (10.3)
23 (9.2)
0.70
Endarterectomy
34 (6.3)
9 (3.6)
0.13
$5
Transmyocardial revascularization
were age, country, race, transmyocardial revascularization, and right internal thoracic artery graft use (Online Table 3).
4 (0.7)
10 (4.0)
96 (17.6)
30 (12.0)
0.05
Graft patching
9 (1.7)
7 (2.8)
0.29
Intra-aortic balloon pump use
3 (0.6)
1 (0.4)
>0.99
Antifibrinolytics given
296 (54.4)
150 (59.8)
0.17
Aspirin post-operative day 0/1
461 (84.7)
202 (80.5)
0.15
Thienopyridine post-operative day 0/1
159 (29.2)
9 (3.6)
<0.001
Any
105 (19.3)
59 (23.5)
0.19
received DAPT for a median duration of 1 year post-
MI
29 (5.3)
9 (3.6)
0.37
CABG. Second, no significant differences in either the
Stroke
18 (3.3)
10 (4.0)
0.68
primary composite outcome (all-cause death, MI, or
Atrial fibrillation
26 (4.8)
18 (7.2)
0.46
stroke) or bleeding outcomes were observed between
Repeat sternotomy for bleeding
13 (2.4)
7 (2.8)
>0.99
aspirin- and DAPT-treated patients. Third, results
Gastrointestinal bleeding
4 (0.7)
0 (0.0)
0.30
were similar across clinically important subgroups in
Renal failure
12 (2.2)
10 (4.0)
0.35
10.0 (7.0, 16.0)
11.0 (7.0, 18.0)
0.46
2.0 (1.0, 4.0)
2.0 (1.0, 4.0)
0.86
tion of DAPT.
Beta-blockers
462 (84.9)
205 (81.7)
0.08
DAPT prescription rates range from 22.0% to 53.8%
Statins
486 (89.3)
218 (86.9)
0.44
(14,22–24). The reasons underpinning this wide range
19 (3.5)
10 (4.0)
0.69
are unclear, but they may reflect differences in case
283 (52.0)
128 (51.0)
0.41
Aldosterone antagonists
77 (14.2)
41 (16.3)
0.45
mix, regional practices patterns, or variations in
Antiarrhythmics
45 (8.3)
22 (8.8)
0.89
Thiazide diuretics
49 (9.0)
26 (10.4)
0.69
DAPT post-CABG (9,10,15). In this analysis, approxi-
Endoscopic vein harvesting
0.002
variables identified associated with DAPT therapy
Perioperative medications
Length of stay Intensive care days
ACE or ARB
pared aspirin monotherapy with DAPT post-CABG in patients with diabetes. We observed 3 important findings. First, approximately two-thirds of patients
including pre-operative acute coronary syndrome, SYNTAX score, complete revascularization, and duraIn retrospective observational studies, post-CABG
Medications at 30 days
Ezetimibe
This post hoc secondary analysis of the FREEDOM trial with centrally adjudicated clinical outcomes com-
Post-operative complications
Hospital days
DISCUSSION
practice guideline recommendation weighting of
108 (19.9)
65 (25.9)
0.09
mately two-thirds of all trial participants were pre-
6 (1.1)
1 (0.4)
0.44
scribed thienopyridines in addition to aspirin. We
107 (19.7)
44 (17.5)
0.49
hypothesize that the higher rates of DAPT prescrip-
PPIs
23 (4.2)
17 (6.8)
0.08
tion observed in this analysis may have been influ-
NSAIDs
17 (3.1)
16 (6.4)
0.05
enced by the FREEDOM study protocol, which
Loop diuretics Digoxin Calcium-channel blockers
Values are median (25th, 75th percentile) or n (%). ACE ¼ angiotensin-converting enzyme inhibitors; ARB ¼ angiotensin receptor blockers; DAPT ¼ dual antiplatelet therapy; EuroSCORE ¼ European System for Cardiac Operative Risk Evaluation; NSAIDs ¼ nonsteroidal anti-inflammatory drugs; PPIs ¼ proton pump inhibitors.
provided participants with up to 1 year of thienopyridine drug coverage at the discretion of their treating physician regardless of study randomization. This may also reflect the perceived benefit of DAPT after
van Diepen et al.
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123
Dual Antiplatelet Therapy in Diabetics After CABG
T A B L E 3 Outcomes in Patients on DAPT and Aspirin Monotherapy
1-Yr Outcomes
Outcome*
DAPT
Aspirin Monotherapy
HR (95% CI)
534 (6.7)
244 (6.6)
1.08 (0.56–2.06)
5-Yr Outcomes
DAPT
Aspirin Monotherapy
HR (95% CI)
0.82
534 (12.5)
244 (16.0)
0.83 (0.54–1.27)
0.39
p Value
p Value
Primary FREEDOM outcome All-cause mortality, MI, or stroke Secondary outcomes All-cause mortality
538 (1.9)
244 (3.7)
0.54 (0.20–1.45)
0.22†
538 (5.8)
244 (9.4)
0.62 (0.34–1.13)
0.12
Vascular mortality
538 (1.3)
244 (1.6)
0.80 (0.23–2.83)
0.73‡
538 (3.5)
244 (3.3)
1.17 (0.50–2.72)
0.72§
MI
534 (3.9)
244 (2.0)
1.87 (0.65–5.36)
0.25
534 (5.2)
244 (3.7)
1.42 (0.63–3.21)
0.40
Stroke
538 (1.1)
244 (1.6)
0.89 (0.21–3.69)
0.87k
538 (3.2)
244 (4.1)
0.85 (0.36–1.99)
0.71k
Cardiovascular hospitalizations
533 (9.9)
243 (10.7)
0.99 (0.59–1.65)
0.97
533 (19.5)
243 (18.1)
1.10 (0.75–1.61)
0.62
Major bleeding
538 (4.3)
244 (4.5)
1.05 (0.48–2.30)
0.91
538 (5.6)
244 (5.7)
1.00 (0.50–1.99)
0.99
Blood transfusions
538 (4.3)
244 (3.7)
1.28 (0.55–2.96)
0.57
538 (4.8)
244 (4.5)
1.09 (0.51–2.34)
0.82
Bleeding hospitalization
538 (1.7)
244 (2.5)
0.73 (0.24–2.25)
0.58¶
538 (2.6)
244 (3.3)
0.85 (0.34–2.17)
0.74¶
Primary safety outcomes
Values are n (%) unless otherwise indicated. *All unadjusted outcomes presented as valid n (event %). Because of 0 events in 1 or more covariate categories, some covariates were excluded from specific time to event analysis as follows: †adjusted for EuroSCORE, region of enrollment, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and PPI or beta-blocker use at 1 month; ‡adjusted for EuroSCORE, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and PPI or beta-blocker use at 1-month visit; §adjusted for EuroSCORE, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and PPI, NSAID, or beta-blocker use at 1-month visit; kadjusted for EuroSCORE, region of enrollment, number of grafts, right internal thoracic artery graft, endarterectomy, endoscopic vein harvesting, and NSAID or beta-blocker use at 1-month visit; ¶adjusted for EuroSCORE, region of enrollment, number of grafts, endoscopic vein harvesting, and PPI or beta-blocker use at 1 month. CI ¼ confidence internal; HR ¼ hazard ratio; other abbreviations as in Tables 1 and 2.
C ENTR AL I LL U STRA T I O N Dual Antiplatelet Therapy in Diabetics After CABG: Adjusted Hazard Ratio Plot of Clinical and Safety Outcomes
van Diepen, S. et al. J Am Coll Cardiol. 2017;69(2):119–27.
No differences were observed in the 5-year incidence the primary FREEDOM outcome (all-cause death, myocardial infarction, or stroke), secondary outcomes, or primary safety outcomes in diabetic patients with multivessel coronary artery disease who underwent CABG treated with dual antiplatelet therapy or aspirin monotherapy. CABG ¼ coronary artery bypass surgery; CI ¼ confidence interval; DAPT ¼ dual antiplatelet therapy; FREEDOM ¼ Future REvascularization Evaluation in patients with Diabetes mellitus: Optimal management of Multivessel disease; MI ¼ myocardial infarction.
van Diepen et al.
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Dual Antiplatelet Therapy in Diabetics After CABG
includes those with antecedent acute coronary syn-
F I G U R E 1 Kaplan-Meier Plot of the 5-Year Primary FREEDOM Outcome
dromes and incomplete revascularization and high SYNTAX
40
log-rank P = 0.377 DAPT
35
(31,32).
Although
our
scientific
post-CABG population is incomplete, observational
Aspirin alone Cumulative Event Rate, %
scores
understanding of the effectiveness of DAPT in the studies suggest a reduced efficacy of DAPT among
30
diabetic patients. A recent DAPT trial secondary 25
analysis reported that patients with diabetes mellitus had a higher long-term risk of cardiovascular events
20
but a significantly attenuated benefit of prolonged
15
DAPT after percutaneous coronary intervention (33). The authors suggested the potential for other ischemic
10
pathophysiological process including greater plaque
5
burden, inflammation, and/or a reduced response to antiplatelet therapies.
0 1
0
2
3
4
5
Time to FREEDOM Outcome , Years
The lack of an observed difference in major bleeding by treatment assignment in this analysis was an un-
DAPT (Yes/No) / Number of patients at risk Yes
540
492
449
349
233
111
No
251
231
207
166
107
43
expected finding. Prior meta-analyses have reported point estimates for bleeding were nonsignificantly higher in DAPT CABG patients (28). We hypothesize this finding may be due to inadequate power because
No differences were observed in the incidence of all-cause mortality, myocardial
of a small number of events or differential treatment
infarction, or stroke in diabetic coronary artery bypass patients treated with dual antiplatelet therapy or aspirin monotherapy. DAPT ¼ dual antiplatelet therapy;
strategies. Prior studies have primarily evaluated
FREEDOM ¼ Future REvascularization Evaluation in patients with Diabetes mellitus:
bleeding outcomes among CABG patients initiated on
Optimal management of Multivessel disease.
early post-operative DAPT, a period when the antithrombotic-related treatment bleeding is potentially highest. In the present study, only 29% of
CABG among cardiovascular physicians when finan-
DAPT-treated patients were initiated on therapy on
cial barriers to drug prescription are removed.
post-operative day 0 or 1 and the DAPT cohort was
Guideline recommendations for DAPT in patients
defined according to DAPT therapy at 30 days.
who underwent a CABG for an acute coronary syn-
The results of this large international cohort anal-
drome are only supported by observational cohorts
ysis add to the limited body of research of DAPT in
and
trials
diabetic post-CABG patients. The observational design
(13–16,25,26). Importantly, all randomized studies of
precludes causal inferences and we recognize the
DAPT after on-pump CABG have failed to demonstrate
modest sample size; however, no benefit was observed
clinical benefits compared to aspirin monotherapy.
with the routine use of DAPT in diabetic patients post-
Select meta-analyses that reported lower mortality in
CABG. These results can potentially be incorporated
DAPT-treated patients have been driven primarily by
into
the inclusion of observational analysis and/or off-
studies evaluating the efficacy of DAPT in post-CABG
pump CABG (15,27–29). The lack of observed differ-
patients; however, future randomized controlled tri-
ences in the primary composite outcome between
als powered for both mortality and graft patency are
subgroup
analyses
of
controlled
meta-analyses
of
primarily
nonrandomized
aspirin- and DAPT-treated patients in the overall
required to evaluate the efficacy and safety of DAPT
cohort is in line with previous randomized studies.
versus aspirin monotherapy. The results of the
However, a subgroup analysis of patients with acute
ongoing TiCAB (Ticagrelor in CABG) trial may also help
coronary syndrome undergoing CABG <7 days from
improve our knowledge of the optimal post-CABG
the PLATO (Platelet Inhibition and Patient Outcomes)
antiplatelet treatment strategy (34).
trial demonstrated benefits of ticagrelor over clopidogrel in aspirin-treated patients that were consistent
STUDY LIMITATIONS. Our findings should be inter-
with the overall trial results, including a statistically
preted in the context of its limitations. First, out-
significant mortality reduction (30). The current
comes were derived from prescription rates at 30 days
analysis builds on prior research by extending these
post-CABG; thus, clinical and bleeding outcomes
findings into a higher risk diabetic population and into
associated with early post-operative use cannot be
clinically important subgroups with a higher long-
inferred from this analysis. Second, this study was
term risk of post-CABG cardiovascular events; this
conducted before the approval of
novel P2Y12
van Diepen et al.
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Dual Antiplatelet Therapy in Diabetics After CABG
T A B L E 4 Outcomes in Clinically Important Subgroups
1-Yr Outcomes
DAPT
Aspirin Monotherapy
Stable angina
389 (6.4)
165 (7.9)
Acute coronary syndrome
145 (7.6)
79 (3.8)
Outcome*
5-Yr Outcomes
p Value
DAPT
Aspirin Monotherapy
0.89 (0.45–1.76)
0.74
389 (11.6)
165 (15.8)
0.82 (0.50–1.34)
0.42
2.28 (0.62–8.39)
0.21†
145 (15.2)
79 (16.5)
1.06 (0.53–2.10)
0.88†
HR (95% CI)
HR (95% CI)
p Value
FREEDOM endpoint Surgical indication
SYNTAX score <22
174 (5.2)
72 (6.9)
0.91 (0.30–2.81)
0.87*
174 (11.5)
72 (18.1)
0.69 (0.34–1.40)
0.30
22-32
228 (7.9)
106 (6.6)
1.20 (0.50–2.89)
0.68
228 (12.7)
106 (17.0)
0.77 (0.43–1.38)
0.38
$32
129 (7.0)
63 (6.3)
1.19 (0.36–3.91)
0.77‡
129 (14.0)
63 (12.7)
1.18 (0.51–2.72)
0.71‡
Revascularization Incomplete Complete
50 (10.0) 484 (6.4)
26 (3.8)
3.24 (0.33–31.97)
218 (6.9)
1.00 (0.54–1.87)
0.31† >0.99
50 (22.0) 484 (11.6)
26 (11.5)
1.92 (0.53–7.00)
0.32†
218 (16.5)
0.75 (0.49–1.15)
0.19
Endarterectomy or vein patching Yes None
41 (17.1)
15 (6.7)
493 (5.9)
229 (6.6)
2.76 (0.34–22.52)
0.34§
0.98 (0.52–1.85)
0.96
493 (11.8)
41 (22.0)
15 (20.0) 229 (15.7)
1.30 (0.35–4.85) 0.80 (0.53–1.22)
0.69§ 0.31
DAPT $1 yr Yes
403 (4.2)
-
-
-
403 (10.4)
-
-
No
135 (14.1)
244 (6.6)
2.45 (1.24–4.83)
0.01
135 (19.3)
244 (16.0)
1.60 (0.96–2.66)
-
On pump
428 (7.2)
203 (5.9)
1.27 (0.65–2.48)
0.49
428 (13.1)
203 (16.3)
0.84 (0.55–1.30)
0.44
Off pump
106 (4.7)
41 (9.8)
0.75 (0.18–3.16)
0.70†
106 (10.4)
41 (14.6)
0.89 (0.30–2.58)
0.83
150 (5.3)
76 (9.2)
0.72 (0.25–2.10)
0.54
150 (10.7)
76 (23.7)
0.47 (0.24–0.95)
0.04
Stable angina
393 (4.3)
165 (4.8)
0.93 (0.40–2.18)
0.87‡
393 (5.6)
165 (6.7)
0.85 (0.41–1.76)
0.66‡
Acute coronary syndrome
145 (4.1)
79 (3.8)
1.02 (0.25–4.11)
0.95†
145 (5.5)
79 (3.8)
1.43 (0.38–5.40)
0.60† 0.69†
0.07
Cardiopulmonary bypass
Renal function GFR <60, per 10 ml/min/1.73 m2 Bleeding outcomes Surgical indication
SYNTAX score <22
175 (6.3)
72 (4.2)
1.59 (0.44–5.79)
0.48†
175 (8.6)
72 (6.9)
1.23 (0.44–3.41)
22-32
229 (3.1)
106 (5.7)
0.55 (0.19–1.66)
0.29‡
229 (3.5)
106 (5.7)
0.63 (0.22–1.83)
0.40‡
131 (3.1)
63 (3.2)
1.05 (0.19–5.88)
0.96§
131 (4.6)
63 (4.8)
1.12 (0.28–4.54)
0.87§
$32 Revascularization Incomplete Complete
50 (0.0)
26 (0.0)
-
-
488 (4.7)
218 (5.0)
0.93 (0.45–1.92)
0.84
50 (4.0)
26 (0.0)
-
-
488 (5.7)
218 (6.4)
0.87 (0.46–1.67)
0.68
Endarterectomy or vein patching Yes None
41 (2.4)
15 (0.0)
497 (4.4)
229 (4.8)
-
-
0.91 (0.44–1.89)
0.80
497 (5.8)
41 (2.4)
15 (0.0)
-
407 (5.7)
0.74§
135 (5.2)
244 (5.7)
229 (6.1)
0.93 (0.49–1.78)
0.83
DAPT $1 yr Yes
407 (3.9)
-
No
135 (5.2)
244 (4.5)
1.17 (0.45–3.04)
-
-
-
0.96 (0.39–2.40)
0.94§
On pump
430 (4.2)
203 (4.4)
0.93 (0.42–2.09)
0.87
430 (5.3)
203 (5.4)
0.98 (0.48–2.03)
0.96
Off pump
108 (4.6)
41 (4.9)
1.06 (0.20–5.55)
0.95§
108 (6.5)
41 (7.3)
0.90 (0.23–3.52)
0.88§
152 (5.9)
76 (5.3)
1.07 (0.32–3.59)
0.91†
152 (7.9)
76 (7.9)
0.92 (0.34–2.52)
0.88†
Cardiopulmonary bypass
Renal function GFR <60, per 10 ml/min/1.73 m2
Values are n (%) unless otherwise indicated. *All unadjusted outcomes presented as valid n (event %). Because of 0 events in 1 or more covariate categories, some covariates were excluded from specific time to event analysis as follows: †adjusted only for EuroSCORE and known PPI at 1-month visit; ‡adjusted only for EuroSCORE and NSAIDs at 1-month visit; §adjusted only for EuroSCORE. GFR ¼ glomerular filtration rate; other abbreviations as in Tables 1 to 3.
inhibitors (ticagrelor and prasugrel); thus, results
dosing was available in the case report form. Finally,
cannot be extrapolated to these agents. Third, a mi-
the analysis was nonrandomized and may not have
nority of patients in this analysis underwent off-
been adequately powered to detect a clinically sig-
pump CABG in whom DAPT post-CABG is recom-
nificant difference; thus, the results should be
mended (15,28). Fourth, no information of DAPT
considered hypothesis-generating.
125
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van Diepen et al.
JACC VOL. 69, NO. 2, 2017 JANUARY 17, 2017:119–27
Dual Antiplatelet Therapy in Diabetics After CABG
CONCLUSIONS
PERSPECTIVES
In a secondary analysis of the FREEDOM trial, we observed that use of DAPT in patients with diabetes post-CABG was high, and, compared with aspirin monotherapy,
no
significant
associations
were
observed with all-cause mortality, MI, or stroke. Additionally,
no
differences
in
outcomes
were
observed in bleeding, clinical indication for revascularization, complexity of coronary artery disease, completeness
of
revascularization,
or
treatment
duration. Collectively, our findings suggest that the routine use of DAPT in post-CABG diabetic patients warrants an adequately powered, prospective randomized clinical outcome trial. REPRINT REQUESTS AND CORRESPONDENCE: Dr.
Sean van Diepen, Department of Critical Care and Division of Cardiology, 2C2 Cardiology Walter MacKenzie Center, University of Alberta Hospital, 8440-11 Street, Edmonton, Alberta T6G 2B7, Canada. E-mail:
COMPETENCY IN MEDICAL KNOWLEDGE: In a nonrandomized, post hoc analysis of patients with diabetes and multivessel coronary artery disease undergoing CABG surgery in the FREEDOM trial, there were no differences in rates of recurrent ischemia or bleeding with DAPT compared with aspirin monotherapy. Results were similar when results were stratified by pre-operative coronary syndrome acuity, SYNTAX score, completeness of revascularization, or use of off-pump bypass. Outcomes were lower among DAPT-treated patients with impaired renal function. TRANSLATIONAL OUTLOOK: Adequately powered randomized trials are needed to more accurately compare the efficacy and safety of DAPT versus aspirin monotherapy in patients with diabetes undergoing CABG surgery.
[email protected].
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KEY WORDS antiplatelet therapy, aspirin, clopidogrel, coronary artery bypass grafting
A PP END IX For supplemental tables, please see the online version of this article.
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