High-Sensitivity Troponin T and Mortality After Elective Percutaneous Coronary Intervention

JOURNAL OF THE AMERICAN COLLEGE OF CARDIOLOGY

VOL. 68, NO. 21, 2016

ª 2016 BY THE AMERICAN COLLEGE OF CARDIOLOGY FOUNDATION

ISSN 0735-1097/$36.00

PUBLISHED BY ELSEVIER

http://dx.doi.org/10.1016/j.jacc.2016.08.059

High-Sensitivity Troponin T and Mortality After Elective Percutaneous Coronary Intervention Gjin Ndrepepa, MD,a Roisin Colleran, MB, BCH,a Siegmund Braun, MD,b Salvatore Cassese, MD,a Julia Hieber, MD,a Massimiliano Fusaro, MD,a Sebastian Kufner, MD,a Ilka Ott, MD,a Robert A. Byrne, MB, BCH, PHD,a Oliver Husser, MD,a Christian Hengstenberg, MD,a Karl-Ludwig Laugwitz, MD,c,d Heribert Schunkert, MD,a,d Adnan Kastrati, MDa,d

ABSTRACT BACKGROUND The prognostic value of high-sensitivity troponin T (hs-TnT) elevation after elective percutaneous coronary intervention (PCI) in patients with or without raised baseline hs-TnT levels is unclear. OBJECTIVES The goal of this study was to assess whether the prognostic value of post-procedural hs-TnT level after elective PCI depends on the baseline hs-TnT level. METHODS This study included 5,626 patients undergoing elective PCI who had baseline and peak post-procedural hs-TnT measurements available. The primary outcome was 3-year mortality (with risk estimates calculated per SD increase of the log hs-TnT scale). RESULTS Patients were divided into 4 groups: nonelevated baseline and post-procedural hs-TnT levels (hs-TnT #0.014 mg/l; n ¼ 742); nonelevated baseline but elevated post-procedural hs-TnT levels (peak post-procedural hs-TnT >0.014 mg/l; n ¼ 2,721); elevated baseline hs-TnT levels (hs-TnT >0.014 mg/l) with no further rise post-procedure (n ¼ 516); and elevated baseline hs-TnT levels with a further rise post-procedure (n ¼ 1,647). A total of 265 deaths occurred: 6 (1.6%) in patients with nonelevated baseline and post-procedural hs-TnT levels; 54 (3.8%) in patients with nonelevated baseline but elevated post-procedural hs-TnT levels; 50 (16.0%) in patients with elevated baseline hs-TnT levels with no further rise post-procedure; and 155 (18.2%) in patients with elevated baseline hs-TnT levels with a further rise post-procedure (p < 0.001). After adjustment, baseline hs-TnT levels (hazard ratio [HR]: 1.22; 95% confidence interval [CI]: 1.09 to 1.38; p < 0.001) but not peak post-procedural hs-TnT levels (HR: 1.04; 95% CI: 0.85 to 1.28; p ¼ 0.679) were associated with an increased risk of mortality. Peak post-procedural hs-TnT findings were not associated with mortality in patients with nonelevated (HR: 0.93; 95% CI: 0.69 to 1.25; p ¼ 0.653) or elevated (HR: 1.24; 95% CI: 0.91 to 1.69; p ¼ 0.165) baseline hs-TnT levels. CONCLUSIONS In patients with coronary artery disease undergoing elective PCI, an increase in post-procedural hs-TnT level did not offer prognostic information beyond that provided by the baseline level of the biomarker. (J Am Coll Cardiol 2016;68:2259–68) © 2016 by the American College of Cardiology Foundation.

C

ardiac troponins are the most commonly

myocardial damage occurring spontaneously or after

used biomarkers for the diagnosis of myo-

percutaneous

cardial damage. High-sensitivity troponin

Although elevation of cardiac troponin levels after

T (hs-TnT) assays enable the detection of even minor

elective PCI is common (3–5), the clinical significance

coronary

intervention

Listen to this manuscript’s audio summary by JACC Editor-in-Chief

From the aDepartment of Adult Cardiology, Deutsches Herzzentrum München, Technische Universität, Munich, Germany; bDe-

Dr. Valentin Fuster.

partment of Laboratory Medicine, Deutsches Herzzentrum München, Technische Universität, Munich, Germany; c1. Medizinische Klinik, Klinikum rechts der Isar, Technische Universität, Munich, Germany; and dDZHK (German Centre for Cardiovascular Research), partner site Munich Heart Alliance, Munich, Germany. Dr. Byrne has received lecture fees from B. Braun Melsungen, Biotronik, and Boston Scientific; and research grants to the institution from Boston Scientific and HeartFlow. All other authors have reported that they have no relationships relevant to the contents of this paper to disclose. Manuscript received June 21, 2016; revised manuscript received August 5, 2016, accepted August 31, 2016.

(PCI)

(1,2).

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Troponin and Mortality After Elective PCI

ABBREVIATIONS

of this finding remains unclear. A rise in hs-

DIAGNOSTIC

AND ACRONYMS

TnT level above the 99th percentile upper

stable angina, defined as chest pain that had

reference limit (URL) after elective PCI was

not changed in intensity, character, frequency, or

recently reported in up to 80% of patients

threshold over the preceding 2 months, underwent

who had baseline hs-TnT levels within

elective PCI if significant stenoses ($70% lumen

normal limits (6). Raised levels of baseline

obstruction) were documented on diagnostic coro-

circulating troponin in patients with stable

nary angiography. Patients undergoing PCI in the

coronary

setting of a scheduled examination after stent im-

CAD = coronary artery disease CI = confidence interval HR = hazard ratio hs-TnT = high-sensitivity troponin T

PCI = percutaneous coronary

artery

disease

(CAD)

are

also

TIMI = Thrombolysis In

PCI. Patients

with

the stented coronary segment or a significant stenosis

SEE PAGE 2269

in a nonstented segment was documented on coro-

Myocardial Infarction

Several previous studies have shown that

URL = upper reference limit

AND

plantation underwent PCI if a significant restenosis in

commonly found (7).

intervention

CRITERIA

baseline, but not post-procedural, troponin

nary angiography. Personnel blinded to patient clinical

or

follow-up

data

performed

angiographic

elevation was associated with a poor outcome after

analysis in the core laboratory using an automated

PCI (7,8). Thus, elevated baseline troponin is a great

edge detection system (CMS, Medis Medical Imaging

confounder that may modulate the association be-

Systems, Neuen, the Netherlands).

tween post-procedural troponin rise and outcome

Cardiovascular risk factors, including diabetes,

after PCI. Notably, whether the prognostic value of

arterial

post-procedural troponin is dependent on the base-

current smoking, were defined according to accepted

hypertension,

hypercholesterolemia,

and

line troponin level remains unknown. Moreover, the

criteria. Epicardial blood flow pre- and post-PCI was

magnitude of change and factors predisposing to

graded by using the Thrombolysis In Myocardial

elevated post-procedural levels after elective PCI in

Infarction (TIMI) group angiographic criteria. Left

patients with or without elevated baseline troponin

ventricular ejection fraction was calculated by using

are unclear.

the area–length method on left ventricular angiog-

The aim of the present study was 2-fold: first, to investigate whether the prognostic value of post-

raphy. Body mass index was calculated by using patient weight and height measured during the index

procedural hs-TnT level after elective PCI depends

hospitalization, and glomerular filtration rate was

on the baseline hs-TnT level; and second, to deter-

calculated according to the Cockcroft-Gault formula.

mine the factors that predispose to post-procedural

Coronary angiography and PCI were performed

hs-TnT elevation in patients with and without

according to standard practices. Before PCI, patients

elevated baseline hs-TnT levels.

received aspirin (325 to 500 mg) and clopidogrel (loading dose of 600 mg) and anticoagulation therapy

PATIENTS AND METHODS

in the form of unfractionated heparin or bivalirudin. After PCI, patients received clopidogrel 150 mg/day

STUDY PATIENTS. The present study was a retro-

until hospital discharge, followed by 75 mg/day for at

spective analysis of 5,626 patients with stable CAD

least 1 month after bare-metal stent implantation or

who underwent elective PCI in our hospitals between

at least 6 months after drug-eluting stent implanta-

October 2009 and January 2015, with the last day of

tion, in addition to aspirin 200 mg/day indefinitely.

follow-up at the end of May 2016. The indication for

Other

the index intervention was stable CAD (if significant

angiotensin-converting enzyme inhibitors, or beta-

coronary stenosis was found on diagnostic angiog-

blockers) were prescribed at the discretion of the

drugs

(comprising

predominantly

statins,

raphy in patients presenting with symptoms) or

treating physician.

restenosis diagnosed in the setting of scheduled

BIOCHEMICAL MEASUREMENTS. Blood samples were

angiography after previous stent implantation. All

collected in tubes containing a lithium-heparin anti-

patients had baseline (pre-procedural) and peak

coagulant. Blood samples for hs-TnT measurements

post-procedural hs-TnT measurements available for

were obtained before the procedure (on admission), 6 h

analysis. Each patient was included in the analysis

after PCI, and on a daily basis thereafter during the

only once (i.e., at his or her first PCI procedure).

hospital stay (usually 48 h). Two or more post-

Patients with acute coronary syndromes, acute in-

procedural hs-TnT measurements were performed in

fections, pregnancy, advanced impairment of renal

98.7% of patients. The peak level was defined as the

function (serum creatinine $2.0 mg/dl), or a known

highest

malignancy were excluded. The study was per-

Troponin T was measured by a high-sensitivity assay

formed

in a cobas e 411 immunoanalyzer using electro-

Helsinki.

in

accordance

with

the

Declaration

of

post-procedural

hs-TnT

concentration.

chemiluminescence technology (Roche Diagnostics,

Ndrepepa et al.

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Troponin and Mortality After Elective PCI

T A B L E 1 Baseline Data

hs-TnT Elevated at Baseline (n ¼ 2,163)

Age, yrs

hs-TnT Not Elevated at Baseline (n ¼ 3,463)

Further Elevation Post-PCI (n ¼ 1,647)

No Further Elevation Post-PCI (n ¼ 516)

p Value

Elevation Post-PCI (n ¼ 2,721)

No Elevation Post-PCI (n ¼ 742)

p Value

75.0 [68.5–81.1]

72.7 [66.7–78.8]

<0.001

69.3 [61.6–74.4]

66.1 [58.3–72.2]

<0.001

Female

332 (20.2)

105 (20.3)

0.925

619 (22.7)

197 (26.6)

Diabetes

624 (37.9)

206 (39.9)

0.407

712 (26.2)

238 (32.1)

0.001

245 (14.9)

87 (16.9)

0.275

180 (6.6)

64 (8.6)

0.058

27.0 [24.3–30.0]

27.5 [24.7–30.4]

0.130

27.3 [24.8–30.1]

27.6 [25.2–30.5]

0.018

1,226 (74.4)

354 (68.6)

0.009

2,089 (76.8)

527 (71.0)

0.001

78 (15.1)

0.218

388 (14.3)

129 (17.4)

0.034

On insulin therapy Body mass index, kg/m2 History of arterial hypertension Current smoker

214 (13.0)

Hypercholesterolemia

0.030

1,256 (76.3)

387 (75.0)

0.559

2,218 (81.5)

581 (78.3)

0.049

History of myocardial infarction

583 (35.4)

172 (33.3)

0.391

819 (30.1)

248 (33.4)

0.082

History of coronary artery bypass grafting

266 (16.2)

70 (13.6)

0.157

317 (11.7)

82 (11.1)

0.651

Baseline hs-TnT, mg/l

0.022 [0.020–0.040]

0.030 [0.020–0.067]

<0.001

0.010 [0.010–0.010]

0.010 [0.009–0.010]

<0.001

Peak post-procedural hs-TnT, mg/l

0.079 [0.040–0.171]

0.030 [0.020–0.060]

<0.001

0.040 [0.020–0.090]

0.010 [0.010–0.010]

<0.001

Glomerular filtration rate, ml/min

59.5 [43.5–79.1]

63.6 [47.3–84.6]

82.0 [64.7–102.8]

87.1 [70.8–107.4]

<0.001

140 (8.5)

61 (11.8)

0.010

No. of stenosed coronary arteries

0.068

1

0.002 434 (16.0)

144 (19.4)

2

370 (22.5)

117 (22.7)

698 (25.7)

218 (29.4)

3

1,137 (69.0)

338 (65.5)

1,589 (58.3)

380 (51.2)

1,507 (91.5)

455 (88.2)

0.023

2,287 (84.0)

598 (80.6)

0.025

785 (47.7)

167 (32.4)

<0.001

1,291 (47.4)

203 (27.4)

<0.001

60.0 [52.0–62.0]

60.0 [52.0–62.0]

0.400

Multivessel disease Multilesion intervention Left ventricular ejection fraction, %*

52.0 [40.0–60.0]

53.0 [43.8–60.0]

0.200

Statin

1,487 (90.6)

463 (89.9)

0.631

2,552 (93.9)

687 (92.7)

0.229

Beta-blocker

1,407 (85.7)

447 (86.8)

0.547

2,386 (87.9)

652 (88.0)

0.956

ACE inhibitor

1,090 (66.6)

352 (68.8)

0.363

1,845 (67.9)

498 (67.2)

0.728

Therapy on discharge

Values are median [25th to 75th percentile] or n (%). *Available in 3,799 patients. ACE ¼ angiotensin-converting enzyme; hs-TnT ¼ high-sensitivity troponin T; PCI ¼ percutaneous coronary intervention.

Risch-Rotkreuz, Switzerland). The limit of blank for

patient clinical or laboratory data performed follow-

this assay (the concentration below which analyte-free

up and adjudication of events.

samples

are

found

with

95%

probability)

is #0.003 m g/l. The functional sensitivity (the lowest

STATISTICAL ANALYSIS. Data are presented as me-

analyte concentration that can be reproducibly

dians with 25th to 75th percentiles, proportions (%), or

measured with a coefficient of variation #10%)

Kaplan-Meier estimates (%). The distribution of

is #0.013 m g/l. The 99th percentile URL is 0.014 m g/l.

continuous data was tested by using the 1-sample

Baseline and peak post-procedural hs-TnT values were

Kolmogorov-Smirnov test. Because all continuous

used for analysis. Creatinine was measured with a ki-

data exhibited a non-Gaussian distribution pattern,

netic colorimetric assay using the compensated Jaffe

the Kruskal-Wallis rank sum test was used for inter-

method. Laboratory personnel unaware of patient

group comparisons. Categorical data were compared

clinical or follow-up data measured other biochemical

by using the chi-square test. The correlates of

parameters using standard laboratory methods.

increased hs-TnT after PCI were assessed by using the multiple linear regression model. All variables in

OUTCOME AND FOLLOW-UP. The primary outcome

Tables 1 and 2, except for left ventricular ejection

measure was all-cause mortality up to 3 years after

fraction (due to incomplete data) and therapy at

PCI. Follow-up was performed by telephone inter-

discharge, were entered into the model. Due to the

view at 1, 6, and 12 months after PCI in the first year

skewed distribution of the hs-TnT levels, baseline and

and yearly thereafter. Data on mortality were ob-

post-procedural hs-TnT measurements were entered

tained from hospital charts, death certificates, tele-

into the model after logarithmic transformation.

phone contact with relatives of the patient or family

Survival analysis was performed by using the

physicians, insurance companies, or the registration

Kaplan-Meier method, and differences in survival

of address office. Medical personnel unaware of

rates were assessed according to the univariable Cox

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Troponin and Mortality After Elective PCI

T A B L E 2 Procedural Data (Lesion-Based Analysis)

hs-TnT Elevated at Baseline (n ¼ 3,500) Further Elevation Post-PCI (n ¼ 2,764)

hs-TnT Not Elevated at Baseline (n ¼ 5,654)

No Further Elevation Post-PCI (n ¼ 736)

Pre-procedural TIMI flow grade*

p Value

Elevated Post-PCI (n ¼ 4,665)

Not Elevated Post-PCI (n ¼ 989)

166 (3.6)

36 (3.6) 24 (2.4)

0.749

0

127 (4.6)

35 (4.8)

0.470

1

58 (2.1)

12 (1.6)

94 (2.0)

2

149 (5.4)

45 (6.1)

274 (5.9)

47 (4.8)

3

2,424 (87.9)

644 (87.5)

4,126 (88.5)

882 (89.2)

114 (4.1)

31 (4.1)

192 (4.1)

36 (3.6)

Vessel treated

<0.001

0.384

Left main coronary artery Left anterior descending coronary artery

1,116 (40.4)

311 (42.3)

1,986 (42.6)

426 (43.1)

Left circumflex artery

669 (24.2)

152 (20.7)

1,121 (24.0)

193 (19.5)

Right coronary artery

796 (28.8)

218 (29.6)

1,300 (27.9)

314 (31.7)

69 (2.5)

24 (3.3)

Bypass graft

p Value

66 (1.4)

20 (2.1)

2,103 (76.1)

516 (70.1)

<0.001

3,422 (73.4)

629 (63.6)

<0.001

Bifurcation lesion

923 (33.8)

211 (28.7)

0.008

1,649 (35.5)

286 (29.0)

<0.001

Restenotic lesion

262 (9.5)

77 (10.5)

0.423

445 (9.5)

124 (12.5)

0.004

0.200

3.00 [2.99–3.50]

3.00 [2.75–3.50]

0.010

Complex lesion (AHA B2/C class)

Balloon diameter, mm

3.00 [3.00–3.50]

3.00 [2.75–3.50]

Maximal balloon pressure, atm

15.0 [12.8–17.0]

14.0 [12.0–16.0]

0.008

15.0 [12.0–17.0]

14.0 [12.0–16.0]

<0.001

Total stented length, mm

24.0 [18.0–35.0]

23.0 [18.0–30.8]

0.002

23.0 [18.0–33.0]

23.0 [18.0–28.0]

<0.001

Post-procedural TIMI flow grade†

0.672

0

7 (0.2)

3 (0.4)

0.927 8 (0.2)

1 (0.1)

1

10 (0.4)

1 (0.1)

3 (0.1)

1 (0.1)

2

44 (1.6)

13 (1.8)

85 (1.8)

17 (1.7)

3

2,699 (97.8)

716 (97.7)

4,563 (97.9)

970 (98.1)

Values are n (%) of lesions or median [25th to 75th percentiles]. *Available for 3,494 lesions in patients with elevated baseline troponin levels and 5,649 lesions in patients with baseline troponin levels within normal limits. †Available for 3,493 lesions in patients with elevated baseline troponin levels and 5,648 lesions in patients with baseline troponin levels within normal limits. AHA ¼ American Heart Association; TIMI ¼ Thrombolysis In Myocardial Infarction; other abbreviations as in Table 1.

proportional hazards model. Independent correlates

the cutoff, patients were divided into a group

of all-cause mortality were assessed by using the

with baseline hs-TnT level within normal limits

multivariable Cox proportional hazards model. All

(hs-TnT #0.014 mg/l [n ¼ 3,463]) and a group with

variables in Tables 1 and 2 were tested in the uni-

elevated baseline hs-TnT level (hs-TnT >0.014 m g/l

variable analysis, and those exhibiting a significant

[n ¼ 2,163]). Using the peak post-procedural hs-TnT

association with mortality were entered into the

level, patients with normal baseline hs-TnT were

model to assess factors associated with mortality. The

divided into a group with elevated post-procedural

baseline and post-procedural hs-TnT measurements

hs-TnT level (hs-TnT >0.014 mg/l [n ¼ 2,721]) and

were entered into the model after logarithmic trans-

another group with normal post-procedural hs-TnT

formation.

equation

level (hs-TnT #0.014 m g/l [n ¼ 742]). Patients with

method was applied in all analyses (including multi-

elevated baseline hs-TnT levels were also divided

variable analyses) that involved lesion characteristics

into 2 groups: 1 with a further post-procedural rise in

to account for clustering of the data in the same pa-

hs-TnT (peak post-procedural hs-TnT level higher

tient. Statistical analysis was performed by using the

than baseline hs-TnT level [n ¼ 1,647]) and another

R

for

group with no further rise in post-procedural hs-TnT

Statistical Computing, Vienna, Austria). A 2-sided

(peak post-procedural hs-TnT equal to or lower than

p value <0.05 was considered to indicate statistical

the baseline hs-TnT level [n ¼ 516]). Baseline data are

2.15.1

The

generalized

Statistical

Package

estimating

(R

Foundation

significance.

RESULTS

shown in Table 1, and procedural characteristics are displayed in Table 2. CORRELATES OF POST-PROCEDURAL HS-TnT. Baseline

PATIENT CLASSIFICATION AND BASELINE DATA. Over-

and peak post-PCI hs-TnT levels in the whole group

all, the study included 5,626 patients. Using the

of patients are shown in the Central Illustration. In

99th percentile URL of baseline hs-TnT (0.014 m g/l) as

patients with nonelevated baseline hs-TnT levels,

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Troponin and Mortality After Elective PCI

C E N T R A L IL LU ST R A T I O N Troponin and Mortality After Elective PCI: Baseline and Post-Procedural hs-TnT Levels

Ndrepepa, G. et al. J Am Coll Cardiol. 2016;68(21):2259–68.

The graph in the left upper corner shows the distribution of paired baseline and peak post-procedural high-sensitivity troponin T (hs-TnT) values in each patient. The graph in the right upper corner shows the median and 25th to 75th percentiles of baseline (0.01 mg/l [0.01 to 0.02 mg/l]) and peak post-procedural (0.04 mg/l [0.02 to 0.10 mg/l]) hs-TnT levels. The median and 25th percentile values of baseline hs-TnT level are the same (0.01 mg/l). The lower graph shows the cumulative distribution curves of the baseline (blue line) and post-procedural (orange line) hs-TnT concentration. PCI ¼ percutaneous coronary intervention.

the mean baseline and post-procedural hs-TnT values

0.020 [0.010 to 0.060] m g/l), and 0.131 m g/l (median:

were 0.0095 m g/l and 0.098 m g/l. In patients with

0.023 [0.004 to 0.080] mg/l) in those with elevated

elevated baseline hs-TnT levels, mean baseline and

baseline hs-TnT levels. The multiple linear regression

mg/l

model with the generalized estimating equation

mg/l. The mean change in hs-TnT

method was used to assess independent correlates of

(peak post-procedural value  baseline value) was

peak post-procedural hs-TnT in patients with and

0.088 m g/l in patients with nonelevated baseline

without elevated baseline hs-TnT levels (2 separate

hs-TnT levels (median [25th to 75th percentiles]:

models). Independent correlates of post-procedural

post-procedural and

0.244

hs-TnT

values

were

0.113

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Troponin and Mortality After Elective PCI

T A B L E 3 Independent Correlates of Post-Procedural hs-TnT Concentration Obtained

From the Multiple Linear Regression Model

hs-TnT are shown in Table 3. The elevated baseline hsTnT level and increased CAD severity and/or procedure complexity were independently associated with

Patients With hs-TnT Elevated at Baseline (n ¼ 2,163)

Diabetes Multivessel disease

Patients With hs-TnT Not Elevated at Baseline (n ¼ 3,463)

Coefficient*

p Value

Coefficient

p Value

–0.111785651

0.022

0.281562811

<0.001

0.287904096

–0.191225601

<0.001

elevated hs-TnT levels after PCI. Notably, restenotic lesions were associated with reduced odds of an elevation in hs-TnT after PCI in patients from both groups.

<0.001

POST-PROCEDURAL HS-TnT AND MORTALITY. Overall,

–

–

0.125431940

0.019

there were 265 deaths during the follow-up period:

0.654213201

<0.001

0.832773399

<0.001

6 deaths (1.6%) in patients with normal baseline and

Previous myocardial infarction

–0.128152726

0.011

–

–

post-procedural hs-TnT levels; 54 deaths (3.8%) in

Restenotic lesion

–0.189879905

<0.001

–0.238671558

<0.001

patients with normal baseline and raised post-

ACC/AHA B2/C class lesion

0.147118526

<0.001

0.178565892

<0.001

Multivessel disease

0.281562811

<0.001

–

–

0.006

–

–

Arterial hypertension Baseline troponin

Glomerular filtration rate

–0.002781484

Body mass index

–

Bifurcation lesion

0.087846055

Left anterior descending artery intervention Maximal balloon pressure Post-procedural TIMI flow Total stented length

0.159625100 – –0.291569192 0.008934003

– 0.044 <0.001 –

procedural hs-TnT levels; 50 deaths (16.0%) in patients with raised baseline levels but no further elevation in post-procedural hs-TnT; and 155 deaths

–0.013267508

0.037

0.142993244

<0.001

(18.2%)

among

<0.001

hs-TnT

levels

0.171036095 0.016835049

<0.001

0.003

–0.334634960

0.005

<0.001

0.009691764

<0.001

*Coefficients denote the change in log post-procedural high-sensitivity troponin T (hs-TnT) per unit change in the independent variable. The negative sign before the coefficients shows the inverse correlation between the independent variable and the post-procedural troponin concentration.

patients and

with

further

elevated elevation

baseline in

post-

procedural hs-TnT (overall log-rank test p < 0.001) (Figure 1). In patients with normal baseline hs-TnT levels, elevated post-procedural hs-TnT measurements were associated with increased risk of mortality compared with patients with a post-procedural hs-TnT level within normal limits (univariable hazard ratio [HR]: 2.38; 95% confidence interval [CI]: 1.03 to

ACC ¼ American College of Cardiology; other abbreviations as in Tables 1 and 2.

5.54; p ¼ 0.043). In patients with elevated baseline

F I G U R E 1 Kaplan-Meier Curves Showing Probability of 3-Year Mortality for Patient Subgroups According to Baseline and Post-Procedural

High-Sensitivity Troponin T Levels

Probability of Mortality (%)

30.0 25.0 HR=2.38 [1.03-5.54]; P=0.043 18.2%

20.0 15.0

16.0% 10.0 5.0

HR=1.09 [0.79-1.51]; P=0.575 3.8%

0.0

1.6% 0

1

Troponin groups/patients at risk Raised at baseline/further raised after PCI Raised at baseline/not raised after PCI Not raised at baseline/raised after PCI Not raised at baseline/not raised after PCI

2

3

529 198 1142 309

248 106 588 144

Years 1647 516 2721 742

912 325 1832 484

The curves are hierarchically ordered according to the order of the numbers of patients at risk. Percentages show the Kaplan-Meier estimates of mortality. Numbers in brackets denote 95% confidence intervals. HR ¼ hazard ratio; PCI ¼ percutaneous coronary intervention.

Ndrepepa et al.

JACC VOL. 68, NO. 21, 2016 NOVEMBER 29, 2016:2259–68

hs-TnT levels, further elevation in post-procedural

T A B L E 4 Results of Multivariable Cox Proportional Hazards Model Applied to

hs-TnT was not associated with increased risk of

Assess Predictors of All-Cause Mortality With Baseline and Post-Procedural

mortality compared with patients with no further

hs-TnT Entered Into the Model

elevation in post-procedural hs-TnT (univariable HR: 1.09; 95% CI: 0.79 to 1.51; p ¼ 0.575). In the univariable analysis, age (p < 0.001), female sex (p ¼ 0.002), diabetes (p ¼ 0.009), arterial hyper-

HR (95% CI)

p Value

Peak post-procedural hs-TnT (for 1-SD increase in logarithmic scale of hs-TnT)

1.04 (0.85–1.28)

0.679

Baseline hs-TnT (for 1-SD increase in logarithmic scale of hs-TnT)

1.22 (1.09–1.38)

<0.001 <0.001

tension (p < 0.001), body mass index (p ¼ 0.019),

Age (for 10-yr increase)

1.92 (1.31–2.81)

hypercholesterolemia (p ¼ 0.005), multivessel dis-

Female

0.57 (0.34–0.91)

0.028

ease (p < 0.001), previous coronary artery bypass

Diabetes

1.09 (0.72–1.65)

0.693

surgery (p < 0.001), baseline hs-TnT level (p < 0.001),

Arterial hypertension

0.54 (0.37–0.79)

0.002

peak post-procedural hs-TnT level (p < 0.001),

Body mass index (for 5 kg/m2 increase)

1.22 (0.96–1.55)

0.112

glomerular filtration rate (p < 0.001), left ventricular

Hypercholesterolemia

0.73 (0.48–1.12)

0.149

ejection

fraction

(p

2265

Troponin and Mortality After Elective PCI

<

0.001),

vessel

treated

(p ¼ 0.004), restenotic lesions (p < 0.001), baseline

Multivessel disease

1.26 (0.63–2.53)

0.505

Previous coronary artery bypass surgery

1.03 (0.64–1.65)

0.897

TIMI flow grade (p ¼ 0.014), balloon diameter

GFR (for 30 ml/min decrease)

1.69 (1.14–2.51)

0.008

LVEF (for 10% decrease)

1.41 (1.23–1.62)

<0.001

(p ¼ 0.003), maximal balloon pressure (p ¼ 0.007),

Vessel treated

1.54 (0.92–2.59)

and post-procedural TIMI flow grade (p ¼ 0.042) were

Restenotic lesions

1.32 (0.87–1.99)

0.187

independently associated with mortality risk. All of

Baseline TIMI flow grade (for 1 grade decrease)

1.26 (0.98–1.64)

0.076

Balloon diameter (for 0.5-mm increase)

1.05 (0.94–1.17)

0.387

Maximal balloon pressure (5 atm increase)

1.16 (0.96–1.39)

0.120

these variables, except for post-procedural TIMI flow (due to strong correlation with post-procedural hsTnT), were entered into the Cox proportional hazards model with the generalized estimating equation

0.102

CI ¼ confidence interval; GFR ¼ glomerular filtration rate; HR ¼ hazard ratio; LVEF ¼ left ventricular ejection fraction; other abbreviations as in Tables 1 and 2.

method. When the post-procedural hs-TnT-mortality association was tested in the model in the entire group of patients and adjusted for the factors associated with mortality risk listed previously (excluding baseline hs-TnT), there was a trend for an association between post-procedural hs-TnT level and the risk of mortality (adjusted HR: 1.22; 95% CI: 0.98 to 1.41; p ¼ 0.082 for each SD increase in the logarithmic scale of post-procedural hs-TnT). When baseline hs-TnT level was entered into the model, the baseline hsTnT level (HR: 1.22; 95% CI: 1.09 to 1.38; p < 0.001), but not peak post-procedural hs-TnT level (HR: 1.04; 95% CI: 0.85 to 1.28; p ¼ 0.679), was associated with increased risk of mortality (both risk estimates calculated per SD increase in the logarithmic scale of hs-TnT) (Table 4). The association between peak post-

>70  the 99th percentile URL cutoff, compared with post-procedural hs-TnT #70  the 99th percentile URL, was associated with increased risk of mortality in patients with elevated baseline hs-TnT level (45.1% vs. 17.1%; univariable HR: 4.20; 95% CI: 1.98 to 8.44; p < 0.001) but not in those with nonelevated levels of the biomarker (5.3% vs. 3.3%; HR: 1.42; 95% CI: 0.03 to 8.72; p ¼ 0.772). In patients with elevated baseline hs-TnT, the association between the >70  the 99th percentile URL cutoff and mortality was tested in the multivariable Cox model, with hs-TnT entered as a categorical variable (dichotomized at the 70  the 99th percentile cutoff). The analysis showed a trend toward an independent association between hs-TnT

procedural hs-TnT and mortality was not significant in the group with normal baseline hs-TnT level (HR:

T A B L E 5 Mortality According to Different Cutoffs of Post-Procedural hs-TnT

0.93; 95% CI: 0.69 to 1.25; p ¼ 0.653) or in the group with elevated baseline hs-TnT level (HR: 1.24; 95% CI:

Elevated Baseline hs-TnT (n ¼ 2,163)

0.91 to 1.69; p ¼ 0.165), with both risk estimates

Patients (%) Mortality (%)* Patients (%) Mortality (%)*

calculated per SD increase in the logarithmic scale of peak post-procedural hs-TnT.

Baseline hs-TnT Within Normal Limits (n ¼ 3,463)

Not increased (vs. baseline)

516 (23.9)

50 (16.0)

742 (21.4)

6 (1.6)

1 to 3  99th percentile URL

595 (27.5)

45 (17.0)

1,475 (42.6)

26 (3.4) 12 (5.4)

MORTALITY ACCORDING TO VARIOUS CUTOFFS OF

>3 to 5  99th percentile URL

362 (16.8)

35 (17.1)

453 (13.1)

>5 to 10  99th percentile URL

295 (13.6)

28 (20.8)

380 (11.0)

7 (2.7)

POST-PROCEDURAL HS-TnT. The association between

>10 to 35  99th percentile URL

286 (13.2)

28 (17.2)

310 (8.9)

7 (4.6)

post-procedural hs-TnT level and mortality was

>35 to 70  99th percentile URL

65 (3.0)

6 (15.5)

62 (1.8)

1 (1.8)

assessed over several multiples of 99th percentile URL

>70  99th percentile URL

44 (2.0)

13 (45.1)

41 (1.2)

1 (5.3)

cutoffs in patients with and without elevations in baseline hs-TnT. The results of this analysis are shown in Table 5. Notably, the hs-TnT elevation

*Numbers in parentheses in the mortality columns represent Kaplan-Meier estimates of mortality. hs-TnT ¼ high-sensitivity troponin T; URL ¼ upper reference limit.

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Troponin and Mortality After Elective PCI

>70  the 99th percentile URL and mortality

the risk of subsequent mortality up to 3 years after PCI.

(p ¼ 0.093), and a trend toward an interaction between

A PCI-related hs-TnT elevation 6 times the URL in pa-

post-procedural hs-TnT >70  the 99th percentile URL

tients with normal baseline hs-TnT and >9 times the

and baseline level of the biomarker with regard to the

URL in patients with elevated baseline levels of the

prediction of mortality (p for interaction ¼ 0.073).

biomarker was not associated with increased mortality risk. The striking separation of the Kaplan-Meier

DISCUSSION

curves for mortality (showing mortality differences predominantly secondary to baseline hs-TnT levels),

The main findings of this study can be summarized as

in addition to the results of the multivariable analysis,

follows: 1) in patients with CAD undergoing elective

lend further support to this finding. Miller et al. (8) also

PCI, a procedure-related hs-TnT rise occurred in the

showed that long-term prognosis was most often

majority of patients (77.6%); 2) post-procedural

related to the baseline troponin level, rather than to

hs-TnT

elevation

was

not

associated

with

an

the biomarker response to PCI. However, the study by

increased risk of mortality for up to 3 years, regard-

Miller et al. differs from the present study in that it

less of the pre-procedural hs-TnT level; 3) the pre-

included not only patients with stable CAD but also

procedural hs-TnT elevation was independently

those with acute coronary syndromes, a conventional

associated with an increased risk of mortality; and 4)

troponin assay was used, and fewer deaths were re-

pre-procedural hs-TnT level and angiographic char-

ported. Notwithstanding these differences, the cur-

acteristics underlying procedure complexity were

rent study corroborates the findings of Miller et al. in a

independent correlates of elevated post-procedural

large series of patients with stable CAD by using a

hs-TnT level in patients both with and without

contemporary high-sensitivity cardiac troponin assay.

elevated baseline levels of the biomarker.

Furthermore, by finding a trend toward an interaction

Circulating troponin after PCI consists of 2 frac-

between the post-procedural hs-TnT >70  the 99th

tions: a pre-procedural or baseline fraction and a

percentile URL and baseline hs-TnT level regarding

fraction

prediction of mortality, the present study may offer

that

reflects

PCI-related

troponin

rise.

Continuous microscopic loss of cardiomyocytes dur-

support to the definition of clinically relevant

ing normal life (9) and cardiomyocyte renewal (10) are

myocardial infarction after coronary revascularization

2 processes that contribute to physiological baseline

in the Consensus Document of the Society for Cardio-

concentrations

vascular Angiography and Interventions (16).

of

circulating

troponin.

Multiple

additional factors can increase levels of circulating

Although factors responsible for baseline hs-TnT

cardiac troponin in clinical scenarios other than acute

elevation help to explain the increased mortality

coronary syndromes (11). Prasad et al. (7) showed that

risk in patients with elevated baseline levels of the

37%

have

biomarker, the relationship between factors associ-

elevated pre-procedural troponin levels. The elevated

ated with troponin rise post-PCI and mortality is less

circulating troponin level in these patients may be

clear. Procedure-related factors or complications

explained by a less favorable cardiovascular and

increasing the risk of myocardial damage via distal

metabolic risk profile (11), more extensive CAD (12), or

embolization, side-branch occlusion, or suboptimal

clinically silent complicated atherosclerotic plaques

myocardial flow are proven risk factors for post-

(13). It is proposed that elevated baseline circulating

procedural troponin rise (3,17,18). The present study

troponin level in patients with stable CAD may be

also found that increased procedural complexity was

caused by cardiometabolic risk–related stress on the

associated with elevated hs-TnT levels after PCI,

myocardium (14,15) or by cycles of silent atheroscle-

regardless of the baseline hs-TnT level. However, if

rotic plaque rupture and sealing, leading to repeated

the troponin response to PCI was assessed by using

myocardial ischemia (13). Both of these conditions are

less sensitive troponin assays, as was the case in

associated with increased cardiovascular risk, and

multiple

they may explain the association between elevated

myocardial damage would be needed to result in a

baseline hs-TnT and mortality.

procedure-related troponin rise. The currently used

of

patients

undergoing

elective

PCI

previous

studies,

relatively

extensive

The principal finding of the present study was that

high-sensitivity troponin assays, including that used

post-procedural hs-TnT elevation was not associated

in the present study, allow detection of troponin

with an increased risk of mortality, regardless of

release from minuscule damage of myocardial tissue.

baseline hs-TnT level. Although elevated baseline hs-

Thus, it is plausible that post-procedural elevation of

TnT in itself was strongly associated with an

the magnitude observed in the present study may

increased risk of mortality, it had no impact on the

reflect subtle PCI-related myocardial damage that is

association between the PCI-related rise in hs-TnT and

too small (or transient) to have clinical sequelae.

Ndrepepa et al.

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Troponin and Mortality After Elective PCI

A study by Lim et al. (19) found that only a small

as others regarding post-procedural troponin mea-

minority (5 of 26 patients) fulfilling troponin criteria

surements. We are aware of the possibility that the

for PCI-related (type 4a) myocardial infarction had

precise peak value of post-procedural troponin may

evidence of peri-procedural necrosis on cardiac

have been missed in a number of patients. This would

magnetic resonance imaging. The investigators sug-

have required multiple measurements in a short time

gest that current troponins are oversensitive for the

interval. Finally, these data are from the hs-TnT assay

diagnosis of PCI-related myocardial injury. In the

and may not be extrapolated to assess the perfor-

present study, despite post-procedural hs-TnT ele-

mance of other conventional or high-sensitivity

vations in the majority of patients and identification

troponin assays. In the present study, a 0.014-mg/l

of several indexes of procedural complexity as pre-

cutoff was used to define the hs-TnT elevation, which

post-

differs from the 0.03-m g/l cutoff we used previously

procedural TIMI flow (grade 3) was restored in >97%

to detect troponin elevations with conventional

of patients. Thus, a combination of factors (including

troponin assays.

disposing

factors

for

this

rise,

optimal

the use of a high-sensitivity troponin assay) capable of detecting troponin elevation caused by subtle PCIrelated myocardial damage, adjustment for baseline hs-TnT level, and the capacity of current-day PCI to achieve optimal revascularization, even in the setting of high procedural complexity, may have attenuated the association of post-procedural troponin rise with mortality. The inverse association between restenotic lesions and post-procedural hs-TnT may offer evidence for the role of distal embolization in the elevation of post-procedural hs-TnT level. Intervention in restenotic lesions, which have a higher fibrotic/atherosclerotic content ratio compared with native atherosclerotic plaques, may be associated with less distal embolization, myocardial injury, and troponin elevation due to this factor.

CONCLUSIONS In patients with CAD undergoing elective PCI, postprocedural hs-TnT elevation was not associated with an increased risk of mortality for up to 3 years in patients with or without elevated baseline levels of the biomarker. Although there was a strong and independent association between baseline hs-TnT and mortality, the PCI-related elevation in hs-TnT did not offer prognostic information beyond that provided by baseline hs-TnT levels. REPRINT REQUESTS AND CORRESPONDENCE: Dr.

Gjin

Ndrepepa,

Deutsches

Herzzentrum,

Laza-

rettstrasse 36, 80636 München, Germany. E-mail: [email protected].

STUDY LIMITATIONS. First, serial testing of hs-TnT

levels before PCI was not performed, resulting in a

PERSPECTIVES

lack of data on biomarker stability at baseline. If hsTnT levels are unstable before PCI, the ability to discriminate between a spontaneous and procedurerelated hs-TnT elevation is limited. This scenario is particularly relevant in the case of patients presenting with acute coronary syndromes. Nonetheless, all patients included in the present study had clinically stable CAD at the time of the index PCI. Moreover, given that the proportion of patients with hs-TnT elevation post-PCI seems to differ little between the groups with or without elevated baseline hs-TnT levels, we believe that PCI was responsible for the biomarker increase in the vast majority of patients in both groups. The collection of blood samples after the

COMPETENCY IN PATIENT CARE AND PROCEDURAL SKILLS: In patients with CAD undergoing elective PCI, the baseline level of hs-TnT was strongly and independently associated with 3-year mortality, whereas post-procedural hs-TnT elevations did not provide additional prognostic information beyond the baseline hs-TnT level. TRANSLATIONAL OUTLOOK: Further studies in larger numbers of patients are needed to determine whether certain thresholds of post-procedural hs-TnT elevation carry independent prognostic value in patients with particular patterns of CAD undergoing PCI.

PCI follows the common practice in our center as well

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2002;53:319–36. KEY WORDS angina, biomarkers, coronary artery disease, coronary stenosis, prognosis, risk factors, stable