Diagnostic accuracy of single baseline measurement of Elecsys Troponin T high-sensitive assay for diagnosis of acute myocardial infarction in emergency department: systematic review and meta-analysis
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* Zhivko Zhelev
* Christopher Hyde
* Emily Youngman
* Morwenna Rogers
* Simon Fleming
* Toby Slade
* Helen Coelho
* Tracey Jones-Hughes
* Vasilis Nikolaou

## Abstract

**Objective** To obtain summary estimates of the accuracy of a single baseline measurement of the Elecsys Troponin T high-sensitive assay (Roche Diagnostics) for the diagnosis of acute myocardial infarction in patients presenting to the emergency department.

**Design** Systematic review and meta-analysis of diagnostic test accuracy studies.

**Data sources** Medline, Embase, and other relevant electronic databases were searched for papers published between January 2006 and December 2013.

**Study selection** Studies were included if they evaluated the diagnostic accuracy of a single baseline measurement of Elecsys Troponin T high-sensitive assay for the diagnosis of acute myocardial infarction in patients presenting to the emergency department with suspected acute coronary syndrome.

**Study appraisal and data synthesis** The first author screened all titles and abstracts identified through the searches and selected all potentially relevant papers. The screening of the full texts, the data extraction, and the methodological quality assessment, using the adapted QUADAS-2 tool, were conducted independently by two reviewers with disagreements being resolved through discussion or arbitration. If appropriate, meta-analysis was conducted using the hierarchical bivariate model.

**Results** Twenty three studies reported the performance of the evaluated assay at presentation. The results for 14 ng/L and 3-5 ng/L cut-off values were pooled separately. At 14 ng/L (20 papers), the summary sensitivity was 89.5% (95% confidence interval 86.3% to 92.1%) and the summary specificity was 77.1% (68.7% to 83.7%). At 3-5 ng/L (six papers), the summary sensitivity was 97.4% (94.9% to 98.7%) and the summary specificity was 42.4% (31.2% to 54.5%). This means that if 21 of 100 consecutive patients have the target condition (21%, the median prevalence across the studies), 2 (95% confidence interval 2 to 3) of 21 patients with acute myocardial infarction will be missed (false negatives) if 14 ng/L is used as a cut-off value and 18 (13 to 25) of 79 patients without acute myocardial infarction will test positive (false positives). If the 3-5 ng/L cut-off value is used, <1 (0 to 1) patient with acute myocardial infarction will be missed and 46 (36 to 54) patients without acute myocardial infarction will test positive.

**Conclusions** The results indicate that a single baseline measurement of the Elecsys Troponin T high-sensitive assay could be used to rule out acute myocardial infarction if lower cut-off values such as 3 ng/L or 5 ng/L are used. However, this method should be part of a comprehensive triage strategy and may not be appropriate for patients who present less than three hours after symptom onset. Care must also be exercised because of the higher imprecision of the evaluated assay and the greater effect of lot-to-lot reagent variation at low troponin concentrations.

**Systematic review registration** PROSPERO registration number CRD42013003926.

## Introduction

Emergency physicians commonly encounter chest pain and other symptoms suggestive of acute coronary syndrome, which account for approximately 5% to 10% of all visits to the emergency department.1 2 Timely diagnosis of such patients, especially ruling in or out of acute myocardial infarction, is of paramount importance. Delays in confirming the diagnosis may increase the risk of complications, and missing it may have fatal consequences for the patient.3 4 Until recently, the triage tools used by emergency physicians—clinical symptoms, history, 12 lead electrocardiogram, and standard troponin assays—did not allow early exclusion of evolving acute myocardial infarction. To avoid inadvertent discharge home, approximately 80% of all patients with chest pain were admitted to hospital for clinical observation and further testing, despite the fact that only a small proportion of them (approximately 25%) were eventually diagnosed as having myocardial infarction.5

The need to triage patients with chest pain more effectively and efficiently—to avoid unnecessary hospital admissions and to speed up the diagnostic process—has driven the development of the so called high sensitivity cardiac troponin assays. To be classified as high sensitivity, a cardiac troponin assay should meet two criteria: firstly, its total imprecision (coefficient of variation) at the 99th centile of the healthy reference population should be 10% or less; secondly, measureable concentrations above the limit of detection and below the 99th centile should be attainable for at least 50% of the reference population.6 Over the past few years in the United Kingdom, standard troponin assays have gradually been replaced with high sensitivity ones. Although authoritative data on how and to what extent they are used in different National Health Service trusts are unavailable, anecdotal evidence strongly suggests both that standard troponin assay use remains common and that where used high sensitivity assays are being used in the same manner as standard troponin assays, not capitalising on their greater sensitivity.

To improve this situation, the National Institute for Health and Care Excellence (NICE) has recently published guidance on the clinical application of high sensitivity troponin assays in the early rule-out of acute myocardial infarction. The guidance recommends the Elecsys Troponin T high-sensitive assay (Roche Diagnostics) and the ARCHITECT*STAT* high sensitive troponin I (Abbott Laboratories) for use with early rule-out protocols that include blood samples taken at the patient’s presentation to the emergency department and a second sample three hours later. A third assay, the AccuTnI+3 (Beckman Coulter) has also been evaluated, but owing to insufficient evidence it is recommended only for use in clinical research.7 The guidance recommends the use of the 99th centile as a cut-off value when deciding whether to rule out acute myocardial infarction or to refer the patient for further investigations. Given the high negative predictive value of high sensitivity troponin assays and the fact that patients who present with very low cardiac troponin concentrations also have a very low risk of myocardial infarction, a rule-out strategy based on a single sample at presentation and lower decision thresholds, such as the assay’s limit of detection or limit of blank, has also been proposed.5 The limit of blank is the highest apparent analyte concentration (analytical noise) expected to be found when replicates of a blank sample containing no analyte are tested. The limit of detection, on the other hand, is the lowest analyte concentration likely to be reliably distinguished from the limit of blank and at which detection is feasible.8 Using these cut-off values may provide the means to identify patients at very low risk in whom acute myocardial infarction could be excluded without a second troponin measurement. The effectiveness and feasibility of such a strategy, however, will depend on a range of factors, including the diagnostic sensitivity and the precision of the assay at such low threshold values.

We did a systematic review and meta-analyses of studies evaluating the diagnostic accuracy of the Elecsys Troponin T high-sensitive assay (hereinafter referred to as the high sensitivity troponin T assay) for early diagnosis of acute myocardial infarction in patients presenting to the emergency department with chest pain and other symptoms suggestive of acute coronary syndrome. The review protocol was registered on the PROSPERO database (registration number CRD42013003926). Here we report the results pertaining to the hypothesis that a single use of the high sensitivity troponin T assay at presentation is sensitive enough to allow the safe exclusion of acute myocardial infarction. The accuracy estimates obtained for serial measurements and change in troponin concentration (the other objective stated in our review protocol) will be reported in a separate publication.

The high sensitivity troponin T assay is a modification of Roche’s fourth generation standard troponin T assay. The specifications provided by the manufacturer are as follows. The assay’s limit of blank is 3 ng/L, the limit of detection is 5 ng/L, and the limit of quantification (the lowest analyte concentration that can be reproducibly measured with coefficient of variation of 10% or less) is 13 ng/L. The 99th centile of a healthy reference population recommended as a positivity threshold for the diagnosis of acute myocardial infarction is 14 ng/L, and the estimated turnaround time is 18 minutes. The assay is also available as a short turnaround time version with an estimated turnaround time of nine minutes.9 It is commercially available and in clinical use worldwide with the exception of the United States, where it is used for research but has not yet obtained clearance from the US Food and Drug Administration.6

## Methods

We followed the recommendations of the Cochrane Collaboration’s Diagnostic Test Accuracy Group.10 We searched the following databases: Ovid Medline and Medline in-process, Ovid Embase, Science Citation Index, Medion database, Database of Abstracts of Reviews of Effects (DARE), Cochrane Database of Systematic Reviews (CDSR), Research Portfolio Online Reporting Tools (RePORT, formally CRISP), and International Network of Agencies for Health Technology Assessment (INAHTA). The search strategies for Embase and Medline are provided in web appendix 1. The initial validation study of the high sensitivity troponin T assay was reported in 2010.11 To capture earlier studies using the pre-commercial version of the assay, we extended the search period back to January 2006 and hand searched the reference lists of all relevant publications including systematic reviews and relevant opinion papers.

The first author (ZZ) did the initial selection on the basis of titles and abstracts. Full text copies of potentially relevant publications were obtained and screened independently by two reviewers (ZZ, HC, TJH), with all discrepancies resolved through discussion or arbitration by a third reviewer (CH). We used the reference management software EndNote X7 for the selection process. We selected studies for inclusion in the review if they met the following pre-specified criteria: diagnostic cohort studies, evaluating the diagnostic accuracy of the Roche high sensitivity troponin T assay for the diagnosis of acute myocardial infarction, in patients presenting to the emergency department with suspected acute coronary syndrome, against a reference standard based on the contemporary universal definition of acute myocardial infarction,12 and published in peer reviewed journals.

We included in the meta-analyses reported here only those studies reporting the diagnostic accuracy of the high sensitivity troponin T assay at the patient’s presentation to the emergency department and using pre-specified positivity thresholds. Two reviewers (ZZ, EY) used a standardised data extraction form to independently abstract relevant details on the publication, the study methods, and the results. We included publications reporting results from the same study or studies based on overlapping samples only if they complemented each other in terms of reported results (for instance, if they reported results for different cut-off values); we took care to avoid double counting. We excluded studies if they failed to meet the inclusion criteria or essential information was missing and could not be obtained from the authors.

Two reviewers (ZZ, EY) independently assessed the methodological quality of the included studies by using a modified version of the QUADAS-2 tool (web appendix 2).13 Any disagreements were resolved through discussion and, if necessary, arbitration by another reviewer (CH).

We constructed two-by-two tables, calculated sensitivity and specificity with 95% confidence intervals, and created coupled forest plots for each subset of data. We used random effects bivariate models to do separate meta-analyses for different pre-specified cut-off values.14 We explored heterogeneity in the first instance through visual examination of the forest plot and the receiver operating characteristics plot for each set of raw data. We considered the following sources of heterogeneity and, if appropriate, added them to a bivariate regression model: target condition, reference test, patients’ characteristics, and QUADAS-2 items. We did sensitivity analysis to check the robustness of the results. We used Cook’s distance to identify particularly influential studies and created a scatter plot of the standardised predicted random effects (standardised level 2 residuals) to check for outliers.15 Then we refitted the model leaving out any outliers and very influential studies, one at a time, to check the robustness of the results. As standard funnel plots and tests for publication bias are not recommended in meta-analysis of diagnostic accuracy studies, we did not investigate publication bias.10 All data processing and statistical analyses were done using Review Manager 5.2 and STATA version 13 including the user written commands metandi and midas.13 15 16 17

## Results

The electronic searches identified 3071 records, of which 141 full text articles were assessed for eligibility. Thirty nine of them met the criteria for inclusion in the review, and one additional paper was included from the hand search.5 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 Twenty studies (23 papers) were included in the meta-analyses reported here (fig 1⇓).5 19 20 21 22 23 28 29 30 31 32 34 35 36 37 39 41 42 45 53 54 55 56 Table 1⇓ shows their main characteristics, and additional details are provided in supplementary tables A-C.

![Figure1](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F1.medium.gif)

[Figure1](http://www.bmj.com/content/350/bmj.h15/F1)

**Fig 1** Flow chart of selection process. hs-cTnT=high sensitivity cardiac troponin T; ROC=receiver operating characteristics

View this table:
[Table 1](http://www.bmj.com/content/350/bmj.h15/T1)

Table 1 
 Characteristics of included studies

Two of the 23 included papers reported results from the ongoing multicentre study Advantageous Predictors of Acute Coronary Syndromes Evaluation (APACE),35 53 and four reported results from two other studies.19 20 21 22 The total number of patients in the included studies was 9428, ranging from 13728 to 207235 53 (median 350, interquartile range 221-491). The reported mean or median age of the included patients ranged from 5429 to 71 years41 (with the exception of the study by Bahrmann et al,23 which included only patients aged 70 years or over), and the proportion of men ranged from 49%23 to 83%.39 One study included only patients with coronary artery disease,39 and another included unselected patients aged 70 or over presenting to the emergency department with a non-surgical condition.23 Ten studies defined specific time from onset of symptoms to presentation as an inclusion criterion, which ranged from four hours39 to 24 hours.5 Most of the patients presented to the emergency department within 12 hours of symptom onset, with study medians ranging from 3.5 hours5 to 6.3 hours,21 22 but the average time was reported inconsistently. In 11 papers, the results for non-ST elevation myocardial infarction were reported separately or patients with ST elevation on the initial electrocardiogram were excluded from the study. The median prevalence of acute myocardial infarction was 21.4% (interquartile range 13.3-34.7%) and ranged from 8.0%29 to 56.2%.42

All included studies used a composite reference standard based on the contemporary universal definition of myocardial infarction.12 In terms of reference assays used to diagnose myocardial necrosis, eight studies used serial high sensitivity troponin T assay; 13 studies used standard troponin T or I assays, or a combination of them; one study used a combination of either standard troponin T or I (local assays) and high sensitivity troponin I assays (central laboratory)29; one study used a combination of standard and high sensitivity troponin T assays41; and the reference assay in one study was unclear36 (in some studies the accuracies according to different reference assays were reported separately).

Twenty studies reported the performance of high sensitivity troponin T at the manufacturer’s recommended cut-off value of 14 ng/L, which represents the 99th centile of a healthy reference population5 20 21 23 28 29 30 31 32 34 35 36 37 39 41 42 45 54 55 56; four studies reported the performance of the test at 3 ng/L (limit of blank)5 22 28 43 and four at 5 ng/L (limit of detection)19 22 34 53; results for receiver operating characteristics optimised or other cut-off values were also reported in some papers (table 1⇑ and supplementary table C).

Table 2⇓ and supplementary table D show the results from the assessment of the methodological quality of the included studies. In approximately half of the studies, patients with ST elevation myocardial infarction were not excluded. As cardiac markers play no role in the diagnosis of this condition, which is made primarily on the results from the electrocardiogram, including patients with this diagnosis may compromise the applicability of the results.32 The use of high sensitivity troponin T as part of the reference standard may lead to incorporation bias, thus inflating the accuracy estimates, whereas using a standard troponin assay as a reference test may result in patients with minor myocardial infarctions being misclassified as false positives. We investigated the effect of using different generations of reference assays in the meta-regression.

View this table:
[Table 2](http://www.bmj.com/content/350/bmj.h15/T2)

Table 2 
 Methodological quality assessment of included studies 

To obtain clinically relevant estimates of the performance of a single baseline measurement of the high sensitivity troponin T assay, we conducted, as far as the data permitted, separate meta-analyses for the different pre-specified cut-off values reported in the papers. The results from these meta-analyses are presented below.

### Performance of assay at 14 ng/L cut-off value

We pooled the results from 20 studies to obtain summary estimates of the sensitivity and specificity at the 14 ng/L cut-off value. When a study reported separately the results for non-ST elevation myocardial infarction and acute myocardial infarction (that is, both patients with ST and non-ST elevation myocardial infarction were included in the study cohort), we included only those for non-ST elevation myocardial infarction, which are clinically more relevant. In a similar way, when both standard troponin and high sensitivity troponin assays were used as reference tests, we included only the results obtained with high sensitivity assays because, being more sensitive, they are able to identify patients with small myocardial infarctions that would be missed by the standard assays. The target condition was acute myocardial infarction in 10 studies and non-ST elevation myocardial infarction in the remaining 10 studies; the reference test was a standard troponin assay in nine studies, high sensitivity troponin assay in eight, either standard or high sensitivity in one, both standard and high sensitivity in one, and unclear in one study. Figure 2⇓ shows a forest plot of the coupled sensitivity and specificity with 95% confidence intervals for each study included in this meta-analysis.

![Figure2](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F2.medium.gif)

[Figure2](http://www.bmj.com/content/350/bmj.h15/F2)

**Fig 2** Forest plots of coupled sensitivity and specificity at 14 ng/L (99th centile). FN=false negative; FP=false positive; TN=true negative; TP=true positive. See footnote to table 1⇑ for other abbreviations 

Pooling the results produced the following summary estimates: sensitivity 89.5% (95% confidence interval 86.3% to 92.1%), specificity 77.1% (68.7% to 83.7%), positive likelihood ratio 3.9 (2.8 to 5.4), and negative likelihood ratio 0.14 (0.10 to 0.18). The summary receiver operating characteristics plot (fig 3⇓) shows the summary sensitivity and specificity (the solid blue spot in the middle) and the 95% confidence and prediction regions (the inner and outer ellipses, respectively).

![Figure3](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F3.medium.gif)

[Figure3](http://www.bmj.com/content/350/bmj.h15/F3)

**Fig 3** Summary receiver operating characteristics plot of sensitivity and specificity at 14 ng/L cut-off value. Each rectangle represents an individual study; size of symbol reflects inverse standard error of specificity (width) and sensitivity (height) estimates; solid spot in middle is summary sensitivity and specificity; inner ellipse represents 95% confidence region, and outer ellipse represents 95% prediction region

As shown in figures 2⇑ and 3⇑, a significant level of heterogeneity was apparent in the results, greater in specificity than in sensitivity. We investigated the effect of the target condition (acute myocardial infarction versus non-ST elevation myocardial infarction) and the reference test (standard versus high sensitivity troponin assay) on the summary estimates of sensitivity and specificity by adding them as covariates to a bivariate regression model (one covariate at a time) and used a likelihood ratio test to determine the statistical significance of the results. As in two studies a combination of standard and high sensitivity assays were used as a reference test,29 41 and the type of the reference assay was unclear in another study,36 we excluded those three studies from the meta-regression. Without them, the likelihood ratio test showed that the use of different reference standards accounts for some of the variability in the sensitivity (P=0.008) but not in the specificity (P=0.66) (fig 4⇓). A model that allowed for sensitivity and its variance to vary between studies using different reference tests (standard versus high sensitivity assays) produced the following summary estimates: sensitivity (standard reference assay) 87.7% (82.6% to 89.9%), sensitivity (high sensitivity reference assay) 93.4% (89.8% to 95.7%), specificity 74.7% (73.6% to 75.8%), positive likelihood ratio (standard reference assay) 3.43 (3.08 to 3.82), positive likelihood ratio (high sensitivity reference assay) 3.69 (3.13 to 4.36), negative likelihood ratio (standard reference assay) 0.18 (0.14 to 0.23), negative likelihood ratio (high sensitivity reference assay) 0.09 (0.06 to 0.14). The target condition, on the other hand, had no effect on the results (P=0.79).

![Figure4](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F4.medium.gif)

[Figure4](http://www.bmj.com/content/350/bmj.h15/F4)

**Fig 4** Summary receiver operating characteristics plot comparing effect of different reference tests (standard troponin assay *v* high sensitivity troponin assay) on summary estimates of sensitivity and specificity (Inoue 2011,36 Lotze 2011,41 and Collinson 201329 were

On the basis of the Cook’s distance, we found the following studies to be the most influential in the meta-analysis (in descending order): Khan et al,39 Melki et al,42 Invernizzi et al,37 and Collinson et al29 (fig 5⇓). Of these, only Khan et al was identified as an outlier having the highest standardised residuals for specificity (fig 6⇓). After refitting the model and leaving this study out, we observed no change in sensitivity (89.5% *v* 89.7%) but specificity decreased from 77.1% to 74.9%. This could be explained by the fact that this study excluded patients without coronary artery disease, thus reducing the probability of false positive results.

![Figure5](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F5.medium.gif)

[Figure5](http://www.bmj.com/content/350/bmj.h15/F5)

**Fig 5** Influence analysis

![Figure6](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F6.medium.gif)

[Figure6](http://www.bmj.com/content/350/bmj.h15/F6)

**Fig 6** Outlier detection

### Performance of assay when either 3 ng/L (limit of blank) or 5 ng/L (limit of detection) was used as cut-off value

Seven papers reported the results for 3 ng/L and/or 5 ng/L cut-off values at presentation.5 19 22 28 34 43 53 Given the small number of studies, pooling the data for each cut-off value separately would have produced unreliable results. Instead, we decided to obtain more precise and reliable summary estimates by including in the meta-analysis all independent 3 ng/L and 5 ng/L data.5 19 22 28 34 53 Two studies reported the results for both cut-off values.22 43 53 As in this analysis we were interested mainly in the sensitivity of the test (its accuracy for ruling out acute myocardial infarction), we decided to include the results for 5 ng/L as the performance at a higher cut-off value would produce a lower sensitivity estimate thus representing the worse case scenario. Owing to the inverse correlation between sensitivity and specificity, we could assume that using even lower cut-off values would further increase the sensitivity of the assay and its ability to rule out the target condition. Thus, from the APACE trial we excluded the results reported by Meune et al,43 included those reported by Rubini Gimenez et al,53 and included only the 5 ng/L data reported by Aldous et al.22 Also, Christ et al reported two different sets of 3 ng/L results, obtained using standard troponin T and high sensitivity troponin T as refrence assays.28 As in the previous analysis, we included the results obtained by using high sensitivity troponin T as a reference assay, which is more sensitive and, thefeore, more likely to capture small myocardial infarctions. Figure 7⇓ shows a forest plot of the sensitivities and specificities of the included studies. Pooling the results from the six studies produced the following summary estimates: sensitivity 97.4% (94.9% to 98.7%), specificity 42.4% (31.2% to 54.5%), positive likelihood ratio 1.69 (1.40 to 2.05), and negative likelihood ratio 0.06 (0.04 to 0.10) (fig 8⇓).

![Figure7](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F7.medium.gif)

[Figure7](http://www.bmj.com/content/350/bmj.h15/F7)

**Fig 7** Forest plot of studies included in meta-analysis of combined 3 ng/L and 5 ng/L. FN=false negative; FP=false positive; TN=true negative; TP=true positive. See footnote to table 1⇑ for other abbreviations

![Figure8](http://www.bmj.com/https://www.bmj.com/content/bmj/350/bmj.h15/F8.medium.gif)

[Figure8](http://www.bmj.com/content/350/bmj.h15/F8)

**Fig 8**  Summary receiver operating characteristics plot of sensitivity and specificity for cut-off value of either 3 ng/L or 5 ng/L

## Discussion

In the meta-analyses reported here, we included 20 studies (23 papers) evaluating the diagnostic accuracy of a single baseline determination of the Elecsys Troponin T high-sensitive assay at pre-specified cut-off values in patients presenting to the emergency department with suspected acute coronary syndrome. We pooled data separately for 14 ng/L and for the combined 3 and 5 ng/L cut-off values. At 14 ng/L, the 99th centile of a healthy reference population as reported by the manufacturer, the summary sensitivity and specificity were 89.5% (95% confidence interval 86.3% to 92.1%) and 77.1% (68.7% to 83.7%). This means that if the pre-test probability is 21% (the median prevalence of the target condition across the studies), then 21 of 100 tested patients will have a final diagnosis of acute myocardial infarction; of them, between 18 and 19 will test positive (true positives) and two or three will test negative (false negatives). Of the 79 without the target condition, between 54 and 66 will test negative (true negatives) and between 13 and 25 will test positive (false positives).

Pooling all independent data for 3 ng/L and 5 ng/L cut-off values produced a summary sensitivity of 97.4% (94.9% to 98.7%) and a summary specificity of 42.4% (31.2% to 54.5%). This means that of 21 patients with acute myocardial infarction, between 20 and 21 will test positive (true positives) and between none and one will be missed (false negatives). Of the 79 without the target condition, between 25 and 43 will test negative (true negatives) and between 36 and 54 will test positive (false positives). Given the presence of a clear threshold effect—sensitivity increases at the expense of specificity when a lower threshold is used—we can anticipate that in patients with high sensitivity troponin T concentrations below 3 ng/L the sensitivity will be even higher and no patients with myocardial infarction will be missed. On the other hand, using lower cut-off values will inevitably result in more false positives.

### Strengths and limitations of study

These results should be treated with caution. They apply only to a specific assay, the Elecsys Troponin T high-sensitive assay (Roche Diagnostics), and may not generalise to other high sensitivity assays by other manufacturers. The sensitivity of a baseline measurement depends on the time between symptom onset and blood draw. Although we were unable to investigate this here, the results reported in the primary studies indicate that in patients who present within three hours of symptom onset the probability of false negatives is higher and a second measurement may be needed to avoid the inadvertent discharge of patients with an evolving acute myocardial infarction.5 18 53

One unexpected result in our review was the effect of the reference assay on the summary estimates. The meta-regression at a 14 ng/L cut-off value showed that the sensitivity estimate was higher when serial high sensitivity troponin assay was used as a reference test and lower when the reference test was a standard troponin assay. Using a high sensitivity rather than a standard troponin assay as a reference test would normally result in fewer false positives. This is because patients with borderline troponin concentrations that fall below the positivity threshold of the standard assay but above that of the high sensitivity one would be reclassified from false positives to true positives.20 Although this would affect the specificity of the test, it would have little effect on its sensitivity. It is entirely possible that the higher sensitivity obtained by using high sensitivity assay as a reference test is a result of incorporation bias rather than a reflection of a real effect. If this is the case, it is unlikely to have affected the summary estimates obtained for the 3-5 ng/L cut-off value, as in this meta-analysis all but one study used a standard assay as the reference test.

We were unable to investigate the effect of some characteristics of patients that are known to affect the accuracy of high sensitivity troponin assays, such as age and comorbidities, as such analysis would have required data from individual patients.10 Most of these factors, however, affect the specificity of the test owing to the increased number of false positives in older patients or patients with other cardiac or non-cardiac conditions and, therefore, are of little relevance to the question we tried to answer here—namely, whether the evaluated test has high enough sensitivity to allow exclusion of acute myocardial infarction with a single baseline measurement.

A further threat to the validity of our results, especially those related to 3-5 ng/L cut-off values, comes from the downward shift observed in the Elecsys Troponin T high-sensitive assay at low concentrations of the measurement interval.57 The shift has caused as much as 88% of the samples from healthy people to be measured with values below the limit of blank rather than the 50% or less in the initial evaluation study.58 59 Recently, the manufacturer Roche Diagnostics has made adjustments to return the assay to its original specifications.57 58 As a consequence, great care would need to be taken with the way the test is carried out in practice to ensure that the test’s accuracy at low thresholds achieved in the research reviewed is maintained consistently in the long term. This need for care is reinforced by the assay’s total imprecision being much higher at the low end of the measurement interval compared with the required coefficient of variation 10% or less at the 99th centile.

With these provisos, the results from the meta-analyses suggest that although single measurement of high sensitivity troponin T at presentation may result in unacceptably high number of patients with acute myocardial infarction being missed if the 99th centile (14 ng/L) is used as a cut-off value, lowering the decision threshold to the limit of blank or limit of detection could increase the negative predictive value of the assay to a point at which no patients with the target condition will be missed.

To appreciate the significance of this result, we need to know what proportion of patients actually present with baseline concentrations below the assay’s limit of blank and limit of detection. Two of the included studies reported such data. In the study by Body et al, 195 (27.7%) of the included 703 patients had undetectable (<3 ng/L) high sensitivity troponin T concentrations at presentation and none of them was diagnosed as having myocardial infarction. Of the 296 (42.1%) patients who had concentrations between 3 ng/L and 14 ng/L, 19 (6.4%) patients developed acute myocardial infarction.5 In the APACE trial, as reported by Rubini Gimenez et al,53 of the 2245 patients included in the analysis, 550 (25%) had values below 5 ng/L at presentation and eight (1.5%) of them were diagnosed as having myocardial infarction. These studies show that a significant proportion of the patients who undergo troponin testing in emergency setting present with high sensitivity troponin T concentrations below the limit of detection, and only a very small proportion of them are later diagnosed as having acute myocardial infarction. A diagnostic strategy that incorporates a baseline measurement with the Elecsys Troponin T high-sensitive assay and uses a low cut-off value, such as the limit of blank or limit of detection, to rule out myocardial infarction may help to reduce the number of patients who undergo unnecessary further testing (often associated with potentially harmful effects) and may save resources and relieve pressure on overcrowded emergency departments. Patients with troponin concentrations above this low rule-out threshold could undergo the usual second sample testing before a decision about discharge or admission for further investigations is made.

A recently published study by Body et al suggests that an alternative to the low threshold rule-out strategy discussed above might be available.60 In this study, the performance of the 99th centile of the Elecsys Troponin T high-sensitive assay at presentation was evaluated not as a standalone test but in conjunction with the emergency physicians’ clinical judgment (based on the patient’s history and clinical examination) and the results from the initial electrocardiogram. When combined, the diagnostic information from these three sources had 100% (95.4% to 100%) sensitivity and 100% (95.7% to 100%) negative predictive value. These findings suggest that the summary estimates obtained from our meta-analyses may underestimate the sensitivity of the assay and that using the 99th centile cut-off value in a single measurement at presentation, especially in patients who present more than three hours after symptom onset, may be sufficient to rule out acute myocardial infarction. As Body et al point out, however, such a strategy needs to be prospectively validated in independent populations before clinical implementation.

### Comparison with other studies

As far as we are aware, the only other systematic review that has investigated the performance of the Elecsys Troponin T high-sensitive assay is the one by Westwood et al,61 which underpins the National Institute for Health and Care Excellence’s recent guidance on high sensitivity troponin assays.7 Our findings are consistent with the NICE guidance to consider two of the high sensitivity troponin assays, including the one evaluated in this study, as options for the early rule-out of non-ST elevation myocardial infarction in people presenting to an emergency department with chest pain and suspected acute coronary syndrome. The NICE guidance was, however, more cautious about using low cut-off values, expressing concern about “the clinical and practical implications of introducing limit of blank and limit of detection cut-off thresholds into practice.”7

### Conclusions and policy implications

In conclusion, when used with blood samples drawn at the patient’s presentation to the emergency department and given a pre-test probability of 21%, the Elecsys Troponin T high-sensitive assay will miss two or three patients with acute myocardial infarction if the 99th centile is used as a cut-off value and no patients or one patient if 5 ng/L is used. Using 3 ng/L is likely to reduce even further the proportion of patients with the target condition that would be missed. In patients presenting within three hours of symptom onset, the proportion of missed patients with acute myocardial infarction might be higher. The above results suggest that if low cut-off values are used a single measurement of high sensitivity troponin T at presentation might be sufficient to rule out acute myocardial infarction. Such a strategy would, however, need to be carefully implemented owing to the high imprecision of the assay and greater effect of lot-to-lot reagent variation at low troponin concentrations. In clinical practice, the 99th centile of the index assay used with samples taken at presentation might be able to exclude acute myocardial infarction with sufficient accuracy when combined with the results from the patient’s history, clinical examination, and the initial electrocardiogram. This, however, needs to be prospectively validated in independent cohorts before implementation.

#### What is already known on this topic

*   Only a small proportion of patients admitted to hospital with chest pain are diagnosed as having acute myocardial infarction

*   High sensitivity cardiac troponin assays may help emergency physicians to rule out this condition early in the triage, thus avoiding unnecessary additional tests and hospital admissions

#### What this study adds

*   A single measurement of the Elecsys Troponin T high-sensitive assay at the patient’s presentation to the emergency department will miss two or three patients who have acute myocardial infarction if 14 ng/L is used as a cut-off value

*   Less than one patient will be missed if 3 ng/L or 5 ng/L is used as a cut-off value; acute myocardial infarction could be ruled out in patients who present with high sensitivity troponin T concentrations below these values

*   This method should be considered as part of a comprehensive triage strategy and may not be appropriate for patients presenting within three hours after symptom onset

## Notes

**Cite this as:** *BMJ* 2015;350:h15

## Footnotes

*   We acknowledge the contribution of Yemisi Takwoingi from the University of Birmingham, who provided valuable advice on the statistical methods used in this study.

*   Contributors: ZZ, CH, SF, and TS drafted the protocol. MR developed the search strategy and did the electronic searches. ZZ, HC, TJ-H, and EY screened the titles and abstracts and selected studies for inclusion. ZZ and EY carried out the data extraction and methodological quality assessment. CH, SF, and TS provided advice and arbitration on the selection process, data extraction, and methodological quality assessment. ZZ and VN did the statistical analysis. ZZ wrote the original draft, and the other authors revised the draft critically for important intellectual content and approved the final version of the paper. ZZ and CH are the guarantors.

*   Funding: This research was funded by the South West Academic Health Science Network (AHSN) and the National Institute for Health Research (NIHR) Collaboration for Leadership for Applied Health Research and Care for the South West Peninsula. The views expressed are those of the author(s) and not necessarily those of the NHS, the NIHR, or the Department of Health. The AHSN and the NIHR had no involvement in the study design; in the collection, analysis, and interpretation of data; in the writing of the report; or in the decision to submit the paper for publication.

*   Competing interests: All authors have completed the ICMJE uniform disclosure form at [www.icmje.org/coi\_disclosure.pdf](http://www.icmje.org/coi_disclosure.pdf) (available on request from the corresponding author) and declare: ZZ and CH received financial support from the NIHR Collaboration for Leadership in Applied Health Research and Care for the South West Peninsula; no financial relationships with any organisations that might have an interest in the submitted work in the previous three years; no other relationships or activities that could appear to have influenced the submitted work.

*   Ethical approval: Not required.

*   Transparency declaration: The lead author (ZZ) affirms that this manuscript is an honest, accurate, and transparent account of the study being reported; that no important aspects of the study have been omitted; and that any discrepancies from the study as planned (and, if relevant, registered) have been explained.

*   Data sharing: No additional data available.

This is an Open Access article distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited and the use is non-commercial. See: [http://creativecommons.org/licenses/by-nc/4.0/](http://creativecommons.org/licenses/by-nc/4.0/).

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