Guidance
3 Evidence
The diagnostics advisory committee considered evidence on high-sensitivity troponin tests for the early rule out of non-ST-segment elevation myocardial infarction (NSTEMI) from several sources. Full details of all the evidence are in the committee papers.
Clinical effectiveness
3.1 The external assessment group (EAG) did a systematic review to identify evidence on the clinical effectiveness of high-sensitivity troponin tests for the early rule out of acute myocardial infarction, including NSTEMI, in people who come to hospital with chest pain. It also considered studies used to develop the original diagnostics guidance on early rule out of myocardial infarction using high-sensitivity troponin tests.
3.2 The EAG identified 37 studies that met the inclusion criteria. Test accuracy data were reported for the following high-sensitivity troponin tests: Elecsys (30 studies), ARCHITECT (9 studies), Atellica (2 studies), ADVIA Centaur (3 studies), Access (2 studies). One study each reported accuracy data for Dimension Vista, VITROS, VIDAS and TriageTrue.
3.3 Seven studies reported diagnostic accuracy data for more than 1 test. No studies were identified that matched the inclusion criteria for the review for Alinity or Dimension EXL tests. Two randomised controlled trials were included in the review: High-STEACS and HiSTORIC.
3.4 Of the 37 included studies, 22 were done in Europe (7 in the UK), 5 in Australia and New Zealand, 6 in the US, 3 in East Asia, and 1 was a worldwide study.
3.5 The randomised controlled trials were quality assessed using the revised Cochrane risk of bias tool for cluster randomised trials. Studies that evaluated a single high-sensitivity test were assessed using the QUADAS‑2 tool. Studies that provided data for 2 or more high-sensitivity tests were assessed using the QUADAS‑2C tool.
Randomised controlled trials
3.6 Both trials used the ARCHITECT test.
3.7 The High-STEACS trial evaluated the implementation of an early rule-out strategy in 10 secondary and tertiary care hospitals in Scotland. It compared the rates at which conditions were reclassified after high-sensitivity troponin tests with the rates of reclassification after standard troponin testing. It also compared the subsequent incidence of myocardial infarction and cardiovascular death.
3.8 The HiSTORIC trial also evaluated the implementation of an early rule-out strategy in 7 acute hospitals in Scotland. The primary outcomes were length of stay and myocardial infarction or cardiac death after discharge at 30 days. The results are academic in confidence.
3.9 During the validation phase of High-STEACS (6 to 12 months), results of the high-sensitivity troponin I test were concealed from the attending clinician, and a standard cardiac troponin test was used to guide care. A high-sensitivity test was introduced after 6 months (early implementation) or 12 months (late implementation).
3.10 In patients whose condition was reclassified in the High-STEACS trial, there were no differences between high-sensitivity and standard troponin tests in the primary or any of the secondary efficacy and safety outcome measures (myocardial infarction, unplanned coronary revascularisation, all-cause death, death from cardiovascular causes, hospital admission for heart failure and ischaemic stroke). The median length of stay for patients without myocardial injury was 7 hours (interquartile range 3 to 24) in the validation phase and 4 hours (interquartile range 3 to 20) in the implementation phase. The authors of High-STEACS concluded that implementing an early rule-out strategy was not associated with any increase in myocardial infarction or cardiovascular death within 1 year of initial presentation.
Diagnostic test accuracy
Elecsys troponin T-high sensitive assay
3.11 Summary estimates of sensitivity and specificity from testing a single sample, using a 99th percentile diagnostic threshold for the general population, were 90% (95% confidence interval [CI] 85 to 94) and 78% (95% CI 72 to 83) respectively, based on data from 22 studies. The summary estimates of sensitivity and specificity, using a single sample and a limit of detection threshold, were 99% (95% CI 97 to 99) and 36% (95% CI 28 to 45) respectively, based on data from 9 studies. The 8 studies that assessed the diagnostic performance of a limit of blank threshold in a single sample gave a similarly high summary estimate of sensitivity of 100% (95% CI 98 to 100), but a reduced specificity of 19% (95% CI 11 to 31). All estimates were similar when the analyses were restricted to studies that excluded people with ST-segment elevation myocardial infarction (STEMI).
3.12 Using multiple sample strategies appears to offer better specificity without substantial loss of sensitivity than using a single sample on presentation and a very low limit of detection or limit of blank threshold. The European Society of Cardiology's (ESC) 0/1‑hour rule-out pathway combines an initial sample and a very low limit of detection threshold (5 ng/litre) in patients reporting a minimum symptom duration of 3 hours. The strategy tests at presentation and 1 hour later for patients whose acute myocardial infarction is not ruled out by the initial test, that is, it uses an 'OR' combination. The threshold for repeat testing is an initial troponin concentration of less than 12 ng/litre with an absolute change in troponin concentration, from 0 to 1 hour, of less than 3 ng/litre. For NSTEMI, the sensitivity and specificity estimates for this strategy were 99% (95% CI 98 to 100) and 68% (95% CI 67 to 70), respectively. Estimates of diagnostic performance were similar for strategies using an 'AND' combination of initial high-sensitivity troponin level and absolute change in troponin level.
ARCHITECT STAT High Sensitive Troponin‑I assay
3.13 Summary estimates of sensitivity and specificity for a single sample using a diagnostic threshold of the 99th percentile for the general population were 75% (95% CI 65 to 82) and 94% (95% CI 94 to 96) respectively, based on data from 5 studies. These estimates were similar if the analysis was restricted to studies that excluded people with STEMI. The summary estimates of sensitivity and specificity, using a limit of detection threshold (2 ng/litre) in a single sample taken on presentation, were 100% (95% CI 99 to 100) and 21% (95% CI 16 to 26) respectively, based on data from 4 studies in NSTEMI.
3.14 For multiple sample strategies, the High-STEACS pathway was used as follows:
-
in the whole population, symptoms for 2 hours or more and a troponin concentration of less than 5 ng/litre at 0 hours, or
-
in women, 16 ng/litre or lower when measured 3 hours from presentation and an absolute change of less than 3 ng/litre at 0 to 3 hours, or
-
in men, 34 ng/litre or lower when measured 3 hours from presentation and an absolute change of less than 3 ng/litre at 0 to 3 hours.
3.15 Using the High-STEACS pathway in this way appeared to offer increased specificity without substantial loss of sensitivity compared with a single sample on presentation and a risk stratification threshold of less than 5 ng/litre. The sensitivity and specificity estimates for this strategy were 99% (95% CI 97 to 100) and 76% (95% CI 73 to 78) respectively, for NSTEMI. The ESC 0/1‑hour rule-out pathway reported a lower specificity than the High-STEACS pathway. It used an initial sample and a limit of detection threshold of less than 2 ng/litre, or repeat testing combining an initial troponin concentration of less than 5 ng/litre and an absolute change in troponin concentration, from 0 to 1 hour, of less than 2 ng/litre. Summary sensitivity and specificity estimates were 99% (95% CI 98 to 100) and 57% (95% CI 56 to 59) respectively for NSTEMI.
Access High-Sensitivity Troponin I Assay
3.16 The 2 studies evaluating the Access test each assessed a different multiple sample strategy. One followed the ESC 0/1‑hour rule-out pathway (initial sample and a limit of detection threshold of less than 4 ng/litre, or repeat testing combining an initial concentration of less than 5 ng/litre and an absolute change in troponin concentration, from 0 to 1 hour, of less than 4 ng/litre), giving sensitivity and specificity estimates of 99% (95% CI 94 to 100) and 70% (95% CI 66 to 74) respectively for NSTEMI. The second study assessed a similar strategy, but with repeat testing at 2 hours. The sensitivity estimates were similar for the 2 strategies, but the specificity of the 2-hour repeat testing strategy was higher than that of the 1‑hour strategy.
VIDAS High sensitive Troponin I assay
3.17 The study evaluating the VIDAS test assessed a multiple sample strategy, with samples taken on presentation and at 2 hours using a threshold of less than 2 ng/litre at presentation, or less than 6 ng/litre at presentation and at 2 hours. The reported sensitivity and specificity estimates were 98% (95% CI 92 to 100) and 64% (95% CI 59 to 68) respectively for NSTEMI.
VITROS High Sensitivity Troponin I Assay
3.18 The study evaluating the VITROS test assessed the ESC 0/1‑hour rule-out pathway. This combined an initial sample and a limit of detection threshold of less than 1 ng/litre, or repeat testing combining an initial troponin concentration of less than 2 ng/litre and an absolute change in troponin concentration, from 0 to 1 hour, of less than 1 ng/litre. The reported sensitivity and specificity estimates were 100% (95% CI 95 to 100) and 60% (95% CI 55 to 64) respectively for NSTEMI.
TriageTrue High-Sensitivity Troponin I Test
3.19 The study evaluating the TriageTrue test assessed the ESC 0/1‑hour rule-out pathway. This combined an initial sample and a limit of detection threshold of less than 4 ng/litre, or repeat testing combining an initial troponin concentration of less than 5 ng/litre and an absolute change in troponin concentration, from 0 to 1 hour, of less than 3 ng/litre. The reported sensitivity of this strategy was 100% (95% CI 97 to 100) and the specificity was 66% (95% CI 62 to 70) for NSTEMI.
ADVIA Centaur high-sensitivity Troponin I assay
3.20 Three studies evaluated the ADVIA Centaur test. Using a rule-out threshold of 2 ng/litre in a single sample taken on presentation, the sensitivity and specificity estimates were 100% (95% CI 99 to 100) and 23% (95% CI 21 to 25) respectively for NSTEMI. Two multiple sample strategies were evaluated. One followed the ESC 0/1‑hour rule-out pathway. This combined an initial sample and a limit of detection threshold of less than 3 ng/litre, or repeat testing combining an initial concentration of less than 6 ng/litre and an absolute change in troponin concentration, from 0 to 1 hour, of less than 3 ng/litre. The sensitivity and specificity estimates for this strategy were 99% (95% CI 95 to 100) and 56% (95% CI 52 to 60) respectively for NSTEMI. The second study assessed a similar strategy, but with higher thresholds and repeat testing at 2 hours. The sensitivity and specificity estimates for this strategy were 100% (95% CI 95 to 100) and 67% (95% CI 61 to 72) respectively for NSTEMI.
Atellica High-Sensitivity Troponin I Assay
3.21 Using a rule-out threshold of 2 ng/litre, in a single sample taken on presentation, the sensitivity and specificity estimates for the Atellica test were 100% (95% CI 98 to 100) and 26% (95% CI 24 to 28) respectively for NSTEMI. Sensitivity and specificity estimates for the High-STEACS pathway (symptoms for at least 2 hours and an initial troponin concentration of less than 5 ng/litre, or a troponin concentration of 34 ng/litre or less in women, or 53 ng/litre or less in men at 3 hours and an absolute change in concentration from 0 to 3 hours, of less than 3 ng/litre) were 98% (95% CI 95 to 100) and 74% (95% CI 72 to 76) respectively for NSTEMI.
Dimension Vista High-Sensitivity Cardiac Troponin I Assay
3.22 The study of the Dimension Vista test assessed a strategy using measurements done at baseline using a troponin concentration threshold of less than 5 ng/litre and an absolute change of less than 2 ng/litre within 1 hour. The sensitivity of the strategy was 100% (95% CI 97 to 100) and specificity was 66% (95% CI 62 to 69) for NSTEMI.
Diagnostic accuracy in relevant subgroups
3.23 The EAG identified some data on the subgroups described in the scope for this guidance. In a study using the Elecsys test and a 99th percentile threshold on a single sample at presentation, a higher sensitivity for any acute myocardial infarction was estimated in people over 70 than for people aged 70 or under (97% [95% CI 92 to 99] and 88% [95% CI 78 to 94] respectively). The estimate of sensitivity for people over 70 was also higher than the corresponding summary estimates from all 22 studies that used the 99th percentile diagnostic threshold. There was a similar pattern for people with a high pre-test probability (determined by clinical judgement of cardiovascular risk factors, type of chest pain, physical findings and electrocardiography [ECG] abnormalities) compared with those with a low to moderate pre-test probability. The same was found for people without pre-existing cardiovascular disease compared with those with pre-existing cardiovascular disease.
3.24 Only the High-STEACS trial reported using sex-specific thresholds. Data from this study appeared to show that testing using a single sample taken on presentation is markedly more sensitive if sex-specific 99th percentile cut-offs are used, compared with a standard troponin test with a uniform threshold. This is particularly true in women, for whom the 99th percentile is lower. This study also used sex-specific thresholds as part of a multiple test strategy: the High-STEACS pathway. It is unclear whether using sex-specific thresholds in this strategy offers any advantage over using a single general population threshold. This is because no equivalent strategy, using a single universal threshold, was evaluated. Other studies reported data on men and women using a single general population threshold in each group. Results from a study on the Elecsys test showed very similar accuracy estimates for the subgroups, although a study on the Dimension Vista reported a lower sensitivity and specificity in men than in women.
3.25 Two studies on the Elecsys test and 2 on the ARCHITECT test reported data on how diagnostic performance varies with renal function. All studies show a decrease in specificity as renal function decreases.
Comparative diagnostic accuracy for more than 1 test
3.26 Seven studies reported accuracy data for more than 1 test.
3.27 The APACE study provided data on the ESC 0/1‑hour pathway using the Elecsys, ARCHITECT and ADVIA Centaur tests. It also provided data on the ESC 0/1‑hour pathway using the Access, VITROS and TriageTrue tests, but these results came from different patient subgroups and were reported in different publications. Data showed that the ESC 0/1‑hour pathway performed consistently across all 6 high-sensitivity troponin tests evaluated with sensitivity estimates of 98% or higher.
3.28 Three other studies, ADAPT, ROMI-3, and TRUST, compared the Elecsys and ARCHITECT tests. Although the sensitivity estimates for the Elecsys test, using the 99th percentile and a single sample at presentation, were higher than those for the ARCHITECT test, both had sensitivity estimates of less than 97%. When the limit of detection threshold was used with a single sample at presentation, sensitivity estimates were comparable for the Elecsys test and the ARCHITECT test, and were always 99% or higher.
3.29 The High-STEACS trial provided data on the rule-out performance of 3 strategies (ESC 0/1‑hour, ESC 0/3-hour and High-STEACS 0/3-hour) using the ARCHITECT and Atellica tests. It is unclear whether both tests were evaluated in the same subgroup of people in the study. Data showed that the sensitivity of the ESC 0/1‑hour pathway was lower using the Atellica test (94% [95% CI 79 to 99]) than using the ARCHITECT test (100% [95% CI 91 to 100]). The sensitivity and specificity estimates for the High-STEACS 0/3-hour rule-out pathway were similar using either test (both had sensitivity estimates of 98% or more). The ESC 0/3-hour rule-out pathway in this study consisted of:
-
symptoms for 6 hours or more and a troponin concentration of 16 ng/litre or less in women or 34 ng/litre or less in men at 0 hours, or
-
a troponin concentration of 16 ng/litre or less in women or 34 ng/litre or less in men at 3 hours, or
-
an absolute change of less than 50% of the 99th percentile at 0 to 3 hours.
The sensitivity and specificity estimates for the ESC 0/3-hour rule-out pathway were both less than 97% using either test.
3.30 The HIGH-US study compared 2 Siemens tests (Atellica and ADVIA Centaur), using 3 low thresholds and a single sample at presentation. The results showed sensitivity estimates were 99% or more for both tests for all thresholds.
3.31 The BEST study compared 2 single sample at presentation strategies using the ADVIA Centaur test (threshold of 3 ng/litre) and Elecsys test (limit of detection [5 ng/litre] threshold). Data were reported in separate publications with different numbers of people. The sensitivity estimates were 99% for both tests, but the Elecsys test had a higher specificity (47% [95% CI 43 to 51]) than the ADVIA Centaur test (33% [95% CI 30 to 36]).
Cost effectiveness
3.32 The EAG did a search to identify evidence on the cost effectiveness of high-sensitivity troponin tests for the early rule out of acute myocardial infarction, including NSTEMI. The EAG also developed a de novo economic model to assess the cost effectiveness of the different testing strategies.
Review of economic evidence
3.33 Studies were eligible if they reported a full economic analysis of the cost effectiveness of either high-sensitivity troponin testing or standard troponin testing. They also had to include survival or quality-adjusted life years (QALYs) as an outcome measure.
3.34 Five studies identified in the original assessment report and 1 new study were included in the systematic review. Results varied in the 5 studies from the original report, and the EAG concluded that there was uncertainty about the cost effectiveness of diagnostic strategies using high-sensitivity troponin testing. The EAG noted that the key drivers of cost effectiveness in the included studies were the accuracy of high-sensitivity troponin tests, and the efficiency of decision making once test results were available.
3.35 The most recent study (Ambavane et al. 2017) reported that a 1‑hour strategy using high-sensitivity troponin testing had higher sensitivity (87% compared with 69%) but lower specificity (96% compared with 97%) than standard care. The reference standard used to calculate diagnostic accuracy was determination of final diagnosis based on a comprehensive review of medical records. Total costs were less for the 1‑hour strategy compared with standard care (£2,480 compared with £4,561). This was mainly because of a shorter length of stay in the emergency department.
Economic analysis
3.36 The EAG developed a de novo economic model to explore the cost effectiveness of high-sensitivity troponin tests for the early rule out of acute myocardial infarction, including NSTEMI, in people with acute chest pain (used up to 4 hours from the onset of chest pain or at presentation). The model compared high-sensitivity tests with standard troponin T or I testing, or both, on admission and at 10 to 12 hours after the onset of symptoms. The population in the model was people presenting to the emergency department with suspected non-ST-segment elevation acute coronary syndrome, who have no major comorbidities needing hospitalisation (for example, heart failure or arrhythmia) and in whom STEMI has been ruled out.
3.37 Only high-sensitivity troponin tests with a sensitivity of 97% or above were used in the economic model, based on expert opinion of the minimum sensitivity acceptable in clinical practice. The strategies evaluated are described in table 1.
Strategy number |
Test |
Strategy |
---|---|---|
1 |
Elecsys |
99th percentile threshold (under 14 ng/litre at 0 hours AND 3 hours) |
2 |
Elecsys |
Limit of detection under 5 ng/litre at 0 hours |
3 |
Elecsys |
ESC 0/1‑hour pathway: symptoms over 3 hours AND under 5 ng/litre at 0 hours |
4 |
Elecsys |
Under 8 ng/litre at 0 hours AND an absolute change of less than 3 ng/litre at 0 to 0.5 hours |
5 |
Elecsys |
Under 12 ng/litre at 0 hours AND an absolute change of less than 3 ng/litre at 0 to 1 hour |
6 |
Dimension Vista |
Under 5 ng/litre at 0 hours AND an absolute change of less than 2 ng/litre at 0 to 1 hours |
7 |
ARCHITECT |
Under 12 ng/litre at 0 hours AND an absolute change of less than 3 ng/litre at 0 to 1 hour |
8 |
ARCHITECT |
ESC 0/1‑hour pathway: symptoms over 3 hours AND under 2 ng/litre at 0 hours |
9 |
ARCHITECT |
High-STEACS pathway: symptoms for 2 hours or more AND under 5 ng/litre at 0 hours |
10 |
ARCHITECT |
Under 4 ng/litre at 0 hours |
11 |
ADVIA Centaur |
Under 2 ng/litre at 0 hours |
12 |
ADVIA Centaur |
Under 3 ng/litre at 0 hours |
13 |
ADVIA Centaur |
ESC 0/1‑hour pathway: symptoms over 3 hours AND under 3 ng/litre at 0 hours |
14 |
ADVIA Centaur |
Under 5 ng/litre at 0 hours |
15 |
Atellica |
Under 2 ng/litre at 0 hours |
16 |
Atellica |
High-STEACS pathway: symptoms for 2 hours or more AND under 5 ng/litre at 0 hours |
17 |
Access |
ESC 0/1‑hour pathway: symptoms over 3 hours AND under 4 ng/litre at 0 hours |
18 |
Access |
Symptoms over 3 hours AND under 4 ng/litre at 0 hours |
19 |
VITROS |
ESC 0/1‑hour pathway: symptoms over 3 hours AND under 1 ng/litre at 0 hours |
20 |
VIDAS |
Under 2 ng/litre at 0 hours OR under 6 ng/litre at 0 AND 2 hours |
21 |
TriageTrue |
ESC 0/1‑hour pathway: symptoms over 3 hours AND under 4 ng/litre at 0 hours |
Model structure
3.38 The model structure from the original diagnostics assessment report was used. This model structure was adapted from the health technology assessment report from Goodacre et al. (2013). It consists of a decision tree and a state-transition model. The decision tree was used to model the 30‑day outcomes after presentation, based on test results and the accompanying treatment decision. The following health states were included:
-
no acute coronary syndrome and no unstable angina (no ACS, no UA)
-
unstable angina (UA)
-
post-acute myocardial infarction, treated and untreated (post-AMI)
-
post-acute myocardial infarction with reinfarction (post-AMI with reinfarction)
-
death.
3.39 People presenting at the emergency department with suspected non-ST elevation acute coronary syndrome were tested and results were classified as either true positive, false positive, false negative or true negative. These people entered health states as listed (people could also die after treatment or be discharged):
-
People with true positive test results were correctly treated for acute myocardial infarction and were allocated to 'non-fatal AMI (treated)'.
-
People with false positive test results were considered to have no acute myocardial infarction, but did not meet early rule-out criteria. They were subdivided between 'no ACS, no UA' and 'UA'. It was assumed that people with false positive test results would remain in the hospital longer but would not be treated for acute myocardial infarction.
-
People with true negative test results were considered not to be treated for acute myocardial infarction and were subdivided between 'no ACS, no UA' and 'UA'.
-
People with false negative test results were assumed to have untreated acute myocardial infarction resulting in increased reinfarction and mortality probabilities for 1 year and were allocated to 'non-fatal AMI (untreated)'.
3.40 The long-term consequences in terms of costs and QALYs were estimated using a state-transition cohort model with a lifetime time horizon (60 years) and a cycle time of 1 year (except for the first cycle which was adjusted to 335.25 days to ensure that the decision tree period and the first cycle summed to 1 year). Discount rates of 3.5% and a half-cycle correction were applied for both costs and effects.
Model inputs
3.41 Estimates for the model input parameters were retrieved from the literature and from consulting experts. Accuracy estimates were derived from the systematic review component of the assessment. The proportion of people testing positive or negative was based on the estimated accuracy of the testing strategies considered (table 2) and the estimated prevalence of NSTEMI in the UK (12.2%).
Number |
Test |
Strategy |
Sensitivity (SE) |
Specificity (SE) |
---|---|---|---|---|
0 |
Standard troponin |
At presentation and after 10 to 12 hours |
1.00 (-) |
1.00 (-) |
1 |
Elecsys |
99th percentile at 0 hours AND 3 hours |
1.00 (0.03) |
0.77 (0.08) |
2 |
Elecsys |
Limit of detection at 0 hours |
0.99 (0.01) |
0.35 (0.05) |
3 |
Elecsys |
ESC 0/1‑hour pathway |
0.99 (0.01) |
0.68 (0.01) |
4 |
Elecsys |
Less than 8 ng/litre at 0 hours AND change of less than 3 ng/litre at 0 to 0.5 hours |
1.00 (0.02) |
0.45 (0.02) |
5 |
Elecsys |
Less than 12 ng/litre at 0 hours AND change of less than 3 ng/litre at 0 to 1 hour |
0.98 (0.01) |
0.73 (0.01) |
6 |
Dimension Vista |
Less than 5 ng/litre at 0 hours AND change less than 2 ng/litre at 0 to 1 hour |
1.00 (0.02) |
0.66 (0.02) |
7 |
ARCHITECT |
Limit of detection at 0 hours |
1.00 (0.00) |
0.21 (0.03) |
8 |
ARCHITECT |
ESC 0/1‑hour pathway |
0.99 (0.00) |
0.57 (0.01) |
9 |
ARCHITECT |
High-STEACS pathway |
0.99 (0.01) |
0.76 (0.01) |
10 |
ARCHITECT |
Less than 4 ng/litre at 0 hours |
0.99 (0.01) |
0.50 (0.01) |
11 |
ADVIA Centaur |
Less than 2 ng/litre at 0 hours |
1.00 (0.00) |
0.23 (0.01) |
12 |
ADVIA Centaur |
Less than 3 ng/litre at 0 hours OR less than 8 ng/litre at 0 hours AND change of less than 7 ng/litre at 0 to 2 hours |
1.00 (0.01) |
0.67 (0.03) |
13 |
ADVIA Centaur |
ESC 0/1‑hour pathway |
0.99 (0.01) |
0.56 (0.02) |
14 |
ADVIA Centaur |
Less than 5 ng/litre at 0 hours |
0.99 (0.01) |
0.52 (0.01) |
15 |
Atellica |
Less than 2 ng/litre at 0 hours |
1.00 (0.01) |
0.26 (0.01) |
16 |
Atellica |
High-STEACS pathway |
0.98 (0.01) |
0.74 (0.01) |
17 |
Access |
ESC 0/1‑hour pathway |
0.99 (0.02) |
0.70 (0.02) |
18 |
Access |
Symptoms at more than 3 hours AND less than 4 ng/litre at 0 hour OR less than 5 ng/litre and change of less than 5 ng/litre at 0 to 2 hours |
0.98 (0.02) |
0.83 (0.01) |
19 |
VITROS |
ESC 0/1‑hour pathway |
1.00 (0.01) |
0.60 (0.02) |
20 |
VIDAS |
Less than 2 ng/litre at 0 hour OR less than 6 ng/litre at 0 AND 2 hours |
0.98 (0.02) |
0.64 (0.02) |
21 |
TriageTrue |
ESC 0/1‑hour pathway |
1.00 (0.01) |
0.66 (0.02) |
ESC, European Society of Cardiology; SE, standard error; ng/litre is nanograms troponin per litre of blood.
3.42 Test-specific resource use consisted of the number of tests done and the duration of hospital stay in hours before discharge or acute myocardial infarction treatment. For test strategies that involved a subsequent test conditional on the outcome of the first test, the rule-out rate for the presentation sample was used to calculate the number of subsequent tests. The resource use included a delay from the time at which sampling could be done to the time at which results became available (2 hours) and delay between arrival at hospital and troponin assessment starting (1 hour).
3.43 Health state costs were taken from a retrospective cohort study done in the UK (Danese et al. 2016). Acute myocardial infarction treatment costs were based on NHS reference costs and hospital stay costs were based on data from the Personal Social Services Research Unit.
3.44 In the base case, test costs were assumed to be identical for all tests (£2.50) except for the point-of-care test (£25.00, based on information provided by Quidel). A scenario analysis was done using test-specific costs and assuming that costs relating to the analyser and staff time were identical for all strategies.
3.45 Age-dependent utility scores from the UK general population were calculated for people in the 'no ACS, no UA' health state. These age-dependent utility scores were combined with age-dependent disutility values for acute myocardial infarction, to calculate utility values for the 'post-AMI' health states (with or without reinfarction). Utility values for the 'UA' health state were calculated based on the 'post-MI' utility values and assuming a utility increment of 0.010.
Assumptions
3.46 The following assumptions were applied in the base-case analysis:
-
Standard troponin testing (at presentation and after 10 to 12 hours) has perfect accuracy.
-
Compared with acute myocardial infarctions occurring during the decision tree period, all acute myocardial infarctions (either first or reinfarction) occurring in the state-transition model are diagnosed correctly, so are treated.
-
Unstable angina is always correctly diagnosed, so is treated.
-
The reinfarction probability for the 'post-AMI with reinfarction' health state is equal to the reinfarction probability for the 'post-AMI' health state.
-
The increased post-acute myocardial infarction reinfarction and mortality probabilities for untreated acute myocardial infarction were assumed to last 1 year. After this a relative risk of 1.0 was applied (for untreated compared with treated acute myocardial infarction).
-
There is no additional benefit of starting treatment early, so treatment effect for high-sensitivity strategies is equal to treatment effect for standard troponin strategies.
-
All 30‑day deaths (after presentation at the emergency department) are due to fatal acute myocardial infarction events and will receive the associated costs.
3.47 For the base case, it was assumed that people who tested negative on standard troponin tests and positive on high-sensitivity troponin tests would have a life expectancy and quality of life equal to people with true negative test results, but this assumption is debatable. A meta-analysis by Liplinski et al. (2015) showed that people with a negative standard troponin test and positive high-sensitivity troponin test have an increased risk of reinfarction and mortality compared with those who test negative on both standard troponin and high-sensitivity troponin tests. Although this risk was not as high as in people with both positive standard troponin and positive high-sensitivity troponin tests, it could still be considered prognostically important. A secondary analysis was done in which the risk of acute myocardial infarction and mortality was adjusted for people with false positive results.
Results
3.48 In the base case, standard troponin testing was the most effective and the most expensive strategy. But other testing strategies with a sensitivity of 100% (subject to uncertainty) were almost equally as effective, resulting in the same QALY gain up to 4 decimal places. Compared with standard troponin testing, high-sensitivity troponin testing resulted in probabilistic incremental cost-effectiveness ratios (ICERs) ranging between £34,307 and £36,842,603 savings per QALY lost.
3.49 In the secondary analysis, standard troponin was the cheapest and the least effective testing strategy. Compared with standard troponin testing, high-sensitivity troponin testing resulted in probabilistic ICERs ranging between £4,043 and £6,148 per QALY gained.
3.50 For all scenario analyses of the secondary analysis, results were similar to those from the secondary analysis base case. Standard troponin remained the cheapest and the least effective testing strategy (deterministic analysis). In all scenario analyses of the secondary analysis, high-sensitivity troponin testing compared with standard troponin testing resulted in ICERs less than £10,000 per QALY gained.
3.51 One-way sensitivity analyses were done including all parameters that were changed in the probabilistic sensitivity analysis. In the secondary analysis, the parameters that had a notable effect on the estimated cost-effectiveness estimates were:
-
30‑day mortality for untreated acute myocardial infarction
-
mortality 1 year after treated and untreated acute myocardial infarction
-
discount rate used for outcomes
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relative mortality for people who had a true positive result compared with those who had a false positive result.
At extreme values (based on 95% confidence intervals) of these inputs, standard troponin testing remains cheaper and less effective than the high-sensitivity troponin tests.