New generation cardiac CT scanners (Aquilion ONE, Brilliance iCT, Discovery CT750 HD and Somatom Definition Flash) for cardiac imaging in people with suspected or known coronary artery disease in whom imaging is difficult with earlier generation CT scanners

One study involving 125 participants reported 543 per segment data on the performance of new generation cardiac CT scanners in detecting coronary artery disease in people with obesity. Obesity was defined as having a body mass index (BMI) of 30 kg/m² or above. The index test was Somatom Definition (a model predating the Somatom Definition Flash) and the reference test was invasive coronary angiography. The sensitivity was 90.4% (95% CI 83.8 to 94.9) and the specificity was found to be 92.1% (95% CI 89.1 to 94.5).

Four studies reported on the performance of new generation cardiac CT scanners in detecting coronary artery disease in people with high levels of coronary calcium. The high calcium score threshold was set to above 400. Data were derived from 1,304 segments in 91 participants. The index test was Somatom Definition and the reference test was invasive coronary angiography. The sensitivity was 92.7% (95% CI 88.3 to 95.6) and the specificity was 90.6% (95% CI 80.6 to 95.8%).

Five studies reported on the performance of new generation cardiac CT scanners in detecting coronary artery disease in people with arrhythmia. Data for 126 patients and 1,526 segments were obtained from the studies. For the patient data, sensitivity was 97.7% (95% CI 88.0 to 99.9) and specificity was 81.7% (95% CI 71.6 to 89.4). For the segment data, sensitivity was 87.4% (95% CI 68.3 to 95.7) and specificity was 96.0% (95% CI 91.2 to 98.2).

Eight studies in total reported 24 data sets on the performance of new generation cardiac CT scanners in detecting coronary artery disease in people with a high heart rate. Five studies with 462 participants reported per-patient data. The pooled estimates of sensitivity and specificity, derived from these data using a bivariate model, were 97.7% (95% CI 93.2 to 99.3) and 86.3% (95% CI 80.2 to 90.7) respectively. Four studies reported data for 664 arteries. The pooled estimates of sensitivity and specificity, derived from this data using a bivariate model, were 93.7% (95% CI 87.8 to 96.9) and 92.4% (95% CI 83.3 to 96.8) respectively. All 8 studies reported accuracy data by arterial segment (8,133 segments). The pooled estimates of sensitivity and specificity, derived from these data using a bivariate model, were 92.7% (95% CI 89.3 to 95.1) and 95.7% (95% CI 92.8 to 97.4) respectively. All 8 studies used a threshold of vessel narrowing of at least 50% to define significant stenosis.

Beta-blockers are normally prescribed to slow the heart rate for people with heart rates too high for scanning. Some people with high heart rates are intolerant to beta-blockers, which makes it difficult to image them with earlier generation CT scanners. However, no studies were identified on the accuracy of new generation cardiac CT scanners for the detection of coronary artery disease in people who are intolerant to beta-blockers.

Seven studies reported 10 data sets describing the accuracy of new generation cardiac CT scanners for the detection of coronary artery disease in people with previous stent implantation. Four studies reported per-patient data for 233 participants. The pooled estimates of sensitivity and specificity were 96.0% (95% CI 88.8 to 99.2) and 81.6% (95% CI 74.7 to 87.3) respectively. Six studies reported accuracy data by stent or stented lesion (n=582). The pooled estimates of sensitivity and specificity were 93.6% (95% CI 86.1 to 97.2) and 91.0% (95% CI 87.3 to 93.7) respectively.

A diagnostic model was used to estimate the initial outcomes of treatment and initial diagnosis. This model was created through extending and linking the 5 sub-models. The primary measures of benefit used in this analysis were:

• the complication rate for invasive coronary angiography and revascularisation (myocardial infarction and stroke)

• the benefits associated with reduction in the incidence of cancer as a result of reduction in radiation dose

• morbidity and mortality from coronary artery disease.

Using invasive coronary angiography as a comparator, three diagnostic strategies were evaluated. These strategies were:

• Invasive coronary angiography only: people in whom imaging is difficult had invasive coronary angiography only, which was assumed to be perfectly accurate.

• New generation cardiac CT scanner only: people in whom imaging is difficult had a new generation cardiac CT scan only; the accuracy of the scan was based on invasive coronary angiography as the reference standard.

• New generation cardiac CT scan plus invasive coronary angiography: cardiac CT was performed on everyone in whom imaging is difficult, and those with a positive scan then had invasive coronary angiography. No false positives could occur with this strategy because invasive coronary angiography was assumed to have perfect specificity.

The clinical outcomes assessed for people with coronary artery disease were mortality, morbidity and the percentage of correct diagnostic classifications (true positives, false positives, true negatives, false negatives) associated with each of the 3 strategies.

Using life tables, a healthy population model that only applied to people without coronary artery disease (true negatives and false positives) was used to predict mortality on the assumption that people with true negative and false positive test results do not differ from the average UK population.

The EUROPA model modelled the progression of stable coronary artery disease by predicting cardiovascular events and mortality. Health-related quality of life estimates were assigned to each Markov state based on age, gender, baseline Canadian Cardiovascular Society classification and whether the person had undergone treatment.

The costs and outcomes of people who experienced a stroke because of initial invasive coronary angiography or revascularisation were modelled with a mortality model. Mortality rates were based on UK life tables and a relative risk of 2.5 to reflect the increased risk of mortality after a stroke.

The York Radiation Model estimated the impact of imaging in terms of radiation dose on cancer morbidity and mortality. This model was used as there is no direct evidence on radiation dose effects in the populations included in the scope.