Comparison of blood flow models and acquisitions for quantitative myocardial perfusion estimation from dynamic CT

Bindschadler, Michael; Modgil, Dimple; Branch, Kelley R.; Rivière, Patrick J. La; Alessio, Adam M.

doi:10.1088/0031-9155/59/7/1533

Cited by 51 publications

(82 citation statements)

References 52 publications

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“…Calibration of detector noise was validated using a uniform phantom and varying clinical scanner tube current. 15 Simulated myocardial time activity curves had peaks which varied with MBF and occurred within the same time window as clinical CTA acquisitions (∼4 to 8 s after peak opacification of the left ventricle). All of the following results are for radiation dose-matched static and dynamic simulated acquisitions resulting in an approximate effective dose of 4.3 mSv.…”

Section: Simulation Outputmentioning

confidence: 91%

“…15 A detailed physiological model of cardiac contrast bolus dynamics was treated as ground truth for simulated patients and drives iodine concentrations over time in a modified XCAT digital phantom. 16 A polyenergetic simulator was used to generate the CT projection data from the dynamic phantoms.…”

Section: Simulation Systemmentioning

confidence: 99%

“…The static image series followed conventional clinical processing and are only beam hardening corrected for water components. Our physiological driving model 15 and CT simulation produced images with myocardial CT numbers at different time points postcontrast injection and at different perfusion levels. Since static cardiac CT acquisition timing is usually based on a timing bolus acquisition monitoring arterial enhancement, we specified the timing of our static acquisition as a delay from the peak opacification of the left ventricular (LV) cavity, which is within 1 to 3 s of peak aortic opacification.…”

Section: Simulation Systemmentioning

confidence: 99%

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Evaluation of static and dynamic perfusion cardiac computed tomography for quantitation and classification tasks

et al. 2016

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Abstract. Cardiac computed tomography (CT) acquisitions for perfusion assessment can be performed in a dynamic or static mode. Either method may be used for a variety of clinical tasks, including (1) stratifying patients into categories of ischemia and (2) using a quantitative myocardial blood flow (MBF) estimate to evaluate disease severity. In this simulation study, we compare method performance on these classification and quantification tasks for matched radiation dose levels and for different flow states, patient sizes, and injected contrast levels. Under conditions simulated, the dynamic method has low bias in MBF estimates (0 to 0.1 ml∕ min ∕g) compared to linearly interpreted static assessment (0.45 to 0.48 ml∕ min ∕g), making it more suitable for quantitative estimation. At matched radiation dose levels, receiver operating characteristic analysis demonstrated that the static method, with its high bias but generally lower variance, had superior performance (p < 0.05) in stratifying patients, especially for larger patients and lower contrast doses [area under the curve ðAUCÞ ¼ 0.95 to 96 versus 0.86]. We also demonstrate that static assessment with a correctly tuned exponential relationship between the apparent CT number and MBF has superior quantification performance to static assessment with a linear relationship and to dynamic assessment. However, tuning the exponential relationship to the patient and scan characteristics will likely prove challenging. This study demonstrates that the selection and optimization of static or dynamic acquisition modes should depend on the specific clinical task.

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Section: Simulation Outputmentioning

confidence: 91%

Section: Simulation Systemmentioning

confidence: 99%

Section: Simulation Systemmentioning

confidence: 99%

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Evaluation of static and dynamic perfusion cardiac computed tomography for quantitation and classification tasks

et al. 2016

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“…Ground truth iodine kinetic curves were generated with a realistic iodine delivery and exchange model, described in 7 . In brief, this model supported iodine exchange between the capillary and extravascular space.…”

Section: Methodsmentioning

confidence: 99%

“…Prior work by our group evaluated different MBF models applied to simple time-attenuation-curves, without the inclusion of the confounding effects in realistic CT data including beam-hardening errors and realistic quantum noise 5 . Recently, we presented preliminary results for MBF estimation with realistic CT simulation 6 . In this study, we extend former studies by evaluating a range of realistic CT data acquisitions and add to the quantitative methods additional evaluation of qualitative static perfusion performance as well as comparisons based on grading disease severity.…”

Section: Introductionmentioning

confidence: 99%

Simulation evaluation of quantitative myocardial perfusion assessment from cardiac CT

et al. 2014

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Contrast enhancement on cardiac CT provides valuable information about myocardial perfusion and methods have been proposed to assess perfusion with static and dynamic acquisitions. There is a lack of knowledge and consensus on the appropriate approach to ensure 1) sufficient diagnostic accuracy for clinical decisions and 2) low radiation doses for patient safety. This work developed a thorough dynamic CT simulation and several accepted blood flow estimation techniques to evaluate the performance of perfusion assessment across a range of acquisition and estimation scenarios. Cardiac CT acquisitions were simulated for a range of flow states (Flow = 0.5, 1, 2, 3 ml/g/min, cardiac output = 3,5,8 L/min). CT acquisitions were simulated with a validated CT simulator incorporating polyenergetic data acquisition and realistic x-ray flux levels for dynamic acquisitions with a range of scenarios including 1, 2, 3 sec sampling for 30 sec with 25, 70, 140 mAs. Images were generated using conventional image reconstruction with additional image-based beam hardening correction to account for iodine content. Time attenuation curves were extracted for multiple regions around the myocardium and used to estimate flow. In total, 2,700 independent realizations of dynamic sequences were generated and multiple MBF estimation methods were applied to each of these. Evaluation of quantitative kinetic modeling yielded blood flow estimates with an root mean square error (RMSE) of ∼0.6 ml/g/min averaged across multiple scenarios. Semi-quantitative modeling and qualitative static imaging resulted in significantly more error (RMSE = ∼1.2 and ∼1.2 ml/min/g respectively). For quantitative methods, dose reduction through reduced temporal sampling or reduced tube current had comparable impact on the MBF estimate fidelity. On average, half dose acquisitions increased the RMSE of estimates by only 18% suggesting that substantial dose reductions can be employed in the context of quantitative myocardial blood flow estimation. In conclusion, quantitative model-based dynamic cardiac CT perfusion assessment is capable of accurately estimating MBF across a range of cardiac outputs and tissue perfusion states, outperforms comparable static perfusion estimates, and is relatively robust to noise and temporal subsampling.

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Two‐compartment modeling of tissue microcirculation revisited

2017

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Physiologically well-defined tissue parameters are structurally identifiable and accurately estimable from DCE data by the conceptually modified two-compartment model in combination with the bias correction. The accuracy of the bias-corrected flow is nearly comparable to that of the three other (theoretically unbiased) model parameters. As compared to conventional two-compartment modeling, this feature constitutes a major advantage for tracer kinetic analysis of both preclinical and clinical DCE imaging studies.

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Comparison of blood flow models and acquisitions for quantitative myocardial perfusion estimation from dynamic CT

Cited by 51 publications

References 52 publications

Evaluation of static and dynamic perfusion cardiac computed tomography for quantitation and classification tasks

Evaluation of static and dynamic perfusion cardiac computed tomography for quantitation and classification tasks

Simulation evaluation of quantitative myocardial perfusion assessment from cardiac CT

Two‐compartment modeling of tissue microcirculation revisited

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