Diagnostic Value of Noninvasive Computed Tomography Perfusion Imaging and Coronary Computed Tomography Angiography for Assessing Hemodynamically Significant Native Coronary Artery Lesions

Sethi, Pooja, Panchal, Hemang B., Veeranki, Sreenivas P., Ur Rahman, Zia, Mamudu, Hadii, Paul, Timir K.

01 September 2017

The objective of this study is to determine the diagnostic performance of computed tomography perfusion (CTP) with and without computed tomography angiography (CTA) in assessment of hemodynamically significant coronary artery lesions in comparison to invasive fractional flow reserve (FFR). Materials and Methods PubMed and Cochrane Center Register of Controlled Trials from January 2010 searched through December 2014. Nine original studies were selected evaluating the diagnostic performance of CTP with and without CTA to invasive coronary angiography in evaluation of hemodynamic significance of coronary lesions (n = 951). Results The sensitivity, specificity, LR+ and LR- and DOR of CTA+CTP were 0.85 [95% confidence interval (CI: 0.79-0.89)] 0.94 (CI: 0.91-0.97), 15.8 (CI: 7.99-31.39), 0.146 (CI: 0.08-0.26), and 147.2 (CI: 69.77-310.66). Summary Receiver Operating Characteristics (SROC) results showed area under the curve (AUC) of 0.97 indicating that CTA+CTP may detect hemodynamically significant coronary artery lesions with high accuracy. The sensitivity, specificity, LR+ and LR- and DOR of CTP were 0.83 (CI: 0.78-0.87), 0.84 (CI: 0.80-0.87) 5.26 (CI: 2.93-9.43), 0.209 (CI: 0.12-0.36), and 31.97 (CI: 11.59-88.20). Conclusions This result suggests that CTP with CTA significantly improves diagnostic performance of coronary artery lesions compared to CTA alone and closely comparable with invasive FFR.

computed tomography angiography

computed tomography perfusion

coronary artery lesion

diagnostic accuracy

fractional flow reserve

Internal Medicine

Health Services Management and Policy

The Clinical Significance of Physiological Assessment of Residual Ischemia After Percutaneous Coronary Intervention

Ojha, Chandra P., Ibrahim, Ahmed, Paul, Timir K., Mulukutla, Venkatachalam, Nagarajarao, Harsha S.

01 April 2020

Purpose of Review: Fractional flow reserve (FFR) and instantaneous wave-free ratio (iFR) have emerged as the invasive diagnostic tools of choice for hemodynamic assessment of the severity of CAD (coronary artery disease). We sought to comprehensively review the evidence on the utility of hemodynamic assessment of the coronary stenoses after percutaneous coronary intervention (PCI) using FFR/iFR, mechanisms of positive post-PCI iFR/FFR, and the clinical impact of significant residual ischemia. Recent Findings: The evidence on the utility of the post-PCI hemodynamic assessment has accumulated over the last few years. The post hoc analysis from the FAME 1 and FAME 2 data shows that higher post-PCI FFR is associated with better symptomatic improvement and lower event rate with larger increase in delta FFR (∆ FFR: post-PCI FFR – pre-PCI FFR). Unlike pre-PCI FFR, a consensus has not been established on the optimal value of post-PCI FFR, though multiple studies point toward better clinical outcomes with higher post-PCI FFR and larger ∆ FFR. Summary: Visual assessment of adequate stent apposition by coronary angiography is insufficient in evaluating for residual ischemia. The hemodynamic evaluation of residual ischemia by post-PCI FFR/iFR yields clinically relevant data and allows for appropriate post PCI optimization.

coronary artery disease

delta FFR

evidence based medicine

fractional flow reserve

percutaneous coronary intervention

Post-PCI FFR

Internal Medicine

Image based Computational Hemodynamics for Non-invasive and Patient-Specific Assessment of Arterial Stenosis

Md Monsurul Islam Khan (6911054)

16 October 2019

While computed tomographic angiography (CTA) has emerged as a powerful noninvasive option that allows for direct visualization of arterial stenosis(AS), it cant assess the hemodynamic abnormality caused by an AS. Alternatively, trans-stenotic pressure gradient (TSPG) and fractional flow reserve (FFR) are well-validated hemodynamic indices to assess the ischemic severity of an AS. However, they have significant restriction in practice due to invasiveness and high cost. To fill the gap, a new computational modality, called <i>InVascular</i> has been developed for non-invasive quantification TSPG and/or FFR based on patient's CTA, aiming to quantify the hemodynamic abnormality of the stenosis and help to assess the therapeutic/surgical benefits of treatment for the patient. Such a new capability gives rise to a potential of computation aided diagnostics and therapeutics in a patient-specific environment for ASs, which is expected to contribute to precision planning for cardiovascular disease treatment. <i>InVascular</i> integrates a computational modeling of diseases arteries based on CTA and Doppler ultrasonography data, with cutting-edge Graphic Processing Unit (GPU) parallel-computing technology. Revolutionary fast computing speed enables noninvasive quantification of TSPG and/or FFR for an AS within a clinic permissible time frame. In this work, we focus on the implementation of inlet and outlet boundary condition (BC) based on physiological image date and and 3-element Windkessel model as well as lumped parameter network in volumetric lattice Boltzmann method. The application study in real human coronary and renal arterial system demonstrates the reliability of the in vivo pressure quantification through the comparisons of pressure waves between noninvasive computational and invasive measurement. In addition, parametrization of worsening renal arterial stenosis (RAS) and coronary arterial stenosis (CAS) characterized by volumetric lumen reduction (S) enables establishing the correlation between TSPG/FFR and S, from which the ischemic severity of the AS (mild, moderate, or severe) can be identified. In this study, we quantify TSPG and/or FFR for five patient cases with visualized stenosis in coronary and renal arteries and compare the non-invasive computational results with invasive measurement through catheterization. The ischemic severity of each AS is predicted. The results of this study demonstrate the reliability and clinical applicability of <i>InVascular</i>.

Mechanical Engineering

computational hemodynamics

arterial stenosis

non-invasive diagnosis

cardiovascular modeling

lumped parameter boundary condition

trans-stenotic pressure gradient

fractional flow reserve

Processamento de imagens médicas e parâmetros hemodinâmicos: validação clínica de modelos cardiovasculares assistidos por computação científica / Processing of medical imaging and hemodynamic parameters: clinical

Bezerra, Cristiano Guedes

16 March 2018

Introdução: A doença arterial coronária (DAC) é avaliada através dos aspectos anatômicos da placa aterosclerótica ou a partir da repercussão funcional da estenose, por métodos diagnósticos diversos. O ultrassom intravascular (IVUS) fornece uma avaliação anatômica precisa do lúmen e da parede do vaso, tendo sido validado como uma ferramenta útil para guiar a intervenção coronária percutânea (ICP). No entanto, do ponto de vista diagnóstico, o IVUS representa mal o estado funcional (isto é, informação relacionada ao comprometimento de fluxo) do vaso interrogado. A reserva de fluxo fracionada (FFR) é método importante para identificação de isquemia, discriminando as estenoses coronárias que podem se beneficiar de ICP. Objetivamos desenvolver e avaliar o desempenho diagnóstico de um novo algoritmo computacional para estimar a FFR à partir das imagens do IVUS tridimensional (IVUSFR), comparando-o com o método padrão ouro para estimação de fluxo coronário invasivo (FFRPW). Métodos: Pacientes com DAC estável conhecida ou suspeita encaminhados para cateterismo cardíaco eletivo foram submetidos a avaliação complementar com medida de fluxo coronário pelo FFRPW e com imagem intravascular pelo IVUS, no mesmo procedimento, a fim de avaliar lesões intermediárias. As imagens do IVUS foram processadas para gerar uma malha computacional tridimensional que condensa as características geométricas do vaso. O IVUSFR foi obtido utilizando dinâmica de fluido computacional, configurando-se as condições de contorno a partir de características específicas do paciente e do território coronário irrigado. As medidas de FFRPW foram dicotomizadas no limiar de 0,80 para definir lesões hemodinamicamente significativas e avaliar o desempenho diagnóstico do IVUSFR. Resultados: Um total de 34 artérias coronárias de 24 pacientes foi analisado. A área luminal mínima média avaliada pelo IVUS de 4,14 ± 1,74 mm2, e carga de placa média de 66±10% caracterizam o grau intermediário das lesões. O IVUSFR correlacionou significativamente (r = 0,79; p < 0,001) e mostrou boa concordância com a FFRPW, apresentando diferença média de -0,008 ± 0,067 (p = 0,47). O IVUSFR apresentou acurácia, sensibilidade, especificidade, valor preditivo positivo e valor preditivo negativo de 91%, 89%, 92%, 80% e 96%, respectivamente, para detectar estenoses hemodinamicamente significativas. Conclusão: O processamento computacional do IVUSFR é um novo método que permite a avaliação funcional da estenose coronária intermediária de forma acurada, enriquecendo as informações anatômicas do IVUS / Introduction: Coronary artery disease (CAD) is assessed through the anatomical aspects of the atherosclerotic plaque or through the functional impairment of the stenosis, by different diagnostic methods. Intravascular ultrasound (IVUS) provides accurate anatomic assessment of lumen and vessel wall and has been validated as a useful tool to guide percutaneous coronary intervention (PCI). However, from the diagnostic point of view, IVUS poorly represents the functional status (i.e. flow-related information) of the imaged vessel. Fractional flow reserve (FFR) is an important tool to identify ischemia, discriminating coronary stenosis that may benefit from PCI. We aimed to develop and evaluate the diagnostic performance of a novel computational algorithm based on three-dimensional IVUS imaging in estimating fractional flow reserve (IVUSFR), compared to gold-standard invasive measurements (FFRPW). Methods: Patients with known or suspected stable coronary disease scheduled for elective cardiac catheterization underwent FFRPW measurement and IVUS imaging in the same procedure to evaluate intermediate lesions. A processing methodology was applied on IVUS to generate a computational mesh condensing the geometric characteristics of the vessel. Through computational fluid dynamics, IVUSFR was obtained from patient-level morphological definition of arterial districts and from territory-specific boundary conditions. FFRPW measurements were dichotomized at the 0.80 thresholds to define hemodynamically significant lesions and evaluate diagnostic performance of IVUSFR. Results: A total of 24 patients with 34 vessels were analyzed. The mean minimum luminal area assessed by IVUS was 4.14 ± 1.74 mm2, and mean plaque burden was 66 ± 10%, characterizing intermediate lesions. IVUSFR significantly correlated (r = 0.79; p < 0.001) and showed good agreement with FFRPW, with a mean difference of -0.008 ± 0.067 (p = 0.47). IVUSFR presented an overall accuracy, sensitivity, specificity, positive predictive value, and negative predictive value of 91%, 89%, 92%, 80%, and 96% respectively to detect significant stenosis. Conclusion: The computational processing of IVUSFR is a new method that allows the evaluation of the functional significance of coronary stenosis in an accurate way, enriching the anatomical information of IVUS

Atherosclerosis

Atherosclerosis

Coronary artery disease

Coronary artery disease

Coronary vessels/diagnostic imaging

Coronary vessels/diagnostic imaging

Fractional flow reserve myocardial

Fractional flow reserve myocardial

Image processing computer-assisted

Image processing computer-assisted

Imaging three-dimensional

Imaging three-dimensional

Intravascular ltrasonography

Ultrasonography intravascular

Processamento de imagens médicas e parâmetros hemodinâmicos: validação clínica de modelos cardiovasculares assistidos por computação científica / Processing of medical imaging and hemodynamic parameters: clinical

Cristiano Guedes Bezerra

16 March 2018

Introdução: A doença arterial coronária (DAC) é avaliada através dos aspectos anatômicos da placa aterosclerótica ou a partir da repercussão funcional da estenose, por métodos diagnósticos diversos. O ultrassom intravascular (IVUS) fornece uma avaliação anatômica precisa do lúmen e da parede do vaso, tendo sido validado como uma ferramenta útil para guiar a intervenção coronária percutânea (ICP). No entanto, do ponto de vista diagnóstico, o IVUS representa mal o estado funcional (isto é, informação relacionada ao comprometimento de fluxo) do vaso interrogado. A reserva de fluxo fracionada (FFR) é método importante para identificação de isquemia, discriminando as estenoses coronárias que podem se beneficiar de ICP. Objetivamos desenvolver e avaliar o desempenho diagnóstico de um novo algoritmo computacional para estimar a FFR à partir das imagens do IVUS tridimensional (IVUSFR), comparando-o com o método padrão ouro para estimação de fluxo coronário invasivo (FFRPW). Métodos: Pacientes com DAC estável conhecida ou suspeita encaminhados para cateterismo cardíaco eletivo foram submetidos a avaliação complementar com medida de fluxo coronário pelo FFRPW e com imagem intravascular pelo IVUS, no mesmo procedimento, a fim de avaliar lesões intermediárias. As imagens do IVUS foram processadas para gerar uma malha computacional tridimensional que condensa as características geométricas do vaso. O IVUSFR foi obtido utilizando dinâmica de fluido computacional, configurando-se as condições de contorno a partir de características específicas do paciente e do território coronário irrigado. As medidas de FFRPW foram dicotomizadas no limiar de 0,80 para definir lesões hemodinamicamente significativas e avaliar o desempenho diagnóstico do IVUSFR. Resultados: Um total de 34 artérias coronárias de 24 pacientes foi analisado. A área luminal mínima média avaliada pelo IVUS de 4,14 ± 1,74 mm2, e carga de placa média de 66±10% caracterizam o grau intermediário das lesões. O IVUSFR correlacionou significativamente (r = 0,79; p < 0,001) e mostrou boa concordância com a FFRPW, apresentando diferença média de -0,008 ± 0,067 (p = 0,47). O IVUSFR apresentou acurácia, sensibilidade, especificidade, valor preditivo positivo e valor preditivo negativo de 91%, 89%, 92%, 80% e 96%, respectivamente, para detectar estenoses hemodinamicamente significativas. Conclusão: O processamento computacional do IVUSFR é um novo método que permite a avaliação funcional da estenose coronária intermediária de forma acurada, enriquecendo as informações anatômicas do IVUS / Introduction: Coronary artery disease (CAD) is assessed through the anatomical aspects of the atherosclerotic plaque or through the functional impairment of the stenosis, by different diagnostic methods. Intravascular ultrasound (IVUS) provides accurate anatomic assessment of lumen and vessel wall and has been validated as a useful tool to guide percutaneous coronary intervention (PCI). However, from the diagnostic point of view, IVUS poorly represents the functional status (i.e. flow-related information) of the imaged vessel. Fractional flow reserve (FFR) is an important tool to identify ischemia, discriminating coronary stenosis that may benefit from PCI. We aimed to develop and evaluate the diagnostic performance of a novel computational algorithm based on three-dimensional IVUS imaging in estimating fractional flow reserve (IVUSFR), compared to gold-standard invasive measurements (FFRPW). Methods: Patients with known or suspected stable coronary disease scheduled for elective cardiac catheterization underwent FFRPW measurement and IVUS imaging in the same procedure to evaluate intermediate lesions. A processing methodology was applied on IVUS to generate a computational mesh condensing the geometric characteristics of the vessel. Through computational fluid dynamics, IVUSFR was obtained from patient-level morphological definition of arterial districts and from territory-specific boundary conditions. FFRPW measurements were dichotomized at the 0.80 thresholds to define hemodynamically significant lesions and evaluate diagnostic performance of IVUSFR. Results: A total of 24 patients with 34 vessels were analyzed. The mean minimum luminal area assessed by IVUS was 4.14 ± 1.74 mm2, and mean plaque burden was 66 ± 10%, characterizing intermediate lesions. IVUSFR significantly correlated (r = 0.79; p < 0.001) and showed good agreement with FFRPW, with a mean difference of -0.008 ± 0.067 (p = 0.47). IVUSFR presented an overall accuracy, sensitivity, specificity, positive predictive value, and negative predictive value of 91%, 89%, 92%, 80%, and 96% respectively to detect significant stenosis. Conclusion: The computational processing of IVUSFR is a new method that allows the evaluation of the functional significance of coronary stenosis in an accurate way, enriching the anatomical information of IVUS

Atherosclerosis

Coronary artery disease

Coronary vessels/diagnostic imaging

Fractional flow reserve myocardial

Image processing computer-assisted

Imaging three-dimensional

Intravascular ltrasonography

Atherosclerosis

Coronary artery disease

Coronary vessels/diagnostic imaging

Fractional flow reserve myocardial

Image processing computer-assisted

Imaging three-dimensional

Ultrasonography intravascular