One-stop patient-specific myocardial blood flow quantification technique based on allometric scaling law

One-stop patient-specific myocardial blood flow quantification technique based on allometric scaling law

Establishing a patient-specific and non-invasive technique to derive blood flow as well as coronary structural information from one single cardiac CT imaging modality. 336 patients with chest pain or ST segment depression on electrocardiogram were retrospectively enrolled. All patients underwent ade...

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Bibliographic Details
Published in:Journal of biomechanics Vol. 151; p. 111513
Main Authors: Li, Junhuan, Wu, Dan, Lv, Lijuan, Dong, Mei, Han, Yeming, Zhang, Mei, Savage, Rock H., Zhang, Hongkai, Bai, Junjie, Cao, Kunlin, Yin, Youbing, Song, Qi, Zhang, Yun, Li, Yuwei, Zhang, Pengfei, Joseph Schoepf, U.
Format: Journal Article
Language:English
Published: United States Elsevier Ltd 01-04-2023
Elsevier Limited
Subjects:
Accuracy
Adenosine
Angiography
Blood
Blood flow
Cardiovascular disease
Computed tomography
Computed Tomography Angiography - methods
Coronary Angiography - methods
Coronary Artery Disease
Coronary physiology
Coronary Stenosis
Coronary vessels
Correlation
EKG
Electrocardiography
Heart
Hemodynamics
Humans
Individualized
Ischemia
Medical imaging
Myocardial M−Q Correlation
One-stop Cardiac CT Technique
Patients
Perfusion
Power Law
Predictive Value of Tests
Retrospective Studies
Scaling
Scaling laws
Tomography, X-Ray Computed - methods
Ventricle
Individualized
One-stop Cardiac CT Technique
Coronary physiology
Myocardial M−Q Correlation
Power Law
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Summary:Establishing a patient-specific and non-invasive technique to derive blood flow as well as coronary structural information from one single cardiac CT imaging modality. 336 patients with chest pain or ST segment depression on electrocardiogram were retrospectively enrolled. All patients underwent adenosine-stressed dynamic CT myocardial perfusion imaging (CT-MPI) and coronary computed tomography angiography (CCTA) in sequence. Relationship between myocardial mass (M) and blood flow (Q), defined as log(Q) = b · log(M) + log(Q0), was explored based on the general allometric scaling law. We used 267 patients to obtain the regression results and found strong linear relationship between M (gram) and Q (mL/min) (b = 0.786, log(Q0) = 0.546, r = 0.704; p < 0.001). We Also found this correlation was applicable for patients with either normal or abnormal myocardial perfusion (p < 0.001). Datasets from the other 69 patients were used to validate this M−Q correlation and found the patient-specific blood flow could be accurately estimated from CCTA compared to that measured from CT-MPI (146.480 ± 39.607 vs 137.967 ± 36.227, r = 0.816, and 146.480 ± 39.607 vs 137.967 ± 36.227, r = 0.817, for the left ventricle region and LAD-subtended region, respectively, all unit in mL/min). In conclusion, we established a technique to provide general and patient-specific myocardial mass-blood flow correlation obeyed to allometric scaling law. Blood flow information could be directly derived from structural information acquired from CCTA.
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ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2023.111513