Estimating absolute aortic pressure using MRI and a one-dimensional model

被引：12

作者：

Khalife, Maya ^{[1
]}

Decoene, Astrid ^{[2
]}

Caetano, Filipa ^{[2
]}

de Rochefort, Ludovic ^{[1
]}

Durand, Emmanuel ^{[1
]}

Rodriguez, Dima ^{[1
]}

机构：

[1] Univ Paris 11, CNRS, UMR 8081, Imagerie Resonance Magnet Med & Multimodalites IR, F-91405 Orsay, France

[2] Univ Paris 11, CNRS, UMR 8628, Lab Math Orsay, F-91405 Orsay, France

来源：

JOURNAL OF BIOMECHANICS | 2014年 / 47卷 / 13期

关键词：

Cardiovascular imaging; MRI; Aorta; Blood pressure; One-dimensional model; Compliance; Non-invasive; BLOOD-FLOW; EXPERIMENTAL VALIDATION; NUMERICAL-SIMULATION; ELASTIC PROPERTIES; WAVE-PROPAGATION; PULSE-WAVE; VELOCITY; HEMODYNAMICS; TRANSMISSION; TONOMETRY;

D O I：

10.1016/j.jbiomech.2014.07.018

中图分类号：

Q6 [生物物理学];

学科分类号：

071011 ;

摘要：

Aortic blood pressure is a strong indicator to cardiovascular diseases and morbidity. Clinically, pressure measurements are done by inserting a catheter in the aorta. However, imaging techniques have been used to avoid the invasive procedure of catheterization. In this paper, we combined MRI measurements to a one-dimensional model in order to simulate blood flow in an aortic segment. Absolute pressure was estimated in the aorta by using MRI measured flow as boundary conditions and MRI measured compliance as a pressure law for solving the model. Model computed pressure was compared to catheter measured pressure in an aortic phantom. Furthermore, aortic pressure was estimated in vivo in three healthy volunteers. (C) 2014 Elsevier Ltd. All rights reserved.

引用

页码：3390 / 3399

页数：10

共 50 条

[31] An energetic formulation of a one-dimensional model of superelastic SMA
Kim Pham
Continuum Mechanics and Thermodynamics, 2014, 26 : 833 - 857
[32] A numerical solution of a one-dimensional blood flow model -: moving grid approach
Melicher, V.
Gajdosik, V.
JOURNAL OF COMPUTATIONAL AND APPLIED MATHEMATICS, 2008, 215 (02) : 512 - 520
[33] One-dimensional modeling of pervaporation systems using a semi-empirical flux model
Ashraf, Muhammad Tahir
Schmidt, Jens Ejbye
Kujawa, Joanna
Kujawski, Wojciech
Arafat, Hassan A.
SEPARATION AND PURIFICATION TECHNOLOGY, 2017, 174 : 502 - 512
[34] The contribution of upper and lower body arterial vessels to the aortic root reflections: A one-dimensional computational study
Abdullateef, Shima
Khir, Ashraf W.
COMPUTER METHODS AND PROGRAMS IN BIOMEDICINE, 2023, 238
[35] Mode selectivity of random lasing in one-dimensional model
Takeda, Seiji
Obara, Minoru
LASER RESONATORS AND BEAM CONTROL IX, 2007, 6452
[36] One-dimensional discharge simulation of nitrogen DBD atmospheric pressure plasma
Choi, YH
Kim, JH
Hwang, YS
THIN SOLID FILMS, 2006, 506 : 389 - 395
[37] Method for estimating pulsatile wall shear stress from one-dimensional velocity waveforms
Muskat, J. C.
Babbs, C. F.
Goergen, C. J.
Rayz, V. L.
PHYSIOLOGICAL REPORTS, 2023, 11 (07):
[38] Underwater striling engine design with modified one-dimensional model
Li, Daijin
Qin, Kan
Luo, Kai
INTERNATIONAL JOURNAL OF NAVAL ARCHITECTURE AND OCEAN ENGINEERING, 2015, 7 (03) : 526 - 539
[39] Analysis of particle settlement characteristics in a one-dimensional deterministic model
Velazquez-Perez, S. E.
Gilardi-Velazquez, H. E.
Campos-Canton, E.
INTERNATIONAL JOURNAL OF MODERN PHYSICS C, 2025,
[40] Construction and Evaluation of a Parametric One-Dimensional Vocal Tract Model
Stone, Simon
Marxen, Michael
Birkholz, Peter
IEEE-ACM TRANSACTIONS ON AUDIO SPEECH AND LANGUAGE PROCESSING, 2018, 26 (08) : 1381 - 1392

← 1 2 3 4 5 →