Advancements and Opportunities in Characterizing Patient-Specific Wall Shear Stress Imposed by Coronary Artery Stenting

LaDisa, John F.; Ghorbannia, Arash; Marks, David; Mason, Peter G.; Otake, Hiromasa

doi:10.3390/fluids7100325

Cited by 4 publications

(3 citation statements)

References 162 publications

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“…The current results should be interpreted relative to several potential limitations. In particular, high-fidelity hemodynamic simulation is challenging to perform longitudinally as 3D reconstruction of the aorta over the course of the disease requires multiple MRI acquisitions and often computationally heavy [46,47]. We, therefore, quantified WSS and IWS from the Hagen-Poiseuille law and force equilibrium using empirical measurements of local hemodynamics over the course of disease development.…”

Section: Resultsmentioning

confidence: 99%

Aortic Remodeling Kinetics in Response to Coarctation-Induced Mechanical Perturbations

et al. 2023

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Coarctation of the aorta (CoA; constriction of the proximal descending thoracic aorta) is among the most common congenital cardiovascular defects. Coarctation-induced mechanical perturbations trigger a cycle of mechano-transduction events leading to irreversible precursors of hypertension including arterial thickening, stiffening, and vasoactive dysfunction in proximal conduit arteries. This study sought to identify kinetics of the stress-mediated compensatory response leading to these alterations using a preclinical rabbit model of CoA. Methods: A prior growth and remodeling (G&R) framework was reformulated and fit to empirical measurements from CoA rabbits classified into one control and nine CoA groups of various severities and durations (n = 63, 5–11/group). Empirical measurements included Doppler ultrasound imaging, uniaxial extension testing, catheter-based blood pressure, and wire myography, yielding the time evolution of arterial thickening, stiffening, and vasoactive dysfunction required to fit G&R constitutive parameters. Results: Excellent agreement was observed between model predictions and observed patterns of arterial thickening, stiffening, and dysfunction among all CoA groups. For example, predicted vascular impairment was not significantly different from empirical observations via wire myography (p-value > 0.13). Specifically, 48% and 45% impairment was observed in smooth muscle contraction and endothelial-dependent relaxation, respectively, which were accurately predicted using the G&R model. Conclusions: The resulting G&R model, for the first time, allows for prediction of hypertension precursors at neonatal ages that is currently challenging to examine in preclinical models. These findings provide a validated computational tool for prediction of persistent arterial dysfunction and identification of revised severity–duration thresholds that may ultimately avoid hypertension from CoA.

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Section: Resultsmentioning

confidence: 99%

Aortic Remodeling Kinetics in Response to Coarctation-Induced Mechanical Perturbations

et al. 2023

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“…It has found widespread use in the functional assessment of CAD and in the elucidation of the role of hemodynamics in CAD initiation, progression, susceptibility and phenotype ( 4 , 11 , 12 ). Additionally, CFD has demonstrated its capability to describe and predict the hemodynamic responses before ( 13 , 14 ) and after cardiovascular interventional procedures ( 15 , 16 ), making it a valuable tool in the development and enhancement of intervention devices and treatment strategies ( 6 , 17 – 21 ). Furthermore, current literature has highlighted that basic modeling concepts are now ripe for incorporation into the knowledge base of interventional cardiologists.…”

Section: Introductionmentioning

confidence: 99%

“…In recent years, computational fluid dynamics (CFD) has emerged as a methodology ready to shift to technology for cardiovascular medicine, potentially enhancing the understanding of pathophysiology, by simulating interventional procedures, and improving decision making regarding CAD treatment (4)(5)(6)(7)(8). CFD utilizes numerical techniques to solve and analyze problems involving fluid flows, including blood flow (4).…”

Section: Introductionmentioning

confidence: 99%

Computational fluid dynamics as supporting technology for coronary artery disease diagnosis and treatment: an international survey

Chiastra,

Zuin,

Rigatelli

et al. 2023

Front. Cardiovasc. Med.

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BackgroundComputational fluid dynamics (CFD) is emerging as an effective technology able to improve procedural outcomes and enhance clinical decision-making in patients with coronary artery disease (CAD). The present study aims to assess the state of knowledge, use and clinical acceptability of CFD in the diagnosis and treatment of CAD.MethodsWe realized a 20-questions international, anonymous, cross-sectional survey to cardiologists to test their knowledge and confidence on CFD as a technology applied to patients suffering from CAD. Responses were recorded between May 18, 2022, and June 12, 2022.ResultsA total of 466 interventional cardiologists (mean age 48.4 ± 8.3 years, males 362), from 42 different countries completed the survey, for a response rate of 45.9%. Of these, 66.6% declared to be familiar with the term CFD, especially for optimization of existing interventional techniques (16.1%) and assessment of hemodynamic quantities related with CAD (13.7%). About 30% of respondents correctly answered to the questions exploring their knowledge on the pathophysiological role of some CFD-derived quantities such as wall shear stress and helical flow in coronary arteries. Among respondents, 85.9% would consider patient-specific CFD-based analysis in daily interventional practice while 94.2% declared to be interested in receiving a brief foundation course on the basic CFD principles. Finally, 87.7% of respondents declared to be interested in a cath-lab software able to conduct affordable CFD-based analyses at the point-of-care.ConclusionsInterventional cardiologists reported to be profoundly interested in adopting CFD simulations as a technology supporting decision making in the treatment of CAD in daily practice.

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Shear‐Responsive Drug Delivery Systems in Medical Devices: Focus on Thrombosis and Bleeding

Shirejini

Carberry

Alt

et al. 2023

Adv Funct Materials

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Cardiovascular disease is the leading cause of death worldwide. Blood‐contacting medical devices provide critical support for patients with severe respiratory and/or cardiac failure. High shear stress zones and non‐biocompatible circuit can increase the risk of thrombus formation in patients. These thrombi restrict blood flow through the circuits and travel to the lungs and brain, creating significant consequences. Antithrombotic drugs are used to lower this risk, but they also raise the incidence of bleeding problems. This article explores the delicate balance between thrombosis and bleeding in medical devices by examining platelet activation and thrombosis formation under shear stress. The feasibility of a shear‐responsive nanomedicine‐based drug delivery system has been explored as a potential approach for targeted administration of antithrombotic medications to lower systemic drug levels and reduce the bleeding risk. Furthermore, the lack of in vitro platforms to investigate the biological behavior of antithrombotic nanoparticles is impeding their clinical translation. As a result, microfluidic technology offers a platform for investigating nanoparticle behavior in vitro and linking it to their performance in vivo. Finally, the challenges and factors that affect the functionality, stability, and circulation time of liposomal drugs are investigated to improve their efficacy for targeted drug administration in medical devices.

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Advancements and Opportunities in Characterizing Patient-Specific Wall Shear Stress Imposed by Coronary Artery Stenting

Cited by 4 publications

References 162 publications

Aortic Remodeling Kinetics in Response to Coarctation-Induced Mechanical Perturbations

Aortic Remodeling Kinetics in Response to Coarctation-Induced Mechanical Perturbations

Computational fluid dynamics as supporting technology for coronary artery disease diagnosis and treatment: an international survey

Shear‐Responsive Drug Delivery Systems in Medical Devices: Focus on Thrombosis and Bleeding

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