Scaling Laws of Flow Rate, Vessel Blood Volume, Lengths, and Transit Times With Number of Capillaries

Razavi, Mohammad; Shirani, Ebrahim; Kassab, Ghassan S.

doi:10.3389/fphys.2018.00581

Cited by 17 publications

(12 citation statements)

References 41 publications

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“…Specifically, unique resistance values were computed for each coronary outlet by applying an equivalent resistor model that obeys the structure-function relationship (Fig. 1 b) 27 . As per the resistor model, under resting flow conditions, blood vessel resistance is a function of the vessel size and viscosity, which was kept constant during the course of the simulation (Fig.…”

Section: Resultsmentioning

confidence: 99%

Non-invasive characterization of complex coronary lesions

Vardhan

Gounley

Chen

et al. 2021

Sci Rep

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Conventional invasive diagnostic imaging techniques do not adequately resolve complex Type B and C coronary lesions, which present unique challenges, require personalized treatment and result in worsened patient outcomes. These lesions are often excluded from large-scale non-invasive clinical trials and there does not exist a validated approach to characterize hemodynamic quantities and guide percutaneous intervention for such lesions. This work identifies key biomarkers that differentiate complex Type B and C lesions from simple Type A lesions by introducing and validating a coronary angiography-based computational fluid dynamic (CFD-CA) framework for intracoronary assessment in complex lesions at ultrahigh resolution. Among 14 patients selected in this study, 7 patients with Type B and C lesions were included in the complex lesion group including ostial, bifurcation, serial lesions and lesion where flow was supplied by collateral bed. Simple lesion group included 7 patients with lesions that were discrete, $$<10\hbox {mm}$$ < 10 mm long and readily accessible. Intracoronary assessment was performed using CFD-CA framework and validated by comparing to clinically measured pressure-based index, such as FFR. Local pressure, endothelial shear stress (ESS) and velocity profiles were derived for all patients. We validates the accuracy of our CFD-CA framework and report excellent agreement with invasive measurements ($$n=14, R^2 = 0.6, p = 0.0013$$ n = 14 , R 2 = 0.6 , p = 0.0013 ). Ultra-high resolution achieved by the model enable physiological assessment in complex lesions and quantify hemodynamic metrics in all vessels up to 1mm in diameter. Importantly, we demonstrate that in contrast to traditional pressure-based metrics, there is a significant difference in the intracoronary hemodynamic forces, such as ESS, in complex lesions compared to simple lesions at both resting and hyperemic physiological states [n = 14, $$p=0.03$$ p = 0.03 ]. Higher ESS was observed in the complex lesion group ($$7.0\pm 4.7$$ 7.0 ± 4.7 Pa) than in simple lesion group ($$4.8\pm 3.6$$ 4.8 ± 3.6 Pa). Complex coronary lesions have higher ESS compared to simple lesions, such differential hemodynamic evaluation can provide much the needed insight into the increase in adverse outcomes for such patients and has incremental prognostic value over traditional pressure-based indices, such as FFR.

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Section: Resultsmentioning

confidence: 99%

Non-invasive characterization of complex coronary lesions

Vardhan

Gounley

Chen

et al. 2021

Sci Rep

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“…Този модел позволява експериментално установяване и математическо представяне на съотношенията между големината на кръвоснабдявания орган (тяло), площта на напречното сечение на началната и дисталната част на васкулатурата, нейната дължина, брой разклонения, общ обем, транзиторно време на кръвта, обем на пренасяния флуид -в случая кръвта и т.н. [5]. Всички тези зависимости могат да бъдат представени като степенни уравнения и въпреки известните междувидови и възрастови различия, те са значително сходни между различните видове бозайници и човека.…”

Section: значение на познаването на фракталната структура на съдоветеunclassified

Fractal structure of cardiovascular system

Gatzov¹

2021

ICF

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The structure of different systems, aiming to supply a volume of definite tissue with a specific fluid, which is for example the blood in the vascular system, obeys on similar lows, which can be expressed by mathematical equations. Those systems have fractal structure, that means every small part of the system repeats the structure of entire system. Knowing those dependencies permits calculation of one particular parameter of cardiovascular system, for example, the amount of myocardium on the basis of diameter of coronary artery supplying it. This approach is extremely applicable to the patients with coronary artery disease, where the amount of ischemic myocardium is of paramount importance for the patient`s fate. The aim of the current review is to present the main interdependencies between anatomical and physiological parameters of cardiovascular system.

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“…Clearly, since we only admit nonnegative diagonal tensor fields c = c(x), (22) is uniformly elliptic and it has solutions unique up to an additive constant. The energy functional (16) needs to be updated as…”

Section: Murray's Law For the Continuum Limit Model On Rectangular Gridsmentioning

confidence: 99%

“…Murray's law is a basic physical principle for transportation networks which predicts the thickness or conductivity of branches, such that the cost for transport and maintenance of the transport medium is minimized. This law is observed in the vascular and respiratory systems of animals, xylem in plants, and the respiratory system of insects [18,16]. It is also a powerful biomimetics design tool in engineering and has been applied in the design of microfluidic devices, self-healing materials, batteries, photocatalysts, and gas sensors; see, e.g., Refs.…”

Section: Introductionmentioning

confidence: 99%

Murray’s law for discrete and continuum models of biological networks

Haškovec

Markowich

Pilli

2019

Math. Models Methods Appl. Sci.

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We demonstrate the validity of Murray's law, which represents a scaling relation for branch conductivities in a transportation network, for discrete and continuum models of biological networks. We first consider discrete networks with general metabolic coefficient and multiple branching nodes and derive a generalization of the classical 3/4-law. Next we prove an analogue of the discrete Murray's law for the continuum system obtained in the continuum limit of the discrete model on a rectangular mesh. Finally, we consider a continuum model derived from phenomenological considerations and show the validity of the Murray's law for its linearly stable steady states.

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Scaling Laws of Flow Rate, Vessel Blood Volume, Lengths, and Transit Times With Number of Capillaries

Cited by 17 publications

References 41 publications

Non-invasive characterization of complex coronary lesions

Non-invasive characterization of complex coronary lesions

Fractal structure of cardiovascular system

Murray’s law for discrete and continuum models of biological networks

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