A Precise Scale-Up Method to Predict Particle Delivered Dose in a Human Respiratory System Using Rat Deposition Data: An In Silico Study

Hamideh Hayati, Yu Feng
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引用次数: 2

Abstract

As surrogates to human beings, rats are used occasionally to study the therapeutic impact of inhaled pulmonary drug particles in microscale. To speculate human responses from rat studies, scale-up factors are widely used to extrapolate particle lung deposition from rat to human. However, available scale-up methods are highly simplified and not accurate, because they directly use the human-to-rat ratios of body weights (RBW) or lung surface areas (RSA) as the scale-up factor. To find a precise scale-up strategy, an experimentally validated Computational Fluid-Particle Dynamics (CFPD) was employed to simulate the transport and deposition of microparticles in both human and rate respiratory systems, which encompasses the pulmonary routes from mouth/nose to airways up to Generation 17 (G17) for human and G23 for the rat. Microparticles with the same range of Stk/Fr were injected into both models with the airflow at resting conditions. Numerical results indicate that particles (with the size ranging from 1 to 13 μm for humans and 0.6 to 6 μm for rat) have similar deposition pattern (DP) and deposition fraction (DF) in both models, which are resulted from both inertial impaction and gravitational sedimentation effects. A novel correlation is proposed to predict DFs in both human and rat respiratory systems as a function of the ratio of Stokes number to Froude number (Stk/Fr). Using the correlation as the novel scale-up tool, inter-species extrapolations can be precisely done on predicting particle depositions in human respiratory systems based on the deposition data in rats obtained from animal studies.
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利用大鼠沉积数据预测人体呼吸系统颗粒递送剂量的精确放大方法:一项计算机研究
作为人类的替代物,偶尔会用大鼠来研究吸入肺部药物颗粒在微观尺度上的治疗作用。为了从大鼠研究中推测人类的反应,放大因子被广泛用于推断大鼠到人的颗粒肺沉积。然而,现有的放大方法高度简化且不准确,因为它们直接使用人与大鼠的体重比(RBW)或肺表面积(RSA)作为放大因子。为了找到精确的放大策略,采用实验验证的计算流体粒子动力学(CFPD)来模拟微颗粒在人类和速率呼吸系统中的运输和沉积,包括从口/鼻到气道的肺部路径,直到人类的第17代(G17)和大鼠的第23代(G23)。在静息状态下,将Stk/Fr范围相同的微粒子注入两种模型。数值结果表明,两种模型中颗粒(人粒径为1 ~ 13 μm,大鼠粒径为0.6 ~ 6 μm)的沉积模式(DP)和沉积分数(DF)相似,这是惯性冲击和重力沉降共同作用的结果。提出了一种新的相关性来预测人类和大鼠呼吸系统的DFs,作为斯托克斯数与弗劳德数(Stk/Fr)之比的函数。利用这种相关性作为一种新的放大工具,可以根据动物研究中获得的大鼠沉积数据,精确地进行物种间外推,预测人类呼吸系统中的颗粒沉积。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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