An innovative in silico model of the oral mucosa reveals the impact of extracellular spaces on chemical permeation through epithelium

Sean M. Edwards, Amy L. Harding, Joseph A. Leedale, Steve D. Webb, Helen E. Colley, Craig Murdoch, Rachel N. Bearon
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Abstract

In pharmaceutical therapeutic design or toxicology, accurately predicting the permeation of chemicals through human epithelial tissues is crucial, where permeation is significantly influenced by the tissue's cellular architecture. Current mathematical models for multi-layered epithelium such as the oral mucosa only use simplistic 'bricks and mortar' geometries and therefore do not account for the complex cellular architecture of these tissues at the microscale level, such as the extensive plasma membrane convolutions that define the extracellular spaces between cells. Chemicals often permeate tissues via this paracellular route, meaning that permeation is underestimated. To address this, measurements of human buccal mucosal tissue were conducted to ascertain the width and tortuosity of extracellular spaces across the epithelium. Using mechanistic mathematical modelling, we show that the convoluted geometry of extracellular spaces significantly impacts chemical permeation and that this can be approximated, provided that extracellular tortuosity is accounted for. We next developed an advanced physically-relevant in silico model of oral mucosal chemical permeation using partial differential equations, fitted to chemical permeation in vitro assays on tissue-engineered human oral mucosa. Tissue geometries were measured and captured in silico, and permeation examined and predicted for chemicals with different physicochemical properties. The effect of altering the extracellular space to mimic permeation enhancers was also assessed by perturbing the in silico model. This novel in vitro-in silico approach has the potential to expedite pharmaceutical innovation for testing oromucosal chemical permeation, providing a more accurate, physiologically-relevant model which can reduce animal testing with early screening based on chemical properties.
创新的口腔黏膜硅学模型揭示了细胞外空间对上皮细胞化学渗透的影响
在药物治疗设计或毒理学研究中,准确预测化学品在人体上皮组织中的渗透率至关重要,因为渗透率在很大程度上受到组织细胞结构的影响。目前针对口腔粘膜等多层上皮的数学模型只使用了简单的 "砖块和灰泥 "几何结构,因此没有考虑到这些组织在微观层面上的复杂细胞结构,例如细胞之间限定细胞外空间的广泛浆膜褶皱。化学品通常通过这种细胞旁途径渗透到组织中,这意味着渗透率被低估了。为了解决这个问题,我们对人类颊粘膜组织进行了测量,以确定上皮细胞外空间的宽度和迂回程度。通过使用机械数学模型,我们发现细胞外空隙迂曲的几何形状会对化学渗透产生重大影响,只要考虑到细胞外空隙的迂曲度,就可以近似地计算出这一影响。接下来,我们利用偏微分方程建立了一个先进的口腔黏膜化学渗透物理相关硅学模型,并将其与体外对组织工程人体口腔黏膜进行的化学渗透试验进行了拟合。在硅学中测量和捕捉了组织的几何形状,并对具有不同物理化学特性的化学物质的渗透性进行了检验和预测。通过扰动硅学模型,还评估了改变细胞外空间以模拟渗透增强剂的效果。这种新颖的无创硅学方法有可能加快测试口腔黏膜化学渗透的制药创新,它提供了一个更准确、更符合生理的模型,可以减少动物试验,根据化学特性进行早期筛选。
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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