Numerical Flow Simulations of the Shear Stress Forces Arising in Filtration Slits during Glomerular Filtration in Rat Kidney.

IF 10.3 1区医学 Q1 UROLOGY & NEPHROLOGY

Journal of The American Society of Nephrology Pub Date : 2024-09-30 DOI:10.1681/ASN.0000000513

Alexander Fuhrmann, Balazs Pritz, Karlhans Endlich, Wilhelm Kriz

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Abstract

Background: The flow dynamic forces during glomerular filtration challenging the fixation of podocytes to the GBM are insufficiently understood.

Methods: Numerical flow simulations were used to estimate these forces in the rat kidney. Simulations were run with a 3D model of the slit diaphragm as a zipper structure according to Rodewald and Karnovsky 1. The GBM was modeled as a porous medium.

Results: Filtrate flow exerted a mean wall shear stress of 39 Pa with a maximum of 152 Pa on the plasma membrane of foot processes and up to 250 Pa on internal surfaces of the slit diaphragm. The slit diaphragm accounted for 25% of the hydrodynamic resistance of the glomerular filtration barrier. Based on the results of the 3D model, we developed a 2D model that allowed us to perform extensive parameter variations. Reducing the filtration slit width from 40 to 30 nm almost doubled wall shear stress. Furthermore, increasing filtrate flow velocity by 50% increased wall shear stress by 47%. When increasing the viscous resistance of the slit diaphragm, the pressure drop across the slit diaphragm increased to intolerably high values. A lower viscous resistance of the slit diaphragm than that of the GBM accounted for a gradual pressure decline along the filtration barrier. The sub-podocyte space tempered these challenges in circumscribed areas of filtration surface but had only a marginal impact on overall forces.

Conclusions: The filtration barrier experiences high levels of shear and pressure stress accounting for the detachment of injured but viable podocytes from the GBM--a hallmark in many glomerular diseases.

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大鼠肾小球滤过过程中滤过狭缝中产生的剪切应力力的数值流动模拟

背景：人们对肾小球滤过过程中挑战荚膜细胞固定到 GBM 的流动动力了解不足：方法：使用数值流动模拟来估算大鼠肾脏中的这些力。根据罗德瓦尔德（Rodewald）和卡尔诺夫斯基（Karnovsky）1 的观点，模拟运行的裂隙隔膜三维模型为拉链结构。GBM 被模拟为多孔介质：结果：滤液流产生的平均壁剪应力为 39 Pa，脚过程的质膜上的最大剪应力为 152 Pa，裂隙隔膜内表面的最大剪应力为 250 Pa。裂隙隔膜占肾小球滤过屏障流体动力阻力的 25%。根据三维模型的结果，我们开发了一个二维模型，可以进行大量的参数变化。将滤过狭缝宽度从 40 纳米减少到 30 纳米几乎使壁剪应力增加了一倍。此外，将滤液流速提高 50%，壁面剪切应力也增加了 47%。当增加狭缝隔膜的粘滞阻力时，穿过狭缝隔膜的压降增加到难以容忍的高值。狭缝隔膜的粘滞阻力低于 GBM 的粘滞阻力，导致压力沿过滤屏障逐渐下降。在过滤表面的限定区域，结节细胞下空间缓解了这些挑战，但对总体压力的影响微乎其微：结论：滤过屏障承受着高水平的剪切力和压力应力，这是许多肾小球疾病的特征之一，也是受伤但存活的荚膜细胞从 GBM 上脱落的原因。

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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来源期刊

Journal of The American Society of Nephrology 医学-泌尿学与肾脏学

CiteScore

22.40

自引率

2.90%

发文量

492

审稿时长

3-8 weeks

期刊介绍： The Journal of the American Society of Nephrology (JASN) stands as the preeminent kidney journal globally, offering an exceptional synthesis of cutting-edge basic research, clinical epidemiology, meta-analysis, and relevant editorial content. Representing a comprehensive resource, JASN encompasses clinical research, editorials distilling key findings, perspectives, and timely reviews. Editorials are skillfully crafted to elucidate the essential insights of the parent article, while JASN actively encourages the submission of Letters to the Editor discussing recently published articles. The reviews featured in JASN are consistently erudite and comprehensive, providing thorough coverage of respective fields. Since its inception in July 1990, JASN has been a monthly publication. JASN publishes original research reports and editorial content across a spectrum of basic and clinical science relevant to the broad discipline of nephrology. Topics covered include renal cell biology, developmental biology of the kidney, genetics of kidney disease, cell and transport physiology, hemodynamics and vascular regulation, mechanisms of blood pressure regulation, renal immunology, kidney pathology, pathophysiology of kidney diseases, nephrolithiasis, clinical nephrology (including dialysis and transplantation), and hypertension. Furthermore, articles addressing healthcare policy and care delivery issues relevant to nephrology are warmly welcomed.