Elijah Weber scite author profile

The kidney proximal tubule is the primary site in the nephron for excretion of waste products through a combination of active uptake and secretory processes, and is also a primary target of drug-induced nephrotoxicity. Here, we describe the development and functional characterization of a 3-dimensional flow-directed human kidney proximal tubule microphysiological system. The system replicates the polarity of the proximal tubule, expresses appropriate marker proteins, exhibits biochemical and synthetic activities, as well as secretory and reabsorptive processes associated with proximal tubule function in vivo. This microphysiological system can serve as an ideal platform for ex vivo modeling of renal drug clearance and drug-induced nephrotoxicity. Additionally, this novel system can be used for preclinical screening of new chemical compounds prior to initiating human clinical trials.

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A Quantitative Approach to Screen for Nephrotoxic Compounds In Vitro

Adler

et al. 2016

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Nephrotoxicity due to drugs and environmental chemicals accounts for significant patient mortality and morbidity, but there is no high throughput in vitro method for predictive nephrotoxicity assessment. We show that primary human proximal tubular epithelial cells (HPTECs) possess characteristics of differentiated epithelial cells rendering them desirable to use in such in vitro systems. To identify a reliable biomarker of nephrotoxicity, we conducted multiplexed gene expression profiling of HPTECs after exposure to six different concentrations of nine human nephrotoxicants. Only overexpression of the gene encoding heme oxygenase-1 (HO-1) significantly correlated with increasing dose for six of the compounds, and significant HO-1 protein deregulation was confirmed with each of the nine nephrotoxicants. Translatability of HO-1 increase across species and platforms was demonstrated by computationally mining two large rat toxicogenomic databases for kidney tubular toxicity and by observing a significant increase in HO-1 after toxicity using an ex vivo three-dimensional microphysiologic system (kidneyon-a-chip). The predictive potential of HO-1 was tested using an additional panel of 39 mechanistically distinct nephrotoxic compounds. Although HO-1 performed better (area under the curve receiver-operator characteristic curve [AUC-ROC]=0.89) than traditional endpoints of cell viability (AUC-ROC for ATP=0.78; AUC-ROC for cell count=0.88), the combination of HO-1 and cell count further improved the predictive ability (AUC-ROC=0.92). We also developed and optimized a homogenous time-resolved fluorescence assay to allow high throughput quantitative screening of nephrotoxic compounds using HO-1 as a sensitive biomarker. This cell-based approach may facilitate rapid assessment of potential nephrotoxic therapeutics and environmental chemicals. Drugs and environmental chemicals, such as aminoglycoside antibiotics, analgesics, chemotherapeutic agents, and heavy metals, as well as endemic toxins like aristolochic acid are a common cause of AKI or CKD. 1,2 Current approaches to conduct safety and risk assessment of compounds rely predominantly on animal studies, and these results are extrapolated to dose effects in humans despite knowledge that the typical responses of animal models and humans can differ greatly. 3 The lack of adequate models to accurately predict human toxicity contributes to an underestimation of the kidney toxic potential of new therapeutic candidates, which also explains why nephrotoxic effects in patients are often only detected during late phase

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Human liver-kidney model elucidates the mechanisms of aristolochic acid nephrotoxicity

Chang¹,

et al. 2017

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Human kidney on a chip assessment of polymyxin antibiotic nephrotoxicity

Weber¹,

Lidberg²,

Wang³

et al. 2018

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Technology Transfer of the Microphysiological Systems: A Case Study of the Human Proximal Tubule Tissue Chip

Sakolish

Weber

Kelly

et al. 2018

Sci Rep

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The adoption of a new technology into basic research, and industrial and clinical settings requires rigorous testing to build confidence in the reproducibility, reliability, robustness, and relevance of these models. Tissue chips are promising new technology, they have the potential to serve as a valuable tool in biomedical research, as well as pharmaceutical development with regards to testing for efficacy and safety. The principal goals of this study were to validate a previously established proximal tubule tissue chip model in an independent laboratory and to extend its utility to testing of nephrotoxic compounds. Here, we evaluated critical endpoints from the tissue chip developer laboratory, focusing on biological relevance (long-term viability, baseline protein and gene expression, ammoniagenesis, and vitamin D metabolism), and toxicity biomarkers. Tissue chip experiments were conducted in parallel with traditional 2D culture conditions using two different renal proximal tubule epithelial cell sources. The results of these studies were then compared to the findings reported by the tissue chip developers. While the overall transferability of this advanced tissue chip platform was a success, the reproducibility with the original report was greatly dependent on the cell source. This study demonstrates critical importance of developing microphysiological platforms using renewable cell sources.

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Elijah Weber

Development of a microphysiological model of human kidney proximal tubule function

A Quantitative Approach to Screen for Nephrotoxic Compounds In Vitro

Human liver-kidney model elucidates the mechanisms of aristolochic acid nephrotoxicity

Human kidney on a chip assessment of polymyxin antibiotic nephrotoxicity

Technology Transfer of the Microphysiological Systems: A Case Study of the Human Proximal Tubule Tissue Chip

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