Enterprise AI Analysis
Drug-induced gastrointestinal toxicity and barrier integrity: cytoskeleton-mediated impairment in a clinically relevant human intestinal epithelium model
Drug-induced gastrointestinal (GI) toxicity is common, dose-limiting and difficult to predict using conventional Caco-2-based assays that lack physiological relevance. Here we evaluate a transepithelial electrical resistance (TEER) assay using nontransformed human intestinal epithelial cells (hIECs), derived from human pluripotent stem cells, which superiorly recapitulated epithelial diversity and polarity as well as intestinal barrier function. Across 17 clinically relevant compounds (cell cycle inhibitors, tyrosine kinase inhibitors and nonsteroidal anti-inflammatory drugs), the hIEC TEER assay outperformed ATP cell viability assays, and the Caco-2 TEER assay (AUC of 0.96 for hIEC TEER, 0.72 for Caco-2 TEER and ≤0.69 for cell viability assays) correlated with integrated GI toxicity scores using a ≥50% TEER reduction cutoff (sensitivity 92%, specificity 100% and accuracy 94%). Drug exposure was quantified by calculating the margin of safety (IC15:Cmax) and a lumen-surrogate margin of safety for oral agents. For mechanistic insight, transcriptomic analysis using representative chemotherapeutics (paclitaxel and docetaxel) showed the downregulation of cytoskeleton-related pathways, including cytoskeleton in muscle cells, cell adhesion molecules and extracellular matrix-receptor interaction, linking microtubule-targeting chemotherapy to intestinal barrier impairment. This platform provides a robust tool that combines predictive accuracy with the evaluation of cytoskeleton-mediated barrier impairment, enabling the early identification of drug-induced GI toxicity.
Executive Impact & Key Metrics
Our analysis of the hIEC model for drug-induced GI toxicity reveals superior predictive accuracy (94%) compared to traditional methods, with an AUC of 0.96. This platform offers enhanced sensitivity for early detection of intestinal barrier impairment, crucial for reducing clinical trial failures and improving drug development efficiency.
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Overall Accuracy for GI Toxicity Prediction (hIEC TEER)
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AUC for hIEC TEER Assay
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Sensitivity at ≥50% TEER Reduction Cutoff
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Specificity at ≥50% TEER Reduction Cutoff
Deep Analysis & Enterprise Applications
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Enhanced Predictive Accuracy
94%
Overall Accuracy for GI Toxicity Prediction (hIEC TEER)
| Assay Type | AUC Value | Key Advantage |
|---|---|---|
| hIEC TEER Assay | 0.96 |
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| Caco-2 TEER Assay | 0.72 |
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| ATP Cell Viability Assays | ≤0.69 |
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Cytoskeleton-Mediated Impairment Mechanism
Enterprise Process Flow
Chemotherapeutic Drug Exposure
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Downregulation of Cytoskeleton-Related Pathways
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Impaired Cell Adhesion & ECM Interaction
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Intestinal Barrier Impairment
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Drug-Induced GI Toxicity
Model Validation & Physiological Relevance
hIECs demonstrate 'Moderate integrity' TEER (129.6 ± 40.9 Ω·cm²)
Mimics in vivo intestinal TEER (50-100 Ω·cm²), unlike Caco-2 (695.7 ± 126.1 Ω·cm²)
Enhanced ROS Detection in hIECs
The hIEC model demonstrates low baseline ROS levels and dose-dependent increases in response to drugs like paclitaxel, cyclophosphamide, and gefitinib. This provides a clear signal for assessing ROS-mediated cytotoxicity and predicting GI toxicity, unlike Caco-2 cells which have inherently high baseline ROS, limiting sensitivity.
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Estimated Annual Cost Savings
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