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Related Concept Videos

Toxicity Testing in Animals01:23

Toxicity Testing in Animals

Toxicity tests in animals are grounded on two main assumptions: first, the effects observed in laboratory animals can be extrapolated to humans, especially when adjusted for body surface area; second, high-dose exposure in animals is essential to identify potential human hazards from lower doses. This is based on the quantal dose-response concept, which faces the challenge of extrapolating results from relatively few test animals to much larger human populations. For example, a 0.01% incidence...
Toxicokinetics: Overview01:21

Toxicokinetics: Overview

Studies that assess how a drug is absorbed, distributed, metabolized, and excreted (ADME) at toxic doses are termed toxicokinetics. Understanding toxicokinetics helps predict adverse drug reactions (ADRs) and manage toxicity in humans.Toxicokinetics differs from pharmacokinetics mainly in the dose levels studied, with toxicokinetics focusing on higher toxic doses. The kinetics at these levels can be non-linear due to altered physiological processes. Toxicodynamics examines the relationship...
Drug Toxicity: Overview01:00

Drug Toxicity: Overview

Drug toxicity quantifies the harm a compound causes to an organism, varying by dose and potentially impacting whole systems or specific organs like the liver. Toxic reactions may arise from venomous insect or spider bites, with effects ranging from mild symptoms to severe outcomes such as brain damage or death. Common forms of acute poisoning include ethanol intoxication and overdose of pain or fever medications, with substances like GHB and heroin being particularly lethal at doses close to...
Toxic Reactions: Overview01:26

Toxic Reactions: Overview

When toxic substances penetrate the human body, they disseminate to various tissues, undergoing metabolic changes. This process yields reactive metabolites that may covalently bind with specific target molecules, resulting in toxicity.
Toxicity falls into two primary categories: local and systemic.
Local toxicity appears at the exposure site, such as protein denaturation caused by caustic substances.
In contrast, systemic toxicity requires the toxic agent's absorption and distribution,...

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Updated: Jun 9, 2026

The Multi-organ Chip - A Microfluidic Platform for Long-term Multi-tissue Coculture
10:05

The Multi-organ Chip - A Microfluidic Platform for Long-term Multi-tissue Coculture

Published on: April 28, 2015

Organ-on-a-chip toxicology.

Sheng Yang1,2,3, Tianyi Zhang1,2,3, Yiling Ge1,2

  • 1Key Laboratory of Environmental Medicine Engineering, Ministry of Education, School of Public Health, Southeast University, Nanjing, Jiangsu 210009, China.

Innovation (Cambridge (Mass.))
|June 8, 2026
PubMed
Summary
This summary is machine-generated.

Organ-on-a-chip toxicology (OCT) offers a new paradigm for toxicity testing, moving beyond animal models. This approach uses advanced engineering and AI to provide human-relevant, predictive insights for drug safety and health risk assessment.

Keywords:
biomedical microdevicesinnovative applicationorgan-on-a-chip toxicologyregulatory toxicologytoxicity mechanisms

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Last Updated: Jun 9, 2026

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Published on: April 28, 2015

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Published on: March 4, 2021

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08:59

An Intestine/Liver Microphysiological System for Drug Pharmacokinetic and Toxicological Assessment

Published on: December 3, 2020

Area of Science:

  • Toxicology
  • Bioengineering
  • Biomedical Research

Background:

  • Traditional toxicology methods using animal models and simple cell cultures lack human relevance and predictive accuracy.
  • Organ-on-a-chip (OoC) technology reconstructs human organ functions for improved toxicity testing but is often viewed as a platform, not a discipline.
  • A need exists for a unified framework to elucidate toxicity mechanisms and improve human health risk assessments.

Purpose of the Study:

  • To propose organ-on-a-chip toxicology (OCT) as a distinct interdisciplinary research paradigm.
  • To establish a unified framework for understanding toxicity at molecular, cellular, and organ levels.
  • To highlight OCT's potential for revolutionizing toxicological assessment and reducing animal testing.

Main Methods:

  • Integrating advanced bioengineering and microfluidic systems with organoid technology for enhanced cellular fidelity.
  • Developing comprehensive systemic toxicity models that include ADME pathways and inter-organ communication.
  • Utilizing AI-driven data analytics for precise interpretation of toxicological data.

Main Results:

  • OCT provides a human-centric approach to toxicity testing, offering predictive insights into drug safety and environmental hazards.
  • The framework enables elucidation of toxicity mechanisms across multiple biological levels.
  • OCT facilitates personalized toxicology, environmental hazard assessment, and food safety evaluations.

Conclusions:

  • Organ-on-a-chip toxicology (OCT) represents a paradigm shift, integrating engineering and biological sciences for more accurate and ethical toxicity assessment.
  • OCT has the potential to significantly reduce reliance on animal testing while improving the precision of human health risk evaluations.
  • Addressing challenges in standardization and regulatory acceptance is crucial for the widespread adoption of OCT in global health risk assessments.