In vitro cellular model systems provide a promising alternative to animal experiments for studying the intestine-organ axis

Alessandra Vitale; Cristiana De Musis; Marida Bimonte; Josep Rubert; Vincenzo Fogliano

doi:10.1080/07388551.2025.2452620

In vitro cellular model systems provide a promising alternative to animal experiments for studying the intestine-organ axis

Alessandra Vitale, Cristiana De Musis, Marida Bimonte, Josep Rubert, Vincenzo Fogliano^*

^*Corresponding author for this work

Research output: Contribution to journal › Literature review › peer-review

Abstract

Limiting animal experiments is essential for ethical issues and also because scientific evidence highlights the discrepancies between human and animal metabolism. This review aims to provide a critical discussion of the strengths and limitations of the most appropriate in vitro intestine model to answer complex research questions in pharmaceutical and nutraceutical fields. This review describes the components contributing to the definition of the gut barrier structure, from the outer mucus layer to the inner part of lamina propria, including endothelial and neuronal networks. We conclude that the main advantage of these co-culture models is their versatility since they are modulable systems in which each component can be added, changed, or removed to reproduce a specific physiological condition each time. Additionally, we compare intestinal organoid models and microfluidic systems with well-established co-culture models.

Original language	English
Number of pages	18
Journal	Critical Reviews in Biotechnology
DOIs	https://doi.org/10.1080/07388551.2025.2452620
Publication status	E-pub ahead of print - 5 Jan 2025

Keywords

Epithelial monolayer
Gut barrier
Gut-axis
In vitro gut model
Leaky gut
Microfluidic system
Organoids
Tight junctions’ proteins
Transepithelial electrical resistance

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10.1080/07388551.2025.2452620Licence: CC BY-NC-ND

https://edepot.wur.nl/687360Licence: CC BY-NC-ND

Cite this

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title = "In vitro cellular model systems provide a promising alternative to animal experiments for studying the intestine-organ axis",

abstract = "Limiting animal experiments is essential for ethical issues and also because scientific evidence highlights the discrepancies between human and animal metabolism. This review aims to provide a critical discussion of the strengths and limitations of the most appropriate in vitro intestine model to answer complex research questions in pharmaceutical and nutraceutical fields. This review describes the components contributing to the definition of the gut barrier structure, from the outer mucus layer to the inner part of lamina propria, including endothelial and neuronal networks. We conclude that the main advantage of these co-culture models is their versatility since they are modulable systems in which each component can be added, changed, or removed to reproduce a specific physiological condition each time. Additionally, we compare intestinal organoid models and microfluidic systems with well-established co-culture models.",

keywords = "Epithelial monolayer, Gut barrier, Gut-axis, In vitro gut model, Leaky gut, Microfluidic system, Organoids, Tight junctions{\textquoteright} proteins, Transepithelial electrical resistance",

author = "Alessandra Vitale and {De Musis}, Cristiana and Marida Bimonte and Josep Rubert and Vincenzo Fogliano",

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AU - Vitale, Alessandra

AU - De Musis, Cristiana

AU - Bimonte, Marida

AU - Rubert, Josep

AU - Fogliano, Vincenzo

PY - 2025/1/5

Y1 - 2025/1/5

N2 - Limiting animal experiments is essential for ethical issues and also because scientific evidence highlights the discrepancies between human and animal metabolism. This review aims to provide a critical discussion of the strengths and limitations of the most appropriate in vitro intestine model to answer complex research questions in pharmaceutical and nutraceutical fields. This review describes the components contributing to the definition of the gut barrier structure, from the outer mucus layer to the inner part of lamina propria, including endothelial and neuronal networks. We conclude that the main advantage of these co-culture models is their versatility since they are modulable systems in which each component can be added, changed, or removed to reproduce a specific physiological condition each time. Additionally, we compare intestinal organoid models and microfluidic systems with well-established co-culture models.

AB - Limiting animal experiments is essential for ethical issues and also because scientific evidence highlights the discrepancies between human and animal metabolism. This review aims to provide a critical discussion of the strengths and limitations of the most appropriate in vitro intestine model to answer complex research questions in pharmaceutical and nutraceutical fields. This review describes the components contributing to the definition of the gut barrier structure, from the outer mucus layer to the inner part of lamina propria, including endothelial and neuronal networks. We conclude that the main advantage of these co-culture models is their versatility since they are modulable systems in which each component can be added, changed, or removed to reproduce a specific physiological condition each time. Additionally, we compare intestinal organoid models and microfluidic systems with well-established co-culture models.

KW - Epithelial monolayer

KW - Gut barrier

KW - Gut-axis

KW - In vitro gut model

KW - Leaky gut

KW - Microfluidic system

KW - Organoids

KW - Tight junctions’ proteins

KW - Transepithelial electrical resistance

U2 - 10.1080/07388551.2025.2452620

DO - 10.1080/07388551.2025.2452620

M3 - Literature review

AN - SCOPUS:85216465196

SN - 0738-8551

JO - Critical Reviews in Biotechnology

JF - Critical Reviews in Biotechnology

ER -

In vitro cellular model systems provide a promising alternative to animal experiments for studying the intestine-organ axis

Abstract

Keywords

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