Organoids and Their Use in Modeling Gut Epithelial Cell Lineage Differentiation and Barrier Properties During Intestinal Diseases

Gómez, D Pupo; Boudreau, François

doi:10.3389/fcell.2021.732137

Cited by 10 publications

(8 citation statements)

References 85 publications

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“…Immortalized intestinal epithelial cell lines and intestinal crypt organoid cultures are often used for in vitro disease modeling. , However, the data obtained from such models often do not correlate with those observed in an in vivo system. Hence, we employed the ex vivo culture of the colon tissue in an in vitro environment to offer a better representation of our disease model (Figure A).…”

Section: Resultsmentioning

confidence: 99%

Hyaluronic Acid-Conjugated Thermoresponsive Polymer-Based Bioformulation Enhanced Wound Healing and Gut Barrier Repair of a TNBS-Induced Colitis Injury Ex Vivo Model in a Dynamic Perfusion Device

Mairal,

Mehrotra,

Kumar

et al. 2024

ACS Appl. Mater. Interfaces

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Impairment of intestinal epithelium is a typical feature of inflammatory bowel disease (IBD) that causes leakage of bacteria and antigens from the intestinal lumen and thus results in persistent immune activation. Hence, healing and regeneration of the damaged gut mucosa is a promising therapeutic approach to achieve deep remission in IBD. Currently, available systemic therapies have moderate effects and are often associated with numerous side effects and malignancies. In this study, we aimed to develop a topical therapy by chemically conjugating a temperature-responsive polymer, i.e., poly(N-isopropylacrylamide), along with hyaluronic acid to obtain a sprayable therapeutic formulation that upon colon instillation adheres to the damaged gut mucosa due to its temperature-induced phase transition and mucoadhesive properties. An ex vivo adhesion experiment demonstrates that this therapeutic formulation forms a thin physical coating on the mucosal lining at a physiological temperature within 5 min. Physicochemical characterization of (P(NIPAM-co-NTBAM)-HA) established this formulation to be biocompatible, hemocompatible, and non-immunogenic. Prednisolone was encapsulated within the polymer formulation to achieve maximum therapeutic efficacy in the case of IBD-like conditions as assessed in a custom-fabricated perfusion-based ex vivo model system. Histological analysis suggests that the prednisolone-encapsulated polymer formulation nearly restored the mucosal architecture after 2,4,6trinitrobenzenesulfonic acid-induced damage. Furthermore, a significant (p ≤ 0.001) increase in mRNA levels of Muc-2 and ZO-1 in treated groups further confirmed the mucosal epithelial barrier restoration.

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Section: Resultsmentioning

confidence: 99%

Hyaluronic Acid-Conjugated Thermoresponsive Polymer-Based Bioformulation Enhanced Wound Healing and Gut Barrier Repair of a TNBS-Induced Colitis Injury Ex Vivo Model in a Dynamic Perfusion Device

Mairal,

Mehrotra,

Kumar

et al. 2024

ACS Appl. Mater. Interfaces

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“…Organoids have been an invaluable resource for the modeling and investigation of the human intestinal system (Corro et al., 2020). A key aspect of the native intestinal system is the barrier function of the intestinal epithelium, which safeguards against microorganisms and infectious agents while managing nutrient, water, and small molecule absorption and transport (Gomez & Boudreau, 2021). Therefore, creating a physiologically relevant human intestine model necessitates accurate representation of barrier function and nutrient absorption.…”

Section: Commentarymentioning

confidence: 99%

Impact of Micro‐ and Nano‐Plastics on Human Intestinal Organoid‐Derived Epithelium

Wang,

Iglesias‐Ledon,

Bishop

et al. 2024

Current Protocols

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The development of patient‐derived intestinal organoids represents an invaluable model for simulating the native human intestinal epithelium. These stem cell‐rich cultures outperform commonly used cell lines like Caco‐2 and HT29‐MTX in reflecting the cellular diversity of the native intestinal epithelium after differentiation. In our recent study examining the effects of polystyrene (PS), microplastics (MPs), and nanoplastics (NPs), widespread pollutants in our environment and food chain, on the human intestinal epithelium, these organoids have been instrumental in elucidating the absorption mechanisms and potential biological impacts of plastic particles. Building on previously established protocols in human intestinal organoid culture, we herein detail a streamlined protocol for the cultivation, differentiation, and generation of organoid‐derived monolayers. This protocol is tailored to generate monolayers incorporating microfold cells (M cells), key for intestinal particle uptake but often absent in current in vitro models. We provide validated protocols for the characterization of MPs/NPs via scanning electron microscopy (SEM) for detailed imaging and their introduction to intestinal epithelial monolayer cells via confocal immunostaining. Additionally, protocols to test the impacts of MP/NP exposure on the functions of the intestinal barrier using transendothelial electrical resistance (TEER) measurements and assessing inflammatory responses using cytokine profiling are detailed. Overall, our protocols enable the generation of human intestinal organoid monolayers, complete with the option of including or excluding M cells, offering crucial techniques for observing particle uptake and identifying inflammatory responses in intestinal epithelial cells to advance our knowledge of the potential effects of plastic pollution on human gut health. These approaches are also amendable to the study of other gut‐related chemical and biological exposures and physiological responses due to the robust nature of the systems. © 2024 Wiley Periodicals LLC.Basic Protocol 1: Human intestinal organoid culture and generation of monolayers with and without M cellsSupport Protocol 1: Culture of L‐WRN and production of WRN‐conditioned mediumSupport Protocol 2: Neuronal cell culture and integration into intestinal epitheliumSupport Protocol 3: Immune cell culture and integration into intestinal epitheliumBasic Protocol 2: Scanning electron microscopy: sample preparation and imagingBasic Protocol 3: Immunostaining and confocal imaging of MP/NP uptake in organoid‐derived monolayersBasic Protocol 4: Assessment of intestinal barrier function via TEER measurementsBasic Protocol 5: Cytokine profiling using ELISA post‐MP/NP exposure.

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“… 59,67 The advantage of these cells is that they can be extracted from different intestine sections and grown into polarized and differentiated epithelial cell lineages. 68 Intestinal organoids can also be acquired from pluripotent stem cells, by either reprogramming adult stem cells of various organs or from embryonic stem cells, 37,68 thus circumventing the invasive deep-body biopsies. In addition to epithelium, various cell models are available for endothelial cells such as human umbilical vein endothelial cells (HUVECs) or human intestinal microvascular endothelial cells (HIMECs), and for immune cells such as human peripheral blood mononuclear cells (PBMCs).…”

Section: The On-chip Implementation Of Gut Physiologymentioning

confidence: 99%

Gut-on-a-chip models for dissecting the gut microbiology and physiology

2023

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Microfluidic technologies have been extensively investigated in recent years for developing organ-on-a-chip-devices as robust in vitro models aiming to recapitulate organ 3D topography and its physicochemical cues. Among these attempts, an important research front has focused on simulating the physiology of the gut, an organ with a distinct cellular composition featuring a plethora of microbial and human cells that mutually mediate critical body functions. This research has led to innovative approaches to model fluid flow, mechanical forces, and oxygen gradients, which are all important developmental cues of the gut physiological system. A myriad of studies has demonstrated that gut-on-a-chip models reinforce a prolonged coculture of microbiota and human cells with genotypic and phenotypic responses that closely mimic the in vivo data. Accordingly, the excellent organ mimicry offered by gut-on-a-chips has fueled numerous investigations on the clinical and industrial applications of these devices in recent years. In this review, we outline various gut-on-a-chip designs, particularly focusing on different configurations used to coculture the microbiome and various human intestinal cells. We then elaborate on different approaches that have been adopted to model key physiochemical stimuli and explore how these models have been beneficial to understanding gut pathophysiology and testing therapeutic interventions.

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Organoids and Their Use in Modeling Gut Epithelial Cell Lineage Differentiation and Barrier Properties During Intestinal Diseases

Cited by 10 publications

References 85 publications

Hyaluronic Acid-Conjugated Thermoresponsive Polymer-Based Bioformulation Enhanced Wound Healing and Gut Barrier Repair of a TNBS-Induced Colitis Injury Ex Vivo Model in a Dynamic Perfusion Device

Hyaluronic Acid-Conjugated Thermoresponsive Polymer-Based Bioformulation Enhanced Wound Healing and Gut Barrier Repair of a TNBS-Induced Colitis Injury Ex Vivo Model in a Dynamic Perfusion Device

Impact of Micro‐ and Nano‐Plastics on Human Intestinal Organoid‐Derived Epithelium

Gut-on-a-chip models for dissecting the gut microbiology and physiology

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