Epidermis-on-a-chip system to develop skin barrier and melanin mimicking model

Li, Qiwei; Wang, Chunyan; Li, Xiaoran; Zhang, Jing; Zhang, Zilin; Yang, Keyu; Ouyang, Jun; Zha, Shaohui; Sha, Lifeng; Ge, Jianjun; Chen, Zaozao; Gu, Zhongze

doi:10.1177/20417314231168529

Cited by 11 publications

(1 citation statement)

References 50 publications

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“…Besides supporting a continuous nutrient supply and waste removal, dynamic perfusion potentially generates shear stresses and mechano-transduction mediated induction of fibroblast function, [38,39] keratinocyte maturation and modulation of epithelial barrier function. [40][41][42] Owing to the static nature of gingiva-insert cultures, the nutrient transport to the cells within the 3D matrix is purely diffusive. In contrast, the perfusion of media and moist air through the Figure 6.…”

Section: Discussionmentioning

confidence: 99%

Microphysiological Modeling of Gingival Tissues and Host‐Material Interactions Using Gingiva‐on‐Chip

Muniraj,

Tan,

Dai

et al. 2023

Adv Healthcare Materials

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Gingiva plays a crucial barrier role at the interface of teeth, tooth‐supporting structures, microbiome, and external agents. To mimic this complex microenvironment, we developed an in vitro microphysiological platform and biofabricated full‐thickness gingival equivalents (gingiva‐on‐chip) within a vertically‐stacked microfluidic device. This design allowed long‐term and air‐liquid interface culture, and host‐material interactions under flow conditions. Compared to static cultures, dynamic cultures on‐chip enabled the biofabrication of gingival equivalents with stable mucosal matrix, improved epithelial morphogenesis, and barrier features. Additionally, a diseased state with disrupted barrier function representative of gingival/oral mucosal ulcers was modeled. The apical flow feature was utilized to emulate the mechanical action of mouth rinse and integrate the assessment of host‐material interactions and transmucosal permeation of oral‐care formulations in both health and diseased states. Although the gingiva‐on‐chip cultures had thicker and more mature epithelium, the flow of oral‐care formulations induced increased tissue disruption and cytotoxic features compared to static conditions. The realistic emulation of mouth rinsing action facilitated a more physiological assessment of mucosal irritation potential. Overall, this microphysiological system enables biofabrication of human gingiva equivalents in intact and ulcerated states, providing a miniaturized and integrated platform for downstream host‐material and host‐microbiome applications in gingival and oral mucosa research.This article is protected by copyright. All rights reserved

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Section: Discussionmentioning

confidence: 99%

Microphysiological Modeling of Gingival Tissues and Host‐Material Interactions Using Gingiva‐on‐Chip

Muniraj,

Tan,

Dai

et al. 2023

Adv Healthcare Materials

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Rapid and Controllable Multilayer Cell Sheet Assembly via Biodegradable Nanochannel Membranes

Yang,

Rathnam,

Hou

et al. 2024

Adv Funct Materials

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The ability to precisely arrange and control the assembly of diverse cell types into intricate 3D structures remains a critical challenge in tissue engineering. Herein, a versatile and programmable 3D cell sheet assembly is described technology by developing a biodegradable nanochannel (BNC) membrane to fulfill this unmet need. This membrane, hierarchically assembled from 2D nanomaterial aggregates, exhibits both exceptional fluid permeability and rapid biodegradation under physiological conditions. The unique properties of the BNC membrane enable precise spatial and temporal control over cell assembly, facilitating the creation of complex 3D cellular architectures. The BNC membrane is integrated with a programmable negative‐pressure‐based cell assembly strategy to form single and multicellular 3D sheets in a highly controllable manner. To demonstrate the feasibility and translatability of this technology in the field of tissue engineering approaches to screen stem cell‐derived therapeutics with “core–shell” macrophage‐fibroblast multicellular patterns and treat murine diabetic skin wounds via scaffold‐free 3D adipose‐derived mesenchymal stem cell (ADMSC) sheets are devised. In summary, the results demonstrate that the BNC membrane‐based 3D cell sheet assembly approach significantly advances current tissue engineering capabilities, offering substantial potential for both regenerative medicine applications and the development of physiologically relevant disease models.

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Environmentally Controlled Microfluidic System Enabling Immune Cell Flow and Activation in an Endothelialised Skin‐On‐Chip

Michielon,

Boninsegna,

Waaijman

et al. 2024

Adv Healthcare Materials

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Integration of reconstructed human skin (RhS) into organ‐on‐chip (OoC) platforms addresses current limitations imposed by static culturing. This innovation, however, is not without challenges. Microfluidic devices, while powerful, often encounter usability, robustness, and gas bubble issues that hinder large‐scale high‐throughput setups. This study aims to develop a novel re‐usable multi‐well microfluidic adaptor (MMA) with the objective to provide a flexible tool for biologists implementing complex 3D biological models (e.g., skin) while enabling simultaneous user control over temperature, medium flow, oxigen (O2), nitrogen (N2), and carbon dioxide (CO2) without the need for an incubator. The presented MMA device is designed to be compatible with standard, commercially available 6‐well multi‐well plates (6MWPs) and 12‐well transwells. This MMA‐6MWP setup is employed to generate a skin‐on‐chip (SoC). RhS viability is maintained under flow for three days and their morphology closely resembles that of native human skin. A proof‐of‐concept study demonstrates the system's potential in toxicology applications by combining endothelialised RhS with flowing immune cells. This dynamic setting activates the monocyte‐like MUTZ‐3 cells (CD83 and CD86 upregulation) upon topical exposure of RhS to a sensitizer, revealing the MMA‐6MWP's unique capabilities compared to static culturing, where such activation is absent.

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Epidermis-on-a-chip system to develop skin barrier and melanin mimicking model

Cited by 11 publications

References 50 publications

Microphysiological Modeling of Gingival Tissues and Host‐Material Interactions Using Gingiva‐on‐Chip

Microphysiological Modeling of Gingival Tissues and Host‐Material Interactions Using Gingiva‐on‐Chip

Rapid and Controllable Multilayer Cell Sheet Assembly via Biodegradable Nanochannel Membranes

Environmentally Controlled Microfluidic System Enabling Immune Cell Flow and Activation in an Endothelialised Skin‐On‐Chip

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