Three‐Dimensional Humanized Model of the Periodontal Gingival Pocket to Study Oral Microbiome

The oral cavity contains distinct microenvironments that serve as oral barriers, such as the non‐shedding surface of the teeth (e.g., enamel), the epithelial mucosa and gingival tissue (attached gingiva) where microbial communities coexist. The interactions and balances between these communities are...

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Bibliographic Details
Published in:Advanced science 2023-04, Vol.10 (12), p.e2205473-n/a
Main Authors: Adelfio, Miryam, Martin‐Moldes, Zaira, Erndt‐Marino, Joshua, Tozzi, Lorenzo, Duncan, Margaret J., Hasturk, Hatice, Kaplan, David L., Ghezzi, Chiara E.
Format: Article
Language:English
Subjects:
Adult
Biopolymers
Collagen
Connective tissue
Disease
Gingiva
Gingival Pocket
Gingivitis
Homeostasis
host‐pathogen interactions
Humans
Hypoxia
Medical equipment
Metabolism
microbiome
Microbiota
nanomanufacturing
Pathogens
Periodontal Diseases
Proteins
Silk
Teeth
tissue model
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Summary:The oral cavity contains distinct microenvironments that serve as oral barriers, such as the non‐shedding surface of the teeth (e.g., enamel), the epithelial mucosa and gingival tissue (attached gingiva) where microbial communities coexist. The interactions and balances between these communities are responsible for oral tissue homeostasis or dysbiosis, that ultimately dictate health or disease. Disruption of this equilibrium can lead to chronic inflammation and permanent tissue damage in the case of chronic periodontitis. There are currently no experimental tissue models able to mimic the structural, physical, and metabolic conditions present in the human oral gingival tissue to support the long‐term investigation of host–pathogens imbalances. Herein, the authors report an in vitro 3D anatomical gingival tissue model, fabricated from silk biopolymer by casting a replica mold of an adult human mandibular gingiva to recreate a tooth‐gum unit. The model is based on human primary cultures that recapitulate physiological tissue organization, as well as a native oxygen gradient within the gingival pocket to support human subgingival plaque microbiome with a physiologically relevant level of microbial diversity up to 24 h. The modulation of inflammatory markers in the presence of oral microbiome indicates the humanized functional response of this model and establishes a new set of tools to investigate host–pathogen imbalances in gingivitis and periodontal diseases. The authors report an in vitro 3D anatomical gingival tissue model, based on silk and collagen proteins. The model recapitulates physiological tissue organization and a native oxygen gradient to support human oral human microbiome with a physiologically relevant microbial diversity. The modulation of inflammatory markers indicates the humanized functional response of this model, as a tool to investigate host–pathogen interactions.
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202205473