Generating Tooth Organoids Using Defined Bioorthogonally Cross-Linked Hydrogels

Xuechen Zhang; Nicola Contessi Negrini; Rita Correia; Paul T Sharpe; Adam D Celiz; Ana Angelova Volponi

doi:10.1021/acsmacrolett.4c00520

Generating Tooth Organoids Using Defined Bioorthogonally Cross-Linked Hydrogels

Xuechen Zhang, Nicola Contessi Negrini, Rita Correia, Paul T Sharpe, Adam D Celiz, Ana Angelova Volponi

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

Abstract

Generating teeth in vitro requires mimicking tooth developmental processes. Biomaterials are essential to support 3D tooth organoid formation, but their properties must be finely tuned to achieve the required biomimicry for tooth development. For the first time, we used bioorthogonally cross-linked hydrogels as defined 3D matrixes for tooth developmental engineering, and we highlighted how their properties play a pivotal role in enabling 3D tooth organoid formation in vitro. We prepared hydrogels by mixing gelatin precursors modified either with tetrazine (Tz) or norbornene (Nb) moieties. We tuned the hydrogel properties ( E = 2-7 kPa; G' = 500-1500 Pa) by varying the gelatin concentration (8% vs 12% w/V) and stoichiometric ratio (Tz:Nb = 1 vs 0.5). We encapsulated dental epithelial-mesenchymal cell pellets in a library of hydrogels and identified a hydrogel formulation that enabled successful growth kinetics and morphogenesis of tooth germs, introducing a defined tunable platform for tooth organoid engineering and modeling.

Original language	English
Pages (from-to)	1620-1626
Number of pages	7
Journal	ACS macro letters
Volume	13
Issue number	12
DOIs	https://doi.org/10.1021/acsmacrolett.4c00520
Publication status	Published - 17 Dec 2024

Keywords

Hydrogels/chemistry
Organoids/drug effects
Tissue Engineering/methods
Tooth/growth & development
Gelatin/chemistry
Humans
Animals
Norbornanes/chemistry
Biocompatible Materials/chemistry
Mice

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10.1021/acsmacrolett.4c00520

Cite this

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title = "Generating Tooth Organoids Using Defined Bioorthogonally Cross-Linked Hydrogels",

abstract = "Generating teeth in vitro requires mimicking tooth developmental processes. Biomaterials are essential to support 3D tooth organoid formation, but their properties must be finely tuned to achieve the required biomimicry for tooth development. For the first time, we used bioorthogonally cross-linked hydrogels as defined 3D matrixes for tooth developmental engineering, and we highlighted how their properties play a pivotal role in enabling 3D tooth organoid formation in vitro. We prepared hydrogels by mixing gelatin precursors modified either with tetrazine (Tz) or norbornene (Nb) moieties. We tuned the hydrogel properties ( E = 2-7 kPa; G' = 500-1500 Pa) by varying the gelatin concentration (8% vs 12% w/V) and stoichiometric ratio (Tz:Nb = 1 vs 0.5). We encapsulated dental epithelial-mesenchymal cell pellets in a library of hydrogels and identified a hydrogel formulation that enabled successful growth kinetics and morphogenesis of tooth germs, introducing a defined tunable platform for tooth organoid engineering and modeling. ",

keywords = "Hydrogels/chemistry, Organoids/drug effects, Tissue Engineering/methods, Tooth/growth & development, Gelatin/chemistry, Humans, Animals, Norbornanes/chemistry, Biocompatible Materials/chemistry, Mice",

author = "Xuechen Zhang and {Contessi Negrini}, Nicola and Rita Correia and Sharpe, {Paul T} and Celiz, {Adam D} and {Angelova Volponi}, Ana",

year = "2024",

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doi = "10.1021/acsmacrolett.4c00520",

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AU - Zhang, Xuechen

AU - Contessi Negrini, Nicola

AU - Correia, Rita

AU - Sharpe, Paul T

AU - Celiz, Adam D

AU - Angelova Volponi, Ana

PY - 2024/12/17

Y1 - 2024/12/17

N2 - Generating teeth in vitro requires mimicking tooth developmental processes. Biomaterials are essential to support 3D tooth organoid formation, but their properties must be finely tuned to achieve the required biomimicry for tooth development. For the first time, we used bioorthogonally cross-linked hydrogels as defined 3D matrixes for tooth developmental engineering, and we highlighted how their properties play a pivotal role in enabling 3D tooth organoid formation in vitro. We prepared hydrogels by mixing gelatin precursors modified either with tetrazine (Tz) or norbornene (Nb) moieties. We tuned the hydrogel properties ( E = 2-7 kPa; G' = 500-1500 Pa) by varying the gelatin concentration (8% vs 12% w/V) and stoichiometric ratio (Tz:Nb = 1 vs 0.5). We encapsulated dental epithelial-mesenchymal cell pellets in a library of hydrogels and identified a hydrogel formulation that enabled successful growth kinetics and morphogenesis of tooth germs, introducing a defined tunable platform for tooth organoid engineering and modeling.

AB - Generating teeth in vitro requires mimicking tooth developmental processes. Biomaterials are essential to support 3D tooth organoid formation, but their properties must be finely tuned to achieve the required biomimicry for tooth development. For the first time, we used bioorthogonally cross-linked hydrogels as defined 3D matrixes for tooth developmental engineering, and we highlighted how their properties play a pivotal role in enabling 3D tooth organoid formation in vitro. We prepared hydrogels by mixing gelatin precursors modified either with tetrazine (Tz) or norbornene (Nb) moieties. We tuned the hydrogel properties ( E = 2-7 kPa; G' = 500-1500 Pa) by varying the gelatin concentration (8% vs 12% w/V) and stoichiometric ratio (Tz:Nb = 1 vs 0.5). We encapsulated dental epithelial-mesenchymal cell pellets in a library of hydrogels and identified a hydrogel formulation that enabled successful growth kinetics and morphogenesis of tooth germs, introducing a defined tunable platform for tooth organoid engineering and modeling.

KW - Hydrogels/chemistry

KW - Organoids/drug effects

KW - Tissue Engineering/methods

KW - Tooth/growth & development

KW - Gelatin/chemistry

KW - Humans

KW - Animals

KW - Norbornanes/chemistry

KW - Biocompatible Materials/chemistry

KW - Mice

U2 - 10.1021/acsmacrolett.4c00520

DO - 10.1021/acsmacrolett.4c00520

M3 - Article

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SN - 2161-1653

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SP - 1620

EP - 1626

JO - ACS macro letters

JF - ACS macro letters

IS - 12

ER -

Generating Tooth Organoids Using Defined Bioorthogonally Cross-Linked Hydrogels

Abstract

Keywords

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