Fibronectin‐induced ductal formation in salivary gland self‐organization model

Farahat, Mahmoud; Rahman, Kazi Anisur; Taketa, Hiroaki; Hara, Emilio Satoshi; Oshima, Masamitsu; Kuboki, Takuo; Matsumoto, Takuya

doi:10.1002/dvdy.78

Cited by 9 publications

(10 citation statements)

References 41 publications

(85 reference statements)

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“…Hydrogel substrate with different mechanical stiffness could effectively alter the cellular behavior of mesenchymal stem cells and change their future lineages (Engler et al 2006). Studies from our group effectively utilized different hydrogel systems to recapitulate and modulate the development and growth of soft tissue (Taketa et al 2015; Sathi et al 2017; Farahat et al 2019) and hard tissue (Sathi et al 2015). In the latter work, we cultured mouse embryonic femur bones inside an agarose hydrogel with different mechanical stiffness.…”

Section: Discussionmentioning

confidence: 99%

Effect of Biomechanical Environment on Degeneration of Meckel’s Cartilage

et al. 2020

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During orofacial tissue development, the anterior and posterior regions of the Meckel’s cartilage undergo mineralization, while the middle region undergoes degeneration. Despite the interesting and particular phenomena, the mechanisms that regulate the different fates of Meckel’s cartilage, including the effects of biomechanical cues, are still unclear. Therefore, the purpose of this study was to systematically investigate the course of Meckel’s cartilage during embryonic development from a biomechanical perspective. Histomorphological and biomechanical (stiffness) changes in the Meckel’s cartilage were analyzed from embryonic day 12 to postnatal day 0. The results revealed remarkable changes in the morphology and size of chondrocytes, as well as the occurrence of chondrocyte burst in the vicinity of the mineralization site, an often-seen phenomenon preceding endochondral ossification. To understand the effect of biomechanical cues on Meckel’s cartilage fate, a mechanically tuned 3-dimensional hydrogel culture system was used. At the anterior region, a moderately soft environment (10-kPa hydrogel) promoted chondrocyte burst and ossification. On the contrary, at the middle region, a more rigid environment (40-kPa hydrogel) enhanced cartilage degradation by inducing a higher expression of MMP-1 and MMP-13. These results indicate that differences in the biomechanical properties of the surrounding environment are essential factors that distinctly guide the mineralization and degradation of Meckel’s cartilage and would be valuable tools for modulating in vitro cartilage and bone tissue engineering.

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Section: Discussionmentioning

confidence: 99%

Effect of Biomechanical Environment on Degeneration of Meckel’s Cartilage

et al. 2020

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“…The first induces PSCs to differentiate towards oral ectoderm in a 3D culture enriched with several growth factors and cytokines to promote the salivary gland morphogenesis [ 125 ]. The second requires the incubation of salivary gland progenitors in 3D scaffolds to promote the formation of the gland structure thanks to several growth factors [ 126 , 127 ]. Salivary organoids have also been obtained thanks to magnetic 3D bioprinting using DPSCs and neural crest-derived mesenchymal stem cells as “ink” [ 128 ].…”

Section: Overview Of Different Types Of Dental Stem Cellsmentioning

confidence: 99%

Hypes and Hopes of Stem Cell Therapies in Dentistry: a Review

Baena

Casasco

Monti

2022

Stem Cell Rev and Rep

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One of the most exciting advances in life science research is the development of 3D cell culture systems to obtain complex structures called organoids and spheroids. These 3D cultures closely mimic in vivo conditions, where cells can grow and interact with their surroundings. This allows us to better study the spatio-temporal dynamics of organogenesis and organ function. Furthermore, physiologically relevant organoids cultures can be used for basic research, medical research, and drug discovery. Although most of the research thus far focuses on the development of heart, liver, kidney, and brain organoids, to name a few, most recently, these structures were obtained using dental stem cells to study in vitro tooth regeneration. This review aims to present the most up-to-date research showing how dental stem cells can be grown on specific biomaterials to induce their differentiation in 3D. The possibility of combining engineering and biology principles to replicate and/or increase tissue function has been an emerging and exciting field in medicine. The use of this methodology in dentistry has already yielded many interesting results paving the way for the improvement of dental care and successful therapies. Graphical abstract

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“…Recent studies have found that stem/progenitor cells isolated from the salivary gland can be expanded and differentiated to generate organoids capable of restoring gland function in vivo (Fig. 2A) (Farahat et al 2019; Sui et al 2020). These processes are controlled by the treatment of numerous growth factors, including EGF, FGFs, and TGF-β (Farahat et al 2019; Sui et al 2020).…”

Section: Construction Of Oral Organoidsmentioning

confidence: 99%

“…2A) (Farahat et al 2019; Sui et al 2020). These processes are controlled by the treatment of numerous growth factors, including EGF, FGFs, and TGF-β (Farahat et al 2019; Sui et al 2020). The artificial niche promoted the development of salivary gland organoids, as indicated by the expression of differentiation markers, structure formation, and response to neurotransmitters in vitro.…”

Section: Construction Of Oral Organoidsmentioning

confidence: 99%

Oral Organoids: Progress and Challenges

Gao

Liao

et al. 2021

J Dent Res

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Oral organoids are complex 3-dimensional structures that develop from stem cells or organ-specific progenitors through a process of self-organization and re-create architectures and functionalities similar to in vivo organs and tissues in the oral and maxillofacial region. Recently, striking advancements have been made in the construction and application of oral organoids of the tooth, salivary gland, and tongue. Dental epithelial and mesenchymal cells isolated from tooth germs or derived from pluripotent stem cells could generate tooth germ–like organoids by self-organization in a specific culture system. Tooth organoids can also be constructed based on tissue engineering principles by seeding stem cells on a scaffold with the bioregulatory functions of odontogenic differentiation. Two main approaches have been used to construct salivary gland organoids: 1) incubation of salivary gland–derived stem/progenitor cells in a 3-dimensional culture system to form the structure of the gland through mimicking regenerative processes and 2) inducing of pluripotent stem cells to generate embryonic salivary glands by replicating the development process. Taste bud organoids can be generated by embedding isolated circumvallate papilla tissue in Matrigel with a mixture of growth factors, while lingual epithelial organoids have been constructed using lingual stem cells in a suitable culture system containing specific signaling molecules. These oral organoids usually maintain the main functions and characteristic structures of the corresponding organ to a certain extent. Furthermore, using cells isolated from patients, oral organoids could replicate specific diseases such as maxillofacial tumors and tooth dysplasia. Until now, oral organoids have been applied in the study of mechanisms of tooth development, pathology and regeneration of the salivary gland, and precision therapeutics for tongue cancer. These findings strongly demonstrate that the organoid technique is a novel paradigm for the study of the development, pathology, and regeneration of oral and maxillofacial tissue.

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Fibronectin‐induced ductal formation in salivary gland self‐organization model

Cited by 9 publications

References 41 publications

Effect of Biomechanical Environment on Degeneration of Meckel’s Cartilage

Effect of Biomechanical Environment on Degeneration of Meckel’s Cartilage

Hypes and Hopes of Stem Cell Therapies in Dentistry: a Review

Oral Organoids: Progress and Challenges

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