Building an Artificial Stem Cell Niche: Prerequisites for Future 3D‐Formation of Inner Ear Structures—Toward 3D Inner Ear Biotechnology

Groot, Simon C. de; Sliedregt, Karen; Benthem, Peter Paul G. van; Rivolta, Marcelo N.; Huisman, Margriet A.

doi:10.1002/ar.24067

Cited by 9 publications

(14 citation statements)

References 181 publications

(246 reference statements)

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“…Similarly, the ECM is crucial in mimicking a stem cell niche in vitro and in driving stem cells toward the three dimensions formation. Technological developments have led to the investigation of biomaterials similar to the native ECM [56].…”

Section: Three-dimensional (3d) Organoid Model Of the Inner Ear (Cochmentioning

confidence: 99%

Application of Mesenchymal Stem Cell Therapy and Inner Ear Regeneration for Hearing Loss: A Review

Kanzaki

Toyoda

Umezawa

et al. 2020

IJMS

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Inner and middle ear disorders are the leading cause of hearing loss, and are said to be among the greatest risk factors of dementia. The use of regenerative medicine for the treatment of inner ear disorders may offer a potential alternative to cochlear implants for hearing recovery. In this paper, we reviewed recent research and clinical applications in middle and inner ear regeneration and cell therapy. Recently, the mechanism of inner ear regeneration has gradually been elucidated. “Inner ear stem cells,” which may be considered the precursors of various cells in the inner ear, have been discovered in the cochlea and vestibule. Research indicates that cells such as hair cells, neurons, and spiral ligaments may form promising targets for inner ear regenerative therapies by the transplantation of stem cells, including mesenchymal stem cells. In addition, it is necessary to develop tests for the clinical monitoring of cell transplantation. Real-time imaging techniques and hearing rehabilitation techniques are also being investigated, and cell therapy has found clinical application in cochlear implant techniques.

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Section: Three-dimensional (3d) Organoid Model Of the Inner Ear (Cochmentioning

confidence: 99%

Application of Mesenchymal Stem Cell Therapy and Inner Ear Regeneration for Hearing Loss: A Review

Kanzaki

Toyoda

Umezawa

et al. 2020

IJMS

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“…Moreover, in contrast to natural scaffolds, synthetic ECM proteins have little batch-to-batch composition variation, and have a reduced risk for pathogen contamination (Dawson et al, 2008;Ghasemi-Mobarakeh et al, 2015). It is important to note that Matrigel R is mouse-derived and due to its batch-to-batch variation and undefined growth factors, it is neither safe nor practical for human studies (de Groot et al, 2020).…”

Section: In Vitro Requirement Of Ecm Proteins For Hf Neogenesismentioning

confidence: 99%

“…A relatively new method to create ECM scaffolds is self-assembling peptide hydrogels formed by RADA-16. One major advantage of RADA-16 over other synthetic scaffolds is the diameter of the microfibers, which is approximately 10 nm compared to 100 µm for synthetic microfibers (de Groot et al, 2020). When cultured with larger microfiber scaffolds, different cells can only adhere to one large fiber at a time, so the cells are effectively still in a 2D environment (de Groot et al, 2020).…”

Section: In Vitro Requirement Of Ecm Proteins For Hf Neogenesismentioning

confidence: 99%

“…Moreover, most studies on HF organogenesis have focused on the biomolecular pathways involved and not on achieving HF neogenesis in vitro. In regenerative biology, it is generally acknowledged that matrix molecules, and their physicochemical characteristics, are involved in the control and completion of organogenesis, but this has hardly been explored in the context of HF morphogenesis (de Groot et al, 2020). It is known that signaling pathways required for early HF morphogenesis are evolutionarily conserved between species (Botchkarev et al, 2003;Wu et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

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Back to the Future: From Appendage Development Toward Future Human Hair Follicle Neogenesis

Groot

Ulrich

Gho

et al. 2021

Front. Cell Dev. Biol.

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Hair disorders such as alopecia and hirsutism often impact the social and psychological well-being of an individual. This also holds true for patients with severe burns who have lost their hair follicles (HFs). HFs stimulate proper wound healing and prevent scar formation; thus, HF research can benefit numerous patients. Although hair development and hair disorders are intensively studied, human HF development has not been fully elucidated. Research on human fetal material is often subject to restrictions, and thus development, disease, and wound healing studies remain largely dependent on time-consuming and costly animal studies. Although animal experiments have yielded considerable and useful information, it is increasingly recognized that significant differences exist between animal and human skin and that it is important to obtain meaningful human models. Human disease specific models could therefore play a key role in future therapy. To this end, hair organoids or hair-bearing skin-on-chip created from the patient’s own cells can be used. To create such a complex 3D structure, knowledge of hair genesis, i.e., the early developmental process, is indispensable. Thus, uncovering the mechanisms underlying how HF progenitor cells within human fetal skin form hair buds and subsequently HFs is of interest. Organoid studies have shown that nearly all organs can be recapitulated as mini-organs by mimicking embryonic conditions and utilizing the relevant morphogens and extracellular matrix (ECM) proteins. Therefore, knowledge of the cellular and ECM proteins in the skin of human fetuses is critical to understand the evolution of epithelial tissues, including skin appendages. This review aims to provide an overview of our current understanding of the cellular changes occurring during human skin and HF development. We further discuss the potential implementation of this knowledge in establishing a human in vitro model of a full skin substitute containing hair follicles and the subsequent translation to clinical use.

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“…The areas of research covered by these papers are organized into related groups starting with a single paper that addresses historical aspects, that is, “Historical aspects of gene therapy and stem cell therapy in the treatment of hearing and balance disorders” (Van De Water, ). This is followed by a group of six papers that utilized in vitro techniques to examine stem cell growth characteristics, migratory behavior, potential for therapeutic application, and isolation of new stem cells from human inner ear tissue: that is, “Building an artificial stem cell niche: prerequisites for future 3‐D‐formation of inner ear structures toward 3D inner ear biotechnology,” (De Groot et al, ); “Imaging bioluminescent exogenous stem cells in intact guinea pig cochlea,” (Schomann et al, ); “The effect of Matrigel on a human neural progenitor dissociated sphere culture,” (Kaiser et al, ); “Isolation and characterization of mammalian otic stem cells that can differentiate into both sensory and neuronal lineages,” (Kojima et al, ); “Progenitor cells from the human inner ear,” (Senn et al, ); and “Evaluation of cilia function in rat trachea reconstructed using collagen sponge scaffold seeded with adipose tissue‐derived stem cells” (Nakamura et al, ). This series of in vitro studies is followed by a group of five papers that probe the behavior of stem cells in vivo , looking at their ability to treat hearing loss and ultrastructural character of stem cell‐initiated hair cell regeneration: that is, “Bone marrow stromal cells accelerate hearing recovery via regeneration or maintenance of cochlear fibrocytes in mouse spiral ligaments,” (Kada et al, ); “Effect of bone marrow‐derived mesenchymal stem cells on cochlear function in an experimental rat model,” (Mittal et al, ); “Transplantation and tracking of human umbilical cord mesenchymal stem cells labeled with SPIO in deaf pigs,” (Xu et al, ); “Ultrastructural characterization of stem cell‐derived replacement vestibular hair cells within ototoxin‐damaged rat utricle explants,” (Werner et al, ); and “Recent advancements in gene and stem cell‐based treatment modalities: potential applications in noise‐induced hearing loss” (Eshraghi et al, ).…”

mentioning

confidence: 99%

A Regenerative Medicine Approach to the Treatment of Hearing, Balance, and Olfactory Disorders: What Is in the Future for Otolaryngology?

Water

2020

The Anatomical Record

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Regenerative medicine is being applied to many fields of medicine and is now starting to be considered and developed for application to treat hearing, balance, olfaction, and voice disorders. This special issue of the Anatomical Record with a series of over 20 papers covers many aspects of gene and stem cell therapies as they are developed for clinical applications in both in vitro and in vivo laboratory studies. These studies cover a wide range of approaches from gene editing in zebrafish with the latest technology (i.e., CRISPR/Cas9) to the isolation of human inner ear progenitor cells, to tracking transplanted human umbilical cord stem cells in mini pigs, to the in vitro building of graft tissues to repair tracheal defects with adipose tissue‐derived stem cells. Anat Rec, 303:385–389, 2020. © 2019 American Association for Anatomy

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Building an Artificial Stem Cell Niche: Prerequisites for Future 3D‐Formation of Inner Ear Structures—Toward 3D Inner Ear Biotechnology

Cited by 9 publications

References 181 publications

Application of Mesenchymal Stem Cell Therapy and Inner Ear Regeneration for Hearing Loss: A Review

Application of Mesenchymal Stem Cell Therapy and Inner Ear Regeneration for Hearing Loss: A Review

Back to the Future: From Appendage Development Toward Future Human Hair Follicle Neogenesis

A Regenerative Medicine Approach to the Treatment of Hearing, Balance, and Olfactory Disorders: What Is in the Future for Otolaryngology?

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