Tissue Beads: Tissue‐Specific Extracellular Matrix Microbeads to Potentiate Reprogrammed Cell‐Based Therapy

Lee, Jung Seung; Roh, Yoon Ho; Choi, Yi Sun; Jin, Yoonhee; Jeon, Eun Je; Bong, Ki Wan; Cho, Seung Woo

doi:10.1002/adfm.201807803

Cited by 34 publications

(29 citation statements)

References 72 publications

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“…Rothrauff et al (2017b) compared cartilage and tendon growth factors and reported promotion of tissue-specific differentiation across multiple cultures and also reported the distributions of various growth factors. Lee et al (2019) confirmed the decellularization of seven tissues including organs such as liver and heart. They fabricated uniform sized tissue microbeads using them ECM and reported three kinds of tissue-specific microbeads derived from liver, heart and muscle (Lee et al, 2019).…”

Section: Discussionmentioning

confidence: 56%

“…Lee et al (2019) confirmed the decellularization of seven tissues including organs such as liver and heart. They fabricated uniform sized tissue microbeads using them ECM and reported three kinds of tissue-specific microbeads derived from liver, heart and muscle (Lee et al, 2019). These significantly enhanced the viability, lineage specific maturation, and functionality of each type of FIGURE 4 | Total protein and human growth factor analysis of soluble decellularized extracellular matrix (ECM) preparations.…”

Section: Discussionmentioning

confidence: 56%

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Potential of Soluble Decellularized Extracellular Matrix for Musculoskeletal Tissue Engineering – Comparison of Various Mesenchymal Tissues

Hanai

Jacob

Nakagawa

et al. 2020

Front. Cell Dev. Biol.

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BackgroundIt is well studied that preparations of decellularized extracellular matrix (ECM) obtained from mesenchymal tissues can function as biological scaffolds to regenerate injured musculoskeletal tissues. Previously, we reported that soluble decellularized ECMs derived from meniscal tissue demonstrated excellent biocompatibility and produced meniscal regenerate with native meniscal anatomy and biochemical characteristics. We therefore hypothesized that decellularized mesenchymal tissue ECMs from various mesenchymal tissues should exhibit tissue-specific bioactivity. The purpose of this study was to test this hypothesis using porcine tissues, for potential applications in musculoskeletal tissue engineering.MethodsNine types of porcine tissue, including cartilage, meniscus, ligament, tendon, muscle, synovium, fat pad, fat, and bone, were decellularized using established methods and solubilized. Although the current trend is to develop tissue specific decellularization protocols, we selected a simple standard protocol across all tissues using Triton X-100 and DNase/RNase after mincing to compare the outcome. The content of sulfated glycosaminoglycan (sGAG) and hydroxyproline were quantified to determine the biochemical composition of each tissue. Along with the concentration of several growth factors, known to be involved in tissue repair and/or maturation, including bFGF, IGF-1, VEGF, and TGF-β1. The effect of soluble ECMs on cell differentiation was explored by combining them with 3D collagen scaffold culturing human synovium derived mesenchymal stem cells (hSMSCs).ResultsThe decellularization of each tissue was performed and confirmed both histologically [hematoxylin and eosin (H&E) and 4’,6-diamidino-2-phenylindole (DAPI) staining] and on the basis of dsDNA quantification. The content of hydroxyproline of each tissue was relatively unchanged during the decellularization process when comparing the native and decellularized tissue. Cartilage and meniscus exhibited a significant decrease in sGAG content. The content of hydroxyproline in meniscus-derived ECM was the highest when compared with other tissues, while sGAG content in cartilage was the highest. Interestingly, a tissue-specific composition of most of the growth factors was measured in each soluble decellularized ECM and specific differentiation potential was particularly evident in cartilage, ligament and bone derived ECMs.ConclusionIn this study, soluble decellularized ECMs exhibited differences based on their tissue of origin and the present results are important going forward in the field of musculoskeletal regeneration therapy.

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Section: Discussionmentioning

confidence: 56%

Section: Discussionmentioning

confidence: 56%

Potential of Soluble Decellularized Extracellular Matrix for Musculoskeletal Tissue Engineering – Comparison of Various Mesenchymal Tissues

Hanai

Jacob

Nakagawa

et al. 2020

Front. Cell Dev. Biol.

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“…[90] Microgels have been fabricated using a variety of biomaterials with different gelation mechanisms, including alginate, [91,92] agarose, [93] methacrylated hyaluronic acid, [94] poly(ethylene glycol) diacrylate (PEGDA), [95] poly(ethylene glycol) maleimide (PEGMAL), [96] GelMA, [97] self-assembled peptides, [98,99] and tissue-specific extracellular matrix (ECM). [100] Two-phase emulsions (e.g., water-in-oil) can be used to template the formation of microgels. [52] While this method is simple and high throughput, it generally produces microgels with a polydisperse size distribution.…”

Section: Cellularized Microcarriersmentioning

confidence: 99%

“…[90,97] A common system is the use of calcium ions to form crosslinked alginate microgels, however, other cellularized biomaterials can also be used by applying the gelation triggers in a contact [96] or non-contact fashion. [93] For example, agarose microdroplets can be set by cooling, [93] ECM and collagen microgels can be gelled by heating (generally to 37 °C), [100] while GelMA microdroplets can be photocrosslinked by UV irradiation. [101] Other fabrication methods include electro-assisted jetting and inkjet printing, [102][103][104] while micromolding [105] and photolithography [106][107][108][109] have been used to produce non-spherical microgels.…”

Section: Cellularized Microcarriersmentioning

confidence: 99%

Assembling Living Building Blocks to Engineer Complex Tissues

Ouyang

Armstrong

Salmerón‐Sánchez

et al. 2020

Adv Funct Materials

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The great demand for tissue and organ grafts, compounded by an ageing demographic and a shortage of available donors, has driven the development of bioengineering approaches that can generate biomimetic tissues in vitro. Despite the considerable progress in conventional scaffold-based tissue engineering, the recreation of physiological complexity has remained a challenge. Bottom-up tissue engineering strategies have opened up a new avenue for the modular assembly of living building blocks into customized tissue architectures. This Progress Report will overview the recent progress and trends in the fabrication and assembly of living building blocks, with a key highlight on emerging bioprinting technologies that can be used for modular assembly and complexity in tissue engineering. By summarizing the work to date, providing new classifications of different living building blocks, highlighting state-of-the-art research and trends, and offering personal perspectives on future opportunities, this Progress Report aims to aid and inspire other researchers working in the field of modular tissue engineering.

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“…Flow-focusing microfluidics was applied to generate microbeads for 3D culture and transplantation of reprogrammed cells. 76 Decellularized tissue-derived ECM solutions were used to encapsulate induced hepatic, cardiac, and myogenic cells all directly reprogrammed from fibroblasts in a tissue type-matched manner. 76 The tissue-specific ECM microbeads supported higher cellular viability and improved maturation and functionality, compared with the collagen type I microbeads.…”

Section: Microdevice Platformsmentioning

confidence: 99%

Bioengineering platforms for cell therapeutics derived from pluripotent and direct reprogramming

Jin

Cho

2021

APL Bioengineering

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Pluripotent and direct reprogramming technologies hold great potential for tissue repair and restoration of tissue and organ function. The implementation of induced pluripotent stem cells and directly reprogrammed cells in biomedical research has resulted in a significant leap forward in the highly promising area of regenerative medicine. While these therapeutic strategies are promising, there are several obstacles to overcome prior to the introduction of these therapies into clinical settings. Bioengineering technologies, such as biomaterials, bioprinting, microfluidic devices, and biostimulatory systems, can enhance cell viability, differentiation, and function, in turn the efficacy of cell therapeutics generated via pluripotent and direct reprogramming. Therefore, cellular reprogramming technologies, in combination with tissue-engineering platforms, are poised to overcome current bottlenecks associated with cell-based therapies and create new ways of producing engineered tissue substitutes.

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Tissue Beads: Tissue‐Specific Extracellular Matrix Microbeads to Potentiate Reprogrammed Cell‐Based Therapy

Cited by 34 publications

References 72 publications

Potential of Soluble Decellularized Extracellular Matrix for Musculoskeletal Tissue Engineering – Comparison of Various Mesenchymal Tissues

Potential of Soluble Decellularized Extracellular Matrix for Musculoskeletal Tissue Engineering – Comparison of Various Mesenchymal Tissues

Assembling Living Building Blocks to Engineer Complex Tissues

Bioengineering platforms for cell therapeutics derived from pluripotent and direct reprogramming

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