Cell Encapsulation Systems Toward Modular Tissue Regeneration: From Immunoisolation to Multifunctional Devices

Correia, Clara R.; Nadine, Sara; Mano, João F.

doi:10.1002/adfm.201908061

Cited by 39 publications

(38 citation statements)

References 249 publications

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“…[1] Upholding superior multifunctionality, liquid environments can be fabricated under mild conditions providing cell containment and protection while offering higher nutrient diffusion. [2] The increased knowledge behind the cellular microenvironment complexity and the possibility of better mimic the native physical and biochemical cues make the choice of the biomaterials critical in the design of high-class platforms. [3] Up to date, a wide variety of polymers DOI: 10.1002/adhm.202100782 (synthetic and natural), biofabrication technologies (e.g., electrospray, microfluidic, among others) and approaches (e.g., layer-by-layer, aqueous biphasic systems) are underneath the design of a shell confinement (i.e., a barrier able to confine cells in a controlled environment).…”

Section: Introductionmentioning

confidence: 99%

Design of Protein‐Based Liquefied Cell‐Laden Capsules with Bioinspired Adhesion for Tissue Engineering

Gomes

Costa

Oliveira

et al. 2021

Adv Healthcare Materials

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Platforms with liquid cores are extensively explored as cell delivery vehicles for cell-based therapies and tissue engineering. However, the recurrence of synthetic materials can impair its translation into the clinic. Inspired by the adhesive proteins secreted by mussels, liquefied capsule is developed using gelatin modified with hydroxypyridinones (Gel-HOPO), a catechol analogue with oxidant-resistant properties. The protein-based liquefied macrocapsule permitted the compartmentalization of living cells by an approachable and non-time-consuming methodology resorting to i) superhydrophobic surfaces as a processing platform of hydrogel beads, ii) gelation of gelatin at temperatures < 25°C, iii) iron coordination of the hydroxypyridinone (HOPO) moieties at physiological pH, and iv) core liquefaction at 37°C. With the design of a proteolytically degradable shell, the possibility of encapsulating human adipose-derived mesenchymal stem cells (hASC) with and without the presence of polycaprolactone microparticles ( PCL) is evaluated. Showing prevalence toward adhesion to the inner shell wall, hASC formed a monolayer evidencing the biocompatibility and adequate mechanical properties of these platforms for proliferation, diminishing the need for PCL as a supporting substrate. This new protein-based liquefied platform can provide biofactories devices of both fundamental and practical importance for tissue engineering and regenerative medicine or in other biotechnology fields.

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Section: Introductionmentioning

confidence: 99%

Design of Protein‐Based Liquefied Cell‐Laden Capsules with Bioinspired Adhesion for Tissue Engineering

Gomes

Costa

Oliveira

et al. 2021

Adv Healthcare Materials

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“…[ 8 ] While spherical systems are the most widely used, the generation of multi‐shaped complex 3D structures are being increasingly explored to mimic the complexity of native tissues. [ 9 ] For example, cylinder‐shaped microgels can be projected to resemble structures of the human body, such as muscle fibers [ 10 ] or blood vessels. [ 11 ]…”

Section: Methodsmentioning

confidence: 99%

“…While spherical systems are the most widely used, the generation of multi-shaped complex 3D structures are being increasingly explored to mimic the complexity of native tissues. [9] For example, cylinder-shaped microgels can be projected to resemble structures of the human body, such as muscle fibers [10] or blood vessels. [11] Despite the favorable properties of hydrogels as 3D cell encapsulation systems, macroscopic hydrogels, as those arose from the assemble of modular units, still present key issues, namely, limited cell-cell contact and signaling, as well as poor mass transportation of essential molecules.…”

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confidence: 99%

Geometrically Controlled Liquefied Capsules for Modular Tissue Engineering Strategies

et al. 2020

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tissues. Living tissues are characterized by repetitive functional units, which include combinations of heterogenous cell populations and extracellular matrix (ECM), structured across multiple length scales. In an attempt to mimic such hierarchical, adaptive and complex functionality and spatial organization, the assemble of 3D functional units with defined microarchitectural features was envisaged, in a concept termed modular TE. [1,2] In modular TE approaches, cell-laden hydrogels are being considerably explored as building blocks to create modular tissues with specific geometries and mechanical properties. [3,4] Hydrogels are attractive 3D cell supportive platforms due to their highly hydrated nature, resembling the tissuelike compliance of the native ECM. [5] Cellladen modular units enable the spatial and temporal manipulation of the biomaterials microenvironment, while avoid the invasive procedures inherent to scaffolds implantation into a defect site. Once created, the modular units can be assembled into larger multifunctional tissues, structured in a scale-range manner. Each modular unit can carry distinct cargo, including multiphenotypic cells and biomolecules of interest. The assembly of 3D modular units was already proposed for the fabrication of different tissues, such as cartilage, [6] hepatic, [7] and heart tissues. [8]

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“…While at the beginning of the TERM field it was believed that engineered structures should replicate the architecture of the tissue microenvironment from the microscopic to macroscopic dimension levels, nowadays it is well-established that there are other and more relevant key criteria that should be integrated during the design of biomaterials. [1][2][3] This paradigm shift in the TERM field was boosted by a deepened knowledge about the complex endogenous tissue repair process, which contributed to the identification of the key players involved, including cells and signaling molecules, and how the orchestration of spatial and temporal cues occurs in vivo. [4,5] Since then, a wide range of bioengineered strategies with tunable biophysical and biochemical characteristics have been proposed.…”

Section: Introductionmentioning

confidence: 99%

Minimalist Tissue Engineering Approaches Using Low Material‐Based Bioengineered Systems

Correia

Bjørge

Nadine

et al. 2021

Adv Healthcare Materials

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From an “over‐engineering” era in which biomaterials played a central role, now it is observed to the emergence of “developmental” tissue engineering (TE) strategies which rely on an integrative cell‐material perspective that paves the way for cell self‐organization. The current challenge is to engineer the microenvironment without hampering the spontaneous collective arrangement ability of cells, while simultaneously providing biochemical, geometrical, and biophysical cues that positively influence tissue healing. These efforts have resulted in the development of low‐material based TE strategies focused on minimizing the amount of biomaterial provided to the living key players of the regenerative process. Through a “minimalist‐engineering” approach, the main idea is to fine‐tune the spatial balance occupied by the inanimate region of the regenerative niche toward maximum actuation of the key living components during the healing process.

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Cell Encapsulation Systems Toward Modular Tissue Regeneration: From Immunoisolation to Multifunctional Devices

Cited by 39 publications

References 249 publications

Design of Protein‐Based Liquefied Cell‐Laden Capsules with Bioinspired Adhesion for Tissue Engineering

Design of Protein‐Based Liquefied Cell‐Laden Capsules with Bioinspired Adhesion for Tissue Engineering

Geometrically Controlled Liquefied Capsules for Modular Tissue Engineering Strategies

Minimalist Tissue Engineering Approaches Using Low Material‐Based Bioengineered Systems

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