Cell-laden hydrogels for osteochondral and cartilage tissue engineering

Yang, Jingzhou; Zhang, Yu Shrike; Yue, Kan; Khademhosseini, Ali

doi:10.1016/j.actbio.2017.01.036

Cited by 514 publications

(407 citation statements)

References 308 publications

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“…These data were used to select preconditioning durations for subsequent testing of ECM synthesis in the absence of TGFβ. Preconditioned MSCs were evaluated for commitment to chondrogenesis encapsulated in agarose, a hydrogel scaffold that has been commonly‐used to study the biology of chondrogenic MSCs and chondrocytes . Negative and positive controls were created by seeding MSCs from undifferentiated expansion culture into agarose, and culturing in the absence or presence of TGFβ, respectively.…”

Section: Methodsmentioning

confidence: 99%

Effect of culture duration on chondrogenic preconditioning of equine bone marrow mesenchymal stem cells in self‐assembling peptide hydrogel

Kisiday

Colbath

Tangtrongsup

2018

Journal Orthopaedic Research

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Ex vivo induction of chondrogenesis is a promising approach to improve upon the use of bone marrow mesenchymal stem cells (MSCs) for cartilage tissue engineering. This study evaluated the potential to induce chondrogenesis with days of culture in chondrogenic medium for MSCs encapsulated in self-assembling peptide hydrogel. To simulate the transition from preconditioning culture to implantation, MSCs were isolated from self-assembling peptide hydrogel into an individual cell suspension. Commitment to chondrogenesis was evaluated by seeding preconditioned MSCs into agarose and culturing in the absence of the chondrogenic cytokine transforming growth factor beta (TGFβ). Positive controls consisted of undifferentiated MSCs seeded into agarose and cultured in medium containing TGFβ. Three days of preconditioning was sufficient to produce chondrogenic MSCs that accumulated ∼75% more cartilaginous extracellular matrix than positive controls by day 17. However, gene expression of type X collagen was ∼65-fold higher than positive controls, which was attributed to the absence of TGFβ. Potential induction of immunogenicity with preconditioning culture was indicated by expression of major histocompatibility complex class II (MHCII), which was nearly absence in undifferentiated MSCs, and ∼7% positive for preconditioned cells. These data demonstrate the potential to generate chondrogenic MSCs with days of self-assembling peptide hydrogel, and the ability to readily recover an individual cell suspension that is suited for injectable therapies. However, continued exposure to TGFβ may be necessary to prevent hypertrophy indicated by type X collagen expression, while immunogenicity may be a concern for allogeneic applications. © 2018 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res.

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Section: Methodsmentioning

confidence: 99%

Effect of culture duration on chondrogenic preconditioning of equine bone marrow mesenchymal stem cells in self‐assembling peptide hydrogel

Kisiday

Colbath

Tangtrongsup

2018

Journal Orthopaedic Research

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“…Tissue engineering that delivers autologous mesenchymal stem cells (MSCs) is one strategy that holds promise for regenerating osteochondral tissues (Yang, Zhang, Yue, & Khademhosseini, ). In particular, bilayer hydrogels have emerged as a promising platform for osteochondral tissue engineering due to their high water content, tunable biochemical cues and stiffness in each layer, and in situ forming capabilities to deliver cells minimally invasively.…”

Section: Introductionmentioning

confidence: 99%

The effects of dynamic compressive loading on human mesenchymal stem cell osteogenesis in the stiff layer of a bilayer hydrogel

Aziz

Eckstein

Ferguson

et al. 2019

J Tissue Eng Regen Med

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Bilayer hydrogels with a soft cartilage‐like layer and a stiff bone‐like layer embedded with human mesenchymal stem cells (hMSCs) are promising for osteochondral tissue engineering. The goals of this work were to evaluate the effects of dynamic compressive loading (2.5% applied strain, 1 Hz) on osteogenesis in the stiff layer and spatially map local mechanical responses (strain, stress, hydrostatic pressure, and fluid velocity). A bilayer hydrogel was fabricated from soft (24 kPa) and stiff (124 kPa) poly (ethylene glycol) hydrogels. With hMSCs embedded in the stiff layer, osteogenesis was delayed under loading evident by lower OSX and OPN expressions, alkaline phosphatase activity, and collagen content. At Day 28, mineral deposits were present throughout the stiff layer without loading but localized centrally and near the interface under loading. Local strains mapped by particle tracking showed substantial equivalent strain (~1.5%) transferring to the stiff layer. When hMSCs were cultured in stiff single‐layer hydrogels subjected to similar strains, mineralization was inhibited. Finite element analysis revealed that hydrostatic pressures ≥~600 Pa correlated to regions lacking mineralization in both hydrogels. Fluid velocities were low (~1–10 nm/s) in the hydrogels with no apparent correlation to mineralization. Mineralization was recovered by inhibiting ERK1/2, indicating cell‐mediated inhibition. These findings suggest that high strains (~1.5%) combined with higher hydrostatic pressures negatively impact osteogenesis, but in a manner that depends on the magnitude of each mechanical response. This work highlights the importance of local mechanical responses in mediating osteogenesis of hMSCs in bilayer hydrogels being studied for osteochondral tissue engineering.

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“…Nanoparticles can be added as well, and loaded with chondrogenic/osteogenic growth factors [65]. In fact, hydrogels with cells and growth factors are proving very useful in engineering OC interface and achieving biochemical gradients [62].…”

Section: Scaffolds As Biomimetic Systems Componentmentioning

confidence: 99%

“…Importantly, cell-laden hydrogels, or cell-hydrogel hybrid constructs, can be manufactured in patient-specific anatomical shapes [62]. Injectable hydrogels are particularly convenient materials for in vivo applications.…”

Section: Scaffolds As Biomimetic Systems Componentmentioning

confidence: 99%

Mimetic Hierarchical Approaches for Osteochondral Tissue Engineering

Gadjanski

2018

Osteochondral Tissue Engineering

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In order to engineer biomimetic osteochondral (OC) construct, it is necessary to address both the cartilage and bone phase of the construct, as well as the interface between them, in effect mimicking the developmental processes when generating hierarchical scaffolds that show gradual changes of physical and mechanical properties, ideally complemented with the biochemical gradients. There are several components whose characteristics need to be taken into account in such biomimetic approach, including cells, scaffolds, bioreactors as well as various developmental processes such as mesenchymal condensation and vascularization, that need to be stimulated through the use of growth factors, mechanical stimulation, purinergic signaling, low oxygen conditioning, and immunomodulation. This chapter gives overview of these biomimetic OC system components, including the OC interface, as well as various methods of fabrication utilized in OC biomimetic tissue engineering (TE) of gradient scaffolds. Special attention is given to addressing the issue of achieving clinical size, anatomically shaped constructs. Besides such neotissue engineering for potential clinical use, other applications of biomimetic OC TE including formation of the OC tissues to be used as high-fidelity disease/ healing models and as in vitro models for drug toxicity/efficacy evaluation are covered. Highlights Biomimetic OC TE uses "smart" scaffolds able to locally regulate cell phenotypes and dual-flow bioreactors for two sets of conditions for cartilage/ bone Protocols for hierarchical OC grafts engineering should entail mesenchymal condensation for cartilage and vascular component for bone Immunomodulation, low oxygen tension, purinergic signaling, time dependence of stimuli application are important aspects to consider in biomimetic OC TE Mimetic Hierarchical Approaches for Osteochondral Tissue Engineering Ivana GadjanskiAbstract In order to engineer biomimetic osteochondral (OC) construct, it is necessary to address both the cartilage and bone phase of the construct, as well as the interface between them, in effect mimicking the developmental processes when generating hierarchical scaffolds that show gradual changes of physical and mechanical properties, ideally complemented with the biochemical gradients. There are several components whose characteristics need to be taken into account in such biomimetic approach, including cells, scaffolds, bioreactors as well as various developmental processes such as mesenchymal condensation and vascularization, that need to be stimulated through the use of growth factors, mechanical stimulation, purinergic signaling, low oxygen conditioning, and immunomodulation. This chapter gives overview of these biomimetic OC system components, including the OC interface, as well as various methods of fabrication utilized in OC biomimetic tissue engineering (TE) of gradient scaffolds. Special attention is given to addressing the issue of achieving clinical size, anatomically shaped constructs. Besides such neotissue en...

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Cell-laden hydrogels for osteochondral and cartilage tissue engineering

Cited by 514 publications

References 308 publications

Effect of culture duration on chondrogenic preconditioning of equine bone marrow mesenchymal stem cells in self‐assembling peptide hydrogel

Effect of culture duration on chondrogenic preconditioning of equine bone marrow mesenchymal stem cells in self‐assembling peptide hydrogel

The effects of dynamic compressive loading on human mesenchymal stem cell osteogenesis in the stiff layer of a bilayer hydrogel

Mimetic Hierarchical Approaches for Osteochondral Tissue Engineering

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