Influence of Physical Properties of Biomaterials on Cellular Behavior

Lin, Susan; Sangaj, Nivedita; Razafiarison, Tojo; Zhang, Chao; Varghese, Shyni

doi:10.1007/s11095-011-0378-9

Cited by 154 publications

(176 citation statements)

References 28 publications

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“…Although polymer chains are relatively less random in LM-PEG, it cannot influence MSC function in a biomimetic manner which indicates that polymer morphology achieved through physical cross-link is an effective mechanism for polymer chain assembly and for promoting bioactive functionality in MSCs. Cellular aggregation and enhanced chondrogenesis in hydrogel is typically achieved with excessive cell density ($10 6 cell Á mL À1 ); [20,32] in our studies, cellular aggregation in PEG-PU gels were achieved from low cell density ($10 5 cell Á mL À1 ), indicating the role of physical cross-links to mediate aggregation and chondrogenesis. While beyond the scope of this study, other factors, e.g., gel mechanical properties, diffusion of matrix molecules, might have also influenced the chondrogenic differentiation because cross-linking of gels are related to these properties.…”

Section: Chondrogenic Differentiation Of Mscs In Gelsupporting

confidence: 48%

Hybrid Cross‐Linking Characteristics of Hydrogel Control Stem Cell Fate

Krishnan

Cheah

Sarkar

2015

Macromolecular Bioscience

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Controlling hydrogel structures by combination of physical and chemical cross-links provides a novel system to regulate (stem) cell fate. In this study, we designed a polyethylene glycol (PEG)-based hydrogel where the polymer chains contain both physical and chemical cross-linking units in the same chain with self-assembling L-tyrosine-based dipeptides and photopolymerizable polyacrylate groups, respectively. It is shown that hydrogel architectures derived from this polymer are correlated to the cross-linking mechanisms. Combination of these cross-links controls three-dimensional gel architecture to regulate stem cell behavior in these hydrogels. Particularly, interaction of mesenchymal stem cells with the hydrogel enabled cellular aggregation to enhance chondrogenic differentiation as observed from the deposition of chondrogenic matrix. Increased chondrogenesis was due to enhanced cell-cell adhesion, which was mediated by gel morphology. This study shows the interplay of physical and chemical cross-links in hydrogels to regulate stem cell function and provides a novel molecular engineering tool for controlling hydrogel properties.

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Section: Chondrogenic Differentiation Of Mscs In Gelsupporting

confidence: 48%

Hybrid Cross‐Linking Characteristics of Hydrogel Control Stem Cell Fate

Krishnan

Cheah

Sarkar

2015

Macromolecular Bioscience

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“…The elastic moduli of the hydrogels used in these studies ranges from 2 kPa to 100 kPa 12,14,20,21 , which is comparable to the moduli of chondrocyte PCM, ranging from 10 kPa to 75 kPa 29 . Enhanced stiffness in covalently crosslinked PEG based hydrogels, found to exhibit minimal stress relaxation here, restricted production of sGAG and collagens, distribution of cartilage matrix, and proliferation of chondrocytes 20,21 . However, our work revealed that the impact of stiffness was dependent on hydrogel relaxation.…”

Section: Discussionmentioning

confidence: 65%

“…As previous work has implicated hydrogel stiffness in mediating cartilage matrix formation 20,21,30 , we next examined how altered hydrogel stiffness regulated the effect of relaxation. In hydrogels with an initial elastic modulus of 20 kPa, trends similar to those in 3 kPa gels were observed, with faster relaxation leading to greater areas of type-II collagen and aggrecan deposition as well as higher quantities of secreted collagen and sGAG (Supplementary Fig.…”

Section: Faster Relaxation or Greater Creep Promotes Enhanced Formatimentioning

confidence: 99%

Mechanical confinement regulates cartilage matrix formation by chondrocytes

et al. 2017

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Cartilage tissue equivalents formed from hydrogels containing chondrocytes could provide a solution for replacing damaged cartilage. Previous approaches have often utilized elastic hydrogels. However, elastic stresses may restrict cartilage matrix formation and alter the chondrocyte phenotype. Here we investigated the use of viscoelastic hydrogels, in which stresses are relaxed over time and which exhibit creep, for 3D culture of chondrocytes. We found that faster relaxation promoted a striking increase in the volume of interconnected cartilage matrix formed by chondrocytes. In slower relaxing gels, restriction of cell volume expansion by elastic stresses led to increased secretion of IL-1β, which in turn drove strong up-regulation of genes associated with cartilage degradation and cell death. As no cell adhesion ligands are presented by the hydrogels, these results reveal cell sensing of cell volume confinement as an adhesion-independent mechanism of mechanotransduction in 3D culture, and highlight stress relaxation as a key design parameter for cartilage tissue engineering.

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“…Poly(ethylene glycol) diacrylate (PEGDA)-based hydrogels were used in this study for the establishment of the 3D coculture system, due to their widespread use in cartilage tissue engineering, [34][35][36][37] their easily tunable mechanical properties, 38,39 and their ability to significantly resist cell adhesion even in serum-containing culture environments relative to many biomaterials. 34,40,41 This latter property permits desired cell adhesion to be ''programmed'' into the PEGDA network through conjugation of bioactive moieties.…”

Section: Introductionmentioning

confidence: 99%

A Three-Dimensional Chondrocyte-Macrophage Coculture System to Probe Inflammation in Experimental Osteoarthritis

Samavedi

Díaz‐Rodríguez

Erndt-Marino

et al. 2017

Tissue Engineering Part A

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The goal of the present study was to develop a fully three-dimensional (3D) coculture system that would allow for systematic evaluation of the interplay between activated macrophages (AMs) and chondrocytes in osteoarthritic disease progression and treatment. Toward this end, our coculture system was first validated against existing in vitro osteoarthritis models, which have generally cultured healthy normal chondrocytes (NCs)-in two-dimensional (2D) or 3D-with proinflammatory AMs in 2D. In this work, NCs and AMs were both encapsulated within poly(ethylene glycol) diacrylate hydrogels to mimic the native 3D environments of both cell types within the osteoarthritic joint. As with previous studies, increases in matrix metalloproteinases (MMPs) and proinflammatory cytokines associated with the early stages of osteoarthritis were observed during NC-AM coculture, as were decreases in protein-level Aggrecan and collagen II. Thereafter, the coculture system was extended to osteoarthritic chondrocytes (OACs) and AMs to evaluate the potential effects of AMs on pre-existing osteoarthritic phenotypes. OACs in coculture with AMs expressed significantly higher levels of MMP-1, MMP-3, MMP-9, MMP-13, IL-1b, TNF-a, IL-6, IL-8, and IFN-g compared to OACs in mono-culture, indicating that proinflammatory macrophages may intensify the abnormal matrix degradation and cytokine secretion already associated with OACs. Likewise, AMs cocultured with OACs expressed significantly more IL-1b and VEGF-A compared to AM mono-culture controls, suggesting that OACs may intensify abnormal macrophage activation. Finally, OACs cultured in the presence of nonactivated macrophages produced lower levels of MMP-9 and proinflammatory cytokines IL-1b, TNF-a, and IFN-g compared to OACs in the OAC-AM system, results that are consistent with anti-inflammatory agents temporarily reducing certain OA symptoms. In summary, the 3D coculture system developed herein captures several key features of inflammatory OA and may prove useful in future screening of therapeutic agents and/or assessment of disease progression mechanisms.

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Influence of Physical Properties of Biomaterials on Cellular Behavior

Cited by 154 publications

References 28 publications

Hybrid Cross‐Linking Characteristics of Hydrogel Control Stem Cell Fate

Hybrid Cross‐Linking Characteristics of Hydrogel Control Stem Cell Fate

Mechanical confinement regulates cartilage matrix formation by chondrocytes

A Three-Dimensional Chondrocyte-Macrophage Coculture System to Probe Inflammation in Experimental Osteoarthritis

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