scholarly journals Effects of cell phenotype and seeding density on the chondrogenic capacity of human osteoarthritic chondrocytes in type I collagen scaffolds

2020 ◽  
Vol 15 (1) ◽  
Author(s):  
Chenxi Cao ◽  
Yujun Zhang ◽  
Yanqi Ye ◽  
Tiezheng Sun
Keyword(s):  
Type I Collagen ◽  
Seeding Density ◽  
Cell Phenotype ◽  
Type I ◽  
Collagen Scaffolds ◽  
Osteoarthritic Chondrocytes

Scaffolds for Engineering Smooth Muscle Under Cyclic Mechanical Strain Conditions

2000 ◽  
Vol 122 (3) ◽  
pp. 210-215 ◽  
Author(s):  
Byung-Soo Kim ◽  
David J. Mooney
Keyword(s):  
Smooth Muscle ◽  
Type I Collagen ◽  
Permanent Deformation ◽  
Mechanical Strain ◽  
Dynamic Environment ◽  
Cyclic Strain ◽  
Time Frame ◽  
Elastic Behavior ◽  
Cell Phenotype ◽  
Type I

Cyclic mechanical strain has been demonstrated to enhance the development and function of engineered smooth muscle (SM) tissues, but appropriate scaffolds for engineering tissues under conditions of cyclic strain are currently lacking. These scaffolds must display elastic behavior, and be capable of inducing an appropriate smooth muscle cell (SMC) phenotype in response to mechanical signals. In this study, we have characterized several scaffold types commonly utilized in tissue engineering applications in order to select scaffolds that exhibit elastic properties under appropriate cyclic strain conditions. The ability of the scaffolds to promote an appropriate SMC phenotype in engineered SM tissues under cyclic strain conditions was subsequently analyzed. Poly(L-lactic acid)-bonded polyglycolide fiber-based scaffolds and type I collagen sponges exhibited partially elastic mechanical properties under cyclic strain conditions, although the synthetic polymer scaffolds demonstrated significant permanent deformation after extended times of cyclic strain application. SM tissues engineered with type I collagen sponges subjected to cyclic strain were found to contain more elastin than control tissues, and the SMCs in these tissues exhibited a contractile phenotype. In contrast, SMCs in control tissues exhibited a structure more consistent with the nondifferentiated, synthetic phenotype. These studies indicate the appropriate choice of a scaffold for engineering tissues in a mechanically dynamic environment is dependent on the time frame of the mechanical stimulation, and elastic scaffolds allow for mechanically directed control of cell phenotype in engineered tissues. [S0148-0731(00)00103-5]

scholarly journals Maintenance of chondrocyte phenotype during expansion on PLLA microtopographies

2018 ◽  
Vol 9 ◽  
pp. 204173141878982 ◽  
Author(s):  
Elisa Costa ◽  
Cristina González-García ◽  
José Luis Gómez Ribelles ◽  
Manuel Salmerón-Sánchez
Keyword(s):  
Lactic Acid ◽  
Type I Collagen ◽  
Collagen Type ◽  
Articular Chondrocytes ◽  
Collagen Type I ◽  
Cell Phenotype ◽  
Type I ◽  
Type Ii ◽  
Collagen Type Ii ◽  
Chondrocyte Phenotype

Articular chondrocytes are difficult to grow, as they lose their characteristic phenotype following expansion on standard tissue culture plates. Here, we show that culturing them on surfaces of poly(L-lactic acid) of well-defined microtopography allows expansion and maintenance of characteristic chondrogenic markers. We investigated the dynamics of human chondrocyte dedifferentiation on the different poly(L-lactic acid) microtopographies by the expression of collagen type I, collagen type II and aggrecan at different culture times. When seeded on poly(L-lactic acid), chondrocytes maintained their characteristic hyaline phenotype up to 7 days, which allowed to expand the initial cell population approximately six times without cell dedifferentiation. Maintenance of cell phenotype was afterwards correlated to cell adhesion on the different substrates. Chondrocytes adhesion occurs via the α5 β1 integrin on poly(L-lactic acid), suggesting cell–fibronectin interactions. However, α2 β1 integrin is mainly expressed on the control substrate after 1 day of culture, and the characteristic chondrocytic markers are lost (collagen type II expression is overcome by the synthesis of collagen type I). Expanding chondrocytes on poly(L-lactic acid) might be an effective solution to prevent dedifferentiation and improving the number of cells needed for autologous chondrocyte transplantation.

scholarly journals Increased Fibroblast Metabolic Activity of Collagen Scaffolds via the Addition of Propolis Nanoparticles

Materials ◽  
2020 ◽  
Vol 13 (14) ◽  
pp. 3118
Author(s):  
Jeimmy González-Masís ◽  
Jorge M. Cubero-Sesin ◽  
Yendry R. Corrales-Ureña ◽  
Sara González-Camacho ◽  
Nohelia Mora-Ugalde ◽  
...  
Keyword(s):  
Metabolic Activity ◽  
Self Assembly ◽  
Type I Collagen ◽  
Fibroblast Cell ◽  
Antimicrobial Activities ◽  
Hydrodynamic Diameter ◽  
Type I ◽  
Collagen Scaffolds ◽  
Simple Method ◽  
Socially Relevant

Propolis natural extracts have been used since ancient times due to their antioxidant, anti-inflammatory, antiviral, and antimicrobial activities. In this study, we produced scaffolds of type I collagen, extracted from Wistar Hanover rat tail tendons, and impregnated them with propolis nanoparticles (NPs) for applications in regenerative medicine. Our results show that the impregnation of propolis NPs to collagen scaffolds affected the collagen denaturation temperature and tensile strength. The changes in structural collagen self-assembly due to contact with organic nanoparticles were shown for the first time. The fibril collagen secondary structure was preserved, and the D-pattern gap increased to 135 ± 28 nm, without losing the microfiber structure. We also show that the properties of the collagen scaffolds depended on the concentration of propolis NPs. A concentration of 100 μg/mL of propolis NPs with 1 mg of collagen, with a hydrodynamic diameter of 173 nm, was found to be an optimal concentration to enhance 3T3 fibroblast cell metabolic activity and cell proliferation. The expected outcome from this research is both scientifically and socially relevant since the home scaffold using natural nanoparticles can be produced using a simple method and could be widely used for local medical care in developing communities.

scholarly journals Interstitial Perfusion Culture with Specific Soluble Factors Inhibits Type I Collagen Production from Human Osteoarthritic Chondrocytes in Clinical-Grade Collagen Sponges

PLoS ONE ◽  
2016 ◽  
Vol 11 (9) ◽  
pp. e0161479 ◽  
Author(s):  
Nathalie Mayer ◽  
Silvia Lopa ◽  
Giuseppe Talò ◽  
Arianna B. Lovati ◽  
Marielle Pasdeloup ◽  
...  
Keyword(s):  
Type I Collagen ◽  
Perfusion Culture ◽  
Type I ◽  
Clinical Grade ◽  
Soluble Factors ◽  
Collagen Production ◽  
Osteoarthritic Chondrocytes

scholarly journals Experimental and Modeling Study of Collagen Scaffolds with the Effects of Crosslinking and Fiber Alignment

2011 ◽  
Vol 2011 ◽  
pp. 1-12 ◽  
Author(s):  
Bin Xu ◽  
Ming-Jay Chow ◽  
Yanhang Zhang
Keyword(s):  
Magnetic Particles ◽  
Type I Collagen ◽  
Collagen Gel ◽  
Collagen Type I ◽  
Mechanical Tests ◽  
Type I ◽  
Collagen Scaffolds ◽  
Fiber Alignment ◽  
Biaxial Tensile ◽  
Anisotropic Mechanical Properties

Collagen type I scaffolds are commonly used due to its abundance, biocompatibility, and ubiquity. Most applications require the scaffolds to operate under mechanical stresses. Therefore understanding and being able to control the structural-functional integrity of collagen scaffolds becomes crucial. Using a combined experimental and modeling approach, we studied the structure and function of Type I collagen gel with the effects of spatial fiber alignment and crosslinking. Aligned collagen scaffolds were created through the flow of magnetic particles enmeshed in collagen fibrils to mimic the anisotropy seen in native tissue. Inter- and intra- molecular crosslinking was modified chemically with Genipin to further improve the stiffness of collagen scaffolds. The anisotropic mechanical properties of collagen scaffolds were characterized using a planar biaxial tensile tester and parallel plate rheometer. The tangent stiffness from biaxial tensile test is two to three orders of magnitude higher than the storage moduli from rheological measurements. The biphasic nature of collagen gel was discussed and used to explain the mechanical behavior of collagen scaffolds under different types of mechanical tests. An anisotropic hyperelastic constitutive model was used to capture the characteristics of the stress-strain behavior exhibited by collagen scaffolds.

Modifying the Properties of Collagen Scaffolds with Microfluidics

2005 ◽  
Vol 897 ◽  
Author(s):  
David I Shreiber ◽  
Harini G Sundararaghavan ◽  
Minjung Song ◽  
Vikram Munikoti ◽  
Kathryn E Uhrich
Keyword(s):  
Mechanical Properties ◽  
Cell Adhesion ◽  
Cellular Response ◽  
Type I Collagen ◽  
Crosslinking Agent ◽  
Force Balance ◽  
Adherent Cell ◽  
Type I ◽  
Spinal Cord Regeneration ◽  
Collagen Scaffolds

AbstractIt is now well accepted that the mechanical properties and cell adhesion profile of 2D and 3D extracellular matrix molecules combine to dictate cellular fate processes, such as differentiation, migration, proliferation, and apoptosis, through a process generally known as 'mechanotransduction', or the conversion of mechanical signals into a cellular response. The stiffness and adhesion density combine to affect the force balance that exists between an adherent cell and the surrounding substrate. We have established BioMEMS, microfluidic technology to alter the mechanical properties and cell adhesion profile of collagen scaffolds. Using soft lithography, we fabricate elastomeric networks that serve as conduits for the controlled mixing of type I collagen solutions. Our technology enables us to generate reproducible, controlled homogeneous and inhomogeneous microenvironments for 3D cell culture, assays of cell behavior in 3D, and the development of bioartificial tissue equivalents for regenerative and reparative therapies. The adhesivity of collagen is modulated by covalently grafting peptides (such as RGD) or proteins (such as albumin) to soluble collagen molecules with 1- ethyl-3-(3-dimethyl aminopropyl) carbodiimide (EDC), a hetero-bifunctional coupling agent. EDC activates the carboxylic group of collagen and forms an amine bond with the grafting molecule. The grafted collagen self-assembles into a fibrillar gel at physiological temperature and pH with no measurable changes in rheological properties compared to controls. A solution of peptide-grafted collagen is then mixed in microfluidic networks with unaltered collagen to form controlled gradients or other patterns of the two solutions, which immobilize upon self-assembly. Separately or in the same network, the mechanical properties of the collagen gel can be altered regionally by the microfluidic delivery a solution of a cell-tolerated crosslinking agent. We use genipin, which has the unique property of generating crosslinks that autofluoresce. The intensity of the fluorescence correlates with the degree of crosslinking (and thus the mechanical properties) enabling us to monitor and measure changes in mechanical properties dynamically and non-invasively. Lastly, though it requires constant delivery or recirculation, the same networks can be used to impose gradients of soluble factors, such as growth factors and cytokines. Thus, we have developed a platform to examine the response of cells to simultaneous chemotactic, haptotactic, and durotactic gradients in a 3D environment. We are employing this technology to examine the response of neural cells to gradients of biomaterial properties to optimize cues for spinal cord regeneration.

Mechanics and Cytocompatibility of Genipin Crosslinked Type I Collagen Nanofibrous Scaffolds

2008 ◽  
Author(s):  
Albert O. Gee ◽  
Brendon M. Baker ◽  
Robert L. Mauck
Keyword(s):  
Type I Collagen ◽  
Cell Attachment ◽  
Type I ◽  
Primary Role ◽  
Fiber Reinforced ◽  
Collagen Scaffolds ◽  
Major Drawback ◽  
Aligned Arrays ◽  
Musculoskeletal Tissues ◽  
Nanofibrous Scaffolds

Collagen is a principal constituent of the extracellular matrix (ECM) and as such, defines the microenvironmental milieu in which cells reside. In fiber-reinforced musculoskeletal tissues, collagen fibers are highly organized and generate the direction-dependent mechanical properties critical to the function of these structures. Given its primary role, collagen is particularly attractive for tissue engineering (TE) applications where scaffolds are coupled with cells to repair or regenerate damaged tissues. One method for producing collagen-based scaffolds is through electrospinning. This technique yields nano- to micron-scale fibers similar in diameter to those of the native ECM. Towards engineering orthopaedic tissues, methods have been devised to electrospin fibers into aligned arrays that can recapitulate the anisotropy of fiber-reinforced tissues [1]. While a number of polymers have been electrospun, collagen-based scaffolds are especially promising as they provide a biomimetic interface for cell attachment [2]. Numerous investigators have electrospun collagen [3], one major drawback is their inherent instability in aqueous environments. To address this, various crosslinking agents including glutaraldehyde (GA), 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride, and N-hydroxysuccinimide chemistries have been used, but these chemicals often prove cytotoxic or excessively laborious in application [4]. Even with crosslinking, dry as-formed nanofibrous collagen scaffolds with moduli greater than 50MPa diminish by 100-fold with rehydration [5].

scholarly journals Modelling fibrillogenesis of collagen-mimetic molecules

2020 ◽  
Author(s):  
A. E. Hafner ◽  
N. G. Gyori ◽  
C. A. Bench ◽  
L. K. Davis ◽  
A. Šarić
Keyword(s):  
Extracellular Matrix ◽  
Electrostatic Interactions ◽  
Collagen Type ◽  
Collagen Type I ◽  
Coarse Grained ◽  
Cell Phenotype ◽  
Type I ◽  
Collagen Scaffolds ◽  
Crucial Component ◽  
Self Assembled

One of the most robust examples of self-assembly in living organisms is the formation of collagen architectures. Collagen type I molecules are a crucial component of the extracellular-matrix where they self-assemble into fibrils of well defined striped patterns. This striped fibrilar pattern is preserved across the animal kingdom and is important for the determination of cell phenotype, cell adhesion, and tissue regulation and signalling. The understanding of the physical processes that determine such a robust morphology of self-assembled collagen fibrils is currently almost completely missing. Here we develop a minimal coarse-grained computational model to identify the physical principles of the assembly of collagen-mimetic molecules. We find that screened electrostatic interactions can drive the formation of collagen-like filaments of well-defined striped morphologies. The fibril pattern is determined solely by the distribution of charges on the molecule and is robust to the changes in protein concentration, monomer rigidity, and environmental conditions. We show that the fibril pattern cannot be easily predicted from the interactions between two monomers, but is an emergent result of multi-body interactions. Our results can help address collagen remodelling in diseases and ageing, and guide the design of collagen scaffolds for biotechnological applications.Statement of SignificanceCollagen type I protein is the most abundant protein in mammals. It is a crucial component of the extracellular-matrix where it robustly self-assembles into fibrils of specific striped architectures that are crucial for the correct collagen function. The molecular features that determine such robust fibril architectures are currently not well understood. Here we develop a minimal coarse-grained model to connect the design of collagen-like molecules to the architecture of the resulting self-assembled fibrils. We find that the pattern of charged residues on the surface of molecules can drive the formation of collagen-like fibrils and fully control their architectures. Our findings can help understand changes in collagen architectures observed in diseases and guide the design of synthetic collagen scaffolds.

Sign in / Sign up

Export Citation Format

Share Document