Three dimensional extrusion printing induces polymer molecule alignment and cell organization within engineered cartilage

Guo, Ting; Ringel, Julia P.; Lim, Casey G.; Bracaglia, Laura G.; Noshin, Maeesha; Baker, Hannah B.; Powell, Douglas; Fisher, John P.

doi:10.1002/jbm.a.36426

Cited by 31 publications

(23 citation statements)

References 35 publications

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“…101 hMSCs increased expression of markers for the superficial zone of cartilage on aligned fibers. 102 hMSCs increased expression of osteogenic markers RUNX2 , ALP , and OCN on aligned parallel electrospun fibers more than on orthogonally aligned fibers, 46 possibly due to increased intercellular communication via gap junctions. In contrast, human skeletal stem cells increased mineral production and ALP activity on MEW fibers patterned at 90° angles more than those angled at 45° or 10°, or randomly oriented fibers.…”

Section: General Fiber Parameters: Fiber Alignmentmentioning

confidence: 98%

Synthetic scaffolds for musculoskeletal tissue engineering: cellular responses to fiber parameters

2019

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Tissue engineering often uses synthetic scaffolds to direct cell responses during engineered tissue development. Since cells reside within specific niches of the extracellular matrix, it is important to understand how the matrix guides cell response and then incorporate this knowledge into scaffold design. The goal of this review is to review elements of cell–matrix interactions that are critical to informing and evaluating cellular response on synthetic scaffolds. Therefore, this review examines fibrous proteins of the extracellular matrix and their effects on cell behavior, followed by a discussion of the cellular responses elicited by fiber diameter, alignment, and scaffold porosity of two dimensional (2D) and three dimensional (3D) synthetic scaffolds. Variations in fiber diameter, alignment, and scaffold porosity guide stem cells toward different lineages. Cells generally exhibit rounded morphology on nanofibers, randomly oriented fibers, and low-porosity scaffolds. Conversely, cells exhibit elongated, spindle-shaped morphology on microfibers, aligned fibers, and high-porosity scaffolds. Cells migrate with higher velocities on nanofibers, aligned fibers, and high-porosity scaffolds but migrate greater distances on microfibers, aligned fibers, and highly porous scaffolds. Incorporating relevant biomimetic factors into synthetic scaffolds destined for specific tissue application could take advantage of and further enhance these responses.

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Section: General Fiber Parameters: Fiber Alignmentmentioning

confidence: 98%

Synthetic scaffolds for musculoskeletal tissue engineering: cellular responses to fiber parameters

2019

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“…[11] Although in this study, the thickness of cartilage tissue in rabbit limited the possibility of implanting a zonal scaffold, it would be of interest to evaluate the ability of a 3D-printed scaffold with a biomimetic zonal structure to induce cell alignment in different regions in a larger animal model with a longer recovery time. [16, 46]…”

Section: Discussionmentioning

confidence: 99%

3D printed biofunctionalized scaffolds for microfracture repair of cartilage defects

et al. 2018

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While articular cartilage defects affect millions of people worldwide from adolescents to adults, the repair of articular cartilage defects still remains challenging due to the limited endogenous regeneration of the tissue and poor integration with implants. In this study, we developed a 3D-printed scaffold functionalized with aggrecan that supports the cellular fraction of bone marrow released from microfracture, a widely used clinical procedure, and demonstrated tremendous improvement of regenerated cartilage tissue quality and joint function in a lapine model. Optical coherence tomography (OCT) revealed doubled thickness of the regenerated cartilage tissue in the group treated with our aggrecan functionalized scaffold compared to standard microfracture treatment. H&E staining showed 366 ± 95 chondrocytes present in the unit area of cartilage layer with the support of bioactive scaffold, while conventional microfracture group showed only 112 ± 26 chondrocytes. The expression of type II collagen appeared almost 10 times higher with our approach compared to normal microfracture, indicating the potential to overcome the fibro-cartilage formation associated with the current microfracture approach. The therapeutic effect was also evaluated at joint function level. The mobility was evaluated using a modified Basso, Beattie and Bresnahan (BBB) scale. While the defect control group showed no movement improvement over the course of study, all experimental groups showed a trend of increasing scores over time. The present work developed an effective method to regenerate critical articular defects by combining a 3D-printed therapeutic scaffold with the microfracture surgical procedure. This biofunctionalized acellular scaffold has great potential to be applied as a supplement for traditional microfracture to improve the quality of cartilage regeneration in a cost and labor effective way.

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“…After the excess media had been diluted by washing, the scaffolds were incubated in live/dead solution-composed of 2 mM Ethdium Homodimer-1 (EH; ThermoFisher Scientific), 4 mM Calcein AM (CAM; ThermoFisher Scientific), and 1mL HBSS per scaffold for 30 minutes in the dark. Scaffolds were contained in PBS until observation via confocal microscopy [39].…”

Section: Methodsmentioning

confidence: 99%

3D printing bioactive PLGA scaffolds using DMSO as a removable solvent

et al. 2018

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Present bioprinting techniques lack the methodology to print with bioactive materials that retain their biological functionalities. This constraint is due to the fact that extrusion-based printing of synthetic polymers is commonly performed at very high temperatures in order to achieve desired mechanical properties and printing resolutions. Consequently, current methodology prevents printing scaffolds embedded with bioactive molecules, such as growth factors. With the wide use of mesenchymal stem cells (MSCs) in regenerative medicine research, the integration of growth factors into 3D printed scaffolds is critical because it can allow for inducible MSC differentiation. We have successfully incorporated growth factors into extrusion printed poly (lactic-co-glycolic acid) (PLGA) scaffolds by introducing dimethyl sulfoxide (DMSO) for low temperature printing. Mechanical testing results demonstrated significantly different compressive and tensile properties for PLGA scaffold printed with or without DMSO. In particular, the PLGA-DMSO scaffold displayed a highly stretchable feature compared to the regular PLGA scaffold. The cellular response of growth factor introduction was evaluated in vitro using human mesenchymal stem cells (hMSCs). By evaporating the DMSO after printing, we ensured that there was no cytotoxic effect on seeded hMSCs. The addition of lineage specific growth factors led to increased expression of corresponding genetic markers for chondrogenesis, osteogenesis, and adipogenesis. We concluded that the use of DMSO for 3D printed scaffold fabrication with bioactive items is a revolutionary methodology in advancing regenerative medicine. The incorporation of bioactive molecules opens pathways to more therapeutic uses for 3D printing in treating damaged or deteriorating native tissue.

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Three dimensional extrusion printing induces polymer molecule alignment and cell organization within engineered cartilage

Cited by 31 publications

References 35 publications

Synthetic scaffolds for musculoskeletal tissue engineering: cellular responses to fiber parameters

Synthetic scaffolds for musculoskeletal tissue engineering: cellular responses to fiber parameters

3D printed biofunctionalized scaffolds for microfracture repair of cartilage defects

3D printing bioactive PLGA scaffolds using DMSO as a removable solvent

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