3D Printed Chitosan Composite Scaffold for Chondrocytes Differentiation

Sahai, Nitin; Gogoi, Manashjit; Tewari, Ravi Prakash

doi:10.2174/1573405616666201217112939

Cited by 9 publications

(9 citation statements)

References 46 publications

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“…65,66 Among them, a simple and efficient process is lyophilisation, which starts with freezing a solution of chitosan with or without additives followed by evaporation of the solvent under reduced pressure. 67,68 At present, there are numerous techniques available to fabricate a chitosan-based membrane or scaffold for tissue engineering such as particle salt leaching, 69,70 electrospinning, 71,72 stereolithography, 73,74 gas foaming, 75,76 freeze-drying, 57,67,75 and 3D bioprinting. [77][78][79][80] Electrospinning is a simple, straightforward, and costeffective technique for producing nanofibers.…”

Section: Chitosan-based Nanocomposite Scaffolds For Tissue Engineeringmentioning

confidence: 99%

“…At present, there are numerous techniques available to fabricate a chitosan‐based membrane or scaffold for tissue engineering such as particle salt leaching, 69,70 electrospinning, 71,72 stereolithography, 73,74 gas foaming, 75,76 freeze‐drying, 57,67,75 and 3D bioprinting 77–80 . Electrospinning is a simple, straightforward, and cost‐effective technique for producing nanofibers.…”

Section: Chitosan‐based Nanocomposite Scaffolds For Tissue Engineeringmentioning

confidence: 99%

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Chitosan‐based nanocomposites for medical applications

Murugesan

Scheibel

2021

Journal of Polymer Science

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Chitosan as a biobased polymer is gaining increasing attention due to its extraordinary physico-chemical characteristics and properties. While a primary use of chitosan has been in horticultural and agricultural applications for plant defense and to increase crop yield, recent research reports display various new utilizations in the field of advanced biomedical devices, targeted drug delivery, and as bioimaging sensors. Chitosan possesses multiple characteristics such as antimicrobial properties, stimuli-responsiveness, tunable mechanical strength, biocompatibility, biodegradability, and water-solubility. Further, chitosan can be processed into nanoparticles, nano-vehicles, nanocapsules, scaffolds, fiber meshes, and 3D printed scaffolds for a variety of applications. In recent times, nanoparticles incorporated in chitosan matrices have been identified to show superior biological activity, as cells tend to proliferate/differentiate faster when they interact with nanocomposites rather than bulk or micron size substrates/scaffolds. The present article intents to cover chitosan-based nanocomposites used for regenerative medicine, wound dressings, drug delivery, and biosensing applications.

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Section: Chitosan-based Nanocomposite Scaffolds For Tissue Engineeringmentioning

confidence: 99%

Section: Chitosan‐based Nanocomposite Scaffolds For Tissue Engineeringmentioning

confidence: 99%

Chitosan‐based nanocomposites for medical applications

Murugesan

Scheibel

2021

Journal of Polymer Science

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“…This technique makes it possible to control the average pore diameterwhich varies from 1 to 250 μm-by means of freezing conditions. An alternative is the manufacturing of chitosan scaffolds by 3D printing, a technique that allows us to obtain systems with a tightly controlled shape and structure [40]. Finally, it is also possible to obtain self-assembled scaffolds.…”

Section: Scaffoldsmentioning

confidence: 99%

Applications of Chitosan in Surgical and Post-Surgical Materials

et al. 2022

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The continuous advances in surgical procedures require continuous research regarding materials with surgical applications. Biopolymers are widely studied since they usually provide a biocompatible, biodegradable, and non-toxic material. Among them, chitosan is a promising material for the development of formulations and devices with surgical applications due to its intrinsic bacteriostatic, fungistatic, hemostatic, and analgesic properties. A wide range of products has been manufactured with this polymer, including scaffolds, sponges, hydrogels, meshes, membranes, sutures, fibers, and nanoparticles. The growing interest of researchers in the use of chitosan-based materials for tissue regeneration is obvious due to extensive research in the application of chitosan for the regeneration of bone, nervous tissue, cartilage, and soft tissues. Chitosan can serve as a substance for the administration of cell-growth promoters, as well as a support for cellular growth. Another interesting application of chitosan is hemostasis control, with remarkable results in studies comparing the use of chitosan-based dressings with traditional cotton gauzes. In addition, chitosan-based or chitosan-coated surgical materials provide the formulation with antimicrobial activity that has been highly appreciated not only in dressings but also for surgical sutures or meshes.

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“…Composite applications provide a promising method for the development of superior biomaterials [ 42 ]. The chitosan-alginate-gelatin composite hydrogel can promote the chondrogenic differentiation of hMSCs and contribute to cartilage regeneration in patients with related cartilage diseases [ 52 ]. Some researchers put hepatocyte-like cells derived from human pluripotent stem cells into the widely used animal-derived hydrogel Matrigel, which is a plant-derived nanocellulose hydrogel in agarose microporous 3D culture plates.…”

Section: Three-dimensional Stem Cell Culture Systemsmentioning

confidence: 99%

Recent Advances in Three-Dimensional Stem Cell Culture Systems and Applications

Wei

et al. 2021

Stem Cells International

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Cell culture is one of the most core and fundamental techniques employed in the fields of biology and medicine. At present, although the two-dimensional cell culture method is commonly used in vitro, it is quite different from the cell growth microenvironment in vivo. In recent years, the limitations of two-dimensional culture and the advantages of three-dimensional culture have increasingly attracted more and more attentions. Compared to two-dimensional culture, three-dimensional culture system is better to realistically simulate the local microenvironment of cells, promote the exchange of information among cells and the extracellular matrix (ECM), and retain the original biological characteristics of stem cells. In this review, we first present three-dimensional cell culture methods from two aspects: a scaffold-free culture system and a scaffold-based culture system. The culture method and cell characterizations will be summarized. Then the application of three-dimensional cell culture system is further explored, such as in the fields of drug screening, organoids and assembloids. Finally, the directions for future research of three-dimensional cell culture are stated briefly.

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3D Printed Chitosan Composite Scaffold for Chondrocytes Differentiation

Cited by 9 publications

References 46 publications

Chitosan‐based nanocomposites for medical applications

Chitosan‐based nanocomposites for medical applications

Applications of Chitosan in Surgical and Post-Surgical Materials

Recent Advances in Three-Dimensional Stem Cell Culture Systems and Applications

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