Electrospun PLGA nanofiber scaffolds for articular cartilage reconstruction: mechanical stability, degradation and cellular responses under mechanical stimulation in vitro

Shin, Hong-Jae; Lee, Chang-Hun; Cho, In Hee; Kim, Young-Jick; Lee, Yong-Jae; Kim, In Ae; Park, Kidong; Yui, Nobuhiko; Shin, Jung-Woog

doi:10.1163/156856206774879126

Cited by 226 publications

(115 citation statements)

References 42 publications

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“…Many studies have been carried out in the application of polymer nanofibers in the tissue engineering of bone [159], blood vessel [160], cartilage [161][162][163], cardiac tissue [164], peripheral nerve system [165], ligaments [166], liver [167] and skin [162]. In most of these studies, biodegradable polymer materials such as PCL, PLA, PGA and PLGA were used.…”

Section: Nanofibrous Scaffolds By Electrospinningmentioning

confidence: 99%

Nanostructured materials for applications in drug delivery and tissue engineering

Goldberg

Langer

Jia

2007

Journal of Biomaterials Science, Polymer Edition

943

554

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Research in the areas of drug delivery and tissue engineering has witnessed tremendous progress in recent years due to their unlimited potential to improve human health. Meanwhile, the development of nanotechnology provides opportunities to characterize, manipulate and organize matter systematically at the nanometer scale. Biomaterials with nano-scale organizations have been used as controlled release reservoirs for drug delivery and artificial matrices for tissue engineering. Drug-delivery systems can be synthesized with controlled composition, shape, size and morphology. Their surface properties can be manipulated to increase solubility, immunocompatibility and cellular uptake. The limitations of current drug delivery systems include suboptimal bioavailability, limited effective targeting and potential cytotoxicity. Promising and versatile nano-scale drug-delivery systems include nanoparticles, nanocapsules, nanotubes, nanogels and dendrimers. They can be used to deliver both small-molecule drugs and various classes of biomacromolecules, such as peptides, proteins, plasmid DNA and synthetic oligodeoxynucleotides. Whereas traditional tissue-engineering scaffolds were based on hydrolytically degradable macroporous materials, current approaches emphasize the control over cell behaviors and tissue formation by nano-scale topography that closely mimics the natural extracellular matrix (ECM). The understanding that the natural ECM is a multifunctional nanocomposite motivated researchers to develop nanofibrous scaffolds through electrospinning or self-assembly. Nanocomposites containing nanocrystals have been shown to elicit active bone growth. Drug delivery and tissue engineering are closely related fields. In fact, tissue engineering can be viewed as a special case of drug delivery where the goal is to accomplish controlled delivery of mammalian cells. Controlled release of therapeutic factors in turn will enhance the efficacy of tissue engineering. From a materials point of view, both the drug-delivery vehicles and tissue-engineering scaffolds need to be biocompatible and biodegradable. The biological functions of encapsulated drugs and cells can be dramatically enhanced by designing biomaterials with controlled organizations at the nanometer scale. This review summarizes the most recent development in utilizing nanostructured materials for applications in drug delivery and tissue engineering.

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Section: Nanofibrous Scaffolds By Electrospinningmentioning

confidence: 99%

Nanostructured materials for applications in drug delivery and tissue engineering

Goldberg

Langer

Jia

2007

Journal of Biomaterials Science, Polymer Edition

943

554

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“…89 Finally, reduction in fiber diameter and increase in surface area increases the rate of diffusion of degradation byproducts from the fibers, which could decrease the rate of autocatalytic degradation. [89][90][91][92] It is likely that all three of these factors play a role in polymeric nanofiber degradation and should be taken into consideration when designing nanofibrous constructs for tissue engineering. Further, the material composition of polymeric nanofibers should be tailored to the intended application to support tissue growth or the release of bioactive factors over the proper time course.…”

Section: Degradation Characteristicsmentioning

confidence: 99%

Polymeric Nanofibers in Tissue Engineering

Dahlin

Kasper

Mikos

2011

Tissue Engineering Part B: Reviews

293

198

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Polymeric nanofibers can be produced using methods such as electrospinning, phase separation, and selfassembly, and the fiber composition, diameter, alignment, degradation, and mechanical properties can be tailored to the intended application. Nanofibers possess unique advantages for tissue engineering. The small diameter closely matches that of extracellular matrix fibers, and the relatively large surface area is beneficial for cell attachment and bioactive factor loading. This review will update the reader on the aspects of nanofiber fabrication and characterization important to tissue engineering, including control of porous structure, cell infiltration, and fiber degradation. Bioactive factor loading will be discussed with specific relevance to tissue engineering. Finally, applications of polymeric nanofibers in the fields of bone, cartilage, ligament and tendon, cardiovascular, and neural tissue engineering will be reviewed.

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“…Degradation by-products has been shown to elicit inflammatory response and decreased pH level [98] Mechanical stiffness can sometimes be undesirable [196] Hydrophobicity [196] [197]; [198]; [199]; [197]; [200]; [201]; [202]; [203]; [204]; [205];;…”

Section: Flexibility In Degradation Ratesmentioning

confidence: 99%

Bioengineering of Articular Cartilage: Past, Present and Future

Felimban

Moulton

et al. 2013

Regen. Med.

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The treatment of cartilage defects poses a clinical challenge owing to the lack of intrinsic regenerative capacity of cartilage. The use of tissue engineering techniques to bioengineer articular cartilage is promising and may hold the key to the successful regeneration of cartilage tissue. Natural and synthetic biomaterials have been used to recreate the microarchitecture of articular cartilage through multilayered biomimetic scaffolds. Acellular scaffolds preserve the microarchitecture of articular cartilage through a process of decellularization of biological tissue. Although promising, this technique often results in poor biomechanical strength of the graft. However, biomechanical strength could be improved if biomaterials could be incorporated back into the decellularized tissue to overcome this limitation.

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Electrospun PLGA nanofiber scaffolds for articular cartilage reconstruction: mechanical stability, degradation and cellular responses under mechanical stimulation in vitro

Cited by 226 publications

References 42 publications

Nanostructured materials for applications in drug delivery and tissue engineering

Nanostructured materials for applications in drug delivery and tissue engineering

Polymeric Nanofibers in Tissue Engineering

Bioengineering of Articular Cartilage: Past, Present and Future

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