Roshan James scite author profile

Electrospinning has emerged to be a simple, elegant and scalable technique to fabricate polymeric nanofibers. Pure polymers as well as blends and composites of both natural and synthetics have been successfully electrospun into nanofiber matrices. Physiochemical properties of nanofiber matrices can be controlled by manipulating electrospinning parameters to meet the requirements of a specific application. Such efforts include the fabrication of fiber matrices containing nanofibers, microfibers, combination of nano-microfibers and also different fiber orientation/alignments. Polymeric nanofiber matrices have been extensively investigated for diversified uses such as filtration, barrier fabrics, wipes, personal care, biomedical and pharmaceutical applications. Recently electrospun nanofiber matrices have gained a lot of attention, and are being explored as scaffolds in tissue engineering due to their properties that can modulate cellular behavior. Electrospun nanofiber matrices show morphological similarities to the natural extra-cellular matrix (ECM), characterized by ultrafine continuous fibers, high surface-to-volume ratio, high porosity and variable pore-size distribution. Efforts have been made to modify nanofiber surfaces with several bioactive molecules to provide cells with the necessary chemical cues and a more in vivo like environment. The current paper provides an overlook on such efforts in designing nanofiber matrices as scaffolds in the regeneration of various soft tissues including skin, blood vessel, tendon/ligament, cardiac patch, nerve and skeletal muscle.

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Electrospun poly(lactic acid-co-glycolic acid) scaffolds for skin tissue engineering

Kumbar

et al. 2008

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Electrospun fiber matrices composed of scaffolds of varying fiber diameters were investigated for potential application of severe skin loss. Few systematic studies have been performed to examine the effect of varying fiber diameter electrospun fiber matrices for skin regeneration. The present study reports the fabrication of poly[lactic acid-co-glycolic acid] (PLAGA) matrices with fiber diameters of 150-225, 200-300, 250-467, 500-900, 600-1200, 2500-3000 and 3250-6000 nm via electrospinning. All fiber matrices found to have a tensile modulus from 39.23 ± 8.15 to 79.21 ± 13.71 MPa which falls in the range for normal human skin. Further, the porous fiber matrices have porosity between 38-60 % and average pore diameters between 10-14µm. We evaluated the efficacy of these biodegradable fiber matrices as skin substitutes by seeding them with human skin fibroblasts (hSF). Human skin fibroblasts acquired a well spread morphology and showed significant progressive growth on fiber matrices in the 350-1100 nm diameter range. Collagen type III gene expression was significantly up-regulated in hSF seeded on matrices with fiber diameters in the range of 350-1100 nm. Based on the need, the proposed fiber skin substitutes can be successfully fabricated and optimized for skin fibroblast attachment and growth.

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Polysaccharide biomaterials for drug delivery and regenerative engineering

Shelke

James

Laurencin

et al. 2014

Polymers for Advanced Techs

255

148

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Polymers derived from plant (polysaccharides) and animal (proteins) kingdoms have been widely used for a variety of biomedical applications including drug delivery and tissue regeneration. These polymers due to their biochemical similarity with human extracellular matrix components are readily recognized and accepted by the body. Natural polymers inherit numerous advantages including natural abundance, relative ease of isolation, and room for chemical modification to meet varying technological needs. In addition, these polymers undergo enzymatic and/or hydrolytic degradation in biologic environments into non-toxic degradation byproducts. Polysaccharides (carbohydrates) are often isolated and purified from renewable sources including plants, animals, and microorganisms. Majority of these polymers are found in the extracellular matrix components of organisms and participate in inter and intracellular cell signaling and contribute to their growth. All these features offer polysaccharide-based biomaterials much desired biological recognition, biocompatibility, and bioactivity. In spite of many merits as biomaterials, these polysaccharides suffer from drawbacks including variations in material properties based on source, microbial contamination, uncontrolled water uptake, poor mechanical strength, and unpredictable degradation patterns. These inconsistencies have limited the usage of polysaccharides and biomedical application related technology development. Many of these polysaccharides have been chemically modified to achieve consistent physicochemical properties including mechanical stability, degradation, and bioactivity and processed into microparticles, hydrogels, and 3D porous structures for tissue regeneration applications. Presence of multiple functionalities on the polymer backbone allows easy structure modifications for the required application. The current article focuses on the application of polysaccharide-based materials in regenerative engineering and delivery.

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Roshan James

Tendon: Biology, Biomechanics, Repair, Growth Factors, and Evolving Treatment Options

Electrospun nanofiber scaffolds: engineering soft tissues

Electrospun poly(lactic acid-co-glycolic acid) scaffolds for skin tissue engineering

Polysaccharide biomaterials for drug delivery and regenerative engineering

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