2021
DOI: 10.1016/j.msec.2021.111930
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Development of electrospun core–shell polymeric mat using poly (ethyl-2) cyanoacrylate/polyurethane to attenuate biological adhesion on polymeric mesh implants

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Cited by 3 publications
(3 citation statements)
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“…The as-designed mesh displayed excellent mechanical strength, biocompatibility, and collagen deposition, exhibiting good anti-hernia and anti-adhesion effects. One more adhesion-free composite material was reported by Chalony et al [72], who fabricated a biocompatible non-woven material from poly (ethyl-2) cyanoacrylate reinforced by polyurethane. The composite fibrous architecture demonstrated adequate mechanical properties for repairing the viscera layer if used as intraperitoneal hernia mesh implants.…”
Section: Other Innovative Materialsmentioning
confidence: 99%
“…The as-designed mesh displayed excellent mechanical strength, biocompatibility, and collagen deposition, exhibiting good anti-hernia and anti-adhesion effects. One more adhesion-free composite material was reported by Chalony et al [72], who fabricated a biocompatible non-woven material from poly (ethyl-2) cyanoacrylate reinforced by polyurethane. The composite fibrous architecture demonstrated adequate mechanical properties for repairing the viscera layer if used as intraperitoneal hernia mesh implants.…”
Section: Other Innovative Materialsmentioning
confidence: 99%
“…Electrospinning acts as an efficient smart platform in a wide range of regenerative tissue applications (tendon, cartilage, cardiovascular, neural, skin, and bone regeneration) as the potential solution to current biomaterial (such as hydrogels) limitations. Coaxial electrospinning [ 318 ], direct blending [ 319 ], emulsion electrospinning [ 320 ], and surface modification [ 321 ] are the most common two-dimensional or 3D tissue engineering scaffold fabrication methods. Since most electrospinning materials are hydrophobic and lack bioactive sites for cell recognition and adhesion, fiber functionalization is sometimes necessary for electrospun fibers to be applied in regenerative medicine [ 322 , 323 ].…”
Section: Smart Engineered Materials For Abdominal Herniamentioning
confidence: 99%
“…Chalony and colleagues [ 114 ] focused their research on creating an adhesion-free, biocompatible, nonwoven material. In this respect, they used poly (ethyl-2) cyanoacrylate reinforced by polyurethane core to generate an electrospun composite mat.…”
Section: Materials Optimization Strategiesmentioning
confidence: 99%