Photofabricated Gelatin-Based Nerve Conduits: Nerve Tissue Regeneration Potentials

Gámez, Eduardo; Goto, Yoshinobu; Nagata, Kazuhiro; Iwaki, Toru; Sasaki, Tomio; Matsuda, Takehisa

doi:10.3727/000000004783983639

Cited by 62 publications

(56 citation statements)

References 34 publications

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“…84 As our knowledge of synthetic materials grows and the technology of manufacturing processes advances, we will no doubt see more novel materials, such as glass, 85 being used as luminal fillers to enhance nerve regeneration.…”

Section: Synthetic Longitudinal Matricesmentioning

confidence: 99%

Luminal Fillers in Nerve Conduits for Peripheral Nerve Repair

Chen

Zhang

Lineaweaver

2006

Annals of Plastic Surgery

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The use of nerve conduits as an alternative for nerve grafting has a long experimental and clinical history. Luminal fillers, factors introduced into these nerve conduits, were later developed to enhance the nerve regeneration through conduits. Though many luminal fillers have been reported to improve nerve regeneration, their use has not been subjected to systematic review. This review categorizes the types of fillers used, the conduits associated with fillers, and the reported performance of luminal fillers in conduits to present a preference list for the most effective fillers to use over specific distances of nerve defect.

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Section: Synthetic Longitudinal Matricesmentioning

confidence: 99%

Luminal Fillers in Nerve Conduits for Peripheral Nerve Repair

Chen

Zhang

Lineaweaver

2006

Annals of Plastic Surgery

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“…By changing the pH of collagen solutions, gel formation can be induced. Denatured collagen, known as gelatin, has also been evaluated for use as a potential scaffold [56]. Collagen gels are natural materials but an immune response could arise if cross species transplantation is used.…”

Section: Synthetic Materials-syntheticmentioning

confidence: 99%

Approaches to neural tissue engineering using scaffolds for drug delivery

Willerth

Sakiyama‐Elbert

2007

Advanced Drug Delivery Reviews

333

249

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This review seeks to give an overview of the current approaches to drug delivery from scaffolds for neural tissue engineering applications. The challenges presented by attempting to replicate the three types of nervous tissue (brain, spinal cord, and peripheral nerve) are summarized. Potential scaffold materials (both synthetic and natural) and target drugs are discussed with the benefits and drawbacks given. Finally, common methods of drug delivery, including degradable/diffusion-based delivery systems, affinity-based delivery systems, immobilized drug delivery systems, and electrically controlled drug delivery systems, are examined and critiqued. Based on the current body of work, suggestions for future directions of research in the field of neural tissue engineering are presented.

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“…[5][6][7][8][9][10][11][12] Chitosan (CS) is a natural, cationic aminopolysaccharide copolymer of glucosamine and N-acetylglucosamine. 13 It is obtained by the alkaline, partial deacetylation of chitin, which originates from shells of crustaceans such as crabs and prawns.…”

Section: Introductionmentioning

confidence: 99%

Morphological property and in vitro enzymatic degradation of modified chitosan as a scaffold

et al. 2011

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Chitosan (CS) was proposed as a promising candidate scaffold for tissue engineering. However, some drawbacks of natural CS remain. The current study modified CS by conjugating thiol to CS polymer (Thio-CS) and substantiated its three-dimensional microstructure and physical properties such as swelling or degradation. The Thio-CS was obtained by CS modification using 2-iminothiolane-HCl (2-IT). Because of the formation of disulfide bonds between thiol moieties based on oxidation of the immobilized thiol groups of CS, Thio-CS exhibits in situ gelling properties according to the reducing amount of free thiol. The content of the thiol group was increased as the amount of 2-IT increased. The swelling test demonstrated that Thio-CS can absorb up to 3.5 times its weight of phosphate buffered saline within 1 h and that the pore size and amount significantly increased with incubation time. The Thio-CS enzymatic degradation rate according to velocity was investigated. The results showed that Thio-CS was more resistant to lysozyme as viscosity increased. Thio-CS sponges were fabricated using freezedrying. The lyophilized Thio-CS had a homogeneous honeycomb-like shape, and its pores were relatively smaller (<2 µm) than those of unmodified CS (>2 µm). These results suggest that Thio-CS might be a candidate regenerative therapeutic device.

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Photofabricated Gelatin-Based Nerve Conduits: Nerve Tissue Regeneration Potentials

Cited by 62 publications

References 34 publications

Luminal Fillers in Nerve Conduits for Peripheral Nerve Repair

Luminal Fillers in Nerve Conduits for Peripheral Nerve Repair

Approaches to neural tissue engineering using scaffolds for drug delivery

Morphological property and in vitro enzymatic degradation of modified chitosan as a scaffold

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