Publication

Fibrillogenesis in Continuously Spun Synthetic Collagen Fiber

Downloadable Content

Persistent URL
Last modified
  • 05/15/2025
Type of Material
Authors
    Jeffrey M. Caves, Emory UniversityVivek A. Kumar, Emory UniversityJing Wen, Emory UniversityWanxing Cui, Emory UniversityAdam Martinez, Emory UniversityRobert Apkarian, Emory UniversityJulie E. Coats, Emory UniversityKeith Berland, Emory UniversityElliot L. Chaikof, Emory University
Language
  • English
Date
  • 2010-04-01
Publisher
  • Wiley: 12 months
Publication Version
Copyright Statement
  • © 2009 Wiley Periodicals, Inc.
Final Published Version (URL)
Title of Journal or Parent Work
ISSN
  • 1552-4973
Volume
  • 93B
Issue
  • 1
Start Page
  • 24
End Page
  • 38
Abstract
  • The universal structural role of collagen fiber networks has motivated the development of collagen gels, films, coatings, injectables, and other formulations. However, reported synthetic collagen fiber fabrication schemes have either culminated in short, discontinuous fiber segments at unsuitably low production rates, or have incompletely replicated the internal fibrillar structure that dictates fiber mechanical and biological properties. We report a continuous extrusion system with an off-line phosphate buffer incubation step for the manufacture of synthetic collagen fiber. Fiber with a cross-section of 53 ± 14 by 21 ± 3 lm and an ultimate tensile strength of 94 ± 19 MPa was continuously produced at 60 m/hr from an ultrafiltered monomeric collagen solution. The effect of collagen solution concentration, flow rate, and spinneret size on fiber size was investigated. The fiber was further characterized by microdifferential scanning calorimetry, transmission electron microscopy (TEM), second harmonic generation (SHG) analysis, and in a subcutaneous murine implant model. Calorimetry demonstrated stabilization of the collagen triple helical structure, while TEM and SHG revealed a dense, axially aligned D-periodic fibril structure throughout the fiber cross-section. Implantation of glutaraldehyde crosslinked and non-crosslinked fiber in the subcutaneous tissue of mice demonstrated limited inflammatory response and biodegradation after a 6-week implant period.
Author Notes
Keywords
Research Categories
  • Chemistry, General
  • Health Sciences, Medicine and Surgery

Tools

Relations

In Collection:

Items

Thumbnail Title File Description Date Uploaded Visibility Actions
file details Publication File - tv0w4.pdf Primary Content 2025-03-27 Public Download