Textile Science and Engineering (한국섬유공학회지)

The Korean Fiber Society (한국섬유공학회)
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Preparation of Poly(p-dioxanone) Non-covens by Electrospinning and Their In -vitro Degradation Behavior

Electrospinning을 이용한 Poly(p-dioxanone) 부직포 제초 및 In -vitro 분해거동

  • 김학용 (전북대학교 섬유공학과) ;
  • 이세철 (전북대학교 섬유공학과) ;
  • 이근형 (전북대학교 유기신물질공학과) ;
  • 이덕래 (전북대학교 섬유공학과) ;
  • 박수진 (한국화학연구소 화학소재연구부)
  • Published : 2002.06.01
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Abstract

The poly(p-dioxanone)(PDO) non-wovens whose fiber diameters were below 10$\mu$m were prepared by melt electrospinning. The morphology and fiber diameter of PDO non-wovens were studied under different eletrospinning conditions such as temperature and applied voltage. The fiber diameter decreased with increasing temperature and applied voltage. Proper fiber bond structure was formed in the PDO non-woven fabrics at 12kV. 19$0^{\circ}C$ respectively. In most of the samples, heat of fusion of the electrospun non-wovens was less than the raw PDO. In order to increase th crystallinity of electrospun PDO non-wovens, annealing was carried out at 50~9$0^{\circ}C$, for 15hrs under nitrogen atmosphere. The heat of fusion of PDO non-wovens increased with increasing the annealing temperature. The PDO non-wovens annealed at different temperatures were degraded at different rates in saline buffer solution at 37$^{\circ}C$. The degradation characteristic of PDO non-wovens was analyzed with heat of fusion, viscosity, PH, and weight loss. Relatively, higher heat of fusion resulted from annealing in the temperature range of 60~8$0^{\circ}C$ as compared with the raw PDO. The heat of fusion increased with increasing immersion time at all annealing temperatures.

Keywords

References

  1. Technomic Publ. Survey of Clinically Important Wound Closure Biomatierials in Biocompatiability of Polymers.Metals and Composities C.C.Chu;M.Szycher(ed.)
  2. Marcel Dekker Encylopedic Handbook of Biomaterirals and Bioengineering C.C.Chu;D.L.Wise(ed.)
  3. Biomaterials v.19 Manufacture of Porous Biodegradable Polymer Conduits by an Extrusion Process for Guided Tissue Regeneration S.W.Markus;P.K.Gupta;L.Lu;R.K.Meszlenyi;R.D.Evans;K.Brandt;T.Savel;A.Gurlek;C.W.Patrickr;A.G.Mikos
  4. Dunitz Martin Ltd. Handbook of Biodegradable Polymers;Synthetic Absorbable Polymers A.J.Domb;J.Kost;D.M.Wiseman
  5. J.Electrostatics v.35 Electrospinining Process and Applications of Electrospun Fibers J.Dochi;D.H.Reneker
  6. J.Biomed.Mater:Res. v.19 The Intracellular Degradation of Poly(epsilon-caprolactone) S.C.Woodward;P.S.Brewer;F.Moatmed;A.Schindler;C.G.Pitt
  7. Polymer v.40 Beaded Nanofibers Formed During Electrospinning H.Fong;I.Chun;D.H.Reneker
  8. Polymer v.40 Processing and Microstructural Characterization of Porous Biocompatible Protein Polymer Thin Films C.J.Buchko;L.C.Chen;Y.S.Shen;D.C.Martin
  9. Polymer v.42 The Effect of Processing Variables on the Morphology of Electrospun Nanofibers and Textiles J.M.Deitzel;J.Kleinmeyer;D.Harrks;N.C.Beck Tan
  10. Surgery,Gynecology & Obstetrics v.153 Polydioxanone (PDS), a Novel Monofilament Synthetic Absorbable Suture J.A.Ray;N.Doddi;D.Regula;J.A.Williams;A.Melveger
  11. Polymer v.41 Morphological Development in Absorbable Poly(glycolide),Poly(glycolide-co-lactide) and Poly(glycolide-co-caprolactone) Copolymers During Isothermal Crystallization Z.G.Wang;B.S.H.Zong;X.H.Zong;F.Yeh;J.J.Zhou;E.Dormier;D.D.Jamiolkowski
  12. Macromolecules v.32 Structure and Morphology Changes in Absorbable Poly(glycolide) and Poly(glycolide-co-lactide)during in Vitro Degradation X.H.Zong;Z.G.Wang;B.S.Huiao;B.Chu