6533b7d6fe1ef96bd1267224
RESEARCH PRODUCT
Poly-left-lactic acid tubular scaffolds via diffusion induced phase separation: Control of morphology
Francesco Carfì PaviaVincenzo La CarrubbaGiulio GhersiValerio Brucatosubject
Settore ING-IND/24 - Principi Di Ingegneria ChimicaScaffoldMaterials sciencescaffold poly-lactic acid tissue engineeringDiffusion Induced Phase separationPolymers and PlasticsPhase separation processPoly-left lactic acidvascular tissue engineeringGeneral ChemistryLactic acidchemistry.chemical_compoundSettore ING-IND/22 - Scienza E Tecnologia Dei MaterialichemistryTissue engineeringHomogeneousSettore BIO/10 - BiochimicaMaterials ChemistryComposite materialPorosityWall thicknessIn vitro cell culturedescription
n this work, tubular poly-left-lactic acid scaffolds for vascular tissue engineering applications were produced by an innovative two-step method. The scaffolds were obtained by performing a dip-coating around a nylon fiber, followed by a diffusion induced phase separation process. Morphological analysis revealed that the internal lumen of the as-obtained scaffold is equal to the diameter of the fiber utilized; the internal surface is homogeneous with micropores 1–2 μm large. Moreover, a porous open structure was detected across the thickness of the walls of the scaffold. An accurate analysis of the preparation process revealed that it is possible to tune up the morphology of the scaffold (wall thickness, porosity, and average pore dimension), simply by varying some experimental parameters. Preliminary in vitro cell culture tests were carried out inside the scaffold. The results showed that cells are able to grow within the internal surface of the scaffolds and after 3 weeks they begin to form a “primordial” vessel-like structure. Modeling predictions of the dip-coating process display always an underestimate of experimental data (dependence of wall thickness upon extraction rate). In this work, tubular poly-left-lactic acid scaffolds for vascular tissue engineering applications were produced by an innovative two-step method. The scaffolds were obtained by performing a dip-coating around a nylon fiber, followed by a diffusion induced phase separation process. Morphological analysis revealed that the internal lumen of the as-obtained scaffold is equal to the diameter of the fiber utilized; the internal surface is homogeneous with micropores 1–2 lm large. Moreover, a porous open structure was detected across the thickness of the walls of the scaffold. An accurate analysis of the preparation process revealed that it is possible to tune up the morphology of the scaffold (wall thickness, porosity, and average pore dimension), simply by varying some experimental parameters. Preliminary in vitro cell culture tests were carried out inside the scaffold. The results showed that cells are able to grow within the internal surface of the scaffolds and after 3 weeks they begin to form a ‘‘primordial’’ vessel-like structure. Modeling predictions of the dipcoating process display always an underestimate of experimental data (dependence of wall thickness upon extraction rate).
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2013-02-01 | Polymer Engineering & Science |