Nanofibrous scaffolds for tissue engineering

PAVLIŇÁK, David, Veronika ŠVACHOVÁ, Eva KEDROŇOVÁ, Milan ALBERTI, Pavel HYRŠL, Monika DUŠKOVÁ, Helena NEJEZCHLEBOVÁ and Libor VOJTEK. Nanofibrous scaffolds for tissue engineering. In Vašina, Petr; Brablec, Antonín; Skácelová, Dana; Hnilica, Jaroslav; Souček, Pavel. Potencial and Applications of Surface Nanotreatment of Polymers and Glass. Brno: NANOcontact, Masaryk University, 2011, p. 39-104.

Basic information

• Original name: Nanofibrous scaffolds for tissue engineering
• Name in Czech: Nanomateriály pro tkáňové inženýrství
• Name (in English): Nanofibrous scaffolds for tissue engineering
• Authors: PAVLIŇÁK, David, Veronika ŠVACHOVÁ, Eva KEDROŇOVÁ, Milan ALBERTI, Pavel HYRŠL, Monika DUŠKOVÁ, Helena NEJEZCHLEBOVÁ and Libor VOJTEK.
• Edition: Brno, Potencial and Applications of Surface Nanotreatment of Polymers and Glass, p. 39-104, 2011.
• Publisher: NANOcontact, Masaryk University

Other information

• Type of outcome: Proceedings paper
• Confidentiality degree: is not subject to a state or trade secret
• Organization unit: Faculty of Science
• Keywords (in Czech): tkáňové inženýrství;nanomateriál;nanotechnologie;elektrospinning;plazmochemické reakce;baktericidita;bioaktivita;chemická luminisence
• Keywords in English: tissue engineering;nanomaterial;nanotechnology;electrospinning;plasma-chemical treatment;bactericidal efect;bioactivity;chemical luminiscence

Abstract

Tissue engineering aims to develop biologically functional scafolds for the repair, replacement, or regeneration of damaged tissues. The aim of this work was to find a new manufacturing process of a biologically functional scaffolds. Various synthetic biopolymers, like a gelatine, PVA, collagen have been electrospun to satisfy different clinical requirments. The main research idea was to develop a suitable bactericidal agent that could be sufficiently biocompatible and biodegradable. These requirements fulfilled an oxycellulose which was produced using plasma-chemical reaction. Chemical composition of treated cellulose samples was evaluated with ATR-FTIR and TGA. Biological activity was evaluated by CL - chemical luminiscence methods.

Abstract (in Czech)

Tissue engineering aims to develop biologically functional scafolds for the repair, replacement, or regeneration of damaged tissues. The aim of this work was to find a new manufacturing process of a biologically functional scaffolds. Various synthetic biopolymers, like a gelatine, PVA, collagen have been electrospun to satisfy different clinical requirments. The main research idea was to develop a suitable bactericidal agent that could be sufficiently biocompatible and biodegradable. These requirements fulfilled an oxycellulose which was produced using plasma-chemical reaction. Chemical composition of treated cellulose samples was evaluated with ATR-FTIR and TGA. Biological activity was evaluated by CL - chemical luminiscence methods.

Abstract (in English)

Tissue engineering aims to develop biologically functional scafolds for the repair, replacement, or regeneration of damaged tissues. The aim of this work was to find a new manufacturing process of a biologically functional scaffolds. Various synthetic biopolymers, like a gelatine, PVA, collagen have been electrospun to satisfy different clinical requirments. The main research idea was to develop a suitable bactericidal agent that could be sufficiently biocompatible and biodegradable. These requirements fulfilled an oxycellulose which was produced using plasma-chemical reaction. Chemical composition of treated cellulose samples was evaluated with ATR-FTIR and TGA. Biological activity was evaluated by CL - chemical luminiscence methods.

Links

• MSM0021622411, plan (intention): Name: Studium a aplikace plazmochemických reakcí v neizotermickém nízkoteplotním plazmatu a jeho interakcí s povrchem pevných látek

Investor: Ministry of Education, Youth and Sports of the CR, Study and application of plasma chemical reactions in non-isothermic low temperature plasma and its interaction with solid surface