Minimally invasive tissue engineering composites and cell printing

Author

Burg, Karen J L ; Boland, Thomas

Author_Institution

Dept. of Bioeng., Clemson Univ., SC, USA

Volume

22

Issue

5

fYear

2003

Firstpage

84

Lastpage

91

Abstract

Injectable composites combined with tissue-printing technology for improved bioengineered devices. The invisible engineering problem, the one often ignored, is the design of a readily implantable, precisely assembled cellular construct. Previous studies have consistently shown that composite tissue-engineered devises are readily implanted via minimally invasive means and, in the systems tested, produce minimal inflammation and fibrous encapsulation. Gels of optimal viscosity are able to maintain separation between the cellular scaffold and allow tissue growth. Studies with the cell/substrate printing system have shown that it is possible to define, in a controlled manner, spatial arrangement of cells within a gel substrate.

Keywords

cellular biophysics; molecular biophysics; patient treatment; proteins; tissue engineering; cell printing; cell/substrate printing system; cellular scaffold; fibrous encapsulation; gel substrate; implantable; injectable tissue-engineering devices; minimal inflammation; optimal viscosity; precisely assembled cellular construct; spatial cell arrangement; tissue engineering problem; tissue growth; Biodegradable materials; Biological materials; Biological tissues; Bones; Minimally invasive surgery; Muscles; Polymers; Printing; Shape; Tissue engineering;

fLanguage

English

Journal_Title

Engineering in Medicine and Biology Magazine, IEEE

Publisher

ieee

ISSN

0739-5175

Type

jour

DOI

10.1109/MEMB.2003.1256277

Filename

1256277