Abstract
Some bacteria can synthesize cellulose when they are cultivated under adequate conditions. These bacteria produce a mat of cellulose on the top of the culture medium, which is formed by a three-dimensional coherent network of pure cellulose nanofibers. Bacterial cellulose (BC) has been widely used in different fields, such as the paper industry, electronics and tissue engineering due to its remarkable mechanical properties, conformability and porosity. Nanocomposites based on BC have received much attention, because of the possibility of combining the good properties of BC with other materials for specific applications. BC nanocomposites can be processed either in a static or an agitated medium. The fabrication of BC nanocomposites in static media can be carried out while keeping the original mat structure obtained after the synthesis to form the final nanocomposite or by altering the culture media with other components. The present article reviews the issue of biocompatibility of BC and BC nanocomposites. Biomedical aspects, such as surface modification for improving cell adhesion, in vitro and in vivo studies are given along with details concerning the physics of network formation and the changes that occur in the cellulose networks due to the presence of a second phase. The relevance of biocompatibility studies for the development of BC-based materials in bone, skin and cardiovascular tissue engineering is also discussed.
Highlights
Cellulose is the most abundant biomass material on earth [1]
We review the use of Bacterial cellulose (BC) and BC-based structures as biomaterials and discuss issues related to their biocompatibility
Bacterial cellulose-based structures have been used for many biomedical applications, including bone tissue engineering, blood vessels and wound dressings, among others, since BC has proved to be a nontoxic biocompatible material
Summary
Cellulose is the most abundant biomass material on earth [1] It forms the basic structural matrix for plant cell walls. It is mainly used in the textile and paper industry, and it is obtained from vegetal products. BC has Iα and Iβ crystalline forms, unlike the cellulose of plants that present mainly the Iβ structure [6]. Biocompatibility of BC-based products have made them suitable for several biomedical applications, including membranes for wound dressings [9], scaffolds for tissue engineering [10,11,12,13], substrates for cell seeding [14,15], structures for biomineralization of hydroxyapatite [16], etc. We give several examples of BC-based structures for biomedical and clinical applications, with details concerning the biocompatibility achieved in each case
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