Fabrication of alginate hydrogel scaffolds and cell viability in calcium-crosslinked alginate hydrogel

Cao, Ning

03 August 2011

Tissue-engineering (TE) is one of the most innovative approaches for tackling many diseases and body parts that need to be replaced, by developing artificial tissues and organs. For this, tissue scaffolds play an important role in various TE applications. A tissue scaffold is a 3D (3D) structure with interconnected pore networks and used to facilitate cell growth and transport of nutrients and wastes while degrading gradually itself. Many fabrication techniques have been developed recently for incorporating living cells into the scaffold fabrication process and among them; dispensing-based rapid prototyping techniques have been drawn considerable attention due to its fast and efficient material processing. This research is aimed at conducting a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. Dispensing-based polymer deposition system was used to fabricate 3D porous hydrogel scaffolds. Sodium alginate was chosen and used as a scaffolding biomaterial. The influences of fabrication process parameters were studied. With knowledge and information gained from this study, 3D hydrogel scaffolds were successfully fabricated. Calcium chloride was employed as crosslinker in order to form hydrogels from alginate solution. The mechanical properties of formed hydrogels were characterized and examined by means of compressive tests. The influences of reagent concentrations, gelation time, and gelation type were studied. A post-fabrication treatment was used and characterized in terms of strengthening the hydrogels formed. In addition, the influence of calcium ions used as crosslinker on cell viability and proliferation during and after the dispensing fabrication process was examined and so was the influence of concentration of calcium solutions and exposing time in both media and alginate hydrogel. The study also showed that the density of encapsulated cells could affect the viscosity of alginate solution. In summary, this thesis presents a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. The results obtained regarding the influence of various factors on the cell viability and scaffold fabrication would form the basis and rational to continue research on fabricating 3D cell-encapsulated scaffolds for specific applications.

ionic crosslinking

cell damage

alginate

scaffold

hydrogel

tissue engineering

Fabrication of alginate hydrogel scaffolds and cell viability in calcium-crosslinked alginate hydrogel

Cao, Ning

03 August 2011

Tissue-engineering (TE) is one of the most innovative approaches for tackling many diseases and body parts that need to be replaced, by developing artificial tissues and organs. For this, tissue scaffolds play an important role in various TE applications. A tissue scaffold is a 3D (3D) structure with interconnected pore networks and used to facilitate cell growth and transport of nutrients and wastes while degrading gradually itself. Many fabrication techniques have been developed recently for incorporating living cells into the scaffold fabrication process and among them; dispensing-based rapid prototyping techniques have been drawn considerable attention due to its fast and efficient material processing. This research is aimed at conducting a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. Dispensing-based polymer deposition system was used to fabricate 3D porous hydrogel scaffolds. Sodium alginate was chosen and used as a scaffolding biomaterial. The influences of fabrication process parameters were studied. With knowledge and information gained from this study, 3D hydrogel scaffolds were successfully fabricated. Calcium chloride was employed as crosslinker in order to form hydrogels from alginate solution. The mechanical properties of formed hydrogels were characterized and examined by means of compressive tests. The influences of reagent concentrations, gelation time, and gelation type were studied. A post-fabrication treatment was used and characterized in terms of strengthening the hydrogels formed. In addition, the influence of calcium ions used as crosslinker on cell viability and proliferation during and after the dispensing fabrication process was examined and so was the influence of concentration of calcium solutions and exposing time in both media and alginate hydrogel. The study also showed that the density of encapsulated cells could affect the viscosity of alginate solution. In summary, this thesis presents a preliminary study on the dispensing-based biofabrication of 3D cell-encapsulated alginate hydrogel scaffolds. The results obtained regarding the influence of various factors on the cell viability and scaffold fabrication would form the basis and rational to continue research on fabricating 3D cell-encapsulated scaffolds for specific applications.

ionic crosslinking

cell damage

alginate

scaffold

hydrogel

tissue engineering

Ionically Crosslinked Polymer Networks for Underwater Adhesion and Long-Term Controlled Release

Lawrence, Patrick G.

January 2014

No description available.

Chemical Engineering

Chemistry

Materials Science

Polymers

Polymer Chemistry

Ionic Crosslinking

Polyelectrolytes

Underwater Adhesion

Stimulus-Responsive

Controlled Release