Hydrogels can be up to 99 percent water and are similar in composition to human tissues.
They can take on a variety of forms and functions beyond that of contact lenses.
Biomedical engineers have successfully used hydrogels as 3D molecular scaffolds that can be filled with cells or molecules for bodily injection or application in order to release drugs or stimulate tissue regeneration.
Alginate hydrogels -- which are made up of the polysaccharide naturally occurring in brown seaweed -- are just such materials.
Joshi leads a team at the Wyss Institute developing new synthetic biomaterials that mimic naturally-occurring materials. "Other types of hydrogels are much more cumbersome to synthesise," said Rajiv Desai, study's first author from the Wyss Institute.
In contrast, the click alginate hydrogel can be created by fast combination of simple solutions. Once the gel is formed, the click chemistry reactions are irreversible, resulting in a chemo-selective hydrogel primed for use as a therapeutic scaffold.
Furthermore, the click alginate hydrogel is easily customised and modified. "With our new method, if you wanted to add a fluorescent dye, peptide, or protein to the new click alginate, you could do so within one minute - a truly unprecedented rate," Joshi pointed out. At the Wyss, the novel hydrogel is already being used to encapsulate cells in culture and to conduct experiments in a tissue-like environment. "It is a great material for studying how cells sense the mechanical environments around them," Desai added. Alginate hydrogels show promise for tissue engineering and drug delivery applications as they can be designed to dissolve away harmlessly in the body while releasing drugs, growth agents or living cells that can accelerate healing and regeneration.
The findings were reported in the journal Biomaterials.