Title :
Strong fiber reinforced hydrogels for biomedical applications
Author :
Agrawal, A. ; Wanasekara, N. ; Chalivendra, V. ; Rahbar, N. ; Calvert, P.
Author_Institution :
Univ. of Massachusetts Dartmouth, North Dartmouth, MA, USA
Abstract :
We describe a new class of hydrogels based on fiber reinforced hydrogel composites with a cartilage-like structure. In analogy to the spinning of a spider web, a pultrusion system is developed to spin micron -diameter fibers from polymer solution in order to build three dimensional patterned fibrous structures. Impregnating the fibrous construct with epoxy -amine hydrogel forms fiber -reinforced hydrogel composites. The fibrous construct improves the strength, modulus and toughness of the hydrogel and also constrains the swelling. By altering the construct geometry (fiber diameter, density and polymer solution) and studying the effect on mechanical properties we will develop the understanding needed to design strong hydrogels for biomedical devices and soft machines.
Keywords :
biomedical materials; biomimetics; elastic moduli; fibre reinforced composites; hydrogels; mechanical strength; polymer solutions; 3D patterned fibrous structures; biomedical materials; cartilage-like structure; epoxy-amine hydrogel; fiber reinforced hydrogel composites; mechanical strength; modulus; polymer solution; pultrusion system; spider web; spin micron-diameter fibers; spinning; toughness; Mechanical factors; Optical fiber devices; Optical fiber networks; Optical fiber testing; Optical fiber theory; Polymers;
Conference_Titel :
Bioengineering Conference (NEBEC), 2011 IEEE 37th Annual Northeast
Conference_Location :
Troy, NY
Print_ISBN :
978-1-61284-827-3
DOI :
10.1109/NEBC.2011.5778724
