TY - JOUR
T1 - In situ forming degradable networks and their application in tissue engineering and drug delivery
AU - Anseth, Kristi S.
AU - Metters, Andrew T.
AU - Bryant, Stephanie J.
AU - Martens, Penny J.
AU - Elisseeff, Jennifer H.
AU - Bowman, Christopher N.
N1 - Funding Information:
The authors would like to acknowledge the support of this work from the National Institutes of Health (DE-12998), the Packard Foundation, and the Howard Hughes Medical Institute.
PY - 2002/1/17
Y1 - 2002/1/17
N2 - Multifunctional macromers based on poly(ethylene glycol) and poly(vinyl alcohol) were photopolymerized to form degradable hydrogel networks. The degradation behavior of the highly swollen gels was characterized by monitoring changes in their mass loss, degree of swelling, and compressive modulus. Experimental results show that the modulus decreases exponentially with time, while the volumetric swelling ratio increases exponentially. A degradation mechanism assuming pseudo first-order hydrolysis kinetics and accounting for the structure of the crosslinked networks successfully predicted the experimentally observed trends in these properties with degradation. Once verified, the proposed degradation mechanism was extended to correlate network degradation kinetics, and subsequent changes in network structure, with release behavior of bioactive molecules from these dynamic systems. A theoretical model utilizing a statistical approach to predict the cleavage of crosslinks within the network was used to predict the complex erosion profiles produced by these hydrogels. Finally, the application of these macromers as in situ forming hydrogel constructs for cartilage tissue engineering is demonstrated.
AB - Multifunctional macromers based on poly(ethylene glycol) and poly(vinyl alcohol) were photopolymerized to form degradable hydrogel networks. The degradation behavior of the highly swollen gels was characterized by monitoring changes in their mass loss, degree of swelling, and compressive modulus. Experimental results show that the modulus decreases exponentially with time, while the volumetric swelling ratio increases exponentially. A degradation mechanism assuming pseudo first-order hydrolysis kinetics and accounting for the structure of the crosslinked networks successfully predicted the experimentally observed trends in these properties with degradation. Once verified, the proposed degradation mechanism was extended to correlate network degradation kinetics, and subsequent changes in network structure, with release behavior of bioactive molecules from these dynamic systems. A theoretical model utilizing a statistical approach to predict the cleavage of crosslinks within the network was used to predict the complex erosion profiles produced by these hydrogels. Finally, the application of these macromers as in situ forming hydrogel constructs for cartilage tissue engineering is demonstrated.
KW - Cartilage tissue engineering
KW - Degradation
KW - Hydrogels
KW - Photopolymerization
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U2 - 10.1016/S0168-3659(01)00500-4
DO - 10.1016/S0168-3659(01)00500-4
M3 - Article
C2 - 11772461
AN - SCOPUS:0037122739
SN - 0168-3659
VL - 78
SP - 199
EP - 209
JO - Journal of Controlled Release
JF - Journal of Controlled Release
IS - 1-3
ER -