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Dynamic compressive loading influences degradation behavior of PEG‐PLA hydrogels
Author(s) -
Nicodemus G.D.,
Shiplet K.A.,
Kaltz S.R.,
Bryant S.J.
Publication year - 2008
Publication title -
biotechnology and bioengineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.136
H-Index - 189
eISSN - 1097-0290
pISSN - 0006-3592
DOI - 10.1002/bit.22105
Subject(s) - self healing hydrogels , peg ratio , degradation (telecommunications) , chemistry , chemical engineering , biophysics , materials science , polymer chemistry , computer science , biology , engineering , telecommunications , finance , economics
Biodegradable hydrogels are attractive 3D environments for cell and tissue growth. In cartilage tissue engineering, mechanical stimulation has been shown to be an important regulator in promoting cartilage development. However, the impact of mechanical loading on the gel degradation kinetics has not been studied. In this study, we examined hydrolytically labile gels synthesized from poly(lactic acid)‐ b ‐poly(ethylene glycol)‐ b ‐poly‐(lactic acid) dimethacrylate macromers, which have been used for cartilage tissue engineering. The gels were subject to physiological loading conditions in order to examine the effects of loading on hydrogel degradation. Initially, hydrogels were formed with two different cross‐linking densities and subject to a dynamic compressive strain of 15% at 0.3, 1, or 3 Hz. Degradation behavior was assessed by mass loss, equilibrium swelling and compressive modulus as a function of degradation time. From equilibrium swelling, the pseudo‐first‐order reaction rate constants were determined as an indication of degradation kinetics. The application of dynamic loading significantly enhanced the degradation time for the low cross‐linked gels ( P  < 0.01) while frequency showed no statistical differences in degradation rates or bulk erosion profiles. In the higher cross‐linked gels, a 3 Hz dynamic strain significantly increased the degradation kinetics resulting in an overall faster degradation time by 6 days compared to gels subject to the 0.3 and 1 Hz loads ( P  < 0.0001). The bioreactor set‐up also influenced overall degradation behavior where the use of impermeable versus permeable platens resulted in significantly lower degradation rate constants for both cross‐linked gels ( P  < 0.001). The compressive modulus exponentially decreased with degradation time under dynamic loading. Together, our findings indicate that both loading regime and the bioreactor setup influence degradation and should be considered when designing and tuning a biodegradable hydrogel where mechanical stimulation is employed. Biotechnol. Bioeng. 2009; 102: 948–959. © 2008 Wiley Periodicals, Inc.

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