Abstract
A new approach for the in situ formation of porosity in a matrix based on differential polymer degradation has been studied. This approach exploits the differences in polymer properties such as molecular weight, hydrophilicity (hydrophobicity), and degradation to induce preferential degradation of one phase in a biphasic polymer system. Biphasic polymer systems polymers derived from alpha-hydroxy acids and poly(anhydrides), which vary in their erosion characteristics (surface vs. bulk) and hydrophobicities were studied. In addition to examining the generality of the approach, potential advantages of such systems in the context of tissue engineering and drug delivery are briefly discussed.
Publication types
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Comparative Study
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Evaluation Study
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Research Support, U.S. Gov't, P.H.S.
MeSH terms
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Anhydrides / chemical synthesis
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Anhydrides / chemistry*
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Drug Delivery Systems / methods*
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Drug Stability
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Extracellular Matrix / chemistry
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Glycolates / chemical synthesis
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Glycolates / chemistry*
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Hot Temperature*
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Lactic Acid
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Materials Testing
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Membranes, Artificial*
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Microspheres
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Particle Size
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Permeability
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Phase Transition
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Polyglycolic Acid
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Polylactic Acid-Polyglycolic Acid Copolymer
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Polymers / chemical synthesis
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Polymers / chemistry
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Porosity
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Tissue Engineering / methods*
Substances
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Anhydrides
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Glycolates
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Membranes, Artificial
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Polymers
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Polylactic Acid-Polyglycolic Acid Copolymer
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Polyglycolic Acid
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Lactic Acid