Tuning the Degradation Profiles of Poly(l‑lactide)-Based Materials through Miscibility

The effective use of biodegradable polymers relies on the ability to control the onset of and time needed for degradation. Preferably, the material properties should be retained throughout the intended time frame, and the material should degrade in a rapid and controlled manner afterward. The degrad...

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Bibliographic Details
Published in:Biomacromolecules 2014-01, Vol.15 (1), p.391-402
Main Authors: Arias, Veluska, Höglund, Anders, Odelius, Karin, Albertsson, Ann-Christine
Format: Article
Language:English
Subjects:
Aliphatic Polyesters
Applied sciences
Atactic Poly(3-Hydroxybutyrate)
Biological properties
Blends
Crystallization
Enzymatic Degradation
Exact sciences and technology
Hydrolytic Degradation
Mechanical-Properties
Organic polymers
Phase-Structure
Physicochemistry of polymers
Poly(Dl-Lactic Acid)
Poly(Lactic Acid)
Polyesters - chemistry
Polyesters - metabolism
Polylactide
Polymers - chemistry
Polymers - metabolism
Properties and characterization
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Summary:The effective use of biodegradable polymers relies on the ability to control the onset of and time needed for degradation. Preferably, the material properties should be retained throughout the intended time frame, and the material should degrade in a rapid and controlled manner afterward. The degradation profiles of polyester materials were controlled through their miscibility. Systems composed of PLLA blended with poly­[(R,S)-3-hydroxybutyrate] (a-PHB) and polypropylene adipate (PPA) with various molar masses were prepared through extrusion. Three different systems were used: miscible (PLLA/a-PHB5 and PLLA/a-PHB20), partially miscible (PLLA/PPA5/comp and PLLA/PPA20/comp), and immiscible (PLLA/PPA5 and PLLA/PPA20) blends. These blends and their respective homopolymers were hydrolytically degraded in water at 37 °C for up to 1 year. The blends exhibited entirely different degradation profiles but showed no diversity between the total degradation times of the materials. PLLA presented a two-stage degradation profile with a rapid decrease in molar mass during the early stages of degradation, similar to the profile of PLLA/a-PHB5. PLLA/a-PHB20 presented a single, constant linear degradation profile. PLLA/PPA5 and PLLA/PPA20 showed completely opposing degradation profiles relative to PLLA, exhibiting a slow initial phase and a rapid decrease after a prolonged degradation time. PLLA/PPA5/comp and PLLA/PPA20/comp had degradation profiles between those of the miscible and the immiscible blends. The molar masses of the materials were approximately the same after 1 year of degradation despite their different profiles. The blend composition and topographical images captured at the last degradation time point demonstrate that the blending component was not leached out during the period of study. The hydrolytic stability of degradable polyester materials can be tailored to obtain different and predetermined degradation profiles for future applications.
ISSN:1525-7797
1526-4602
1526-4602
DOI:10.1021/bm401667b