Here
we present a series of copolyesters of poly(butylene terephthalate)
(PBT) with the renewable building block isosorbide (1,4:3,6-dianhydro-d-glucitol, IS), designated PBIT. The aim of this work is to
systematically elucidate how the inherent properties (reactivity,
structural asymmetry, structural rigidity, and hydrophilicity) of
IS would affect the synthesis and thermal/(bio)degradable performance
of PBIT copolyesters. The target copolyesters containing 0–50
mol % IS units were successfully synthesized by melt polycondensation
and were afforded in fully random microsequential structures. Their
number-average molecular weights and intrinsic viscosities are in
the ranges of 22 400–31 000 g/mol and 0.5–0.65
dL/g, respectively. The thermal properties determined by differential
scanning calorimetric analysis firmly confirmed the remarkable T
g-enhancing effect of IS. Comprehensive degradation
study further revealed that IS incorporation promotes remarkable hydrolytic
degradation in a relatively harsh acidic environment at high temperature
(80 °C), but maintains excellent stability in a neutral hydrolytic
and enzymatic environment (with porcine pancreatic lipase) at low
temperature (37 °C). The synergistic effects of IS incorporation
on thermal properties and degradability are dependent on degrading
conditions. The results shown in this work are expected to give some
insights regarding property improvement of the existing semiaromatic
polyesters via copolymerization, as well as consideration of suitable
working conditions for these polymers.
Isohexides
are versatile carbohydrate-based building blocks for
designing biodegradable polymers with tunable biodegradability and
enhanced material properties owing to their unique high structural
rigidity and hydrophilicity. However, the limited reactivity and thermal
stability of isohexides, especially the isomers with endo-hydroxyl groups, hamper their practical applications. In this work,
fully aliphatic copolyesters based on two isohexide stereoisomers,
isosorbide (IS) and isomannide (IM), were comparatively synthesized
via a mild lipase-catalyzed polymerization [enzymatic polymerization
(EP)] technique. The products were obtained with fairly high molecular
weights (M
n values: 15,300–31,500
g·mol–1), negligible degree of discoloration,
and 20–40 °C higher thermal stabilities (T
d,5%: 335–360 °C) compared to those of their
counterparts obtained by melt polymerization (MP). Molecular dynamics
(MD) simulation revealed that the endo-OH is preferred
to the exo-OH under the EP process having a high
hydrogen-bonding frequency with the catalytic site of CALB (lipase
immobilized from Candida antarctica, CALB), and it also requires considerably low energy (70–100
kJ·mol–1) to form the second tetrahedral transition-state
intermediates. The wide-angle X-ray diffraction (WAXD) study further
elucidates the interesting influence of the EP process on inducing
specific β-type crystalline structures.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.