Naozumi Teramoto scite author profile

Natural fiber‐reinforced biodegradable polyester composites were prepared from biodegradable polyesters and surface‐untreated or ‐treated abaca fibers (length ca. 5 mm) by melt mixing and subsequent injection molding. Poly(butylene succinate)(PBS), polyestercarbonate (PEC)/poly(lactic acid)(PLA) blend, and PLA were used as biodegradable polyesters. Esterifications using acetic anhydride and butyric anhydride, alkali treatment, and cyanoethylation were performed as surface treatments on the fiber. The flexural moduli of all the fiber‐reinforced composites increased with fiber content. The effect of the surface treatment on the flexural modulus of the fiber‐reinforced composites was not so pronounced. The flexural strength of PBS composites increased with fiber content, and esterification of the fiber by butyric anhydride gave the best result. For the PEC/PLA composites, flexural strength increased slightly with increased fiber content (0–20 wt.‐%) in the case of using untreated fiber, while it increased considerably in the case of using the fiber esterified by butyric anhydride. For the PLA composite, flexural strength did not increase with the fiber reinforcement. The result of soil‐burial tests showed that the composites using untreated fiber have a higher weight loss than both the neat resin and the composites made using acetylated fiber. Flexural modulus of PBS composites as a function of fiber content.magnified imageFlexural modulus of PBS composites as a function of fiber content.

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Biodegradation of aliphatic polyester composites reinforced by abaca fiber

Teramoto

Urata

Ozawa

et al. 2004

Polymer Degradation and Stability

175

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Trehalose and Trehalose-based Polymers for Environmentally Benign, Biocompatible and Bioactive Materials

2008

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Trehalose is a non-reducing disaccharide that is found in many organisms but not in mammals. This sugar plays important roles in cryptobiosis of selaginella mosses, tardigrades (water bears), and other animals which revive with water from a state of suspended animation induced by desiccation. The interesting properties of trehalose are due to its unique symmetrical low-energy structure, wherein two glucose units are bonded face-to-face by 1→1-glucoside links. The Hayashibara Co. Ltd., is credited for developing an inexpensive, environmentally benign and industrial-scale process for the enzymatic conversion of α-1,4-linked polyhexoses to α,α-d-trehalose, which made it easy to explore novel food, industrial, and medicinal uses for trehalose and its derivatives. Trehalose-chemistry is a relatively new and emerging field, and polymers of trehalose derivatives appear environmentally benign, biocompatible, and biodegradable. The discriminating properties of trehalose are attributed to its structure, symmetry, solubility, kinetic and thermodynamic stability and versatility. While syntheses of trehalose-based polymer networks can be straightforward, syntheses and characterization of well defined linear polymers with tailored properties using trehalose-based monomers is challenging, and typically involves protection and deprotection of hydroxyl groups to attain desired structural, morphological, biological, and physical and chemical properties in the resulting products. In this review, we will overview known literature on trehalose’s fascinating involvement in cryptobiology; highlight its applications in many fields; and then discuss methods we used to prepare new trehalose-based monomers and polymers and explain their properties.

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Thermal and mechanical properties of poly(butylene succinate) nanocomposites with various organo‐modified montmorillonites

Someya

Nakazato

Teramoto

et al. 2003

J of Applied Polymer Sci

115

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Nanocomposites based on biodegradable poly(butylene succinate) (PBS) and layered silicates were prepared by melt intercalation. Nonmodified montmorillonite (MMT) and MMTs (DA-M, ODA-M, ALA-M, LEA-M, and HEA-M) organo-modified by protonated ammonium cations {i.e., those of dodecylamine, octadecylamine, 12-aminolauric acid, N-lauryldiethanolamine, and 1-[N,N-bis(2-hydroxyethyl)amino]-2-propanol, respectively} were used as layered silicates. From morphological studies using transmission electron microscopy, DA-M, ODA-M, and LEA-M were found to be dispersed homogeneously in the matrix polymer, whereas some clusters or agglomerated particles were observed for ALA-M, HEA-M, and MMT. The enlargement of the difference in the interlayer spacing between the clay and PBS/clay composite, as measured by X-ray diffraction, had a good correlation with the improvement of the clay dispersion and with the increase in the tensile modulus and the decrease in the tensile strength of the PBS composites with an inorganic concentration of 3 wt %. Dynamic viscoelastic measurements of the PBS/LEA-M nanocomposite revealed that the storage modulus and glass-transition temperature increased with the inorganic concentration (3-10 wt %).

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Bio-based polymer networks by thiol–ene photopolymerizations of allyl-etherified eugenol derivatives

Yoshimura

Shimasaki

Teramoto

et al. 2015

European Polymer Journal

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