• Nakanishi, Nobuhiro
• Yokota, Shin-Ichiro
• Yoshida, Shuhei
• Osawa, Ryuji
• Arimoto, Yonejiro
• Ozaki, Makoto
• Tomizaki, Kin-Ya
• Hirao, Kan
• Umetani, Tomohiro
• Endo, Natsumi
• Kosaka, Tsubasa
• Kayamori, Fumihiro
• Usui, Kenji

Abstract

<jats:title>Abstract</jats:title><jats:p>Microwaves are used for diverse applications such as mobile phones, ovens, and therapy devices. However, there are few reports on the effects of microwaves on diseases other than cancer, and on physiological processes. Here, we focused on CaCO<jats:sub>3</jats:sub> mineralization as a model of biomineralization and attempted to elucidate the effect of microwaves on CaCO<jats:sub>3</jats:sub> mineralization using peptides. We conducted AFM, ζ potential, HPLC, ICP-AES, and relative permittivity measurements. Our findings show that microwaves alter the nanomorphology of the CaCO<jats:sub>3</jats:sub> precipitate, from sphere-like particles to string-like structures. Furthermore, microwaves have little effect on the mineralization when the mineralization ability of a peptide is high, but a large effect when the precipitation ability is low. Our findings may be applicable to not only the treatment of teeth and bones but also the development of organic–inorganic nanobiomaterials. This methodology can be expanded to other molecular/atomic reactions under various microwave conditions to alter reaction activity parameters.</jats:p>

Topics

• impedance spectroscopy
• atomic force microscopy
• dielectric constant
• precipitate
• precipitation
• Calcium
• atomic emission spectroscopy
• Auger electron spectroscopy
• High-performance liquid chromatography