Your search keyword '"Ryo Hyodo"' showing total 7 results

1. Synergic Effects of Surfactant and Chelating Agent on Stubborn Keratin Grime for Easy Cleaning

Author

Shinya SUDO, Yosuke WATANABE, Ryo HYODO, and Atsushi NAITO

Subjects

General Medicine

Published

2022

2. Synergic Effects of Surfactant and Chelating Agent on Stubborn Keratin Grime for Easy Cleaning

Author

Yosuke Watanabe, Shinya Sudo, Atsushi Naito, Kazuya Inomata, Atsunori Morigaki, and Ryo Hyodo

Subjects

General Chemical Engineering, Detergents, macromolecular substances, Surface-Active Agents, Pulmonary surfactant, Keratin, medicine, Chelation, Chelating Agents, chemistry.chemical_classification, Aqueous solution, integumentary system, Water, Drug Synergism, General Medicine, General Chemistry, Permeation, Solutions, chemistry, Chemical engineering, Wettability, Keratins, Calcium, Wetting, Swelling, medicine.symptom, Data scrubbing

Abstract

We report on the synergic effect of surfactants and chelating agents on the mechanism to remove stubborn keratin grime (keratin-Ca), which is bound with calcium ions and one of the most difficult grimes to remove, in order to make it easier to clean bathtubs in less time and with less scrubbing. Our approach was to focus on keratin swelling, which we achieved by applying aqueous solutions with chelating agents and anionic surfactants, the combination of which greatly improved the swelling ratio, resulting in quick, easy removal of keratin-Ca with water rinsing and little scrubbing. For the swelling process, we added chelating agents and anionic surfactants to swell the keratin-Ca by both capturing calcium ions and improving solution permeation. Furthermore, we measured the structural change of the keratin-Ca during swelling by TD-NMR and confirmed that a certain combination of chelating agent and anionic surfactant improved swelling by affecting not only the amorphous part such as the keratin matrix, but also the crystalline part such as the intermediate filaments (IFs).

Published

2021

3. Synergic Effects of Surfactant and Chelating Agent on Stubborn Keratin Grime for Easy Cleaning.

Author

Shinya Sudo, Yosuke Watanabe, Atsunori Morigaki, Kazuya Inomata, Ryo Hyodo, and Atsushi Naito

Subjects

SURFACE active agents, CHELATING agents, CLEANING, CALCIUM ions, KERATIN

Abstract

We report on the synergic effect of surfactants and chelating agents on the mechanism to remove stubborn keratin grime (keratin-Ca), which is bound with calcium ions and one of the most difficult grimes to remove, in order to make it easier to clean bathtubs in less time and with less scrubbing. Our approach was to focus on keratin swelling, which we achieved by applying aqueous solutions with chelating agents and anionic surfactants, the combination of which greatly improved the swelling ratio, resulting in quick, easy removal of keratin-Ca with water rinsing and little scrubbing. For the swelling process, we added chelating agents and anionic surfactants to swell the keratin-Ca by both capturing calcium ions and improving solution permeation. Furthermore, we measured the structural change of the keratin-Ca during swelling by TD-NMR and confirmed that a certain combination of chelating agent and anionic surfactant improved swelling by affecting not only the amorphous part such as the keratin matrix, but also the crystalline part such as the intermediate filaments (IFs). [ABSTRACT FROM AUTHOR]

Published

2021

4. Scattering and Spectroscopic Study on the Hydration and Phase Behavior of Aqueous Alcohol Ethoxylate and Methyl Ester Ethoxylate: Effects of Terminal Groups in Hydrophilic Chains

Author

Takesi Akahane, Kenshi Amano, Ryo Hyodo, Takaaki Sato, Taku Ogura, and Keiichi Yanase

Subjects

Aqueous solution, Small-angle X-ray scattering, Scattering, Chemistry, Relaxation (NMR), Analytical chemistry, Viscometer, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Surfaces, Coatings and Films, Pulmonary surfactant, Dynamic light scattering, Phase (matter), Materials Chemistry, Physical and Theoretical Chemistry, 0210 nano-technology

Abstract

Using dielectric relaxation spectroscopy (DRS), small-angle X-ray scattering (SAXS), dynamic light scattering (DLS), and viscometry, we have investigated the hydration behavior, static structures, Brownian dynamics, and mechanical properties of aqueous solutions of alcohol ethoxylate (C12E15) and methyl ester ethoxylate (C12MEE), hereafter abbreviated as AE and MEE, respectively, in which we especially focus on the effects of the endcaps of these nonionic surfactants. We find that AE and MEE exhibit fairly different phase behaviors in water: AE produces liquid crystalline phases at w (surfactant weight fraction)0.35, whereas MEE retains a liquid phase in an extremely wide concentration range (w0.7) at ambient temperature. The structure factor deduced from SAXS intensities using a generalized indirect Fourier transformation technique and the effective hydration number evaluated from the negative excess bulk water relaxation amplitude revealed by DRS unambiguously demonstrate that hydration water molecules, exhibiting about 4-times-slower collective reorientational dynamics than that of bulk water, contribute to the excluded volume of the micelles. The blocked terminal hydrogen-bond donor/acceptor site of MEE leads to smaller hydration number of MEE than compared to that of AE, and consequently the lower excluded volume of the MEE micelles. The effective micellar volume fraction, ϕ(eff), should be defined by incorporating such different hydration effects. Importantly, voluminosity, defined as the micellar volume fraction per unit mass, is clearly a decreasing function of w, demonstrating progressive dehydration at a higher w. The collective diffusion constants determined by DLS for the AE and MEE micelles show a monotonous increase up to ϕ(eff) ≈ 0.5, as expected for the hard spheres. Low-shear-rate viscosities follow a Krieger-Dougherty model in the identical micellar packing fraction range. All static, dynamic, and mechanical properties of these micellar solutions can be explained in a consistent and quantitative manner only when the excluded volume of hydration water molecules is properly taken into account.

Published

2016

5. The nanostructure of murine alveolar bone and its changes due to type 2 diabetes

Author

Chika Akabane, Andreas Roschger, Shinsuke Kataoka, Wolfgang Wagermaier, Taku Ogura, Tomomichi Okano, Silvia Pabisch, Richard Weinkamer, Peter Fratzl, Norio Tobori, Shinya Murakami, and Ryo Hyodo

Subjects

0301 basic medicine, Nanostructure, Materials science, Alveolar Bone Loss, Mandible, Matrix (biology), Mandibular first molar, 03 medical and health sciences, Mice, stomatognathic system, Structural Biology, Periodontal fiber, Animals, Tooth Socket, Mastication, Dental alveolus, Minerals, Buccal administration, Anatomy, Nanostructures, stomatognathic diseases, 030104 developmental biology, Diabetes Mellitus, Type 2, Bone Remodeling, Biomedical engineering

Abstract

Alveolar bone - the bony ridge containing the tooth sockets - stands out by its remodeling activity where bone is being formed and resorbed at a much higher rate than in any other bony tissue. Teeth that are anchored in the jaw through the periodontal ligament exert very large localized loads during mastication that could lead to a unique adaptation of the collagen/mineral structure in the bone. Our aim was to characterize the nanostructure of alveolar bone and to determine the influence of diabetes on structural characteristics of the mineralized matrix. Using small- and wide-angle X-ray scattering (SAXS/WAXS), we studied a spontaneous diabetic mouse model (KK+) and its corresponding healthy controls (KK-) (n=6) to determine the size and mutual alignment of the mineral nanoparticles embedded in the collagen matrix. On cross-sections (buccal-lingual) of the first molar multiple line scans with a spatial resolution of 30μm were performed on each sample, from the lingual to the buccal side of the mandible. Mineral particle thickness and length are decreasing towards the tooth in both buccal and lingual sides of alveolar bone. While mineral particles are well aligned with the long axis of the tooth on the buccal side, they are in a quarter of the measurements oriented along two preferred directions on the lingual side. These nanostructural differences can be interpreted as the result of an asymmetric loading during mastication, leading to a tilting of the tooth in its socket. In diabetic mice particle thicknesses are smaller compared to control animals.

Published

2016

6. Structural Viscosity Induced by Depletion Effect in Stable Vesicle Dispersion.

Author

Asami Miyajima?, Ryo Inoue, Erika Onishi, Miyuki Miyake, and Ryo Hyodo

Subjects

VISCOSITY, DEXTRINS, CATIONIC surfactants, FLOCCULATION, CONDUCTING polymers

Abstract

Producing structural viscosity in colloidal dispersions, such as vesicles and capsules, prevents separation of dispersed particles by increasing the viscosity between them, which is advantageous in terms of usability. So far, the separation behavior of various particles has been studied; however, there are very few examples wherein a stable dispersion state was constructed and controlled. In this study, we produced stable dispersions induced by the depletion effect in mixtures of vesicles of cationic surfactant derived from triethanolamine-based esterquat (TEQ) and a specific dextrin derivative (SDD) as a non-adsorptive polymer. In the composition region, where 8 to 16% of TEQ vesicles and 1.2% or less of SDDs were mixed, the viscosity increased proportionally with the particle concentration, and it was observed that stable dispersions were produced by structural viscosity. Furthermore, the effects of TEQ and SDD concentrations, and SDD size on the structural viscosity and cohesive energy were investigated, which were similar to the depletion effect in the Asakura-Oosawa (AO) theory. From the results, it was suggested that the structural viscosity of the mixed dispersions (TEQ vesicles and SDDs) was produced by the aggregated TEQ vesicle networks induced by the depletion flocculation. [ABSTRACT FROM AUTHOR]

Published

2019

7. Scattering and Spectroscopic Study on the Hydration and Phase Behavior of Aqueous Alcohol Ethoxylate and Methyl Ester Ethoxylate: Effects of Terminal Groups in Hydrophilic Chains.

Author

Takaaki Sato, Takesi Akahane, Kenshi Amano, Ryo Hyodo, Keiichi Yanase, and Taku Ogura

Published

2016