Yoshiko Miura

Self-organization of supramolecular helical dendrimers into complex electronic materials

The discovery of electrically conducting organic crystals and polymers has widened the range of potential optoelectronic materials, provided these exhibit sufficiently high charge carrier mobilities and are easy to make and process. Organic single crystals have high charge carrier mobilities but are usually impractical, whereas polymers have good processability but low mobilities. Liquid crystals exhibit mobilities approaching those of single crystals and are suitable for applications, but demanding fabrication and processing methods limit their use. Here we show that the self-assembly of fluorinated tapered dendrons can drive the formation of supramolecular liquid crystals with promising optoelectronic properties from a wide range of organic materials. We find that attaching conducting organic donor or acceptor groups to the apex of the dendrons leads to supramolecular nanometre-scale columns that contain in their cores π-stacks of donors, acceptors or donor–acceptor complexes exhibiting high charge carrier mobilities. When we use functionalized dendrons and amorphous polymers carrying compatible side groups, these co-assemble so that the polymer is incorporated in the centre of the columns through donor–acceptor interactions and exhibits enhanced charge carrier mobilities. We anticipate that this simple and versatile strategy for producing conductive π-stacks of aromatic groups, surrounded by helical dendrons, will lead to a new class of supramolecular materials suitable for electronic and optoelectronic applications.

Self-assembly of amphiphilic dendritic dipeptides into helical pores

Natural pore-forming proteins act as viral helical coats and transmembrane channels, exhibit antibacterial activity and are used in synthetic systems, such as for reversible encapsulation or stochastic sensing. These diverse functions are intimately linked to protein structure. The close link between protein structure and protein function makes the design of synthetic mimics a formidable challenge, given that structure formation needs to be carefully controlled on all hierarchy levels, in solution and in the bulk. In fact, with few exceptions, synthetic pore structures capable of assembling into periodically ordered assemblies that are stable in solution and in the solid state have not yet been realized. In the case of dendrimers, covalent and non-covalent coating and assembly of a range of different structures has only yielded closed columns. Here we describe a library of amphiphilic dendritic dipeptides that self-assemble in solution and in bulk through a complex recognition process into helical pores. We find that the molecular recognition and self-assembly process is sufficiently robust to tolerate a range of modifications to the amphiphile structure, while preliminary proton transport measurements establish that the pores are functional. We expect that this class of self-assembling dendrimers will allow the design of a variety of biologically inspired systems with functional properties arising from their porous structure.

Amyloid-β detection with saccharide immobilized gold nanoparticle on carbon electrode

The electrochemical sensing of saccharide-protein interactions using a couple of sialic acid derivatives and Alzheimers amyloid-beta (Abeta) is described. The densely-packed saccharide area for recognition of protein was fabricated onto a carbon electrode by three steps, which were electrochemical deposition of Au nanoparticles on a screen printed strip, self-assembled monolayer (SAM) formation of the acetylenyl group on Au nanoparticles, and the cycloaddition reaction of an azide-terminated sialic acid to the acetylenyl group. The attachment of Abeta peptides to the sialic acid layer was confirmed by electrochemistry and atomic force microscopy imaging. The intrinsic oxidation signal of the captured Abeta(1-40) and (1-42) peptides, containing a single tyrosine (Tyr) residues, was monitored at a peak potential of 0.6 V (vs Ag/AgCl within this sensor) in connection with differential pulse voltammetry. The peak current intensities were concentration dependent. The proposed process provides new routes for analysis of saccharide-protein interactions and electrochemical biosensor development.

Reversible Absorption of CO2 Triggered by Phase Transition of Amine-Containing Micro- and Nanogel Particles

Herein we report that an aqueous solution of temperature-responsive micro- and nanogel particles (GPs) consisting of N-isopropylacrylamide (NIPAm) and N-[3-(dimethylamino)propyl]methacrylamide (DMAPM) reversibly absorbs and desorbs CO(2) via a phase transition induced by cooling and heating cycles (30-75 °C). Below the phase-transition temperature, most of the amines in the swollen GPs are capable of forming ion pairs with absorbed bicarbonate ions. However, above the phase-transition temperature, shrinkage of the GPs lowers the pK(a) and the number of amine groups exposed to water, thereby resulting in almost complete desorption of CO(2). The GPs can reversibly absorb more than the DMAPM monomer and polymer without NIPAm, which indicates the importance of the temperature-responsive phase transition of polymers in determining the degree of absorption. The results show the potential of temperature-responsive polymer solutions as absorbents to sequester CO(2) at a low energy cost.

Temperature-Responsive Microgel Films as Reversible Carbon Dioxide Absorbents in Wet Environment†

Hydrogel films composed of temperature-responsive microgel particles (GPs) containing amine groups work as stimuli-responsive carbon dioxide absorbent with a high capacity of approximately 1.7 mmol g(-1). Although the dried films did not show significant absorption, the reversible absorption capacity dramatically increased by adding a small amount of water (1 mL g(-1)). The absorption capacity was independent of the amount of added water beyond 1 mL g(-1), demonstrating that the GP films can readily be used under wet conditions. The amount of CO2 absorbed by the GP films was proportional to their thickness up to 200-300 μm (maximum capacity of about 2 L m(-2) . Furthermore, the films consisting of GPs showed faster and greater absorption and desorption of CO2 than that of monolithic hydrogel films. These results indicated the importance of a fast stimulus response rate of the films that are composed of GPs in order to achieve long-range and fast diffusion of bicarbonate ions. Our study revealed the potential of stimuli-responsive GP films as energy-efficient absorbents to sequester CO2 from high-humidity exhaust gases.

Negative surface potential produced by self-assembled monolayers of helix peptides oriented vertically to a surface

Abstract Self-assembled monolayers (SAMs) of helix peptides oriented vertically to a gold surface were prepared and the surface potential measured using the Kelvin technique up to 140°C. Negative surface potentials of a few hundred millivolts were observed for the helix peptide SAMs, indicating the occurrence of the large dipole moment of the helices directing toward the surface. The longer the helix peptide, the larger was the negative surface potential obtained. The absolute value of the surface potential decreased with increase in temperature due to thermal perturbation in the helical structure. However, Fourier transform infrared reflection–absorption spectroscopy revealed that perturbation is not significant and the α-helical conformation is stable even at 140°C.

Polymer-modified gold nanoparticles via RAFT polymerization: A detailed study for a biosensing application

Glycopolymers of polyacrylamide derivatives with mannose were prepared via the living radical polymerization of a reversible addition–fragmentation chain transfer reagent. The polymers obtained showed narrow polydispersities. The polymer terminal group was reduced to a thiol, and the resulting polymers were mixed with gold nanoparticles to prepare glycopolymer-substituted gold nanoparticles. The mannose density was adjusted by varying the copolymer preparation and the glycopolymer–polyacrylamide mixture. The colloidal stability of the polymer-coated gold nanoparticles is dependent on the mannose density. Polymer-coated nanoparticles with low mannose densities showed better colloidal stabilities. The molecular recognition abilities of the polymer were investigated using UV-vis spectroscopy. The polymer-coated nanoparticles showed strong protein recognition abilities because of multivalent binding effects. Polymers with high mannose densities showed stronger recognition abilities. The molecular recognition abilities of the glycopolymer–polyacrylamide mixed nanoparticles are dependent on the mannose density. An immunochromatographic assay was performed using the polymer-coated nanoparticles. The color was detected from the gold nanoparticles in the nanoparticle systems with strong molecular recognition and good colloid stability.

Selective Protein Separation Using Siliceous Materials with a Trimethoxysilane-Containing Glycopolymer

A copolymer with α-D-mannose (Man) and trimethoxysilane (TMS) units was synthesized for immobilization on siliceous matrices such as a sensor cell and membrane. Immobilization of the trimethoxysilane-containing copolymer on the matrices was readily performed by incubation at high heat. The recognition of lectin by poly(Man-r-TMS) was evaluated by measurement with a quartz crystal microbalance (QCM) and adsorption on an affinity membrane, QCM results showed that the mannose-binding protein, concanavalin A, was specifically bound on a poly(Man-r-TMS)-immobilized cell with a higher binding constant than bovine serum albumin. The amount of concanavalin A adsorbed during permeation through a poly(Man-r-TMS)-immobilized membrane was higher than that through an unmodified membrane. Moreover, the concanavalin A adsorbed onto the poly(Man-r-TMS)-immobilized membrane was recoverable by permeation of a mannose derivative at high concentration.

Rational Design of Synthetic Nanoparticles with a Large Reversible Shift of Acid Dissociation Constants: Proton Imprinting in Stimuli Responsive Nanogel Particles

Synthetic materials that alter their binding affi nity to target ions and molecules in response to external stimuli have gained considerable attention as substitutes for proteins. Inspired by reversible ion capture triggered by the conformation change of monensin, Shinkai et al. developed photoresponsive synthetic receptors for reversible recognition of specifi c ions. [ 11 ] It has also been reported that temperature-responsive poly( N -isopropyl acrylamide) (pNIPAm) hydrogel fi lms, NPs, and fi bers comprising functional groups reversibly captured targets such as ionic dyes, [ 12 ] bicarbonate ions, [ 10 ] drugs, [ 13 ] peptides, [ 14 ] proteins, [ 15 ] nucleotides, [ 7 ] and cells [ 16 ] under heating and cooling cycles. The binding affi nity of pNIPAm NPs to capture target ions, [ 17 ] peptides, [ 18 ] and proteins [ 19 ] can be further enhanced by polymerizing NPs in the presence of target molecules that serve as a template. In this polymerization procedure of molecular/ion imprinting, the three-dimensional shape of the target molecule is transferred into the polymer network, leaving complementary binding sites in the network after removal of the target. [ 20 ] The imprinted NPs showed a greater affi nity shift in response to the phase transition than the nonimprinted NPs. [ 19 ]

Aggregation of Alzheimer Amyloid β Peptide (1−42) on the Multivalent Sulfonated Sugar Interface

The mechanism of amyloidosis of amyloid beta (1-42) (Abeta (1-42)) was investigated by the well-defined glycocluster interface. We prepared monovalent, divalent, and trivalent 6-sulfo-N-acetyl-d-glucosamine (6S-GlcNAc) immobilized substrates. The morphology and secondary structure of Abeta (1-42) aggregates on the substrates were investigated by dynamic-mode AFM and FTIR-RAS. Abeta (1-42) interactions with multivalent sugars were evaluated by surface plasmon resonance, and the cytotoxicity of Abeta (1-42) to HeLa cells was evaluated by MTT assay. Morphological images showed, interestingly, that Abeta (1-42) aggregates had a tendency to form globules rather than fibrils as the valency of 6S-GlcNAc on the substrate was increased. The SPR measurements indicated that this morphological change of Abeta (1-42) was related to the change of binding mode, and the binding mode was dependent on the multivalency of the sugar. Globular Abeta (1-42) was more toxic than fibrillar Abeta (1-42) to HeLa cells. These results suggested that the multivalency of sugars for the amyloidosis of Abeta (1-42) was significant in its morphology and aggregation effects at the surface of the cell membrane mimic.