Search

Your search keyword '"Nakajima, Tasuku"' showing total 713 results
Start Over Author "Nakajima, Tasuku"
713 results on '"Nakajima, Tasuku"'

361. Supramolecular hydrogels with multi-cylindrical lamellar bilayers: Swelling-induced contraction and anisotropic molecular diffusion.

Author

Mito, Kei, Haque, Md. Anamul, Nakajima, Tasuku, Uchiumi, Maki, Kurokawa, Takayuki, Nonoyama, Takayuki, and Gong, Jian Ping

Subjects
*HYDROGELS, *BILAYER lipid membranes, *HYDROGEN bonding, *DIFFUSION, *AQUEOUS solutions, *ANISOTROPY
Abstract

Novel, supramolecular, anisotropic hydrogels (called MC-PDGI gels) are presented in this study. These MC-PDGI gels consist of multi-cylindrical lipid bilayers aligned in a uniaxial manner and embedded in a soft hydrogel matrix. The bilayers and the hydrogel interact weakly due to hydrogen bonding. These MC-PDGI gels swell after exposure to water, which causes their volume and diameter to increase while simultaneously causing their length to decrease. This anisotropic swelling-induced contraction behavior is the result of competition between the isotropic elasticity of the hydrogel matrix and the interfacial tension of the lipid bilayers. Moreover, the MC-PDGI gels exhibit unique quasi one-dimensional diffusion behavior owing to the difficulty of molecular penetration through the multi-layered lipid bilayers. These materials would be useful for prolonged drug release or as an actuator. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

362. Tough polyion-complex hydrogels from soft to stiff controlled by monomer structure.

Author

Luo, Feng, Sun, Tao Lin, Nakajima, Tasuku, Kurokawa, Takayuki, Li, Xufeng, Guo, Honglei, Huang, Yiwan, Zhang, Huijie, and Gong, Jian Ping

Subjects
*POLYIONS, *HYDROGELS, *MONOMERS, *STIFFNESS (Mechanics), *SELF-healing materials, *IONIC bonds
Abstract

Tough hydrogels with adjustable stiffness are expected for adapting application as various biomaterials. Oppositely charged polyelectrolytes form tough and self-healing physical polyion-complex (PIC) hydrogels via formation of inter-chain ionic bonds with a wide distribution in bond strength. The strong bonds serve as permanent crosslinking to impart elasticity and the weak bonds as reversible sacrificial bonds to dissipate energy and to self-heal. In this work, we fabricate four PIC hydrogels using four positively charged trimethyl-ammonium monomers with slightly different chemical moieties and a same negatively charged polymer. The obtained PIC hydrogels all show high toughness but large difference in stiffness, extensibility, and self-recovery kinetics. With slight difference in the monomer structure of the polycations, the modulus of the hydrogels varies over two orders in magnitude, from 0.36 to 56 MPa, and the difference in elongation at break is up to five times. The presence of acryloyl moiety and methyl moiety increase the stiffness of the hydrogels. In the temperature range studied, all the four PIC hydrogels exhibit the rheological simple behaviours, following the time-temperature superposition principle. The four samples show quite different dynamic relaxation spectra over wide frequency range, revealing large difference in the strength distribution of dynamic ionic bonds. SEM observation reveals quite different phase separation structure for the four samples, in which the polymer chain stiffness should play an important role. This understanding of structure-properties of the PIC hydrogels will merit the designing of various supramolecular tough hydrogels and therefore broaden the scope of hydrogels for the applications as biomaterials. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

363. A Comparative Study of the Structures of {alpha}-Glucans from Suspension-Cultured Nonglutinous and Glutinous Rice Cells

Author

Kato, Yoji, Otsuki, Tatsuya, Nakajima, Tasuku, Ojima, Kunihiko, and Matsuda, Kazuo

Abstract

α-Glucans (average mol wt, 1.3 � 104) extracted with perchloric acid from 8-day-old suspension-cultured nonglutinous (var. Sasanishiki) and glutinous rice (var. Miyakogane) cells were compared. The results of hydrolysis by alpha;-, β- and iso-amylases and methylation analysis of the α-glucans suggested that their basic structures are almost the same. These α-glucans are highly-branched polysaccharides with an average chain length of about 9–10, with exterior and interior chain lengths of about 6–7 and 2–3, respectively.

Published
1988

364. Anisotropic tough double network hydrogel from fish collagen and its spontaneous in vivo bonding to bone.

Author

Mredha, Md. Tariful Islam, Kitamura, Nobuto, Nonoyama, Takayuki, Wada, Susumu, Goto, Keiko, Zhang, Xi, Nakajima, Tasuku, Kurokawa, Takayuki, Takagi, Yasuaki, Yasuda, Kazunori, and Gong, Jian Ping

Subjects
*ANISOTROPIC crystals, *HYDROGELS, *COLLAGEN, *ORTHOPEDIC implants, *TRAUMATIC bone defects, *BONE grafting, *CARTILAGE physiology, *IN vivo studies, *THERAPEUTICS
Abstract

Soft supporting tissues in the human body, such as cartilages and ligaments, are tough materials and firmly fixed to bones. These soft tissues, once injured, cannot regenerate spontaneously in vivo . Developing tough and biocompatible hydrogels as artificial soft supporting tissues would substantially improve outcomes after soft tissue injury. Collagen is the main rigid component in soft connective tissues which is organized in various hierarchical arrays. We have successfully developed a novel class of collagen fibril-based tough hydrogels based on the double network (DN) concept using swim bladder collagen (SBC) extracted from Bester sturgeon fish. The DN hydrogels, SBC/PDMAAm, are composed of physically/chemically crosslinked anisotropic SBC fibril as the first network and neutral, biocompatible poly(N,N′-dimethylacrylamide) (PDMAAm) as the second network. The anisotropic structure of SBC fibril network, which is well retained in the DN hydrogels, is formed by free injection method, taking advantage of the excellent fibrillogenesis capacity of SBC. The denaturation temperature of collagen is improved in the DN hydrogels. These DN gels possess anisotropic swelling behavior, exhibit excellent mechanical properties comparable to natural cartilage. The 4 weeks implantation of the gels in the osteochondral defect of rabbit knee also shows excellent biomechanical performance in vivo . Furthermore, the hydroxyapatite (HAp) coated DN gels, HAp/SBC/PDMAAm gels, strongly bond to bone after 4 weeks. This new class of collagen-based hybrid DN gels, as soft and elastic ceramics, having good biomechanical performance and strong bonding ability with bone would expand the choice for designing next-generation orthopedic implants such as artificial cartilage, bone defect repair material in the load-bearing region of the body. [ABSTRACT FROM AUTHOR]

Published
2017
Full Text
View/download PDF

365. Unique stick-slip crack dynamics of double-network hydrogels under pure-shear loading.

Author

Zheng Y, Wang Y, Tian F, Nakajima T, Hui CY, and Gong JP

Abstract

In this work, we have found that a prenotched double-network (DN) hydrogel, when subjected to tensile loading in a pure-shear geometry, exhibits intriguing stick-slip crack dynamics. These dynamics synchronize with the oscillation of the damage (yielding) zone at the crack tip. Through manipulation of the loading rate and the predamage level of the brittle network in DN gels, we have clarified that this phenomenon stems from the significant amount of energy dissipation required to form the damage zone at the crack tip, as well as a kinetic contrast between the rapid crack extension through the yielding zone (slip process) and the slow formation of a new yielding zone controlled by the external loading rate (stick process)., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published
2024
Full Text
View/download PDF

366. Hydrogel morphogenesis induced by force-controlled growth.

Author

Wang ZJ, Lin J, Nakajima T, and Gong JP

Abstract

Morphogenesis is one of the most marvelous natural phenomena. The morphological characteristics of biological organs develop through growth, which is often triggered by mechanical force. In this study, we propose a bioinspired strategy for hydrogel morphogenesis through force-controlled chemical reaction and growth under isothermal conditions. We adopted a double network (DN) hydrogel with sacrificial bonds. Applying mechanical force to the gel caused deformation and sacrificial bond rupture. By supplying monomers to the gel, the radicals generated by the bond rupture triggered the formation of a new network inside the deformed gel. This new network conferred plasticity to the elastic gel, allowing it to maintain its deformed shape, along with increased volume and strength. We demonstrated that sheet-shaped DN hydrogels rapidly adopted various three-dimensional shapes at ambient temperature when subjected to forces such as drawing and blowing. This mechanism enables morphogenesis of elastic hydrogels and will promote the application of these materials in biomedical fields and soft machines., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published
2024
Full Text
View/download PDF

367. Effect of the Activation Force of Mechanophore on Its Activation Selectivity and Efficiency in Polymer Networks.

Author

Wang ZJ, Wang S, Jiang J, Hu Y, Nakajima T, Maeda S, Craig SL, and Gong JP

Abstract

In recent decades, more than 100 different mechanophores with a broad range of activation forces have been developed. For various applications of mechanophores in polymer materials, it is crucial to selectively activate the mechanophores with high efficiency, avoiding nonspecific bond scission of the material. In this study, we embedded cyclobutane-based mechanophore cross-linkers (I and II) with varied activation forces ( f a ) in the first network of the double network hydrogels and quantitively investigated the activation selectivity and efficiency of these mechanophores. Our findings revealed that cross-linker I, with a lower activation force relative to the bonds in the polymer main chain ( f a-I / f a-chain = 0.8 nN/3.4 nN), achieved efficient activation with 100% selectivity. Conversely, an increase of the activation force of mechanophore II ( f a-II / f a-chain = 2.5 nN/3.4 nN) led to a significant decrease of its activation efficiency, accompanied by a substantial number of nonspecific bond scission events. Furthermore, with the coexistence of two cross-linkers, significantly different activation forces resulted in the almost complete suppression of the higher-force one (i.e., I and III, f a-I / f a-III = 0.8 nN/3.4 nN), while similar activation forces led to simultaneous activations with moderate efficiencies (i.e., I and IV, f a-I / f a-IV = 0.8 nN/1.6 nN). These findings provide insights into the prevention of nonspecific bond rupture during mechanophore activation and enhance our understanding of the damage mechanism within polymer networks when using mechanophores as detectors. Besides, it establishes a principle for combining different mechanophores to design multiple mechanoresponsive functional materials.

Published
2024
Full Text
View/download PDF

368. Azobenzene as a photoswitchable mechanophore.

Author

Li Y, Xue B, Yang J, Jiang J, Liu J, Zhou Y, Zhang J, Wu M, Yuan Y, Zhu Z, Wang ZJ, Chen Y, Harabuchi Y, Nakajima T, Wang W, Maeda S, Gong JP, and Cao Y

Abstract

Azobenzene has been widely explored as a photoresponsive element in materials science. Although some studies have investigated the force-induced isomerization of azobenzene, the effect of force on the rupture of azobenzene has not been explored. Here we show that the light-induced structural change of azobenzene can also alter its rupture forces, making it an ideal light-responsive mechanophore. Using single-molecule force spectroscopy and ultrasonication, we found that cis and trans para-azobenzene isomers possess contrasting mechanical properties. Dynamic force spectroscopy experiments and quantum-chemical calculations in which azobenzene regioisomers were pulled from different directions revealed that the distinct rupture forces of the two isomers are due to the pulling direction rather than the energetic difference between the two isomers. These mechanical features of azobenzene can be used to rationally control the macroscopic fracture behaviours of polymer networks by photoillumination. The use of light-induced conformational changes to alter the mechanical response of mechanophores provides an attractive way to engineer polymer networks of light-regulatable mechanical properties., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published
2024
Full Text
View/download PDF

369. Effect of Predamage on the Fracture Energy of Double-Network Hydrogels.

Author

Zheng Y, Wang Y, Nakajima T, and Gong JP

Abstract

Double-network (DN) hydrogels are tough soft materials, and the high fracture resistance can be attributed to the formation of a large damage zone (internal fracture of the brittle first network) around the crack tip. In this work, we studied the effect of predamage in the brittle network on the fracture energy Γ c of DN hydrogels. The prestretch of the first network was induced by prestretching the DN gels to prestretch ratio λ pre . Depending on the λ pre in relative to the yielding stretch ratio λ y , above which the brittle first network starts to break into discontinuous fragments inside DN gels, two regimes were observed: Γ c decreases monotonically with λ pre in the regime of λ pre < λ y , mainly due to the decreasing contribution from the bulk internal damage, while Γ c increases with λ pre in the regime of λ pre > λ y . The latter can be understood by the release of the hidden length of the stretchable network strands by the rupture of the brittle network, whereby the broken fragments of the brittle network could serve as sliding cross-links to further delocalize the stress-concentration near the crack tip and prevent chain scissions.

Published
2024
Full Text
View/download PDF

370. Role of hierarchy structure on the mechanical adaptation of self-healing hydrogels under cyclic stretching.

Author

Li X, Cui K, Zheng Y, Ye YN, Yu C, Yang W, Nakajima T, and Gong JP

Abstract

Soft materials with mechanical adaptability have substantial potential for various applications in tissue engineering. Gaining a deep understanding of the structural evolution and adaptation dynamics of soft materials subjected to cyclic stretching gives insight into developing mechanically adaptive materials. Here, we investigate the effect of hierarchy structure on the mechanical adaptation of self-healing hydrogels under cyclic stretching training. A polyampholyte hydrogel, composed of hierarchical structures including ionic bonds, transient and permanent polymer networks, and bicontinuous hard/soft-phase networks, is adopted as a model. Conditions for effective training, mild overtraining, and fatal overtraining are demonstrated in soft materials. We further reveal that mesoscale hard/soft-phase networks dominate the long-term memory effect of training and play a crucial role in the asymmetric dynamics of compliance changes and the symmetric dynamics of hydrogel shape evolution. Our findings provide insights into the design of hierarchical structures for adaptive soft materials.

Published
2023
Full Text
View/download PDF

371. Sustainable mechanochemical growth of double-network hydrogels supported by vascular-like perfusion.

Author

Wei G, Kudo Y, Matsuda T, Wang ZJ, Mu QF, King DR, Nakajima T, and Gong JP

Subjects
Perfusion, Hydrogels, Polymers chemistry
Abstract

Double-network (DN) gels are unique mechanochemical materials owing to their structures that can be dynamically remodelled during use. The mechanical energy applied to DN gels is efficiently transferred to the chemical bonds of the brittle network, generating mechanoradicals that initiate the polymerisation of pre-loaded monomers, thereby remodelling the materials. To attain continuous remodelling or growth in response to repetitive mechanical stimuli, a sustainable supply of chemical reagents to such dynamic materials is essential. In this study, inspired by the vascular perfusion transporting nutrients to cells, we constructed a circulatory system for a continuous supply of chemicals to channel-containing DN hydrogels (c-DN gels). The perfusion of monomer solutions through the channel and permeability of the c-DN gels not only replenishes the monomers consumed by the polymerisation but also replenishes the water loss caused by the surface evaporation of hydrogel, thereby freeing the mechanochemical process of DN gels from the constraints of the underwater environment. The facile chemical supply enabled us to modulate the mechanical enhancement of the c-DN gel and attain muscle-like strengthening under repeated mechanical training in deoxygenated air. We also studied the kinetics of polymer growth and strengthening and deciphered unique features of mechanochemical reaction in DN gels including the extremely long-living radicals and delayed mechanical strengthening.

Published
2023
Full Text
View/download PDF

372. Inverse mechanical-swelling coupling of a highly deformed double-network gel.

Author

Imaoka C, Nakajima T, Indei T, Iwata M, Hong W, Marcellan A, and Gong JP

Abstract

Mechanical behaviors of a polymer gel are coupled with its swelling behavior. It has been known that typical hydrogels display extension-induced swelling and drying-induced stiffening, called normal mechanical-swelling coupling. In this study, we experimentally found that highly extended double-network (DN) hydrogels exhibit abnormal inverse mechanical-swelling coupling such as extension-induced deswelling and drying-induced softening. We established theoretical hyperelastic and swelling models that reproduced all the complicated mechanical and swelling trends of the highly deformed DN hydrogels. From these theoretical analyses, it is considered that the inverse mechanical-swelling coupling of a DN gel is derived from the extreme nonlinear elasticity of its first network at its ultimate deformation state. These findings contribute toward the understanding of the mechanics of rubber-like materials up to their ultimate deformation and fracture limit.

Published
2023
Full Text
View/download PDF

373. In Situ and Real-Time Visualization of Mechanochemical Damage in Double-Network Hydrogels by Prefluorescent Probe via Oxygen-Relayed Radical Trapping.

Author

Zheng Y, Jiang J, Jin M, Miura D, Lu FX, Kubota K, Nakajima T, Maeda S, Ito H, and Gong JP

Abstract

Visualization of mechanochemical damages, especially for those in the molecular-scale (e.g., bond scission in polymeric materials), is of great industrial and academic significance. Herein, we report a novel strategy for in situ and real-time visualization of mechanochemical damages in hydrogels by utilizing prefluorescent probes via oxygen-relayed free-radical trapping. Double-network (DN) hydrogels that generate numerous mechanoradicals by homolytic bond scission of the brittle first network at large deformation are used as model materials. Theoretical calculation suggests that mechanoradicals generated by the damage of the first network undergo an oxygen-relayed radical-transfer process which can be detected by the prefluorescent probe through the radical-radical coupling reaction. Such an oxygen-relayed radical-trapping process of the prefluorescent probe exhibits a dramatically enhanced emission, which enables the real-time sensing and visualization of mechanochemical damages in DN hydrogels made from brittle networks of varied chemical structures. To the best of authors' knowledge, this work is the first report utilizing oxygen as a radical-relaying molecule for visualizing mechanoradical damages in polymer materials. Moreover, this new method based on the probe post-loading is simple and does not introduce any chemical structural changes in the materials, outperforming most previous methods that require chemical incorporation of mechanophores into polymer networks.

Published
2023
Full Text
View/download PDF

374. Mechanical Model for Super-Anisotropic Swelling of the Multi-Cylindrical PDGI/PAAm Gels.

Author

Nakajima T, Mito K, and Gong JP

Abstract

MC-PDGI/PAAm gels are cylindrical composite gels containing poly(dodecyl glyceryl itaconate) (PDGI) as a polymerized lipid oriented in a multilayer tubular shape within a polyacrylamide (PAAm) network. The most unique feature of the MC-PDGI/PAAm gel is its super-anisotropic swelling, wherein the diameter of the gel increases, but the length decreases with an increase in the volume of the gel. Through swelling and small-angle X-ray diffraction experiments, we investigated the effects of PDGI lipid bilayers and polymer network on the swelling of the MC-PDGI/PAAm gel, which suggests that the swelling anisotropy of the MC-PDGI/PAAm gel is dominated by the elasticity of the PDGI bilayers. Furthermore, we investigated the equation of state of the gel that roughly reproduced the experimental swelling results. These findings are crucial for realizing the controlled super-anisotropic swelling of MC-PDGI/PAAm gels and their applications as anisotropic actuation devices.

Published
2023
Full Text
View/download PDF

375. Nanoscale TEM Imaging of Hydrogel Network Architecture.

Author

Kiyama R, Yoshida M, Nonoyama T, Sedlačík T, Jinnai H, Kurokawa T, Nakajima T, and Gong JP

Abstract

In this work, the authors succeed in direct visualization of the network structure of synthetic hydrogels with transmission electron microscopy (TEM) by developing a novel staining and network fixation method. Such a direct visualization is not carried out because sample preparation and obtaining sufficient contrast are challenging for these soft materials. TEM images reveal robust heterogeneous network architectures at mesh size scale and defects at micro-scale. TEM images also reveal the presence of abundant dangling chains on the surface of the hydrogel network. The real space structural information provides a comprehensive perspective that links bulk properties with a nanoscale network structure, including fracture, adhesion, sliding friction, and lubrication. The presented method has the potential to advance the field., (© 2022 Wiley-VCH GmbH.)

Published
2023
Full Text
View/download PDF

376. Surfactant induced bilayer-micelle transition for emergence of functions in anisotropic hydrogel.

Author

Haque MA, Kurokawa T, Nakajima T, Kamita G, Fatema Z, and Gong JP

Subjects
Micelles, Sodium Dodecyl Sulfate chemistry, Hydrogels, Anisotropy, Surface-Active Agents chemistry, Pulmonary Surfactants
Abstract

Tuning the self-assembled structures in amorphous hydrogels will enrich the functionality of hydrogels. In this study, we tuned the structure of a photonic hydrogel, which consists of polymeric lamellar bilayers entrapped inside a polyacrylamide network, simply by molecular triggering using an ionic surfactant. Owing to the binding of ionic surfactants (sodium dodecyl sulfate), the lamellar bilayers comprising non-ionic polymeric surfactants [poly(dodecyl glyceryl itaconate)] changed to micelles, whereas the unidirectional lamellar structure was preserved in the hydrogel. The bilayer-micelle structure transition caused a dramatic decrease in the swelling anisotropy and mechanical softening of the photonic gel. With the micelle structure, the softened gel shows fast (0.3 s) and reversible color change over the entire visible light range in response to a small mechanical pressure (5 kPa). This low stress-induced color-changing hydrogel could be applied as a visual tactile sensor in various fields, especially in biomedical engineering.

Published
2022
Full Text
View/download PDF

377. Force-triggered rapid microstructure growth on hydrogel surface for on-demand functions.

Author

Mu Q, Cui K, Wang ZJ, Matsuda T, Cui W, Kato H, Namiki S, Yamazaki T, Frauenlob M, Nonoyama T, Tsuda M, Tanaka S, Nakajima T, and Gong JP

Subjects
Hydrogels chemistry, Water chemistry
Abstract

Living organisms share the ability to grow various microstructures on their surface to achieve functions. Here we present a force stamp method to grow microstructures on the surface of hydrogels based on a force-triggered polymerisation mechanism of double-network hydrogels. This method allows fast spatial modulation of the morphology and chemistry of the hydrogel surface within seconds for on-demand functions. We demonstrate the oriented growth of cells and directional transportation of water droplets on the engineered hydrogel surfaces. This force-triggered method to chemically engineer the hydrogel surfaces provides a new tool in addition to the conventional methods using light or heat, and will promote the wide application of hydrogels in various fields., (© 2022. The Author(s).)

Published
2022
Full Text
View/download PDF

378. Corrigendum: A Glycosylphosphatidylinositol-Anchored α-Amylase Encoded by amyD Contributes to a Decrease in the Molecular Mass of Cell Wall α-1,3-Glucan in Aspergillus nidulans .

Author

Miyazawa K, Yamashita T, Takeuchi A, Kamachi Y, Yoshimi A, Tashiro Y, Koizumi A, Ogata M, Yano S, Kasahara S, Sano M, Yamagata Y, Nakajima T, and Abe K

Abstract

[This corrects the article DOI: 10.3389/ffunb.2021.821946.]., (Copyright © 2022 Miyazawa, Yamashita, Takeuchi, Kamachi, Yoshimi, Tashiro, Koizumi, Ogata, Yano, Kasahara, Sano, Yamagata, Nakajima and Abe.)

Published
2022
Full Text
View/download PDF

379. A Glycosylphosphatidylinositol-Anchored α-Amylase Encoded by amyD Contributes to a Decrease in the Molecular Mass of Cell Wall α-1,3-Glucan in Aspergillus nidulans .

Author

Miyazawa K, Yamashita T, Takeuchi A, Kamachi Y, Yoshimi A, Tashiro Y, Koizumi A, Ogata M, Yano S, Kasahara S, Sano M, Yamagata Y, Nakajima T, and Abe K

Abstract

α-1,3-Glucan is one of the main polysaccharides in the cell wall of Aspergillus nidulans . We previously revealed that it plays a role in hyphal aggregation in liquid culture, and that its molecular mass (MM) in an agsA -overexpressing ( agsA OE ) strain was larger than that in an agsB -overexpressing ( agsB OE ) strain. The mechanism that regulates its MM is poorly understood. Although the gene amyD , which encodes glycosylphosphatidylinositol (GPI)-anchored α-amylase (AmyD), is involved in the biosynthesis of α-1,3-glucan in A . nidulans , how it regulates this biosynthesis remains unclear. Here we constructed strains with disrupted amyD (Δ amyD ) or overexpressed amyD ( amyD OE ) in the genetic background of the ABPU1 (wild-type), agsA OE , or agsB OE strain, and characterized the chemical structure of α-1,3-glucans in the cell wall of each strain, focusing on their MM. The MM of α-1,3-glucan from the agsB OE amyD OE strain was smaller than that in the parental agsB OE strain. In addition, the MM of α-1,3-glucan from the agsA OE Δ amyD strain was greater than that in the agsA OE strain. These results suggest that AmyD is involved in decreasing the MM of α-1,3-glucan. We also found that the C-terminal GPI-anchoring region is important for these functions., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Miyazawa, Yamashita, Takeuchi, Kamachi, Yoshimi, Tashiro, Koizumi, Ogata, Yano, Kasahara, Sano, Yamagata, Nakajima and Abe.)

Published
2022
Full Text
View/download PDF

380. How chain dynamics affects crack initiation in double-network gels.

Author

Zheng Y, Matsuda T, Nakajima T, Cui W, Zhang Y, Hui CY, Kurokawa T, and Gong JP

Abstract

Double-network gels are a class of tough soft materials comprising two elastic networks with contrasting structures. The formation of a large internal damage zone ahead of the crack tip by the rupturing of the brittle network accounts for the large crack resistance of the materials. Understanding what determines the damage zone is the central question of the fracture mechanics of double-network gels. In this work, we found that at the onset of crack propagation, the size of necking zone, in which the brittle network breaks into fragments and the stretchable network is highly stretched, distinctly decreases with the increase of the solvent viscosity, resulting in a reduction in the fracture toughness of the material. This is in sharp contrast to the tensile behavior of the material that does not change with the solvent viscosity. This result suggests that the dynamics of stretchable network strands, triggered by the rupture of the brittle network, plays a role. To account for this solvent viscosity effect on the crack initiation, a delayed blunting mechanism regarding the polymer dynamics effect is proposed. The discovery on the role of the polymer dynamic adds an important missing piece to the fracture mechanism of this unique material., Competing Interests: The authors declare no competing interest.

Published
2021
Full Text
View/download PDF

381. Downregulation of the ypdA Gene Encoding an Intermediate of His-Asp Phosphorelay Signaling in Aspergillus nidulans Induces the Same Cellular Effects as the Phenylpyrrole Fungicide Fludioxonil.

Author

Yoshimi A, Hagiwara D, Ono M, Fukuma Y, Midorikawa Y, Furukawa K, Fujioka T, Mizutani O, Sato N, Miyazawa K, Maruyama JI, Marui J, Yamagata Y, Nakajima T, Tanaka C, and Abe K

Abstract

Many eukaryotic histidine-to-aspartate (His-Asp) phosphorelay systems consist of three types of signal transducers: a His-kinase (HK), a response regulator (RR), and a histidine-containing phosphotransfer intermediate (HPt). In general, the HPt acts as an intermediate between the HK and the RR and is indispensable for inducing appropriate responses to environmental stresses. In a previous study, we attempted but were unable to obtain deletion mutants of the ypdA gene in order to characterize its function in the filamentous fungus Aspergillus nidulans . In the present study, we constructed the C ypdA strain in which ypdA expression is conditionally regulated by the A. nidulans alcA promoter. We constructed C ypdA strains with RR gene disruptions (C ypdA-sskA Δ, C ypdA-srrA Δ, and C ypdA-sskA Δ srrA Δ). Suppression of YpdA induced by ypdA downregulation activated the downstream HogA mitogen-activated protein kinase cascade. YpdA suppression caused severe growth defects and abnormal hyphae, with features such as enhanced septation, a decrease in number of nuclei, nuclear fragmentation, and hypertrophy of vacuoles, both regulated in an SskA-dependent manner. Fludioxonil treatment caused the same cellular responses as ypdA suppression. The growth-inhibitory effects of fludioxonil and the lethality caused by ypdA downregulation may be caused by the same or similar mechanisms and to be dependent on both the SskA and SrrA pathways., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Yoshimi, Hagiwara, Ono, Fukuma, Midorikawa, Furukawa, Fujioka, Mizutani, Sato, Miyazawa, Maruyama, Marui, Yamagata, Nakajima, Tanaka and Abe.)

Published
2021
Full Text
View/download PDF

382. Molecular mechanism of abnormally large nonsoftening deformation in a tough hydrogel.

Author

Ye YN, Cui K, Hong W, Li X, Yu C, Hourdet D, Nakajima T, Kurokawa T, and Gong JP

Abstract

Tough soft materials usually show strain softening and inelastic deformation. Here, we study the molecular mechanism of abnormally large nonsoftening, quasi-linear but inelastic deformation in tough hydrogels made of hyperconnective physical network and linear polymers as molecular glues to the network. The interplay of hyperconnectivity of network and effective load transfer by molecular glues prevents stress concentration, which is revealed by an affine deformation of the network to the bulk deformation up to sample failure. The suppression of local stress concentration and strain amplification plays a key role in avoiding necking or strain softening and endows the gels with a unique large nonsoftening, quasi-linear but inelastic deformation., Competing Interests: The authors declare no competing interest.

Published
2021
Full Text
View/download PDF

383. Experimental Verification of the Balance between Elastic Pressure and Ionic Osmotic Pressure of Highly Swollen Charged Gels.

Author

Nakajima T, Hoshino KI, Guo H, Kurokawa T, and Gong JP

Abstract

The equilibrium swelling degree of a highly swollen charged gel has been thought to be determined by the balance between its elastic pressure and ionic osmotic pressure. However, the full experimental verification of this balance has not previously been conducted. In this study, we verified the balance between the elastic pressure and ionic osmotic pressure of charged gels using purely experimental methods. We used tetra-PEG gels created using the molecular stent method (St-tetra-PEG gels) as the highly swollen charged gels to precisely and separately control their network structure and charge density. The elastic pressure of the gels was measured through the indentation test, whereas the ionic osmotic pressure was determined by electric potential measurement without any strong assumptions or fittings. We confirmed that the two experimentally determined pressures of the St-tetra-PEG gels were well balanced at their swelling equilibrium, suggesting the validity of the aforementioned relationship. Furthermore, from single-strand level analysis, we investigated the structural requirements of the highly swollen charged gels in which the elasticity and ionic osmosis are balanced at their swelling equilibrium.

Published
2021
Full Text
View/download PDF

384. Polyzwitterions as a Versatile Building Block of Tough Hydrogels: From Polyelectrolyte Complex Gels to Double-Network Gels.

Author

Yin H, King DR, Sun TL, Saruwatari Y, Nakajima T, Kurokawa T, and Gong JP

Subjects
Gels chemistry, Molecular Structure, Particle Size, Surface Properties, Hydrogels chemistry, Polyelectrolytes chemistry, Polymers chemistry, Sulfonic Acids chemistry
Abstract

The high water content of hydrogels makes them important as synthetic biomaterials, and tuning the mechanical properties of hydrogels to match those of natural tissues without changing chemistry is usually difficult. In this study, we have developed a series of hydrogels with varied stiffness, strength, and toughness based on a combination of poly(2-acrylamido-2-methylpropane sulfonic acid) (PAMPS), a strong acidic polyelectrolyte, and poly- N -(carboxymethyl)- N , N -dimethyl-2-(methacryloyloxy) ethanaminium) (PCDME), a polyzwitterion with a weak acidic moiety. We demonstrate that modifying the true molar ratio, R , of PCDME to PAMPS results in four unique categories of hydrogels with different swelling ratios and Young's moduli. When R < 1, a negatively charged polyelectrolyte gel (PE) is formed; when 1 < R < 3, a tough and viscoelastic polyelectrolyte complex gel (PEC) is formed; when 3 < R < 6.5, a conventional, elastic interpenetrating network gel (IPN) is formed; and when R > 6.5, a tough and stiff double-network gel (DN) is formed. Both the PEC and DN gels exhibit high toughness and fracture stress, up to 1.8 and 1.5 MPa, respectively. Importantly, the PEC gels exhibit strong recovery properties along with high toughness, distinguishing them from DN gels. Without requiring a change in chemistry, we can tune the mechanical response of hydrogels over a wide spectrum, making this a useful system of soft and hydrated biomaterials.

Published
2020
Full Text
View/download PDF

385. Chitin-Based Double-Network Hydrogel as Potential Superficial Soft-Tissue-Repairing Materials.

Author

Huang J, Frauenlob M, Shibata Y, Wang L, Nakajima T, Nonoyama T, Tsuda M, Tanaka S, Kurokawa T, and Gong JP

Subjects
Animals, Biocompatible Materials, Mice, NIH 3T3 Cells, Tissue Scaffolds, Chitin, Hydrogels
Abstract

Chitin is a biopolymer, which has been proven to be a biomedical material candidate, yet the weak mechanical properties seriously limit their potentials. In this work, a chitin-based double-network (DN) hydrogel has been designed as a potential superficial repairing material. The hydrogel was synthesized through a double-network (DN) strategy composing hybrid regenerated chitin nanofiber (RCN)-poly (ethylene glycol diglycidyl ether) (PEGDE) as the first network and polyacrylamide (PAAm) as the second network. The hybrid RCN-PEGDE/PAAm DN hydrogel was strong and tough, possessing Young's modulus (elasticity) E 0.097 ± 0.020 MPa, fracture stress σ f 0.449 ± 0.025 MPa, and work of fracture W f 5.75 ± 0.35 MJ·m -3 . The obtained DN hydrogel was strong enough for surgical requirements in the usage of soft tissue scaffolds. In addition, chitin endowed the DN hydrogel with good bacterial resistance and accelerated fibroblast proliferation, which increased the NIH3T3 cell number by nearly five times within 3 days. Subcutaneous implantation studies showed that the DN hydrogel did not induce inflammation after 4 weeks, suggesting a good biosafety in vivo. These results indicated that the hybrid RCN-PEGDE/PAAm DN hydrogel had great prospect as a rapid soft-tissue-repairing material.

Published
2020
Full Text
View/download PDF

386. Effect of the constituent networks of double-network gels on their mechanical properties and energy dissipation process.

Author

Nakajima T, Kurokawa T, Furukawa H, and Gong JP

Abstract

Double-network (DN) gels, consisting of brittle first and ductile second networks, possess extraordinary strength, extensibility, and fracture toughness while maintaining a high solvent content. Herein, we prepare DN gels consisting of various concentrations of the first and second networks to investigate the effect of each network structure on the tensile and fracture properties of DN gels. The results showed that the tensile properties of DN gels before yielding are mainly dominated by the first network, serving as a skeleton, whereas the properties after necking are determined by both networks. Moreover, we found that the DN gels with significant energy dissipation capacities exhibit high fracture resistance. Thus, this study not only confirms the factors determining the mechanical characteristics of DN gels but also explains how the two networks concertedly improve the toughness of DN gels.

Published
2020
Full Text
View/download PDF

387. Double-network gels as polyelectrolyte gels with salt-insensitive swelling properties.

Author

Nakajima T, Chida T, Mito K, Kurokawa T, and Gong JP

Abstract

Polyelectrolyte gels exhibit intrinsic salt-sensitive swelling behaviour, which causes size instability in ionic environments. Thus, polyelectrolyte gels that show salt-insensitive swelling have been anticipated for applications in ionic environments, such as medical materials used in vivo. We found that double-network (DN) gels consisting of both a polyelectrolyte network and a non-ionic network are resistant to salt-sensitive swelling. This resistance is attributed to their lower osmotic pressure originating from mobile ions relative to the osmotic pressure of mixing at swelling equilibrium. Our investigation indicated that the two contrasting network structures within the DN gels are vital for achieving these properties, where the structures include a highly prestretched and sparse polyelectrolyte network and a coiled and dense non-ionic network. The salt-insensitivity of the DN gels will lead to their unique applications in ionic environments.

Published
2020
Full Text
View/download PDF

388. Network elasticity of a model hydrogel as a function of swelling ratio: from shrinking to extreme swelling states.

Author

Hoshino KI, Nakajima T, Matsuda T, Sakai T, and Gong JP

Abstract

In this work, we intended to investigate the relationship between the swelling ratio Q and Young's modulus E of hydrogels from their contracted state to extreme swelling state and elucidate the underlining molecular mechanism. For this purpose, we used tetra-poly(ethylene glycol) (tetra-PEG) gel, whose network parameters are well known, as the polymer backbone, and we succeeded in tuning the swelling of the gel by a factor of 1500 times while maintaining the topological structure of the network unchanged, using an approach combining a molecular stent method and a PEG dehydration method. A master curve of Q-E, independent of the method of obtaining Q, was obtained. Using the worm-like chain model, the experimentally determined master curve can be well reproduced. We also observed that the uniaxial stress-strain curve of the hydrogel can be well predicted by the worm-like chain model using the structure parameters determined from the fitting of the Q-E experimental curve.

Published
2018
Full Text
View/download PDF

389. Elastic-Plastic Transformation of Polyelectrolyte Complex Hydrogels from Chitosan and Sodium Hyaluronate.

Author

Shi R, Sun TL, Luo F, Nakajima T, Kurokawa T, Bin YZ, Rubinstein M, and Gong JP

Abstract

Hydrogels formed by polyelectrolyte complexation (PEC) of oppositely charged biopolymers, free of any chemical additives, are promising biomaterials. In this work, the mechanical behavior of hydrogels consisting of positively charged chitosan and negatively charged sodium hyaluronate (HA) at balanced charge composition is investigated. These hydrogels exhibit strong tensile strain and strain rate dependence. They are elastic-like, independent of the strain rate at small strain, but exhibit plastic-like behavior above the yield point by showing a monotonous decrease of the stress. The cyclic tensile test demonstrates that these hydrogels exhibit small and quickly recoverable hysteresis in the elastic-like region, but large and partially recoverable hysteresis above the yield point. The stress relaxation experiment shows a plateau in the reduced stress followed by an abrupt fracture, and the time-to-failure decreases exponentially with increasing applied step-strain. Such elastic-to-plastic-like transformation of the biopolymer PEC gels is quite different from the behaviors of PEC hydrogels formed by oppositely charged vinyl-type synthetic polyelectrolytes due to the difference in flexibility, charge density, and ionic bond strength of these polymers., Competing Interests: The authors declare no competing financial interest.

Published
2018
Full Text
View/download PDF

390. Micro patterning of hydroxyapatite by soft lithography on hydrogels for selective osteoconduction.

Author

Kiyama R, Nonoyama T, Wada S, Semba S, Kitamura N, Nakajima T, Kurokawa T, Yasuda K, Tanaka S, and Gong JP

Subjects
Animals, Cell Line, Durapatite chemistry, Durapatite pharmacology, Female, Mice, Rabbits, Bone Regeneration drug effects, Bone Substitutes chemistry, Bone Substitutes pharmacology, Hydrogels chemistry, Hydrogels pharmacology
Abstract

Mechanically robust hydrogels are promising biomaterials as artificial supportive tissue. These applications require selective and robust bonding of the hydrogels to living tissue. Recently, we achieved strong in vivo bone bonding of a tough double network (DN) hydrogel, a potential material for use as artificial cartilage and tendon, by hybridizing osteoconductive hydroxyapatite (HAp) in the gel surface layer. In this work, we report micro patterning of HAp at the surface of the DN hydrogel for selective osteoconduction. Utilizing the dissolution of HAp in an acidic environment, the soft lithography technique using an acid gel stamp was adopted to form a high-resolution HAp pattern on the gel. The HAp-patterned gel showed well-regulated migration and adhesion of cells in vitro. Moreover, the HAp-patterned gel showed selective and robust bonding to the rabbit bone tissue in vivo. This HAp soft lithography technique allows for simple and quick preparation of tailor-made osteoconductive hydrogels and can be applied to other hydrogels for selective bone bonding. STATEMENT OF SIGNIFICANCE: Hydrogels, preserving large amount of water, have been studied for next-generation artificial soft tissues. However, fixation of hydrogels to living tissue was unsolved issue for clinical application. Recently, we achieved robust bonding of a tough double network gel to bone in vivo by coating of osteoconductive hydroxyapatite in the gel surface layer. For further progress for practical use, we report the micro patterning of HAp at the surface of the DN hydrogel by using soft lithography technique, to perform selective bonding to only objective area without unnecessary coalescence. The HAp lithography technique is simple, quick and non-toxic method to prepare tailor-made osteoconductive hydrogels and has universality of species of hydrogels., (Copyright © 2018 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published
2018
Full Text
View/download PDF

391. A Facile Method to Fabricate Anisotropic Hydrogels with Perfectly Aligned Hierarchical Fibrous Structures.

Author

Mredha MTI, Guo YZ, Nonoyama T, Nakajima T, Kurokawa T, and Gong JP

Abstract

Natural structural materials (such as tendons and ligaments) are comprised of multiscale hierarchical architectures, with dimensions ranging from nano- to macroscale, which are difficult to mimic synthetically. Here a bioinspired, facile method to fabricate anisotropic hydrogels with perfectly aligned multiscale hierarchical fibrous structures similar to those of tendons and ligaments is reported. The method includes drying a diluted physical hydrogel in air by confining its length direction. During this process, sufficiently high tensile stress is built along the length direction to align the polymer chains and multiscale fibrous structures (from nano- to submicro- to microscale) are spontaneously formed in the bulk material, which are well-retained in the reswollen gel. The method is useful for relatively rigid polymers (such as alginate and cellulose), which are susceptible to mechanical signal. By controlling the drying with or without prestretching, the degree of alignment, size of superstructures, and the strength of supramolecular interactions can be tuned, which sensitively influence the strength and toughness of the hydrogels. The mechanical properties are comparable with those of natural ligaments. This study provides a general strategy for designing hydrogels with highly ordered hierarchical structures, which opens routes for the development of many functional biomimetic materials for biomedical applications., (© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2018
Full Text
View/download PDF

392. Tough and Variable-Band-Gap Photonic Hydrogel Displaying Programmable Angle-Dependent Colors.

Author

Haque MA, Mito K, Kurokawa T, Nakajima T, Nonoyama T, Ilyas M, and Gong JP

Abstract

One-dimensional photonic crystals or multilayer films produce colors that change depending on viewing and light illumination angles because of the periodic refractive index variation in alternating layers that satisfy Bragg's law. Recently, we have developed multilayered photonic hydrogels of two distinct bulk geometries that possess an alternating structure of a rigid polymeric lamellar bilayer and a ductile polyacrylamide (PAAm) matrix. In this paper, we focus on fabrication of composite gels with variable photonic band gaps by controlling the PAAm layer thickness. We report programmable angle-dependent and angle-independent structural colors produced by composite hydrogels, which is achieved by varying bulk and internal geometries. In the sheet geometry, where the lamellae are aligned parallel to the sheet surface, the photonic gel sheet exhibits strong angle-dependent colors. On the other hand, when lamellae are coaxially aligned in a cylindrical geometry, the gel rod exhibits an angle-independent color, in sharp contrast with the gel sheet. Rocking curves have been constructed to justify the diverse angle-dependent behavior of various geometries. Despite varying the bulk geometry, the tunable photonic gels exhibit strong mechanical performances and toughness. The distinct angle dependence of these tough photonic materials with variable band gaps could benefit light modulation in displays and sensor technologies., Competing Interests: The authors declare no competing financial interest.

Published
2018
Full Text
View/download PDF

393. Anisotropic Growth of Hydroxyapatite in Stretched Double Network Hydrogel.

Author

Fukao K, Nonoyama T, Kiyama R, Furusawa K, Kurokawa T, Nakajima T, and Gong JP

Abstract

Bone tissues possess excellent mechanical properties such as compatibility between strength and flexibility and load bearing owing to the hybridization of organic/inorganic matters with anisotropic structure. To synthetically mimic such an anisotropic structure of natural organic/inorganic hybrid materials, we carried out hydroxyapatite (HAp) mineralization in stretched tough double network (DN) hydrogels. Anisotropic mineralization of HAp took place in stretched hydrogels, as revealed by high brightness synchrotron X-ray scattering and transmission electron microscopic observation. The c-axis of mineralized HAp aligned along the stretching direction, and the orientation degree S calculated from scattering profiles increased with increasing in the elongation ratio λ of the DN gel, and S at λ = 4 became comparable to that of rabbit tibial bones. The morphology of HAp polycrystal gradually changed from spherical to unidirectional rod-like shape with increased elongation ratio. A possible mechanism for the anisotropic mineralization is proposed, which would be one of the keys to develop mechanically anisotropic organic/inorganic hybrid materials.

Published
2017
Full Text
View/download PDF

394. Anisotropic tough double network hydrogel from fish collagen and its spontaneous in vivo bonding to bone.

Author

Mredha MTI, Kitamura N, Nonoyama T, Wada S, Goto K, Zhang X, Nakajima T, Kurokawa T, Takagi Y, Yasuda K, and Gong JP

Subjects
Acrylamides therapeutic use, Animals, Anisotropy, Bone and Bones injuries, Cartilage chemistry, Female, Fishes, Humans, Hydrogel, Polyethylene Glycol Dimethacrylate therapeutic use, Materials Testing, Mechanical Phenomena, Rabbits, Weight-Bearing, Acrylamides chemistry, Bone and Bones surgery, Collagen Type I chemistry, Collagen Type I therapeutic use, Hydrogel, Polyethylene Glycol Dimethacrylate chemistry
Abstract

Soft supporting tissues in the human body, such as cartilages and ligaments, are tough materials and firmly fixed to bones. These soft tissues, once injured, cannot regenerate spontaneously in vivo. Developing tough and biocompatible hydrogels as artificial soft supporting tissues would substantially improve outcomes after soft tissue injury. Collagen is the main rigid component in soft connective tissues which is organized in various hierarchical arrays. We have successfully developed a novel class of collagen fibril-based tough hydrogels based on the double network (DN) concept using swim bladder collagen (SBC) extracted from Bester sturgeon fish. The DN hydrogels, SBC/PDMAAm, are composed of physically/chemically crosslinked anisotropic SBC fibril as the first network and neutral, biocompatible poly(N,N'-dimethylacrylamide) (PDMAAm) as the second network. The anisotropic structure of SBC fibril network, which is well retained in the DN hydrogels, is formed by free injection method, taking advantage of the excellent fibrillogenesis capacity of SBC. The denaturation temperature of collagen is improved in the DN hydrogels. These DN gels possess anisotropic swelling behavior, exhibit excellent mechanical properties comparable to natural cartilage. The 4 weeks implantation of the gels in the osteochondral defect of rabbit knee also shows excellent biomechanical performance in vivo. Furthermore, the hydroxyapatite (HAp) coated DN gels, HAp/SBC/PDMAAm gels, strongly bond to bone after 4 weeks. This new class of collagen-based hybrid DN gels, as soft and elastic ceramics, having good biomechanical performance and strong bonding ability with bone would expand the choice for designing next-generation orthopedic implants such as artificial cartilage, bone defect repair material in the load-bearing region of the body., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published
2017
Full Text
View/download PDF

395. Stretching-induced ion complexation in physical polyampholyte hydrogels.

Author

Cui K, Sun TL, Kurokawa T, Nakajima T, Nonoyama T, Chen L, and Gong JP

Abstract

Recently, we have developed a series of charge balanced polyampholyte (PA) physical hydrogels by random copolymerization in water, which show extraordinarily high toughness, self-healing ability and viscoelasticity. The excellent performance of PA hydrogels is ascribed to dynamic ionic bond formation through inter- and intra-chain interactions. The randomness results in ionic bonds of wide strength distribution, the strong bonds, which serve as permanent crosslinking, imparting the elasticity, while the weak bonds reversibly break and re-form, dissipating energy. In this work, we developed a simple physical method, called a pre-stretching method, to promote the performance of PA hydrogels. By imposing a pre-stretching on the sample in the as-prepared state, ion complexation during dialysis is prominently accelerated and the final performance is largely promoted. Further analysis suggests that the strong bond formation induced by pre-stretching is responsible for the change in final performance. Pre-stretching decreases the entropy of the system and increases the chain alignment, resulting in an increased possibility for strong bond formation.

Published
2016
Full Text
View/download PDF

396. Substantial decrease in cell wall α-1,3-glucan caused by disruption of the kexB gene encoding a subtilisin-like processing protease in Aspergillus oryzae.

Author

Mizutani O, Shiina M, Yoshimi A, Sano M, Watanabe T, Yamagata Y, Nakajima T, Gomi K, and Abe K

Subjects
Aspergillus oryzae genetics, Cell Wall chemistry, Cell Wall metabolism, Chitin chemistry, Glucans chemistry, Glucose metabolism, Subtilisin metabolism, beta-Glucans chemistry, beta-Glucans metabolism, Aspergillus oryzae enzymology, Fungal Proteins genetics, Glucans biosynthesis, Peptide Hydrolases genetics, Serine Endopeptidases genetics
Abstract

Disruption of the kexB encoding a subtilisin-like processing protease in Aspergillus oryzae (ΔkexB) leads to substantial morphological defects when the cells are grown on Czapek-Dox agar plates. We previously found that the disruption of kexB causes a constitutive activation of the cell wall integrity pathway. To understand how the disruption of the kexB affects cell wall organization and components, we analyzed the cell wall of ΔkexB grown on the plates. The results revealed that both total N-acetylglucosamine content, which constitutes chitin, and chitin synthase activities were increased. Whereas total glucose content, which constitutes β-1,3-glucan and α-1,3-glucan, was decreased; this decrease was attributed to a remarkable decrease in α-1,3-glucan. Additionally, the β-1,3-glucan in the alkali-insoluble fraction of the ΔkexB showed a high degree of polymerization. These results suggested that the loss of α-1,3-glucan in the ΔkexB was compensated by increases in the chitin content and the average degree of β-1,3-glucan polymerization.

Published
2016
Full Text
View/download PDF

397. Double-Network Hydrogels Strongly Bondable to Bones by Spontaneous Osteogenesis Penetration.

Author

Nonoyama T, Wada S, Kiyama R, Kitamura N, Mredha MT, Zhang X, Kurokawa T, Nakajima T, Takagi Y, Yasuda K, and Gong JP

Subjects
Animals, Durapatite chemistry, Rabbits, Bone and Bones chemistry, Hydrogels chemistry, Osteogenesis
Abstract

On implanting hydroxyapatite-mineralized tough hydrogel into osteochondral defects of rabbits, osteogenesis spontaneously penetrates into the gel matrix owing to the semi-permeablility of the hydrogel. The gradient layer (around 40 μm thick) contributes quite strong bonding of the gel to bone. This is the first success in realizing the robust osteointegration of tough hydrogels, and the method is simple and feasible for practical use., (© 2016 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2016
Full Text
View/download PDF

398. Coupled instabilities of surface crease and bulk bending during fast free swelling of hydrogels.

Author

Takahashi R, Ikura Y, King DR, Nonoyama T, Nakajima T, Kurokawa T, Kuroda H, Tonegawa Y, and Gong JP

Abstract

Most studies on hydrogel swelling instability have been focused on a constrained boundary condition. In this paper, we studied the mechanical instability of a piece of disc-shaped hydrogel during free swelling. The fast swelling of the gel induces two swelling mismatches; a surface-inner layer mismatch and an annulus-disc mismatch, which lead to the formation of a surface crease pattern and a saddle-like bulk bending, respectively. For the first time, a stripe-like surface crease that is at a right angle on the two surfaces of the gel was observed. This stripe pattern is related to the mechanical coupling of surface instability and bulk bending, which is justified by investigating the swelling-induced surface pattern on thin hydrogel sheets fixed onto a saddle-shaped substrate prior to swelling. A theoretical mechanism based on an energy model was developed to show an anisotropic stripe-like surface crease pattern on a saddle-shaped surface. These results might be helpful to develop novel strategies for controlling crease patterns on soft and wet materials by changing their three-dimensional shape.

Published
2016
Full Text
View/download PDF

399. Tough Physical Double-Network Hydrogels Based on Amphiphilic Triblock Copolymers.

Author

Zhang HJ, Sun TL, Zhang AK, Ikura Y, Nakajima T, Nonoyama T, Kurokawa T, Ito O, Ishitobi H, and Gong JP

Abstract

A series of physical double-network hydrogels is synthesized based on an amphiphilic triblock copolymer. The gel, which contains strong hydrophobic domains and sacrificial dynamic bonds of hydrogen bonds, is stiff and tough, and even stiffens in concentrated saline solution. Furthermore, due to its supramolecular structure, the gel features improved self-healing and self-recovery abilities., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2016
Full Text
View/download PDF

400. Molecular structure of self-healing polyampholyte hydrogels analyzed from tensile behaviors.

Author

Sun TL, Luo F, Kurokawa T, Karobi SN, Nakajima T, and Gong JP

Abstract

Recently, charge balanced polyampholytes (PA) have been found to form tough and self-healing hydrogels. This class of physical hydrogels have a very high equilibrated polymer concentration in water (ca. 40-50 wt%), and are strongly viscoelastic. They are synthesized by random copolymerization of equal amounts of oppositely charged monomers at a high concentration, followed by a dialysis process of the small counter-ions and co-ions in water. The randomly distributed, opposite charges of the polymer form multiple ionic bonds of intra- and inter-chains with strength distribution. The strong inter-chain bonds, stabilized by topological entanglement, serve as quasi-permanent crosslinks, imparting the elasticity, while the weak bonds, both inter- and intra-chains, reversibly break and re-form to dissipate energy to toughen the materials. In this work, we intend to clarify the structure of the physical PA hydrogels from the tensile behaviors of the PA hydrogels. To clarify the structure and its formation mechanism, we analysed the tensile behaviors of the samples before and after the dialysis. We separated the quasi-permanent crosslinking of strong inter-chain bonds and the dynamic crosslinking of weak inter-chain bonds by using a combined model that consists of the Upper Convected Maxwell model and the Gent strain hardening model. The model fitting of the tensile behaviors extracts quantitative structural parameters, including the densities of weak and strong inter-chain bonds and the theoretical finite extensibility of polymer chains. Based on the fitting results of the combined model, the structural parameters of partial chains at a fixed observation time, including the Kuhn number, Kuhn length, and chain conformation, are determined using the scaling theory. The effects of monomer concentration at preparation, the effect of dialysis and the initial strain rate on the dynamic structure of PA gels, are discussed based on these analyses.

Published
2015
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results