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Control of Chiral Nanostructures by Self‐Assembly of Designed Amphiphilic Peptides and Silica Biomineralization 下载免费PDF全文
Zhehao Huang Dr. Yuan Yao Dr. Lu Han Prof. Shunai Che 《Chemistry (Weinheim an der Bergstrasse, Germany)》2014,20(51):17068-17076
Peptides, the fundamental building units of biological systems, are chiral in molecular scale as well as in spatial conformation. Shells are exquisite examples of well‐defined chiral structures produced by natural biomineralization. However, the fundamental mechanism of chirality expressed in biological organisms remains unclear. Here, we present a system that mimics natural biomineralization and produces enantiopure chiral inorganic materials with controllable helicity. By tuning the hydrophilicity of the amphiphilic peptides, the chiral morphologies and mesostructures can be changed. With decreasing hydrophilicity of the amphiphilic peptides, we observed that the nanostructures changed from twisted nanofibers with a hexagonal mesostructure to twisted nanoribbons with a lamellar mesostructure, and the extent of the helicity decreased. Defining the mechanism of chiral inorganic materials formed from peptides by noncovalent interactions can improve strategies toward the bottom‐up synthesis of nanomaterials as well as in the field of bioengineering. 相似文献
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The control of crystal formation has been developed to a remarkable degree by many organisms. Oriented nucleation, control over crystal morphology, formation of unique composites of proteins and single crystals, and the production of ordered multicrystal arrays, are all well within the realm of biological capability. Understanding the control and design principles in biomineralization is a fascinating subject that may well contribute to the improved fabrication of synthetic materials on the one hand, and to the solution of many serious pathological problems involving mineralization, on the other. 相似文献
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Bäuerlein E 《Angewandte Chemie (International ed. in English)》2003,42(6):614-641
With evolution, Nature has ingeniously succeeded in giving rise to an impressive variety of inorganic structures. Every organism that synthesizes biogenic minerals does so in a form that is unique to that species. This biomineralization is apparently biologically controlled. It is thus expected that both the synthesis and the form of every specific biogenic mineral is genetically determined and controlled. An investigation of the mechanism of biomineralization has only become possible with the development of modern methods in molecular biology. Unicellular organisms such as magnetic bacteria, calcareous algae, and diatoms, all of which are amongst the simplest forms of life, are particularly suited to be investigated by these methods. Crystals and composites of proteins and amorphous inorganic polymers are formed as complex structures within these organisms; these structures are not known in conventional inorganic chemistry. 相似文献
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Model studies of colloidal silica precipitation using biosilica extracts from<Emphasis Type="Italic"> Equisetum telmateia</Emphasis> 总被引:1,自引:0,他引:1
Structural materials containing silicon are produced in single celled organisms through to higher plants and animals. Hydrated amorphous silica is a colloidal mineral of infinite functionality that is formed into structures with microscopic and macroscopic form. Proteins and proteoglycans are suggested to play a critical role in the catalysis of silica polycondensation and in structure direction during the formation of these magnificent structures. This article extends knowledge on the effect of protein containing biosilica extracts from Equisetum telmateia on the kinetics of silica formation and structure regulation. Utilising potassium silicon catecholate as the source of soluble silicon, bioextracts obtained from plant silica by dissolution of the siliceous phase with aqueous HF following extensive acid digestion of the plant cell wall were found to modify the kinetic rate constants for the formation of small silicic acid oligomers under circumneutral pH conditions and to modify the solubility of silicic acid in solution. Addition of the bioextracts at ca. 1 wt% to the reaction medium reduced the sizes and range of sizes of the fundamental silica particles formed and led to the formation of crystalline polymorphs of silica under conditions of ca. neutral pH, room temperature and in the absence of multiply charged cations, conditions assumed to be relevant to the biological mineralization environment. The ability of biological organisms to regulate the formation of silica structures with prevention of crystallinity is discussed as are the implications of this study in terms of the generation of new materials with specific form and function for industrial application. 相似文献
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Gottfried Krampitz Gabriele Graser 《Angewandte Chemie (International ed. in English)》1988,27(9):1145-1156
Biological calcification processes (calcification, biomineralization) occur in microorganisms, in plants, and in the animal kingdom. Under physiological conditions, the results of mineral deposition in biological systems can be seen in the formation of bones, teeth, mollusc shells, egg shells, pearls, and corals. There are, however, also pathological aspects of biomineralization, including the formation of kidney stones (renal calculus), gallstones (biliary calculus), intravasal depositions (atherosclerosis, calcinosis), gallstones (biliary calculus), intravasal depositions (atherosclerosis, calcinosis). Abnormal mineralization processes (demineralization) can be found, e.g., in bone resorption (osteoporosis) and caries. A detailed knowledge of the molecular mechanisms of biomineralization could help considerably toward solving some of the problems encountered in orthopedics, urology, cardiovascular science, dentistry and veterinary medicine. Research in biomineralization is always interdisciplinary. In this article the typical interaction between mineral phase and organic matrix will be demonstrated using two examples—mollusc shells and egg shells. 相似文献
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Mirosława Różycka Ismael Coronado Katarzyna Brach Joanna Olesiak-Bańska Marek Samoć Mirosław Zarębski Jerzy Dobrucki Maciej Ptak Eva Weber Dr. Iryna Polishchuk Dr. Boaz Pokroy Jarosław Stolarski Prof. Andrzej Ożyhar 《Chemistry (Weinheim an der Bergstrasse, Germany)》2019,25(55):12740-12750
The biological mediation of mineral formation (biomineralization) is realized through diverse organic macromolecules that guide this process in a spatial and temporal manner. Although the role of these molecules in biomineralization is being gradually revealed, the molecular basis of their regulatory function is still poorly understood. In this study, the incorporation and distribution of the model intrinsically disordered starmaker-like (Stm-l) protein, which is active in fish otoliths biomineralization, within calcium carbonate crystals, is revealed. Stm-l promotes crystal nucleation and anisotropic tailoring of crystal morphology. Intracrystalline incorporation of Stm-l protein unexpectedly results in shrinkage (and not expansion, as commonly described in biomineral and bioinspired crystals) of the crystal lattice volume, which is described herein, for the first time, for bioinspired mineralization. A ring pattern was observed in crystals grown for 48 h; this was composed of a protein-enriched region flanked by protein-depleted regions. It can be explained as a result of the Ostwald-like ripening process and intrinsic properties of Stm-l, and bears some analogy to the daily growth layers of the otolith. 相似文献
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钙硅生物矿化的结构特征及其矿化机制 总被引:3,自引:0,他引:3
讨论了生物体系中生物矿化作用的主要原理,阐述了钙,硅化合物被生物体作为生物矿物的原因和生物矿物的形成机制,并着重讨论了钙,硅矿化过程的差异,概括了生物矿物的类型,分析了生物矿物及生物矿化的特征。 相似文献
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This tutorial review provides an overview of bio-directed synthesis of nanomaterials, starting with the foundation of biomineralization research--how organisms are able to biomineralize materials in vivo--and progressing to studies of biomineralization in vitro. This research is of interest to biologists, chemists and materials scientists alike, especially in light of efforts to find 'greener' methods of inorganic material synthesis. Examples of applications of nanomaterials synthesized by these methods are provided to demonstrate the end goals of biomineralization research. 相似文献
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Gulcihan Gulseren Gulistan Tansik Ruslan Garifullin Ayse B. Tekinay Mustafa O. Guler 《Macromolecular bioscience》2019,19(1)
Dentin phosphoprotein (DPP) is a major component of the dentin matrix playing crucial role in hydroxyapatite deposition during bone mineralization, making it a prime candidate for the design of novel materials for bone and tooth regeneration. The bioactivity of DPP‐derived proteins is controlled by the phosphorylation and dephosphorylation of the serine residues. Here an enzyme‐responsive peptide nanofiber system inducing biomineralization is demonstrated. It closely emulates the structural and functional properties of DPP and facilitates apatite‐like mineral deposition. The DPP‐mimetic peptide molecules self‐assemble through dephosphorylation by alkaline phosphatase (ALP), an enzyme participating in tooth and bone matrix mineralization. Nanofiber network formation is also induced through addition of calcium ions. The gelation process following nanofiber formation produces a mineralized extracellular matrix like material, where scaffold properties and phosphate groups promote mineralization. It is demonstrated that the DPP‐mimetic peptide nanofiber networks can be used for apatite‐like mineral deposition for bone regeneration. 相似文献
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The structure, adsorption behavior and applications of eggshell waste materials have been reviewed. The ultrastructure of eggshell particles has been discussed to understand the pore structure as well as the surface geometry of the materials leading to its multifarious applicability. Besides, the ultrastructure studies give full information regarding the chemical constituents of egghell particles as well as eggshell membranes. The process of biomineralization in living organisms, their consequent effect of controlling the formation of inorganic–organic composites propelling their application in biomimetic designing of advanced composites with optimized novel properties leading to advances in materials design have been discussed. Utilization of eggshell waste materials for the removal of organic dyes and heavy inorganic ions has been reviewed with suitable models for understanding their adsorption quality and capacity. The applications of these materials in various fields of research have been extensively discussed. 相似文献
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Bioinspired growth of crystalline carbonate apatite on biodegradable polymer substrata 总被引:12,自引:0,他引:12
Mineralization in biological systems is a widespread, yet incompletely understood phenomenon involving complex interactions at the biomacromolecule-mineral nucleus interface. This study was aimed at understanding and controlling mineral formation in a poly(alpha-hydroxy ester) model system, to gain insight into biological mineralization processes and to develop biomaterials for orthopaedic tissue regeneration. We specifically hypothesized that providing a high surface density of anionic functional groups would enhance nucleation and growth of bonelike mineral following exposure to simulated body fluids (SBF). Polymer surface functionalization was achieved via hydrolysis of 85:15 poly(lactide-co-glycolide) (PLG) films. This treatment led to an increase in surface carboxylic acid and hydroxyl groups, resulting in a substantial increase in polymer surface energy from 42 to 49 dynes/cm2. Treated polymers exhibited a 3-fold increase in heterogeneous mineral grown and growth of a continuous mineral film on the polymer surface. The mineral grown on PLG surfaces is a carbonate apatite, the major mineral component of vertebrate bone tissue. Mineral crystal size and morphology were dependent on the solution characteristics but unaffected by the degree of surface prehydrolysis. The mechanism of heterogeneous carbonate apatite growth was examined via ion binding assays, which indicated that calcium binding is mediated independently by the presence of soluble phosphate counterions and surface functional groups. These findings indicate that poly(alpha-hydroxy ester) materials can be readily mineralized using a biomimetic process, and that the impetus for mineral nucleation in this system appears more complicated than the simple electrostatic interactions proposed in previous biomineralization theory. 相似文献
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Spectroscopic characterization of mineral crystals produced by the bacterium Azospirillum brasilense
Kamnev AA Antonyuk LP Chernyshev AV Ignatov VV De Vargas MC 《Analytical and bioanalytical chemistry》1996,355(5-6):739-741
The results of spectroscopic structural and trace elemental analyses of mineral crystals produced by the soil nitrogen-fixing bacterium Azospirillum brasilense cultivated in a synthetic medium are presented and discussed. The mineral formed is shown to have a structure close to struvite (MgNH(4)PO(4) x 6H(2)O; ASTM file No. 15-762) with some differences which may be attributed to the presence of isomorphic admixtures of other cations (struvite is known to have a variety of forms). AAS/AES and ion chromatography analyses for a number of biologically important microelements and their role in the formation of the crystal structure, as well as some questions related to biomineralization are also discussed. 相似文献
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在进化的过程中,生物体学会了利用材料来改造自身以适应环境的变化。自然界中的一些生物体可以通过生物矿化合成无机纳米材料为自己提供保护或其他特殊功能。但是自然界中还有部分生物体不具备生物矿化功能,受到自然界生物体利用纳米材料的启发,科学家们开始尝试通过人工赋予生物体纳米材料来对其进行改造。本文就基于生物-材料界面复合技术的纳米材料对生物体的改造,依次从调控机制、改造方法、功能应用等方面做了系统的阐述,重点介绍了通过仿生矿化对生物体进行纳米改造的研究进展,对仿生无机纳米材料改造生物体的领域现状做了分析和总结,并且对该领域的发展前景进行了展望。 相似文献
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Coradin T Marchal A Abdoul-Aribi N Livage J 《Colloids and surfaces. B, Biointerfaces》2005,44(4):191-196
The formation of silica nanostructures by several living organisms, such as diatoms or sponges, involves specific macromolecules that control the growth and the organization of silica nanoparticles. In order to investigate if a single molecular system could perform both particle size control and morphological template, gelatine thin films of various concentration and strength were prepared as biomimetic models and their reactivity towards sodium silicate aqueous solutions was studied. Simultaneous formation of silica particles in the nanometric and micrometric size range was observed. The former corresponds to colloids grown at the surface of the gelatine films and the latter to particles induced by gelatine chain brushes formed at the film/water interface. These results are in good agreement with well-known principles of biomineralization and suggest that multi-molecular systems, rather than single components, are responsible for biogenic silica nanostructure formation. 相似文献
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近年来,随着材料科学领域的发展,机械性能优异且具有特定功能的有机-无机复合材料成为了研究热点。而天然的生物矿化过程产生了在自然界中分布广泛、结构特征多样性、机械性能优异的天然生物矿物,比如牙齿、骨骼、珍珠、贝壳、海胆刺、海洋红虫颚等。这些天然复合增强材料中的矿化组织结构特点和矿化机理为仿生设计与合成具有特定结构、特定功能和优异机械性能的材料提供了理论依据。通过模拟天然过程的仿生矿化方法,利用有机基质调控无机矿物成核生长为固态矿物,最终能够定向组装具有特定有序结构和先进功能的有机-无机复合材料。本文主要综述了自然界中通过生物矿化过程得到的高强度、高韧性的天然复合增强材料,以及受生物矿化增强现象的启发,在化学与材料仿生矿化合成中出现的一些有机-无机复合的增强材料。 相似文献
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Chuan Gao Guang Yao Xiong Hong Lin Luo Kai Jing Ren Yuan Huang Yi Zao Wan 《Cellulose (London, England)》2010,17(2):365-373
Bone is a composite of organic phase (collagen nanofibers) and Ca–P minerals (hydroxylapatite) and an important biological
structure in the field of biomineralization, but the interaction between organic matrixes and inorganic minerals is still
too ambiguous. In order to investigate the interaction between the growing Ca–P minerals and organic nanofibers during early
biomineralization process, bacterial cellulose (BC) nanofibers were used as templates to mimic collagen nanofibers for Ca–P
minerals deposition via biomineralization for periods from as short as 4–72 h. Our findings pointed out that the resultant
Ca–P minerals formed on BC nanofibers were platelet-like calcium-deficient HAp which was analogous to those in natural bone
tissue. Strikingly, we found that the growth of Ca–P minerals had influence on the structure and properties of BC nano-templates
during biomineralization process. 相似文献