• Title/Summary/Keyword: Bio-mimetic materials

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Cellulose based Electro-Active Paper Actuator: Materials and Applications (셀룰로오스 기반 Electro-Active Paper 작동기: 재료 및 응용)

  • Jang, Sang-Dong;Yang, Sang-Yeol;Ko, Hyun-U;Kim, Dong-Gu;Mun, Sung-Chul;Kang, Jin-Ho;Jung, Hye-Jun;Kim, Jae-Hwan
    • Journal of the Korean Society for Precision Engineering
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    • v.28 no.11
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    • pp.1227-1233
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    • 2011
  • Cellulose Electro-Active Paper (EAPap) has been known as a new smart material that is attractive for a bio-mimetic actuator due to its merits in terms of lightweight, dry condition, large displacement output, low actuation voltage and low power consumption. Cellulose EAPap is made by regenerating cellulose and aligning its micro-fibrils. This paper introduces several EAPap materials, which are based on natural cellulose and its hybrid nanocomposites mixed/blended with inorganic functional materials. By chemically bonding and mixing with carbon nanotubes and inorganic nanoparticles, the cellulose EAPap can be a hybrid nanocomposite that has versatile properties and can meet material requirements for many applications. Recent research trend of the cellulose EAPap is introduced in terms of material preparations as well as application devices including actuators, temperature and humidity sensors, biosensors, chemical sensors, and so on. This paper also explains wirelessly driving technology for the cellulose EAPap, which is attractive for bio-mimetic robotics, surveillance and micro-aerial vehicles.

Large Area Deposition of Biomimetic Polydopamine-Graphene Oxide Hybrids using Langmuir-Schaefer Technique (랭뮤어-쉐퍼 기법 이용 생체모사 폴리도파민-산화그래핀 복합체 대면적 적층 기법 연구)

  • Kim, Tae-Ho;Song, Seok Hyun;Jo, Kyung-Il;Koo, Jaseung
    • Journal of Adhesion and Interface
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    • v.20 no.3
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    • pp.110-115
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    • 2019
  • Graphene oxide has been gathering interests as a way to exfoliate graphene. Since the oxidation group of graphene oxide can hydrogen bond with various functional groups, tremendous efforts have been actively conducted to apply various applications. However, graphene oxide alone cannot substantially possess the mechanical properties required for the practical application. Therefore, in this study, polydopamine, which is a bio-mimetic mussel protein-inspired material, was combined with graphene oxide to form a large-area composite membrane at the liquid-gas interface. In addition, the morphology of the polydopamine-graphene oxide composite thin film was also controlled to obtain a composite membrane having a nano-wrinkle structure. It can be expected to be used in the next generation seawater desalination membranes or carbon composites because it can form mechanically superior and sophisticated nanostructures.

A Study on Mechanical Properties of IPMC actuators (IPMC 작동기의 기계적 물성에 관한 연구)

  • Kim, Hong-Il;Kim, Dae-Kwan;Han, Jae-Hung
    • Composites Research
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    • v.20 no.3
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    • pp.50-54
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    • 2007
  • The Ionic Polymer Metal Composite (IPMC), an electro-active polymer, has many advantages including bending actuation, low weight, low power consumption, and flexibility. These advantages coincide with the requirements of a bio-related application. Thus, IPMC is promising materials for bio-mimetic actuator and sensor applications. Before applying IPMC to actual application, basic mechanical properties of IPMC should be studied in order to utilize IPMC for practical uses. Therefore, IPMCs are fabricated to investigate the mechanical characteristics. Nafion is used as a base ionic polymer. Mason samples cast with various thicknesses are used to test the thickness effects of IPMC. Subsequently, IPMC is fabricated using the chemical reduction method. The deformation, blocking force and frequency response of the IPMC actuator are important properties. In this present study, the performances of the IPMC actuators, including the deformation, blocking force and natural frequency, are then obtained according to only the input voltage and IPMC dimensions. Finally, the empirical performance model and the equivalent stiffness model of the IPMC actuator are established using experiments results.

Analysis of the solution structure of the human antibiotic peptide dermcidin and its interaction with phospholipid vesicles

  • Jung, Hyun-Ho;Yang, Sung-Tae;Sim, Ji-Yeong;Lee, Seung-Kyu;Lee, Ju-Yeon;Kim, Ha-Hyung;Shin, Song-Yub;Kim, Jae-Il
    • BMB Reports
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    • v.43 no.5
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    • pp.362-368
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    • 2010
  • Dermcidin is a human antibiotic peptide that is secreted by the sweat glands and has no homology to other known antimicrobial peptides. As an initial step toward understanding dermcidin's mode of action at bacterial membranes, we used homonuclear and heteronuclear NMR to determine the conformation of the peptide in 50% trifluoroethanol solution. We found that dermcidin adopts a flexible amphipathic $\alpha$-helical structure with a helix-hinge-helix motif, which is a common molecular fold among antimicrobial peptides. Spin-down assays of dermcidin and several related peptides revealed that the affinity with which dermcidin binds to bacterial-mimetic membranes is primarily dependent on its amphipathic $\alpha$-helical structure and its length (>30 residues); its negative net charge and acidic pI have little effect on binding. These findings suggest that the mode of action of dermcidin is similar to that of other membrane-targeting antimicrobial peptides, though the details of its antimicrobial action remain to be determined.