• Title/Summary/Keyword: mussel-inspired

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Mussel-Inspired, Fast Surface Modification of Solid Substrates

  • Hong, Sang-Hyeon;Kang, Sung-Min;Lee, Hae-Shin
    • Proceedings of the Korean Vacuum Society Conference
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    • 2011.08a
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    • pp.201-201
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    • 2011
  • Recently, mussel-inspired surface modification, called polydopamine coating has been extensively implemented to many areas, due to its material versatility and ease to use. In particular, incubation of substrates in an alkaline dopamine solution resulted in self-polymerization of dopamine and modified variety of material surfaces, including noble metals, metal oxides, ceramics, and synthetic polymers. However, the polydopamine coating has a drawback to practical use; it takes more than 12 hrs to introduce sufficient polydopamine layers to solid substrates. Here, we investigated the rate-enhanced polydopamine coating by varying reaction conditions: pH, concentration, and the addition of the oxidizing agent. As a result, the optimum condition for fast polydopamine coating was found, and solid substrates were efficiently coated with polydopamine layers in just few minutes using the condition. The polydopamine-modified surface was characterized by XPS and contact angle goniometry, and the biocompatibility of the modified surface was also proved by cell attachment test.

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Recent Progress in Mussel-inspired Catechol-conjugated Chitosan Hemostats (홍합 모사 카테콜기가 도입된 키토산 지혈제 연구 동향)

  • Seongyeon Jo;Soomi Kim;Chanwoo Park;Seungwon Hong;Hong Kee Kim;Ji Hyun Ryu
    • Journal of Adhesion and Interface
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    • v.24 no.4
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    • pp.113-119
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    • 2023
  • Since it was reported that the unusual amino acid DOPA in synergy with lysine and histidine residues found in mussel adhesive proteins plays a pivotal role in mussel adhesion in underwater environments, there has been a burgeoning development of various catecholamines-based adhesives for biomedical applications. Among these, catechol-conjugated chitosan, containing catecholamine, featuring multiple catechol groups within its aminerich chitosan backbone, has found versatile utility in fields, such as tissue adhesion, wound dressing, tissue healing, hemostats, drug delivery systems, and tissue engineering scaffolds. Significantly, chitosan-catechol is a mussel-inspired material approved by both US Food and Drug Administration (FDA) and KR Ministry of Food and Drug Safety (MFDS) for its effectiveness in hemostasis. This review focuses on 1) general aspects of catechol-conjugated chitosan, highlighting catechol group integration into chitosan backbones, 2) examination of proposed mechanisms of hemostasis, and 3) exploration of diverse physical forms, including solution, hydrogels, patches, and thin films with practical applications inapplicable to hemostasis.

Beyond Mussel-inspired Polydopamice Coatings: Derivatives of Catecholamines (카테콜아민의 화학치환: 홍합 모방 코팅 물질인 도파민을 넘어서)

  • Lee, Haesung A.;LEE, Haeshin
    • Journal of Adhesion and Interface
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    • v.19 no.3
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    • pp.123-128
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    • 2018
  • As a mussel-inspired surface independent modification chemistry using catecholamine family molecule was suggested on 2007, there are tremendous efforts being done by researchers from around the world to adjust and develop diverse applications using catecholamine family. Accordingly, we will discuss about the novel method to extend catecholamine applications, which is through the functional group substitution of catecholamine molecules.

Synthesis and Characterization of Catechol-Containing Biomimetic Mucoadhesive Polymers (카테콜 함유 생체모방 점막접착형 고분자의 합성 및 특성 연구)

  • Park, Dong Jin;Lee, Sang Jin;Lee, Sang Cheon
    • Polymer(Korea)
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    • v.37 no.5
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    • pp.625-631
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    • 2013
  • Mucoadhesive property is the major function as an adhesive for medical devices, and therefore, these days many researches have conducted to develop polymers having this property. Recently, biomimetic technology has been used for developing mucoadhesive polymers. Among many technologies, mussel-inspired approaches have received noticeable attention because of its thread's strong adhesive characteristics. In this study, we synthesized mucoadhesive biomimetic polymers employing catechol structures which are abundant in mussel adhesive proteins, and their structures and molecular weights were characterized by using nuclear magnetic resonance spectroscopy and gel permeation chromatography. To evaluate in vitro mucoadhesive strength, the sheet type of the small intestinal porcine submucosa was prepared. Compared to commercial fibrin glue adhesives, catechol-containing mucoadhesive polymers showed enhanced adhesive strength. The study of adhesive strength with considering diverse factors, such as temperature, pressure, and oxidant amount indicated that mussel-inspired mucoadhesive polymer could be a promising candidate for an adhesive in various biomedical applications.

Preparation of Nitrogen-doped Carbon Nanowire Arrays by Carbonization of Mussel-inspired Polydopamine

  • Oh, Youngseok;Lee, Jea Uk;Lee, Wonoh
    • Composites Research
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    • v.29 no.4
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    • pp.132-137
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    • 2016
  • Based on mussel-inspired polydopamine (PDA), a novel technique to fabricate carbon nanowire (CNW) arrays is presented for a possible use of porous carbon electrode in electrochemical energy storage applications. PDA can give more porosity and nitrogen-doping effect to carbon electrodes, since it has high graphitic carbon yield characteristic and rich amine functionalities. Using such outstanding properties, the applicability of PDA for electrochemical energy storage devices was investigated. To achieve this, the decoration of the CNW arrays on carbon fiber surface was performed to increase the surface area for storage of electrical charge and the chemical active sites. Here, zinc oxide (ZnO) nanowire (NW) arrays were hydrothermally grown on the carbon fiber surface and then, PDA was coated on ZnO NWs. Finally, high temperature annealing was performed to carbonize PDA coating layers. For higher energy density, manganese oxide ($MnO_x$) nanoparticles (NPs), were deposited on the carbonized PDA NW arrays. The enlarged surface area induced by carbon nanowire arrays led to a 4.7-fold enhancement in areal capacitance compared to that of bare carbon fibers. The capacitance of nanowire-decorated electrodes reached up to $105.7mF/cm^2$, which is 59 times higher than that of pristine carbon fibers.