• Title/Summary/Keyword: Chitosan membrane

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A Glutamate Oxidase-based Biosensor for the Determination of Glutamate (Glutamate Oxidase를 이용한 Glutamate 측정용 Biosensor의 개발)

  • Lee, Young-Chun;Lee, Sang-Hyun
    • Korean Journal of Food Science and Technology
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    • v.29 no.6
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    • pp.1075-1081
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    • 1997
  • The objective of this research was to develop a glutamate enzyme sensor for rapid determinations of glutamate in samples. Glutamate oxidase was immobilized onto activated nylon, chitosan and other membranes. The enzymic and nonactin membranes were attached to an ammonia electrode to detect ammonia generated by the reaction between glutamate oxidase and glutamate. The enzyme immobilized on activated nylon membrane was stable for 2 months, and was able to perform about 250 glutamate determinations without losing activities. The enzyme immobilized on chitosan membrane had higher enzyme activity, but was not as much stable as that immobilized on nylon. The glutamate biosensor was able to accurately determine $0.1{\sim}5\;mM$ of glutamate in samples.

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Preparation and Characterization of Polysaccharide-based Nanofiber Using Electrospinning Method (전기방사 방법을 이용한 천연 다당류 나노섬유 제조 및 특성 연구)

  • Kim, Se Jong;Lee, Su Jeong;Woo, Chang Hwa;Nam, Sang Yong
    • Membrane Journal
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    • v.26 no.4
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    • pp.318-327
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    • 2016
  • In this study, alginate/poly(ethylene oxide) (PEO), and chitosan/PEO solution are prepared by dissolving alginate and chitosan into specific solvent for electrospinning. Solutions are poured into 10 mL plastic syringes with a metal nozzle supplied a high voltage power. The solution of alginate and chitosan is controlled by polymer concentration, temperature, relative humidity, applied voltage, distance from nozzle and flow rate of solution. Morphologies of fabricated nanofiber are observed by scanning electron microscopy (SEM). Optimal conditions for electrospinning of alginate nanofiber membrane are 2 wt% of alginate, 2 wt% of PEO at $60^{\circ}C$, 15 cm from the nozzle, $8{\mu}m/min$ flow rate and 20~24 kV. The conditions for elctrospinning of chitosan nanofiber membrane are 2 wt% of chitosan, 2 wt% PEO at $25^{\circ}C$, 15 cm from the nozzle, $8{\mu}m/min$ flow rate and 24 kV. The fabrication conditions of complex nanofiber prepared with chitosan and alginate are 20 cm from the nozzle, $8{\mu}m/min$ flow rate and 26 kV.

Resorbability and histological reaction of bioabsorbable membranes (수종의 흡수성 차단막의 생체 분해도와 조직학적 반응)

  • Suk, Hun-Joo;Kwon, Suk-Hoon;Kim, Chang-Sung;Choi, Seong-Ho;Jeon, Dong-Won;Kim, Chong-Kwan
    • Journal of Periodontal and Implant Science
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    • v.32 no.4
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    • pp.781-800
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    • 2002
  • The major goals of periodontal therapy are the functional regeneration of periodontal supporting structures already destructed by periodontal disease. There have been many efforts to develop materials and therapeutic methods to promote periodontal wound healing. With the development of non-resorbable membrane, GTR has proved to be the representive technique of periodontal regeneration. However, due to various clinical problems of non-resorbable membrane, resorbable membrane was developed and it showed to be clinically effective. The newly developed Para-Dioxanone membrane has a characteristic of non-woven fabric structures which is different from the generally used membranes with structure of mesh form. In addition, Chitosan membrane has been developed to apply its adventage maximally in GTR. Although a number of different types of membranes had been clinically used, researches on absorption rate of membranes were inadequate and limited to subjective opinions. However, since long term period of resorption and space maintenance are required in implant or ridge augmentation, accurate verification of resorption rate is clinically important. In this study, we had implanted Resolut(R), Biomesh(R), Para-Dioxanone membrane and Chitosan membrane (Size : 4mm ${\times}$ 4mm) on dorsal side of Sprague Dawley rat, and sacrified them after 4 weeks, 8 weeks, 12 weeks respectively. Histologic observation was carried out, and the following results were obtained by calculating the objective resorption rate. 1. In case of Resolut(R), external resorption took place initially, followed by internal resorption. Surface area are 5.76${\pm}$2.37$mm^2$, 4.90${\pm}$l.06$mm^2$, 4.90${\pm}$0.98$mm^2$ at 4 weeks, 8 weeks, 12 weeks respectively, and invasion rate of connective tissue to membrane are 31.6${\pm}$4.5%, 52.8${\pm}$9.4%, 56.4${\pm}$5.1% respectively. 2. Biomesh(R) showed a pattern of folding, relatively slow resorption rate with small size of membrane. Surface area are 3.62${\pm}$0.82$mm^2$, 3.63${\pm}$0.76$mm^2$, 4.07${\pm}$1.14$mm^2$ at 4 weeks, 8 weeks, 12 weeks respectively, and invasion rate of connective tissue to membrane are 26.1${\pm}$5.8%, 30.9${\pm}$3.4%, 29.2${\pm}$3.6%, respectively. 3. Para-Dioxanone membrane was surrounded by fibrous conncetive tissue externally, and resorption took place internally and externally. Surface area are 5.96${\pm}$1.05$mm^2$, 4.77${\pm}$10.76$mm^2$, 3.86${\pm}$0.84$mm^2$ at 4 weeks, 8 weeks, 12 weeks respectively, and invasion rate of connective tissue to membrane are 30.7${\pm}$5.1%, 53.3${\pm}$4.4%, 69.5${\pm}$3.1%, respectively. 4. Each fiber of Chitosan membrane was surrounded by connective tissue and showed external resorption pattern. It showed little invasion of inflammatory cells and excellent biocompatability. The resorption rate was relatively slow. Surface area are 6.01${\pm}$2.01$mm^2$, 5.49${\pm}$1.3$mm^2$, 5.06${\pm}$1.38$mm^2$ at 4 weeks, 8 weeks, 12 weeks respectively, and invasion rate of connective tissue to membrane are 31.3${\pm}$3.6%, 38.4${\pm}$3.80%, 39.7${\pm}$5.6%, respectively. Consequently, Para-Dioxanone membrane and Chitosan membrane are found to be clinically effective for their excellent tissue reaction and biocompatibility. Futhermore, the advantage of bone regenerating ability as well as the relatively long resorption period of Chitosan membrane, it might be widely used in implant or ridge augmentation.

Studies on Utilization of Chitosan for Fixation of Copper Compound in Wood Preservative Treatment (목재방부리(木材防腐理)에 있어서 구리화합물(化合物) 정착제(定着濟)로서 키토산 이용(利用)에 관한 연구(硏究))

  • Lee, Jong-Shin
    • Journal of the Korean Wood Science and Technology
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    • v.25 no.4
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    • pp.92-98
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    • 1997
  • To make good use of chitosan forming complex with heavy metals in wood preservative treatment, woods impregnated with chitosan and copper sulfate were prepared. Amounts of leached copper, decay resistance, anti-mold efficacy, iron corrosion rates, moisture regain rates and degradation pattern in chitosan pre-treated and untreated wood were compared. After leaching test, amounts of leached copper from chitosan pre-treated wood had a much smaller than chitosan untreated wood, and good decay resistance was retained even after leaching test. From these results, it was proved that chitosan-copper complex formed in wood played and important role for decay durability. In chitosan pre-treated wood, damage values by test molds became remarkably smaller, but the growth of test molds was not perfectly inhibited. Distinct differences in iron corrosion rates between chitosan pre-treated and untreated woods was not recognized but chitosan pre-treated wood showed the lower moisture regain rates than chitosan untreated wood because of water insoluble chitosan membrane formed in wood. After leaching test, the tracheid walls in the wood treated with 2.0% copper sulfate only were eroded by the fungal attacks, but those in the wood pre-treated with chitosan remained almost intact.

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Clinical study on therpeutic effects of Guided tissue regeneration by $Nanogide-C^{(R)}$ and $Biomesh^{(R)}$ in furcation defects (($Nanogide-C^{(R)}$$Biomesh^{(R)}$를 이용한 이개부 결손부에 대한 조직유도재생술의 임상효과)

  • Han, Kyung-Hee;Jung, Jong-Won;Hyun, Ha-Na;Kim, Ji-Man;Kim, Yun-Sang;Pi, Sung-Hee;Shin, Hyung-Shik
    • Journal of Periodontal and Implant Science
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    • v.35 no.4
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    • pp.877-889
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    • 2005
  • This study was designed to compare the effects of treatment using chitosan membrane $(Nanogide-C^{(R)})$ resorbable barrier with control treated by polylactic acid/polylacticglycolic acid membrane(PLA/PLGA membrane, $Biomesh^{(R)}$). 44 furcation defecs from 44 patients with class 2 furcation degree were used for this study, 22 sites of them were treated by chitosan membrane as experimental group and 22 site were treated by PLA/PLGA membrane as control group. Clinical parameters including probing depth, gingival recession, attachment level and radiographic examination were evlauated at base line, 1 month, 2 month and 3 month. after surgery. Statistical test used to analyze these data included paired t-test, one way ANOVA. The results are as follows : 1. Probing depth was significanlly decreased in the two group and there were significant differences between groups(p<0.05). 2. Gingival recession was not significanlly increased in the two group and there were no significant differences between groups(p<0.05). 3. Loss of attachment was statistically decreased in the two group and there were no significant differences between groups(p<0.05). 4. Horizontal bone level was significanlly increased in the two group and there were significant differences between groups(p<0.05). On the basis of these results, chitoans resorbable membrane has similar potential to PLA/PLGA membrane in GTR for furcation defect.

Biomechanical Properties and Cytotoxicity of Chitosan Patch Scaffold for Artificial Eardrum (인조고막용 키토산 패치 지지체의 생체역학적 특성 및 독성 평가)

  • Chung, Jong-Hoon;Kim, Jang-Ho;Choung, Yun-Hoon;Im, Ae-Lee;Lim, Ki-Taek;Hong, Ji-Hyang;Choung, Pill-Hoon
    • Journal of Biosystems Engineering
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    • v.32 no.1 s.120
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    • pp.57-62
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    • 2007
  • The objectives of this study were to prepare a new artificial eardrum patch using water-insoluble chitosan for healing the tympanic membrane perforations and to investigate biomechanical properties and cyotoxicity of the chitosan patch scaffold (CPS). Tensile strength and elongation at the rupture point of CPSs were 2.49-74.05 MPa and 0.11-107.06%, respectively. As the biomechanical properties or CPSs varied with the concentration of chitosan and glycerol, the proper conditions for the CPS were found out. SEM analysis showed very smooth and uniform surface of CPSs without pores at x1000. The result of MTT test showed that CPSs had no cytotoxicity.

Preparation and Characterization of Crosslinked Sodium Alginate Membranes for the Dehydration of Organic Solvents

  • Goo, Hyung Seo;Kim, In Ho;Rhim, Ji Won;Golemme, Giovanni;Muzzalupo, Rita;Drioli, Enrico;Nam, SangYong
    • Korean Membrane Journal
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    • v.6 no.1
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    • pp.55-60
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    • 2004
  • In recent years, an increasing interest in membrane technology has been observed in chemical and environmental industry. Membrane technology has advantages of low cost, energy saving and environmental clean technology comparing to conventional separation processes. Pervaporation is one of new advanced membrane technology applied for separation of azeotropic mixtures, aqueous organic mixtures, organic solvent and petrochemical mixtures. Sodium alginate composite membranes were prepared for the enhancement of long-term stability of pervaporation performance of water-ethanol mixture using pervaporation. Sodium alginate membranes were crosslinked with CaCl$_2$ and coated with polyelectrolyte chitosan to protect washing out of calcium ions from the polymer. The surface structures of PAN and hydrolysed PAN membrane were confirmed by ATR Fourier transform infrared (FT-IR). A field emission scanning electron microscopy (FE-SEM; Jeol 6340F) operated at 15 kV. Concentration profiles for Ca in the membrane surface and membrane cross-section were taken by an energy dispersive X-ray (EDX) analyser (Jeol) attached to the field emission scanning electron microscopy (Jeol 6340F). Pervaporation experiments were done with several operation run times to investigate long-term stability of the membranes.