Preparation of alginate/chitosan microcapsules and enteric coated granules of mistletoe lectin

Lyu, Su-Yun; Kwon, Young-Ju; Joo, Hyejin; Park, Won-Bong

doi:10.1007/bf02980057

Cited by 27 publications

(25 citation statements)

References 32 publications

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“…There were evident effects of alginate content on the encapsulation efficiency, phycocyanin load and shape of phycocyanin microcapsules. Both encapsulation efficiency and phycocyanin load were increased with alginate content increased ranging from 1.0% to 3.5%, different from the results reported by others (Lyu et al, 2004;Meng and Chen, 2010). Microcapsule shape could be affected by the viscosity of the alginate solution, and higher viscosity would bring difficulty in extrusion process and easily result in tailing.…”

Section: Preparation Of Phycocyanin Microcapsulescontrasting

confidence: 89%

“…Content of calcium chloride had no significant effect on the encapsulation efficiency and phycocyanin load of microcapsules, as shown in Table 1, different from the conclusion obtained by Lyu et al (2004), Vandenberg et al (2001) and Gao et al (2009). Its reason was possibly that high-molecularweight phycocyanin could not exude from the alginate gel (Yoo et al, 2006) formed even at lower content of calcium chloride.…”

Section: Preparation Of Phycocyanin Microcapsulescontrasting

confidence: 74%

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Preparation of phycocyanin microcapsules and its properties

Yan

Liu

Jiao

et al. 2014

Food and Bioproducts Processing

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a b s t r a c tPhycocyanin was microencapsulated by an extrusion method using alginate and chitosan as coating materials. This work was aimed to optimize the encapsulation process, characterize the physicochemical properties of microcapsules, and evaluate the storage stability and in vitro release performance. The optimum process conditions for preparing microcapsule gained from the single factor experiments were as follows: alginate content 2.5%, ratio of phycocyanin to alginate 1.5:1, content of calcium chloride 2.5%, and chitosan content 2.0%. Phycocyanin/alginate/chitosan microcapsules (PACM) were found to have compact spherical shape with mean diameters of 1.03 mm, whereas phycocyanin/alginate microspheres (PAM) were internal porous spherical appearances with mean diameters of 1.81 mm. Storage stability study showed that encapsulation by alginate and chitosan conferred greater ability to phycocyanin against temperature during storage. In vitro release study revealed that both PAM and PACM could be resistant against acidic environment, and would rapidly release phycocyanin under mild alkali condition. The sustained-release profile of phycocyanin from PACM was superior to that from PAM.© 2013 The Institution of Chemical Engineers. Published by Elsevier B.V. All rights reserved.Keywords: Microcapsule; Phycocyanin; Alginate; Chitosan IntroductionPhycocyanin is a blue phycobiliprotein, composed of two relatively homologous subunits: the ␣-chain with one phycocyanobilin attached at cysteine 84 and the ␤-chain with two phycocyanobilins attached at cysteines 84 and 155. The two subunits form ␣␤ monomers, which aggregate into ␣ 3 ␤ 3 trimers and further into disc-shaped ␣ 6 ␤ 6 hexamers, the functional unit of phycocyanin (Eriksen, 2008). It has good therapeutic values, such as antioxidative, immunomodulating, anti-cancer, antiviral, anti-allergic, anti-mutagenic, anti-inflammatory, hepatoprotective, blood vessel-relaxing and blood lipid-lowering activities (Thangam et al., 2013), which made it a better active ingredient in functional food. It is also used as natural dyes in food including chewing gum, ice sherbets, soft drinks, and candies, and cosmetics including lipstick and eyeliners, replacing the synthetic colourants (Chaiklahan et al., 2011). Another application of phycocyanin is as phycofluor probes for immunodiagnosis owing to its fluorescence properties. However, its application is often limited by the instability towards moisture, light and temperature due to the degradation of the protein fraction (Chaiklahan * Corresponding author. , 2012). Studies show that microencapsulation is an effective and economical method for protecting natural colourants against adverse conditions (Rocha et al., 2012). Therefore, it was inferred that the stability of phycocyanin should be improved using microencapsulation technologies. However, up to now, reports were scarce about phycocyanin microencapsulation. Microencapsulation is a technique by which the sensitive ingredients, called core materials, are entrapped in coati...

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Section: Preparation Of Phycocyanin Microcapsulescontrasting

confidence: 89%

Section: Preparation Of Phycocyanin Microcapsulescontrasting

confidence: 74%

Preparation of phycocyanin microcapsules and its properties

Yan

Liu

Jiao

et al. 2014

Food and Bioproducts Processing

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“…In our previous study, we developed a system composed of stabilizing cores (granules) which contained VCA, coated with a biodegradable polymer (Eudragit Ò ) wall. This system produced outstanding results with ideal release profiles and only minimal losses of cytotoxicity in human hepatocarcinoma cells after the manufacturing step [16]. We also studied the transport mechanism of VCA by M cells in human follicle-associated epithelium (FAE) in vitro [30], and the modulation of cytokines and immunoglobulin (Ig) A in intestinal epithelial cells (IEC) [31].…”

Section: Introductionmentioning

confidence: 97%

“…In this study, we evaluated the effects of enteric-coated mistletoe we have previously developed [16] on the growth of mouse melanoma cells in vitro and in vivo.…”

Section: Introductionmentioning

confidence: 99%

“…A galactose-and N-acetyl-Dgalactosamine-specific lectin (Viscum album L. var. coloratum agglutinin, VCA) was isolated from Korean mistletoe [8] which is composed of two different subunits; the A-chain which inactivates the 60S ribosomal subunit in eukaryotic cells resulting in the inhibition of protein synthesis, and the B-chain which binds to the cell-surface glycoconjugates and thereby permits entry into the cell of the toxic A-chain subunit [7,[14][15][16].…”

Section: Introductionmentioning

confidence: 99%

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Anti-cancer effects of enteric-coated polymers containing mistletoe lectin in murine melanoma cells in vitro and in vivo

et al. 2015

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In this study, we evaluated the effects of Korean mistletoe (Viscum album L. var. coloratum) coated with a biodegradable polymer (Eudragit(®)) wall on the growth of mouse melanoma in vivo. Oral administration of 4% (430 mg/kg/day) enteric-coated mistletoe resulted in a significant reduction in tumor volume on day 14 compared to the negative control group in B16F10 melanoma-inoculated BDF1 mice. When we measured the survival rate, enteric-coated mistletoe-received mice had a higher survival rate after day 12. Also, we investigated the mechanism involving the cancer cell growth inhibition when melanoma cells were treated with Korean mistletoe lectin (Viscum album L. var. coloratum agglutinin, VCA) and its extract in vitro. As a result, a significant G0/G1 arrest was observed in both B16BL6 and B16F10 melanoma cells with VCA or mistletoe extract. In addition, VCA or mistletoe extract induced an increase in both early and late apoptosis in cells. When we studied the molecular mechanism, our results showed that VCA and mistletoe extract can increase activated multiple caspases (caspase-1, 3, 4, 5, 6, 7, 8, and 9), dose-dependently. We also found out that VCA and mistletoe treatment causes a significant decrease in the expression of procaspase-3 and 8.

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Application of microencapsulation technology in silk fibers

Xiao

Liu

Zhao

et al. 2022

J of Applied Polymer Sci

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Silk, a natural protein fiber, is top-rated with people as skin-friendly clothing for centuries. However, silk fiber (SF) still has disadvantages such as photoinduced aging and yellowing and wrinkling. Higher value, as well as novel and unique functions, are added according to the application of microencapsulation in the functional finishing of SF. By using microencapsulation technology, finishing agents, special functional materials, and so forth, can be encapsulated in polymer film-forming materials to form microcapsule finishing agents. Since the properties of the coated materials will not change after the formation of microcapsules, the functional materials can be protected.Only during processing or use, under the external environment such as pressure, friction, and temperature, can the microcapsules be ruptured or released through the diffusion effect of the microcapsule wall to achieve good and desired effects. In this review, recent developments in microencapsulation technology in the application of SFs are highlighted. First, the basic principle and technology of microencapsulation are introduced. Subsequently, adhesion between microcapsules and SFs are described. Finally, the application and effect of microencapsulation technology in SFs are summarized. In addition, the potential challenges and future prospects of microencapsulation technology in natural SFs are discussed.

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Preparation of alginate/chitosan microcapsules and enteric coated granules of mistletoe lectin

Cited by 27 publications

References 32 publications

Preparation of phycocyanin microcapsules and its properties

Preparation of phycocyanin microcapsules and its properties

Anti-cancer effects of enteric-coated polymers containing mistletoe lectin in murine melanoma cells in vitro and in vivo

Application of microencapsulation technology in silk fibers

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