Quantitative characterization of degradation behaviors of antioxidants stabilized in lipid particles

Sang Hoon Han; Jong Suk Lee; Yong Jin Kim; Junoh Kim; Ih Seop Chang; Dong June Chung; Kyung Do Suh; Jin Woong Kim

doi:10.1016/j.talanta.2006.09.006

Quantitative characterization of degradation behaviors of antioxidants stabilized in lipid particles

Sang Hoon Han
, Jong Suk Lee
, Yong Jin Kim
, Junoh Kim
, Ih Seop Chang
, Dong June Chung
, Kyung Do Suh
, Jin Woong Kim

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

This study describes a flexible approach that allows us to characterize the long-term stability of antioxidants by using a thermodynamically extended Arrhenius equation. We use retinol, Vitamin A, as a model antioxidant and its degradation behaviors are characterized for both stabilized and non-stabilized systems; in this study, by using a fluid bed technique, we immobilize the retinol in lipid particles, thus increasing its thermal stability in complex formulations, such as aqueous polymer gels and emulsions. Our approach demonstrates that the degradation behaviors of the retinol show a functional relationship with temperature and time, which makes it possible to use the Arrhenius approach. This result allows us to precisely characterize the stability of antioxidants in complex formulations for long time.

Original language	English
Pages (from-to)	2129-2133
Number of pages	5
Journal	Talanta
Volume	71
Issue number	5
DOIs	https://doi.org/10.1016/j.talanta.2006.09.006
State	Published - 30 Mar 2007
Externally published	Yes

Keywords

Antioxidant
Arrhenius equation
Degradation behaviors
Fluid bed technique
Long-term stability

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10.1016/j.talanta.2006.09.006

Cite this

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title = "Quantitative characterization of degradation behaviors of antioxidants stabilized in lipid particles",

abstract = "This study describes a flexible approach that allows us to characterize the long-term stability of antioxidants by using a thermodynamically extended Arrhenius equation. We use retinol, Vitamin A, as a model antioxidant and its degradation behaviors are characterized for both stabilized and non-stabilized systems; in this study, by using a fluid bed technique, we immobilize the retinol in lipid particles, thus increasing its thermal stability in complex formulations, such as aqueous polymer gels and emulsions. Our approach demonstrates that the degradation behaviors of the retinol show a functional relationship with temperature and time, which makes it possible to use the Arrhenius approach. This result allows us to precisely characterize the stability of antioxidants in complex formulations for long time.",

keywords = "Antioxidant, Arrhenius equation, Degradation behaviors, Fluid bed technique, Long-term stability",

author = "Han, \{Sang Hoon\} and Lee, \{Jong Suk\} and Kim, \{Yong Jin\} and Junoh Kim and Chang, \{Ih Seop\} and Chung, \{Dong June\} and Suh, \{Kyung Do\} and Kim, \{Jin Woong\}",

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doi = "10.1016/j.talanta.2006.09.006",

language = "English",

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TY - JOUR

T1 - Quantitative characterization of degradation behaviors of antioxidants stabilized in lipid particles

AU - Han, Sang Hoon

AU - Lee, Jong Suk

AU - Kim, Yong Jin

AU - Kim, Junoh

AU - Chang, Ih Seop

AU - Chung, Dong June

AU - Suh, Kyung Do

AU - Kim, Jin Woong

PY - 2007/3/30

Y1 - 2007/3/30

N2 - This study describes a flexible approach that allows us to characterize the long-term stability of antioxidants by using a thermodynamically extended Arrhenius equation. We use retinol, Vitamin A, as a model antioxidant and its degradation behaviors are characterized for both stabilized and non-stabilized systems; in this study, by using a fluid bed technique, we immobilize the retinol in lipid particles, thus increasing its thermal stability in complex formulations, such as aqueous polymer gels and emulsions. Our approach demonstrates that the degradation behaviors of the retinol show a functional relationship with temperature and time, which makes it possible to use the Arrhenius approach. This result allows us to precisely characterize the stability of antioxidants in complex formulations for long time.

AB - This study describes a flexible approach that allows us to characterize the long-term stability of antioxidants by using a thermodynamically extended Arrhenius equation. We use retinol, Vitamin A, as a model antioxidant and its degradation behaviors are characterized for both stabilized and non-stabilized systems; in this study, by using a fluid bed technique, we immobilize the retinol in lipid particles, thus increasing its thermal stability in complex formulations, such as aqueous polymer gels and emulsions. Our approach demonstrates that the degradation behaviors of the retinol show a functional relationship with temperature and time, which makes it possible to use the Arrhenius approach. This result allows us to precisely characterize the stability of antioxidants in complex formulations for long time.

KW - Antioxidant

KW - Arrhenius equation

KW - Degradation behaviors

KW - Fluid bed technique

KW - Long-term stability

UR - https://www.scopus.com/pages/publications/33847707735

U2 - 10.1016/j.talanta.2006.09.006

DO - 10.1016/j.talanta.2006.09.006

M3 - Article

AN - SCOPUS:33847707735

SN - 0039-9140

VL - 71

SP - 2129

EP - 2133

JO - Talanta

JF - Talanta

IS - 5

ER -

Quantitative characterization of degradation behaviors of antioxidants stabilized in lipid particles

Abstract

Keywords

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