Negative and Positive Ion Mode LC/MS/MS for Simple, Sensitive Analysis of Sorbic Acid

Sorbic acid (SA: CH3–CH=CH–CH=CH–COOH) is one of the widely used food preservatives, although there have been some reports of its toxic activity, for example, on DNA and skin cells. In order to examine the effects of SA on mammalian tissues, we have developed a highly sensitive analytical method usi...

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Bibliographic Details
Published in:Chemical & pharmaceutical bulletin Vol. 58; no. 1; pp. 106 - 109
Main Authors: Horiyama, Shizuyo, Honda, Chie, Suwa, Kiyoko, Okada, Yasuyo, Semma, Masanori, Ichikawa, Atsushi, Takayama, Mitsuo
Format: Journal Article
Language:English
Published: Japan The Pharmaceutical Society of Japan 01-01-2010
Japan Science and Technology Agency
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Summary:Sorbic acid (SA: CH3–CH=CH–CH=CH–COOH) is one of the widely used food preservatives, although there have been some reports of its toxic activity, for example, on DNA and skin cells. In order to examine the effects of SA on mammalian tissues, we have developed a highly sensitive analytical method using LC/MS/MS with positive and negative ion mode electrospray ionization (ESI). In a previous study, we found that a nonacidic eluent offers better ionization efficiency than acids or their ammoniun salts. However, optimal results could not be obtained because the anion form of SA is poorly retained on a conventional reversed phase column. To resolve this problem, we chose a new type of column and used high-resolution mass spectrometry and positive ion mode analysis. There have only been a few reports using these methods in the positive mode, for example derivatized SA, because acid compounds such as SA are usually used in the negative ion mode. However, a new type of low-carbon-content and polar-endcapped C18 phase column was developed for better separation of SA from the matrix. High-resolution selected reaction monitoring (SRM) gave the best signal to noise ratio in normal-resolution SRM. In the positive ion mode, the CH3OH–0.05% HCOOH/0.1% CH3COOH eluent system yielded the best ionization efficiency. We propose a highly sensitive and simple analysis using a two-ion-mode ESI SRM method. Such systems should allow quantification of the amount of SA in or around the cells, without the need for pretreatment such as solid phase extraction.
ISSN:0009-2363
1347-5223
DOI:10.1248/cpb.58.106