Vitamin e Forms – Bioavailability and Protective Effects on Colitis and Colon Cancer

Kilia Y Liu, Purdue University

Abstract

Vitamin E is a natural lipophilic antioxidant contains eight structurally related forms, i.e., α-, β-, γ-, δ-tocopherols (αT, βT, γT, and δT) and corresponding tocotrienols. Recent research indicates that vitamin E forms are differentially metabolized to various carboxychromanols. Some these vitamin E metabolites have been shown to exhibit strong anti-inflammatory and anticancer effects, yet little is known about their bioavailability. Without this knowledge, it is impossible to assess the role of vitamin E metabolism in biological functions of vitamin E forms and their protective effects on chronic diseases. While αT and γT appear to improved gut health, the underlying mechanisms are not well understood. Furthermore, specific forms of vitamin E such as γT have been reported to have cancer-preventing effects, but their anticancer efficacy is relatively modest. For these reasons, this dissertation focused on the characterization of the pharmacokinetic formation of vitamin E metabolites after supplementation, and the investigation of the underlying mechanisms of the protective effect of vitamin E forms, αT and γT, on gut health, as well as anticancer efficacy of the combination of aspirin and γT on carcinogen-induced colon tumorigenesis. The first project focuses on characterizing the pharmacokinetic formation of vitamin E metabolites after single dose supplementation of γ-tocopherol-rich mixed tocopherol (γTmT) and δ-tocotrienol (δTE). With our recently developed LC/MS/MS assay for quantifying vitamin E metabolites, we can simultaneously quantify the level of shortchain, long-chain, and sulfated carboxychromanols in plasma, urine, and fecal samples of supplemented animals. In this study, we investigated the pharmacokinetics including excretion of vitamin E forms and the formation of their metabolites after a single dose intragastric administration of tocopherols and tocotrienols in rats. We also measured vitamin E metabolites in the serum obtained from healthy humans after T supplementation. In the plasma of rat, the pharmacokinetic profiles of γT and δTE are described as the following: γT, Cmax = 25.6  9.1 μM, Tmax = 4 h; δTE, Cmax = 16.0  2.3 μM, Tmax = 2 h. Sulfated CEHCs and sulfated 11’-COOHs were the predominant metabolites in the plasma of rat with Cmax of 0.4-0.5 μM (Tmax ~ 5-7 h) or ~0.3 μM (Tmaxat 4.7 h), respectively. In 24-h urine, 2.7% of T and 0.7% of TE were excreted as conjugated CEHCs, the major identified urinary metabolites. In the feces, 17-45% of supplemented vitamers were excreted as un-metabolized forms and 4.9-9.2% as metabolites. The majority of metabolites excreted in feces were unconjugated carboxychromanols, among which 13’- COOHs constituted ~50% of total metabolites. Interestingly, 13’-COOHs derived from TE were 2-fold higher than 13’-COOH from T. Unlike rats, -CEHC is the predominant metabolites found in human plasma, although 11’-COOHs and 13’-COOHs (sulfated and unconjugated) were elevated by >20 folds responding to T supplement. In this study, we found that tocopherols and tocotrienols, when taken as supplements, are mainly excreted as un-metabolized forms and long-chain carboxychromanols in feces. High fecal availability of 13’-COOHs may contribute to modulating effects on gut health. The second project of my dissertation investigated the effect of vitamin E forms, αT and γT, on intestinal barrier function in a cellular model and a mouse colitis model.

Degree

Ph.D.

Advisors

Burgess, Purdue University.

Subject Area

Agronomy|Medicine|Pathology|Pharmaceutical sciences

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