Voltammetric studies on vitamin E in organic solvents and within lipid bilayer membranes
A series of model tocopherol compounds with differing degrees of methyl substitution around the aromatic ring were studied by variable scan rate (0.1- 500 V s-1) cyclic voltammetry experiments in CH3CN and CH2Cl2. On short voltammetric timescales α-TOH is oxidised in a chemically reversible –2e–/–H+...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2011
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| Online Access: | https://hdl.handle.net/10356/44564 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | A series of model tocopherol compounds with differing degrees of methyl substitution around the aromatic ring were studied by variable scan rate (0.1- 500 V s-1) cyclic voltammetry experiments in CH3CN and CH2Cl2. On short voltammetric timescales α-TOH is oxidised in a chemically reversible –2e–/–H+ process to form a phenoxonium cation (α-TO+). The equilibrium and rate constants associated with the chemical steps were estimated by digital simulations of the variable scan rate data over a range of temperatures (T = 253-313K).
α-Tocopherol films were deposited on the surface of gold, glassy carbon and platinum electrodes and their voltammetric behavior examined in aqueous solutions between pH 3 and 13. The voltammetric mechanism involved α-tocopherol being oxidised in a –2e–/–H+ process to form a phenoxonium cation (similar to the experiments in non-aqueous solvents), which underwent rapid reaction with water (or –OH¯ at pH > 7) and rearrangement to form α-tocopherol quinone in a chemically irreversible process.
Electrochemical experiments were also performed by incorporating α-tocopherol into lecithin multilayers deposited onto the electrode surfaces. The results were very similar to those obtained for pure α-tocopherol films. α-tocopherol was oxidised to α-tocopherol quinone within the lecithin multilayers. However, the reduction process of α-tocopherol quinone appeared to be less chemically reversible as the pH was increased above pH 7. Two methods were used to incorporate α-tocopherol within the lecithin multilayers and both methods yielded similar electrochemical results. |
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