Abstract
The thermodynamic stability of twenty-nine Fe(III) complexes with various deprotonated forms of lipoic (LA) and dihydrolipoic (DHLA) acids, with coordination numbers 4, 5 and 6, is studied at the M06(SMD)/6-31++G(d,p) level of theory in water under physiological pH conditions at 298.15 K. Even though the complexes with LA- are more stable than those with DHLA−, the most thermodynamically stable Fe(III) complexes involve DHLA2−. The twenty-four exergonic complexes are used to evaluate the secondary antioxidant activity of DHLA and LA relative to the Fe(III)/Fe(II) reduction by and ascorbate. Rate constants for the single-electron transfer (SET) reactions are calculated. The thermodynamic stability of the Fe(III) complexes does not fully correlate with the rate constant of their SET reactions, but more exergonic complexes usually exhibit smaller SET rate constants. Some Cu(II) complexes and their reduction to Cu(I) are also studied at the same level of theory for comparison. The Fe(III) complexes appear to be more stable than their Cu(II) counterparts. Relative to the Fe(III)/Fe(II) reduction with ascorbate, DHLA can fully inhibit the formation of •OH radicals, but not by reaction with . Relative to the Cu(II)/Cu(I) reduction with ascorbate, the effects of DHLA are moderate/high, and with they are minor. LA has minor to negligible inhibition effects in all the cases considered.
Highlights
Emotional stress and environmental pollution can lead to the excessive biochemical production of free radicals beyond the human system’s ability to detoxify reactive intermediates and repair the subsequent cellular damage [1]
Iron complexes in each group have been labelled in sequence starting with the most stable one
Twenty-four exergonic Fe(III) complexes were used to study the kinetics of the single-electron transfer (SET) reaction with O−
Summary
Emotional stress and environmental pollution can lead to the excessive biochemical production of free radicals beyond the human system’s ability to detoxify reactive intermediates and repair the subsequent cellular damage [1]. 2 and ascorbate, [10,11,26,27,28] to the best of our knowledge, theoretical kinetic studies of secondary antioxidant activity relative to the Fe(III)/Fe(II) reduction, and their comparison with the Cu(II)/Cu(I) redox system, have not been previously reported for any antioxidant. This is a topic of relevance that has been studied experimentally for a variety of substrates [29,30,31,32,33]
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