New insights on the mechanism of oxidation of d-galacturonic acid by hypervalent chromium

Abstract: The pollutant Cr(VI) is known to be very carcinogenic. In conditions of excess of Cr(VI), oxidation of D-galacturonic acid (Galur), the major metabolite of pectin, yields d-galactaric acid (Galar) and Cr(III). The redox reaction takes place through a multistep mechanism involving formation of intermediate Cr(II/IV) and Cr(V) species. The mechanism combines one- and two-electron pathways for the reduction of Cr(IV) by the organic substrate: Cr(VI)→ Cr(IV)→ Cr(II) and Cr(VI)→ Cr(IV)→ Cr(III). This is supported b… Show more

“…The UV-vis absorption spectrum of the QA/Cr VI reaction mixture in an acidic medium (HClO 4 ) showed the characteristic behavior of Cr VI in an acidic medium [25][26][27] with a shoulder at 420/450 nm and a band at 350 nm (Fig. 2).…”

“…As was previously described in the main text, 18,26,27,37 aqueous CrO 2+ species can be generated in situ by rapid oxidation of Cr 2+ using oxygen. To generate the required Cr 2+ , it is necessary to employ a highly reducing medium.…”

“…11,[13][14][15][16][17] The formation of Cr V and Cr II/IV intermediates during the oxidation of a variety of organic compounds by Cr VI has been observed, [18][19][20][21][22] and their involvement in Cr-induced cancers 1,23 has aroused much curiosity in the chemistry and biochemistry of chromium. 24 In fact, the detection by continuous-wave electron paramagnetic resonance (CW-EPR) or electron spin resonance (ESR) of a long-lived Cr V species [25][26][27][28] is focused on the probable role(s) performed by Cr V species in carcinogenesis brought about by Cr VI . A similar situation has arisen with Cr IV .…”

Quinic acid and hypervalent chromium: a spectroscopic and kinetic study

“…The UV-vis absorption spectrum of the QA/Cr VI reaction mixture in an acidic medium (HClO 4 ) showed the characteristic behavior of Cr VI in an acidic medium [25][26][27] with a shoulder at 420/450 nm and a band at 350 nm (Fig. 2).…”

“…As was previously described in the main text, 18,26,27,37 aqueous CrO 2+ species can be generated in situ by rapid oxidation of Cr 2+ using oxygen. To generate the required Cr 2+ , it is necessary to employ a highly reducing medium.…”

“…11,[13][14][15][16][17] The formation of Cr V and Cr II/IV intermediates during the oxidation of a variety of organic compounds by Cr VI has been observed, [18][19][20][21][22] and their involvement in Cr-induced cancers 1,23 has aroused much curiosity in the chemistry and biochemistry of chromium. 24 In fact, the detection by continuous-wave electron paramagnetic resonance (CW-EPR) or electron spin resonance (ESR) of a long-lived Cr V species [25][26][27][28] is focused on the probable role(s) performed by Cr V species in carcinogenesis brought about by Cr VI . A similar situation has arisen with Cr IV .…”

Quinic acid and hypervalent chromium: a spectroscopic and kinetic study

“…The nature of the five-coordinated oxo-Cr(V)-bischelate complexes formed in Cr(VI)/gl mixtures at pH 1-5 was investigated using continuous-wave and pulsed ESR (EPR) and DFT. 39 The Cr(VI) oxidation of m-toluidine in aqueous nitric acid is inhibited by substrate at low [H + ] and believed to be proceeded by two routes to give the coloured product; consecutive reactions have been discussed. 40 For chromic anhydride oxidation of pyridines and their deuterium isotopomers in H 2 SO 4 , oxidation of both the Me group and pyridine nucleus is believed to involve fast nucleophilic attack of the oxidant, followed by a slow separation of hydride ion in the transition state resulting in two-electron reduction of Cr(VI) to Cr(IV).…”

“…The mechanism (Scheme 5) of the oxidative C−H transformation of allyl arenes to alkenyl aldehydes by 2,3-dichloro-5,6-dicyano-1,4-benzoquinone (37) and catalysed by FeCl 2 in C 2 H 4 Cl 2 had the initial reaction in which (37) oxidized allyl benzene (38), or [(Z)-prop-1-enyl]benzene (39), assisted by FeCl 2 , through a singleelectron transfer to the corresponding allyl radical (40) and Fe(III) complex (41). Next, (41) oxidized (40) to the allyl cation (42) and was reduced to Fe(I) complex (43).…”

Oxidation and Reduction

High‐Valent Cr, Mn, and Fe Species