Spin-spin interactions in iron(III) porphyrin radical cations with ruffled and saddled structure

Oxidation of essentially pure intermediate-spin iron(III) porphyrinates such as ruffled Fe(TⁱPrP)ClO₄ and saddled Fe(OETPP)ClO₄ produces the corresponding six-coordinate iron(III) porphyrin(por) radical cations [Fe(Por)(ClO₄)₂], where TⁱPrP and OETPP are dianions of 5,10,15,20-tetraisopropylporphyrin and 2,3,7,8,12,13,17,18-octaethyl-5,10,15,20-tetraphenylporphyrin, respectively.Spin-spin interactions in these complexes are very much different; while ruffled [Fe(TⁱPrP)(ClO₄)₂] exhibits no antiferromagnetic coupling, saddled [Fe(OETPP)(ClO₄)₂] does exhibit it. The difference in magnetic behaviors has been explained in terms of the deformation mode and electron configuration of these complexes.     

Chemiluminescence of the Fenton reaction and a dihydroxybenzene-driven Fenton reaction

A dihydroxybenzenes(DHB)-driven Fenton reaction was found to be more efficient than a simple Fenton reaction based on OH radical and activated species production. The reason for this enhanced reactivity by [Fe DHB] complexes is not well understood, but results suggest that it may be explained by the formation of oxidation species different from those formed during the classic Fenton reactions. In previous work, greater concentrations, and more sustained production of OH over time were observed in DHB driven Fenton reactions versus neat Fenton and Fenton-like reactions. In this work, chemiluminescence (CL) was monitored, and compared to OH production kinetics. The CL of the DHB-driven Fenton reaction was shorter than that for sustained production of OH. CL appears to have been caused by excited Fe(IV) species stabilized by the DHB ligands initially formed in the reaction. Formation of this species would have to have occurred by the reaction between OH and Fe(III) in a DHB complex.     

Dark production of reactive oxygen species in photosystem II membrane particles at elevated temperature: EPR spin-trapping study

In our study, EPR spin-trapping technique was employed to study dark production of two reactive oxygen species, hydroxyl radicals (OH) and singlet oxygen (¹O₂), in spinach photosystem II (PSII) membrane particles exposed to elevated temperature (47 °C). Production of OH, evaluated as EMPO-OH adduct EPR signal, was suppressed by the enzymatic removal of hydrogen peroxide and by the addition of iron chelator desferal, whereas externally added hydrogen peroxide enhanced OH production. These observations reveal that OH is presumably produced by metal-mediated reduction of hydrogen peroxide in a Fenton-type reaction. Increase in pH above physiological values significantly stimulated the formation of OH, whereas the presence of chloride and calcium ions had the opposite effect. Based on our results it is proposed that the formation of OH is linked to the thermal disassembly of water-splitting manganese complex on PSII donor side. Singlet oxygen production, followed as the formation of nitroxyl radical TEMPO, was not affected by OH scavengers. This finding indicates that the production of these two species was independent and that the production of ¹O₂ is not closely linked to PSII donor side.