ABSTRACT
Novel 6-hydroxychroman-2-carbonitrile compounds have been synthesized, and their antiperoxidant activity against superoxide-dependent, iron-promoted mycocardial phospholipid peroxidation has been evaluated quantitatively. With few exceptions, these compounds afforded significant, concentration-dependent antiperoxidant protection to myocardial-membrane phospholipid at sub- to low-micromolar concentrations. Structure-activity correlation demonstrated that R1-, R2-, and R3-methyl groups in the aromatic ring enhanced antiperoxidant activity, whereas hydrophobic groups at either R4 or R5 of the pyran ring compromised antiperoxidant efficacy. The most efficacious antiperoxidant synthesized contained a catechol moiety at R4 and was some 10-fold more potent than alpha-tocopherol. None of the 6-hydroxychroman-2-carbonitrile antiperoxidants scavenged superoxide or inhibited the enzymatic superoxide generator, xanthine oxidase, at effective antiperoxidant concentrations. The ability of these compounds to interrupt the propagatory phase of an on-going peroxidation reaction indicated that they acted as antiperoxidants by trapping chain-carrying lipid peroxyl radicals. Since a number of the 6-hydroxychroman-2-carbonitriles were most potent antiperoxidants than a variety of known chain-breaking compounds, this new class of phenolic antioxidants may represent a novel approach to the design of therapeutics against diseases in which lipid peroxidation is a causative factor or in which lipid peroxidases serve as mediators.
