Dual fluorophore-nitroxide probes for analysis of vitamin C in biological liquids.

A new method for quantitative analysis of vitamin C in biological and chemical liquids was proposed. The method is based on the use of dual molecule consisting of a fluorescent chromophore and a nitroxide radical. In the dual molecule, the nitroxide acts as a quencher of the fluorescence of the chromophore fragment. Reduction of the nitroxide fragment by ascorbic acid results in decay of ESR signal and enhancement of the fluorescence. By performing the series of pseudo-first-order reactions between the dual molecule and ascorbic acid and consequent plotting rate constants versus ascorbic acid concentrations the calibration curves for the vitamin C analysis were obtained. Variations of chemical structure of fluorophore and nitroxide fragments allow to regulate fluorescent properties and redox potentials of the dual molecules. The proposed fluorophore-nitroxide hybrids retain all features of the spin labels and fluorescence probes gaining new advantages for monitoring redox reactions and radical processes by two independent techniques: ESR and steady-state fluorescent spectroscopy. The method was applied to the vitamin C analysis in commercial fruit juices.

Gadolinium(III) di- and tetrachelates designed for in vivo noncovalent complexation with plasma proteins: a novel molecular design for blood pool MRI contrast enhancing agents.

A new series of gadolinium chelates designed as blood pool contrast enhancing agents for magnetic resonance imaging applications is described. Complexes having four Gd(III) chelate units display a significant increase in molecular relaxivity per gadolinium ion in water (9-13 L x mmol(-1) x (s-1) compared to Gd(III)-DTPA (5 L x mmol(-1) x s(-1). A further jump in relaxivity (25 L x mmol(-1) x sec(-1) in 4% BSA solution was observed in the case of a fatty acid-containing tetrachelate and is attributed to noncovalent binding of the tetrachelate to serum albumin. This agent was successfully used for imaging the rat circulatory system.

Does the antiarrhythmic effect of DMPO originate from its oxygen radical trapping property or the structure of the molecule itself?

Using the isolated perfused rat heart with transient (30 min) normothermic global ischemia, it was shown that DMPO (5,5-dimethyl-pyrroline-N-oxide), an organic spin trap agent designed specifically to trap free radicals, dramatically reduced the vulnerability of the myocardium to reperfusion-induced ventricular fibrillation (VF) and ventricular tachycardia (VT). DMPO (concentration range 30-500 mumol/l) infused in the heart at the moment and during the first 10 min of reperfusion exerted a dose-dependent antiarrhythmic effect. Thus, the doses of 30, 100, and 500 mumol/l of DMPO reduced the incidence of reperfusion-induced VF and VT from their control values of 100% and 100% to 83% and 91%, 50% (p < 0.05) and 67%, 25% (p < 0.01) and 50% (p < 0.05), respectively. Furthermore, the recovery of myocardial function was improved during postischemic reperfusion. A modification in the molecular structure of DMPO leading to HMIO (1,2,2,4,5,5-hexamethyl-3-imidazoline-oxide), so-called inactive DMPO which does not trap free radicals in the presence of a radical generating system or in the effluent of reperfused hearts, failed to reduce the incidence of reperfusion-induced arrhythmias or improve the recovery of postischemic reperfused myocardium. These findings suggest that the free radical trapping properties of DMPO or the effects of the formed DMPO-OH, a stable nitroxyl radical adduct, are responsible for the reduction of reperfusion-induced arrhythmias, and not the molecular structure of DMPO itself. Finally, it is of interest to note that the detection of free radicals was observed in fibrillating hearts, but not in nonfibrillating hearts. This consideration should be taken into account when making therapeutic interventions and risk assessments of a radical scavenger in this setting.

[Macromolecular spin pH-probes on the basis of human serum albumin]. / Makromolekuliarnye spinovye pH-zondy na osnove syvorotochnogo al'bumina cheloveka.

Human serum albumin has been chemically modified by two different spin pH-sensitive labels of the imidazoline series containing in their structure alkylating and carboxyl groups, respectively. The ESR spectra of spin-labeled proteins are sensitive to pH of the medium. The pK values of spin-labeled proteins measured by the ESR method are: pKI = 3.2 +/- 0.1; pKII = 4.75 +/- 0.1. The resulting macromolecular spin pH probes may be used for measuring the local values of pH by the ESR technique within the pH range of 1.8-6.2.

Quantitative determination of SH groups in low- and high-molecular-weight compounds by an electron spin resonance method.

To quantitatively determine SH groups in high- and low-molecular-weight compounds, a disulfide biradical (RS-SR), where R is imidazoline residue, has been used. The biradical is shown to participate in a thiol-disulfide exchange reaction with compounds containing SH groups. In this case the ESR spectra of the biradical RS-SR and the resulting monoradical R-SH are different. The reaction of the biradical with cysteine, glutathione, and human serum albumin has been studied using the ESR method and the rate constants kf of this reaction have been calculated. Studies of the pH dependence of kf indicate that the thiol-disulfide exchange occurs by reaction with mercaptidione. Protein human serum albumin and hemoglobin have been modified by RS-SR. It has been shown that the treatment of modified proteins with reduced glutathione leads to removal of the radical from the protein; such modifications are thus reversible. The method proposed has been used to quantitatively determine the SH groups of cysteine and glutathione in mouse and rat blood. The method is shown to coincide within experimental error with the determination of glutathione and cysteine by titration with p-chloromercuribenzoate or reaction with Ellman's reagent. This method allows detection of 10(-6)-10(-7) M SH compounds even in colored and highly absorbing samples. The kinetics of the SH group modification can also be determined, leading to deduction about accessibility of the SH group in protein.