Molecular orbital study on the glutathione-dependent detoxication of ozonides

To What Extent Does Ozone Therapy Need a Real Biochemical Control System? Assessment and Importance of Oxidative Stress

Ozone therapy is not officially allowed in many countries, but private medical services are using this therapy worldwide. However, appropriate control systems to assess the benefits and risks of systemic ozone therapy are not always used and in such cases the treatment is based on anecdotal reports. Oxidative stress phenomenon is becoming a highlighted biological process for ozone therapy because it is deeply involved in its mechanism of action. On the contrary, ozone therapy is an efficient regulator of the oxidative stress processes. In terms of therapeutic effects, it is convenient to know the metabolic status of the organism to face new oxidative challenges before and during ozone therapy applications. Oxidative stress is also important because it is involved as a cause or effect of many diseases. Since the 1990s, there has been the necessity of developing reliable systems for measuring oxidative stress in humans. In this sense, we have proposed a system for oxidative stress diagnosis that can serve as a control system for systemic ozone therapy applications. The system is based on the blood measurement of eight biomarkers (GSH, GPx, GST, SOD, CAT, DC, SRATB, and HPT) and the interpretation of these values by a computer-developed algorithm yielding four new indices (total antioxidant activity, total prooxidant activity, redox index and grade of oxidative stress). The system shows the patient's redox status and estimation of the oxidative stress level, with this information being relevant regarding implications on dosage and therapeutic effectiveness of ozone therapy.

Gas chromatography-mass spectrometry profile of urinary organic acids of Wistar rats orally treated with ozonized unsaturated triglycerides and ozonized sunflower oil

The main products in the ozonolysis of unsaturated triglycerides or vegetable oils are peroxides, aldehydes, Criegee ozonides and carboxylic acids. Some of these compounds are present in different concentrations in the biological fluids. The aim of this work is to study, using gas chromatography-mass spectrometry (GC-MS), the organic acid excretion in urine of rats orally treated with ozonized sunflower oil (OSO), ozonized triolein or ozonized trilinolein. Oral administration of OSO to Wistar rats has produced changes in the urinary content of dicarboxylic organic acids. Among others heptanedioic (pimelic acid) and nonanedioic acids (azelaic acid) were the major increased dicarboxylic acids found. The urinary dicarboxylic acid profiles of rats which received ozonized triolein only showed an increase in heptanedioic and nonanedioic acids. However, when ozonized trilinolein is applied, the profile is similar to that obtained when OSO is administered. A biochemical mechanism is proposed to explain the formation of dicarboxylic acids from ozonated unsaturated triglycerides.

Ozone-induced lung toxicity: mediated by ozonides?

In an in vitro study a comparison was made between the cytotoxicities of a model ozonide, methyl linoleate-9,10-ozonide (MLO), and a model peroxidative agent, cumene hydroperoxide (CumOOH), by measuring the effects of both compounds on the phagocytosing capacity of rat alveolar macrophages. Toxicity as well as detoxication characteristics of the ozonide were found to be similar to those of ozone: (1) vitamin E protected the alveolar macrophages in vitro against the ozonide, (2) glutathione (GSH) depletion enhanced the sensitivity of the cells towards the ozonide and (3) the ozonide did not enhance lipid peroxidation. This also suggests that GSH depletion, followed by lipid peroxidation, does not underlie the MLO toxicity. This was supported by the differences in protection provided by vitamin C, vitamin E and GSH. Supplementation of the macrophages with vitamin C resulted in a decrease in their sensitivity towards MLO and an increase in their sensitivity towards CumOOH. Following GSH depletion the sensitivity of the cells towards CumOOH had increased more than that towards MLO. Exposure to CumOOH led to a more extensive vitamin E depletion. The results of an in vivo study on the toxicity of MLO (in the rat) largely confirmed the findings of the in vitro study: partial contributions of vitamin E and the glutathione system to the protection against MLO.