Dietary unsaponifiable fraction of extra virgin olive oil supplementation attenuates lung injury and DNA damage of rats co-exposed to aluminum and acrylamide.

Aluminum chloride (AlCl3) and acrylamide (ACR) are well known as environmental pollutants inducing oxidative stress. Our study investigated the effects of these contaminants and if the hydrophilic fraction of extra virgin olive oil was able to prevent lung oxidative stress and DNA damage. Animals were divided into four groups of six each: group 1, serving as controls, received distilled water; group 2 received in drinking water aluminum chloride (50 mg/ kg body weight) and by gavage acrylamide (20 mg/kg body weight); group 3 received both aluminum and acrylamide in the same way and the same dose as group 2 and hydrophilic fraction from olive oil (OOHF) (1 ml) by gavage; group 4 received only OOHF by gavage. Exposure of rats to both aluminum and acrylamide provoked oxidative stress in lung tissue based on biochemical parameters and histopathological alterations. In fact, we have observed an increase in malondialdehyde (MDA), H2O2, and advanced oxidation protein product (AOPP) and a decrease in reduced glutathione (GSH), non-protein thiols (NPSH), and vitamin C levels. Activities of catalase (CAT), glutathione peroxidase (GPx), and superoxide dismutase (SOD) were also decreased. Histopathological changes in lung tissue were noted like emphysema, vascular congestion, and infiltration of inflammatory cells. A random DNA degradation was observed on agarose gel in the lung of AlCl3 and acrylamide (ACR)-treated rats. Co-administration of OOHF to treated rats improved biochemical parameters to near control values and lung histoarchitecture. The smear formation of genomic DNA was reduced. The hydrophilic fraction of extra virgin olive oil might provide a basis for developing a new dietary supplementation strategy in order to prevent lung tissue damage.

Potential protective effects of extra virgin olive oil on the hepatotoxicity induced by co-exposure of adult rats to acrylamide and aluminum.

Extra virgin olive oil has been shown to be effective against oxidative stress associated diseases. In addition to the high quantities of oleic acid, it is rich in phenolic compounds. We investigated the protective efficacy of extra virgin olive oil (EVOO) against the hepatotoxicity induced by both aluminum and acrylamide. Animals were divided into four groups containing six rats each: group 1, serving as controls, received distilled water; group 2 received drinking water containing aluminum chloride (50 mg kg(-1) body weight) and acrylamide (20 mg kg(-1) body weight) by gavage; group 3 received both aluminum and acrylamide in the same ways as well as EVOO (300 µl) by gavage; group 4 received only EVOO by gavage for 3 weeks. The rats exposed to both aluminum and acrylamide exhibited oxidative stress observed by an increase in MDA, AOPP and a decrease in GSH, NPSH and vitamin C levels. The activities of CAT and GPx were decreased, while SOD activity was increased. The liver metallothioneins, such as MT1 and MT2 genes expression, were also increased. EVOO supplementation improved all the parameters mentioned above. The plasma transaminases (AST and ALT), LDH activities, glucose and albumin levels, TC, LDL-C levels, TC/HDL-C and LDL-C/HDL-C ratios were increased, while high density lipoprotein-cholesterol (HDL-C) and TG decreased. The co-administration of EVOO to acrylamide and aluminum treated rats restored their hepatic markers to near-normal values. Liver histological studies confirmed the biochemical parameters and the beneficial role of EVOO. These results suggest that extra virgin olive oil, when added to the diet, may have a beneficial role in decreasing the liver damage induced by both aluminum and acrylamide.

Evolution of sesquiterpene hydrocarbons in virgin olive oil during fruit ripening.

Despite the potential of sesquiterpene hydrocarbons in olive oil authentication, their metabolism in Olea europaea is poorly understood, and little is known about their biochemical regulation in olives as a function of ripening. To ascertain some metabolic relationships between sesquiterpene hydrocarbons and olive ripening, the content of sesquiterpene hydrocarbons was assessed in virgin olive oils from two olive varieties grown in the same geographical area and produced at different harvesting periods. During the ripening, the accumulation of sesquiterpenes in the olive itself, and thus in the oil, differed according to their molecular structure: bicyclic sesquiterpenes, showed decreasing concentrations the later the harvest, while acyclic farnesene-like compounds progressively increased through the olive ripening process. This is first evidence that the accumulation of sesquiterpene hydrocarbons in olive, and hence in olive oil, is modulated during ripening. Therefore, the degree of ripening of olives should be taken into consideration when considering the sesquiterpenic profile of virgin olive oil for their authentication.