Detección de aceite argán adulterado con aceites vegetales: Nuevos marcadores

This work aims to contribute to controlling the authenticity of pure argan oil, a valuable Moroccan product. Fatty acids, hydrocarbon fraction, 3,5-stigmastadiene, the alkyl esters of fatty acids, chlorophyllic pigments and physical properties such as viscosity, density and refractive index were studied in order to detect the adulteration of argan oil with edible vegetable oils. The results found in this study show that 3,5-stigmastadiene, kaurene and pheophytin-a can be used as possible new markers for argan oil blends of up to 5% with refined, sunflower and virgin olive oils. Due to the similarity of the fatty acid compositions of the edible oils studied and argan oil, fatty acids can be employed as markers for the detection of argan oil adulteration at levels higher than 10%. Among the physical properties studied, the refractive index shows significant differences for sunflower oil and its blend at 10% with argan oil.El objetivo principal de este trabajo es contribuir al control de la autenticidad del aceite argán, un producto marroquí muy valorado. Con el fin de detectar la adulteración del aceite de argán con aceites vegetales comestibles, se han estudiado los siguientes parámetros: ácidos grasos, fracción de hidrocarburos, 3,5-estigmastadieno, ésteres alquílicos, pigmentos clorofílicos y propiedades físicas como la viscosidad, densidad e índice de refracción. Los resultados de este estudio muestran que el 3,5-estigmastadieno, kaureno y la feofitina-a podrían utilizarse como nuevos marcadores en la detección del aceite de argán adulterado con aceites refinados y aceite oliva virgen al 5%. La composición en ácidos grasos puede emplearse para la detección de la adulteración del aceite de argán a niveles superiores al 10%, debido a la similitud en la composición de los aceites estudiados. Entre las propiedades físicas analizadas, el índice de refracción mostró diferencias significativas entre el aceite de argán y sus mezclas con el aceite de girasol al 10%

Characterization of Glyceridic and Unsaponifiable Compounds of Sacha Inchi ( Plukenetia huayllabambana

This work deals with the characterization of the main glyceridic and unsaponifiable components of oils obtained from Sacha inchi (Plukenetia huayllabambana L.) seed ecotypes collected during two harvests in the Department of Amazonas in Peru. The seed-oil yield was 30.3-41.2%; standing out are the high percentages of the ¿3- and ¿6-fatty acids series whose ranges lie within those of the present Regulation for Sacha inchi oils. Triacylglycerols with even equivalent carbon number (ECN; 36-42) were the main components. Minor glyceridic polar compounds such as oxidized triglycerides, diglycerides, monoglycerides, and free fatty acids were determined by high-performance size exclusion chromatography. The low campesterol/stigmasterol ratio (1:6), unusual in the majority of vegetable oils, stands out. Regarding aliphatic hydrocarbons, these oils showed a particular profile for the saturated series of odd and even carbon atom numbers. According to our results Sacha inchi P. huayllabambana oils can be offered as a good alternative to P. volubilis, the species mainly commercialized for this vegetable oil

Chemical evaluation and thermal behavior of Chilean hazelnut oil (Gevuina avellana Mol) a comparative study with extra virgin olive oil

There is a growing interest in the study of oils from native fruits, especially when the oil has high quality. In this sense it is mandatory to evaluate the oxidative stability and the relationship with the modifications of the fatty acid content, physicochemical parameters, the antioxidant capacity and its protection against the thermal deterioration processes. The fatty acid profiles of Chilean hazelnut oil showed a relevant presence of the omega series (ω-9, ω-5, and ω-9) with good stability across the thermal treatment. The physico–chemical parameters such as polar compounds and absorption coefficients K232 and K270 showed a similar behavior compared with olive oil oxidation in the range of 25–360 °C. The antioxidant capacity and total phenolic content in olive oil is significatively higher than Chilean hazelnut oil at 25 °C; however, this antioxidant capacity decreases in the olive oil after 100 °C; until 247 °C the antioxidant capacities for both oils are equalized. Total phenolic content of olive oil diminishes after 100 °C until the final study temperature (360 °C), where its concentration is very similar to Chilean hazelnut oil. The results of the thermogravimetric and differential analysis in the range of 100–700 °C show that the thermal oxidative decomposition processes occurred in both samples mainly in three steps with a total mass loss for olive oil and Chilean hazelnut oil of 99.7% and 99.9%, respectively. It is important to note that hazelnut oil remains thermally stable up to 247 °C just a few degrees lower than olive oil (252 °C).Oscar Forero-Doria Thanks FONDECYT (FONDECYT Postdoctoral Fellowship No. 3170757) and Luis Guzmán thanks FONDECYT (FONDECYT Initiation No. 11150390).Peer Reviewe

Argan [Argania spinosa (L.) Skeels] oil

Argan oil is extracted from the kernels of Argania spinosa (L.) Skeels, a tree that almost exclusively grows endemically in southern Morocco. If argan oil was initia11y only known around its traditional production area, major efforts combining chemical, agronomic and human sciences have led to its international recognition and marketing. In addition, to ensure the sustainable production of a sufficient quantity of argan kernels, a vast and unprecedented program that led to the reforestation of large areas of drylands has been developed in Morocco. Therefore, argan oil production is considered as an economic and ecologic success. Edible argan oil is prepared by cold-pressing roasted argan kernels. Unroasted kernels afford an oil of cosmetic grade, showing a bitter taste. Both oils, which are not refined and are virgin oils, share a similar fatty acid content that includes oleic and linoleic acids as major components. Additiona11y, argan oil is rich in antioxidants. Together, these components likely contribute to the oil pharmacological properties that, in humans, traditionally included cardiovascular disease and skin protection. Recent scientific studies have greatly expanded the scope of these pharmacological activities. Argan oil is now rewarded with a "Geographic Indication" that certifies its exclusive and authentic Moroccan origin and the compliance with strict production rules. In addition, the quality of argan oil can nowadays be ascertained by using an array of physicochemica1 methods. By-products, generated in large quantity during argan oil production, are also finding promising development routes