Determination of quantitative content of phenol carboxylic in raw material of Salvia Stepposa Schost

The article presents the results of the quantitative content of the sum of phenol carboxylic acids in the Salvia Stepposa Schost. feedstock. It was experimentally confirmed that the optimal extractant when ex­tracting the sum of phenol carboxylic acids from the Salvia Stepposa Schost. feedstock. is 70 % ethyl alcohol. The maximum content of the sum of phenol carboxylic acids is noted in extracts obtained from samples of raw materials ground to particle size passing through a sieve with a diameter of holes of 2 mm. The content of the total phenol carboxylic acids is: in leaves 1,43 %, in flowers 1,22 % and in grass 1,74 %. The obtained experimental data can be used in the development of regulatory documentation for a new type of medicinal vegetal raw material “Sage of steppe grass”.

1. Golovkin B. N., Rudenskaya R. N., Trofimova I. A., Schreter A. I. Biologically active substances of plant origin: in three volumes. Vol. I, II. Moscow: Nauka; 2001. 764 р. (In Russ.).

2. Shukshina S. S., Nigmatullina R. R. The content of phenol-carboxylic acids in raspberry fruits. Priority scientific directions: from theory to practice. 2016; 25 (1): 12–16. (In Russ.)

3. Merkl R., Hradkova I., Filip V., Smidrkal J. Antimicrobial and antioxidant properties of phenolic Alkyl esters. Czech Journal of Food Sciences. 2010; 28 (4): 275–279.

4. Kulikov A. A., Vdovenko V. S. Methods for determining the qualitative and quantitative composition of phenol-carboxylic acids in plant raw materials. Agrarian Bulletin of the South-East. Saratov. 2020; 2 (25): 18–21. (In Russ.).

5. Ambigaipalan P., de Camargo A. C., Shahidi F. Identification of phenolic antioxidants and bioactives of pomegranate seeds following juice extraction using HPLC-DAD-ESI-MSn. Food Chemistry. 2017; 221: P. 1883–1894.

6. Makhatova B. G., Datkhaev U. M., Burda N. E., Kislichenko V. S. Determination of phenol-carboxylic acids in Verbascum Songaricum raw materials. Vestnik KazNMU = Bulletin of KazNMU. 2015; (4): 521–523. (In Russ.).

7. Matkowski A., Woźniak D., Lamer-Zarawska E., Oszmiański J., Leszczyńska A. Flavonoids and phenol carboxylic acids in the oriental medicinal plant Astragalus membranaceus acclimated in Poland. Zeitschrift für Naturforschung. C, Journal of biosciences. 2003; 58 (7-8): 602–604. doi: 10.1515/znc-2003-7-826.

8. Sannikova E. G., Popova O. I., Kompantseva E. V., Frolova O. O. The study of phenol-carboxylic acids of the shoots of the three-staminate willow growing in the North Caucasus. Farmatsiya i farmakologiya = Pharmacy and pharmacology. 2015; 2 (9): 13–17. (In Russ.).

9. Itagaki S., Kurokawa T., Nakata C., Saito Yo. In vitro and in vivo antioxidant properties of ferulic acid: a comparative study with other natural oxidation inhibitors. Food Chemistry. 2009; 114: 466–471.

10. Gohil K. J., Kshirsagar S. B., Sahane R. S. Ferulic acid – a comprehensive pharmacology of an important bioflavonoid. International Journal of Pharmaceutical Sciences and Research. 2012; 3 (1): 700–710.

11. Zduńska K., Dana A., Kolodziejczak A., Rotsztejn H. Antioxidant Properties of Ferulic Acid and Its Possible Application. Skin Pharmacol Physiol. 2018; 31 (6): 332–336. doi: 10.1159/000491755.