Abstract
Lovage is a popular medicinal and spice plant. Its usable organs are roots, fruits and leaves. The aim of this study was to evaluate the influence of plantation establishment and different methods of lovage leaves stabilization on its functional characteristics, including the essential oil content, chemical composition and quality of odor. Higher content of essential oil was determined in leaves harvested from plantations established with seedlings in comparison to the one from late fall sowing (respectively: 0.890 ml.100 g-1, 0.755 ml.100 g-1). Freezing, oven-drying and freeze-drying resulted in a decrease of this substance content. Compounds present in the tested essential oils were monoterpenes and their oxygen-containing derivatives (an average of 80.2%). The main component in the analysed essential oils was the -terpinyl acetate (average 36.6%). Percentage of -terpinyl acetate, (Z)-ligustylid, (Z)-butylidenoftalid, (E)-butylidenoftalid and
(E)-ligustylid increased under the used stability methods. Appearance in the oils collected from stabilized raw materials trans-p-menth-2-en-1-ol, cis-β-elemene, and butylophtalide (compounds that were absent in the essential oil from fresh raw material) was also observed.
References
Andruszczak S., 2004. The effect of foundation method and harvesting time on the yield of lovage (Levisticum officinale Koch.). Annales UMCS sec. E, Agricultura, 59, 3, 1049–1056.
Asekun O.T., Grierson D.S., Afolayan A.J., 2007. Effects of drying methods on the quality and quantity of the essential oil of Mentha longifolia L. subsp. Capensis. Food Chem. 101, 995–998.
Baryłko-Pikielna N., Matuszewska I., 2009. Sensoryczne badania żywności. Podstawy – Metody – Zastosowania. Wyd. Nauk. PTTŻ, 181–203, 313–333.
Beck J.J., Chou S., 2007. The structural diversity of phthalides from the Apiaceae. J. Natur. Prod. 70, 891–900.
Bylaite E., Roozen J.P., Legger A., Venskutonis R.P., Posthumus M.A., 2000. Dynamic headspace-gas chromatography-olfactometry analysis of different anatomical parts of lovage (Levisticum officinale Koch.) at eight growing stages. J. Agric. Food Chem. 48, 6183–6190.
Ezz El-Din A.A., Hendawy S.F., 2010. Comparative efficiency of organic and chemical fertilizers on herb production and essential oil of lovage plants growing in Egypt. Amer. Eurasian J. Agric. Environ. Sci. 8, 1, 60–66.
Figiel A., Szumny A., Gutiérrez-Ortíz A., Carbonell-Barrachina A.A., 2010. Composition of oregano essential oil (Origanum vulgare) as affected by drying method. J. Food Eng. 98, 240–247.
Giannakourou M.C., Taoukis P.S., 2003. Kinetic modelling of vitamin C loss in frozen green vegetables under variable storage conditions. Food Chem. 83, 33–41.
Gijbels M.J., Scheffer J.J, Baerheim S.A., 1982. Phthalides in the essential oil from roots of Levisticum officinale. Planta Med. 44, 4, 207–211.
Hogg C.L., Svoboda K.P. Hampson, J.B., Brocklehurst S., 2001. Investigation into the composition and bioactivity of essential oil from lovage (Levisticum officinale W.D.J. Koch), Inter. J. Aromath. 11, 144–151.
Jing T., Chu C., Yan Y., Jun-Rong D., Wen Y., Cheng-Yuan W., 2009. Pharmacological activities of Z-ligustilide and metabolites in rats. J. Sichuan Univ. (Medical Science Edition) 40, 5, 839–42.
Jun-Rong D., Yan Y., Yao Y., Bo B., Xu Z., Yang L., Cheng-Yuan W., Zhong-Ming Q., 2007. Ligustilide reduces phenylephrine induced-aortic tension in vitro but has no effect on systolic pressure in spontaneously hypertensive rats. Amer. J. Chinese Medic. 35, 3, 487–496.
Justensen U., Knuthsen, P., 2001. Composition of flavonoids in fresh herb and calculation of flavonoid intake by use of herbs in traditional Danish dishes. Food Chem. 73, 245–250.
Majchrzak M., Kamiński E., 2004. Flavour compounds of lovage (Levisticum officinale Koch.) cultivated in Poland. Herba Pol. 50, 1, 8–14.
Mirjalili M.H., Salehi P., Sonbolia A., Hadian J., Ebrahimi S.N., Yousefzadi M., 2010. The composition and antibacterial activity of the essential oil of Levisticum officinale Koch. flowers and fruits at different developmental stages. J. Serbian Chem. Soc. 75, 12, 1661–1669.
Novák I., Németh E., 2002. Effect of harvesting time and plant age on some quality parameters of lovage (Levisticum officinale Koch.). Acta Hort. 576, 311–314.
Polish Pharmacopoeia, 2002. Determination of essential oil content. (6th ed.) Warsaw: Polish Pharmaceutical Society, 151.
Raal A., Arak E., Orav A., Kailas T., Müürisepp M., 2008. Composition of the essential oil of Levisticum officinale W.D.J. Koch from some European countries. J.Ess. Oil Res. 20, 4, 318–322.
Rizi V., Reza M., Abbas H., 2007. The essential oil composition of Levisticum officinalis from Iran . Asian J. Biochem. 2, 161–163.
Rosłon W., Osińska E., Gajc-Wolska J. 2009. The influence of raw material stabilization on the quality of celery (Apium graveolens L.) leaves. Acta Hort. 877, 201–208.
Sahari M.A., Boostani M.F., Hamidi, Z.E. 2004. Effect of low temperature on the ascorbic acid content and quality characteristic of strawberry. Food Chem. 86, 537–363.
Sellami I.H., Wannes W.A., Bettaieb I, Berrima S., Chahed T, Marzouk B, Limam F., 2011. Qualitative and quantitative changes in the essential oil of Laurus nobilis L. leaves as affected by different drying methods. Food Chem. 126, 691–697.
Słupski J., Lisiewska Z., Kmiecik W., 2005. Effect of usable parts of dill and of preliminary processing on the quality of frozen products depending on the time and temperature of storage. Acta Scien. Pol., Techn. Alimen. 3, 2, 65–75.
Szumny A., Figiel A., Gutiérrez-Ortíz A., Carbonell-Barrachina A.A., 2010. Composition of rosemary essential oil (Rosmarinus officinalis) as affected by drying method. J. Food Eng. 97, 253–260.
Venskutonis P.R., 1997. Effect of drying on the volatile constituents of thyme (Thymus vulgaris L.) and sage (Salvia officinalis L.). Food Chem. 59, 2, 219–227.
Wojdyło A., Oszmiański J., Czemerys R. 2007. Antioxidant activity and phenolic compounds in 32 selected herbs. Food Chem. 105, 940–949.
Yang Z., Kinoshita T., Tanida, A., Sayama H., Morita A., Watanabe N. 2009. Analysis of coumarin and its glycosidically bound precursor in Japanese green tea having sweet-herbaceous odor. Food Chem. 114, 289–294.
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