Chemical Composition and Antimicrobial Properties of Essential Oils Obtained from the Resin of Picea orientalis L.

References

• Bozkurt, S. and Akkemik, Ü. (2018). Flora of Gürün district (Sivas) and its immediate surroundings. Eurasian J. Forest Sci. 6(3): 35-68.
   Google Scholar
• Fidan, M.S., Öz, A., Adanur, H. and Turan, B. (2013). Amounts of use of some important non-wood forest products growing in the region of Gumushane. Gumushane Uni. J. Sci. Tech. Ins. 3(2): 40-48.
   Google Scholar
• Karatas, S.M., Öz, M., Fidan, M.S., Baltaci, C., and Ücüncü, O. (2022). Determination of chemical content and biological activities obtaining essential oil from Ribes petraeum Wulfen plant grown in Gumushane region. Gumushane Uni. J. Sci. Tech. Ins. 12(2): 498-511.
   Google Scholar
• Öz, M., Deniz, İ., Okan, O.T. and Fidan, M.S. (2015). Chemical composition of oleoresin and larvae gallery resin of Pinus brutia attacked by Dioryctria sylvestrella Ratz. Drvna. Ind. 66(3): 179-188.
   Google Scholar
• Merev, N. (2003). Wood anatomy and wood introduction, First Edition, KTU Press, Publication no: 209, Trabzon, Turkey.
   Google Scholar
• Eminagaoglu, Ö. (2018). Picea A. Dietr. (Ed. Ü. Akkemik) Natural-exotic trees and shrubs of Turkey. Publications of the General Directorate of Forestry, Ankara, Turkey.
   Google Scholar
• Hafızoglu, H., Usta, M. and Bilgin, Ö. (1997). Wood and bark composition of Picea orientalis (L.) Link. Holzforschung. 51(2): 114-118.
   Google Scholar
• Ay, N. and Sahin, H. (1998). An investigation on internal morphological proporties of sapwood and heartwood of oriental spruce (Picea orientalis L. Link.). Turk. J. Agric. For. 22(2): 203-208.
   Google Scholar
• Balaban, M. and Ucar, G. (2003). Estimation of volatile acids in wood and bark. Holz. Roh. Werkst. 61: 465-468.
   Google Scholar
• Özgenc, Ö., Durmaz, S., Celik, G., Korkmaz, B. and Yaylı, N. (2017). Comparative phytochemical analysis of volatile organic compounds by SPME-GC-FID/MS from six coniferous and nine deciduous tree bark species grown in Turkey. S. Afr. J. Bot. 113: 23-28.
   Google Scholar
• Özcelik, H. and Orhan Erdogan, İ. (2019). Picea orientalis L. Peterm. (Oriental Spruce). J. Turk. Pharm. 4(3): 61-69.
   Google Scholar
• Akbulut, S. and Özkan, Z.C. (2014). Traditional usage of some wild plants in Trabzon region (Turkey). Kastamonu Uni. J. For. Fac. 14(1): 135-145.
   Google Scholar
• Sarac, D.U., Özkan, Z.C. and Akbulut, S. (2013). Ethnobotanic features of Rize/ Turkey province. Biol. Divers. Conserv. 6(3): 57-66.
   Google Scholar
• Karaköse, M. and Colak Karaköse, G. (2017). Medicinal and aromatic plants of Esenli (Giresun) forest planning unit. Int. J. Second. Metab. 4(3): 285-305.
   Google Scholar
• Karaköse, M. and Akbulut, S. (2021). Traditional knowledge of medicinal plants in Yusufeli (Artvin) region (Chapter 4). First Edition, Gece Publishing, Research and Reviews in Agriculture, Forestry and Aquaculture Sciences-I, Ankara, Turkey.
   Google Scholar
• Kültür, S., Altınbasak, O., Anıl, S. and Melikoglu, G. (2018). Medicinal plants used in stomach ulcer in Turkey. Marmara Pharm. J. 22(1): 1-14.
   Google Scholar
• Kılıc, A. (2008). Methods of essential oil production. J. Bartın Fac. For. 10(13): 37-45.
   Google Scholar
• Mohammadhosseini, M. and Nekoei, M. (2014). Chemical Compositions of the essential oils and volatile compounds from the aerial parts of Ferula ovina using hydrodistillation, MAHD, SFME and HS-SPME methods. Journal of J. Essent. Oil-Bear. Plants. 17(5): 747-757
   Web of Science ®Google Scholar
• Nekoei, M. and Mohammadhosseini, M. (2016). Chemical compositions of the essential oils from the aerial parts of Achillea wilhelmsii using traditional hydrodistillation, microwave assisted hydro-distillation and solvent-free microwave extraction methods: Comparison with the volatile compounds obtained by headspace solid-phase microextraction. J. Essent. Oil-Bear. Plants. 19(1): 59-75.
   Web of Science ®Google Scholar
• Mohammadhosseini, M., Akbarzadeh, A. and Flamini, G. (2017). Profiling of compositions of essential oils and volatiles of Salvia limbata using traditional and advanced techniques and evaluation for biological activities of their extracts. Chem. Biodivers. 14(5): e1600361.
   Web of Science ®Google Scholar
• Cansu, T.B., Yucel, M., Sinek, K., Baltaci, C., Karaoglu, S.A. and Yayli, N. (2011). Microwave assisted essential oil analysis and antimicrobial activity of M. alpestris subsp alpestris. Asian J. Chem. 23(3): 1029-1031.
   Google Scholar
• Mohammadhosseini, M. (2017). Essential oils extracted using microwave-assisted hydrodistillation from aerial parts of eleven Artemisia species: Chemical compositions and diversities in different geographical regions of Iran. Rec. Nat. Prod. 11(2): 114.
   Google Scholar
• Mohammadhosseini, M. (2017). The ethnobotanical, phytochemical and pharmacological properties and medicinal applications of essential oils and extracts of different Ziziphora species. Ind. Crops. Prod. 105: 164-192.
   Web of Science ®Google Scholar
• Fidan, M.S., Öz, M., Ücüncü, O. Baltaci, C., and Karatas, S.M. (2022). Composition of antimicrobial and antioxidant activities and chemical components of essential oil from flowers and leaves of Pyrus elaeagnifolia Pallas in Turkey. Fresenius Environ. Bull. 31(4): 4106-4117.
   Google Scholar
• Ertas, M., Fidan, M.S., Kaya, S. and Angın, N. (2019). The effect of microwave and hydrodestillation methods on the chemical composition of essential oil obtained from juniper cones. Artvin Coruh Uni. J. For. Fac. 20(2): 272-277.
   Google Scholar
• Öz, M., Fidan, M.S., Baltaci, C., Ücüncü, O. and Karatas, S.M. (2021). Determination of antimicrobial and antioxidant activities and chemical components of volatile oils of Atropa belladonna L. growing in Turkey. J. Essent. Oil-Bear. Plants. 24(5): 1072-1086.
   Google Scholar
• Tümen, I., Hafizoglu, H., Kilic, A., Dönmez, I.E., Sivrikaya, H. and Reunanen, M. (2010). Yields and constituents of essential oil from cones of Pinaceae spp. natively grown in Turkey. Molecules. 15(8): 5797–5806.
   PubMed Web of Science ®Google Scholar
• Kücük, M., Gülec, C., Yasar, A., Ücüncü, O., Yayli, N., Coskuncebi, K., Terzioglu, S. and Yayli, N. (2006). Chemical composition and antimicrobial activities of the essential oils of Teucrium chamaedrys subsp. chamaedrys, T. orientale var. puberulens, and T. chamaedrys subsp. lydium. Pharm. Biol. 44(8): 592-599.
   Web of Science ®Google Scholar
• Djordjevic, N., Mancic, S., Karabegovic, I., Cvetkovic, D., Stanojevic, J., Savic, D. and Danilovic, B. (2021). Influence of the isolation method to the composition and antimicrobial and antioxidative activity of winter savory (Satureja montana L.) essential oil. J. Essent. Oil-Bear. Plants. 24(3): 386-399.
   Web of Science ®Google Scholar
• Adams, R.P. (2007). Identification of essential oil components by gas chromatography/mass spectrometry. 4th ed. Allured publishing Corporation, Carol stream, IL, USA.
   Google Scholar
• Adrien, K.M., Henri Guillaume, S.K., Souleymane, M., Lucien, B.G. and David, J.N. (2018). In vitro antibacterial and antidiarraheic activity of root bark extract of Anogeissus leiocarpa (Combretaceae) during an experimental bacterial diarrhea induced by Escherichia coli extended-spectrum β-lactamases (ESBL) in albino Wistar rats. J. Med. Plants Res. 12(27): 463–743
   Google Scholar
• Radulescu, V., Saviuc, C., Chifiriuc, C., Oprea, E., Ilies, D. C., Marutescu, L. and Lazar, V. (2011). Chemical composition and antimicrobial activity of essential oil from shoots spruce (Picea abies L.). Rev. Chim-Bucharest. 62(1): 69-72.
   Google Scholar
• Wajs-Bonikowska, A., Szoka, Ł., Karna, E., Wiktorowska-Owczarek, A. and Sienkiewicz, M. (2017). Composition and biological activity of Picea pungens and Picea orientalis seed and cone essential oils. Chem. Biodivers. 14(3): 1-12 e1600264.
   Google Scholar
• Lee, Na-Hyun., Lee, Sang-Min., Lee, Tae-Min., Chung, Namhyun and Lee, Hoi-Seon. (2015). GC-MS Analyses of the essential oils obtained from Pinaceae leaves in Korea. J. Essent. Oil-Bear. Plants. 18(3): 538-542.
   Web of Science ®Google Scholar
• Garneau, F.X., Collin, G., Gagnon, H. and Pichette, A. (2012). Chemical composition of the hydrosol and the essential oil of three different species of the Pinaceae Family: Picea glauca (Moench) Voss., Picea mariana (Mill.) B.S.P., and Abies balsamea L. Mill. J. Essent. Oil-Bear. Plants. 15(2). 227-236.
   Web of Science ®Google Scholar
• Yasar, S., Beram, A. and Guler, G. (2018). Effect of extraction technique on composition of volatile constituents of oleoresin from Pinus brutia Ten. Drvna. Ind. 69(3): 239-245.
   Google Scholar
• Gölükcü, M., Toker, R., Tokgöz, H. and Yıldız Turgut, D. (2015). Bitter orange (Citrus aurantium L.) peel essential oil compositions obtained with different methods. Derim. 32(2): 161-170.
   Google Scholar
• Gülsoy, S. and Merdin, A. (2017). Essential oil yield and components of juniper (Juniperus excelsa Bieb.) leaves. Bilgesci. 1(2): 119-128.
   Google Scholar
• Kılıc-Pekgözlü, A. and Ceylan, E. (2021). Effect of heat treatment on the turpentine composition. J. Bartın Fac. For. 23(3): 878–884.
   Google Scholar
• Baser, K.H.C. and Buchbauer, G. (2015). Handbook of essential oils: Science, technology, and applications. Second edition, CRC Press, New York, USA.
   Google Scholar
• Öz, M., Deniz, İ., Okan, O.T., Baltaci, C. and Karatas, S.M. (2021). Determination of the chemical composition, antioxidant and antimicrobial activities of different parts of Rosa canina L. and Rosa pimpinellifolia L. essential oils, J. Essent. Oil-Bear. Plants. 24(3): 519-537.
   Google Scholar
• Eryılmaz, M., Tosun, A. and Tümen, İ. (2016). Antimicrobial activity of some species from Pinaceae and Cupressaceae. Turk. J. Pharm. Sci. 13(1): 35-40.
   Google Scholar
• Kırbag, S. and Bagcı, E. (2000). An investigation on the antimicrobial activity of the Picea abies L. Karst. and Picea orientalis L. Link. essential oils. J. Qafqaz Uni. 3(1): 183-190.
   Google Scholar
• Koca, Y. (2019). GC-MS analysis and antimicrobial activities of essential oils obtained from Picea orientalis L. Peterm. and Picea abies L. H. Karst. Master Thesis, Kastamonu University Institute of Science Department of Forest Engineering, Kastamonu, p.39.
   Google Scholar