علوم باغبانی

شماره جاری

بر اساس شماره‌های نشریه

بر اساس نویسندگان

بر اساس موضوعات

نمایه نویسندگان

نمایه کلیدواژه ها

درباره نشریه

اهداف و چشم انداز

بانک ها و نمایه نامه ها

پرسش‌های متداول

فرایند پذیرش مقالات

اطلاعات آماری نشریه

اخبار و اعلانات

پیوندهای مفید

دریافت فایل های راهنما

دستورالعمل کلی ارسال مقاله

چک لیست ارسال مقاله

ارسال مقاله

راهنمای داوران

اسامی داوران

ارزیابی تاثیر روش‌های مختلف خشک‌کردن بر زمان خشک‌شدن و برخی خصوصیات فیتوشیمیایی شمعدانی عطری (Pelargonium graveolens)

نوع مقاله : مقالات پژوهشی

نویسندگان

دانشگاه لرستان

چکیده

خشک­کردن یکی از مهم‌ترین فرآیندهای پس از برداشت گیاهان دارویی است. در این پژوهش به‏منظور بررسی تأثیر روش‌های مختلف خشک‌کردن بر گیاه دارویی شمعدانی عطری، آزمایشی بر پایه طرح کاملاً تصادفی با سه تکرار و 12 تیمار اجرا شد. تیمارهای مورد آزمایش شامل خشک­کردن در ماکروویو (توان 300، 600 و 900 وات)، خشک کردن در آون (دمای 45، 55 و 65 درجه سانتی­گراد)، خشک کردن طبیعی (خشک­کردن در سایه محصور اتاق، سایه هوای آزاد، 5 ساعت آفتاب و سپس انتقال به سایه، 10 ساعت آفتاب و سپس انتقال به سایه، و آفتاب کامل) و نمونه گیاهی تازه (به­عنوان شاهد) بودند. در روش‌های مختلف خشک­کردن، کاهش وزن نمونه­ها تا رسیدن محتوای رطوبت به 12 درصد (بر پایه ماده خشک گیاهی) ادامه یافت. نتایج تجزیه واریانس نشان­دهنده تاثیر معنی­دار روش­های مختلف خشک­کردن بر زمان خشک­کردن، فنل کل، فلاونوئید کل، فعالیت آنتی‌اکسیدانی با دو روش دی‌پی‌پی‌اچ و اف‌آر‌اِی‌پی و محتوای اسانس بود. کم­ترین و بیش­ترین زمان خشک­کردن (05/4 دقیقه و 6 روز) به­ترتیب مربوط به تیمارهای خشک­کردن با توان­ 900 وات ماکروویو و خشک­کردن در سایه هوای آزاد بود. بالاترین محتوای فنل کل (78/14 میلی­گرم گالیک اسید در صد گرم ماده خشک) و فلاونوئید کل (83/12 میلی­گرم کوئرستین در صدگرم ماده خشک) به­ترتیب در تیمار سایه محصور و سایه هوای آزاد و بیشترین ظرفیت آنتی‌اکسیدانی (02/1IC50=) در نمونه تازه مشاهده گردید. هم­چنین گیاهان خشک‌شده در آون با دمای 45 درجه نیز از نظر فنل کل، فلاونوئید کل و فعالیت آنتی‌اکسیدانی غنی بودند. در حالی­که نمونه‌های خشک­شده در سه توان ماکروویو و نمونه‌های خشک‏شده در آفتاب کامل کم­ترین میزان را برای این صفات نشان دادند. بالاترین محتوای اسانس (2/0 درصد وزنی/وزنی بر پایه ماده خشک گیاهی) نیز در تیمار خشک‌‌کردن در آون با دمای 45 درجه مشاهده گردید. به‌طور کلی می‌توان گفت که خشک‌کردن در دماهای بالای آون و توان­های بالای ماکروویو باعث کاهش میزان ترکیبات فنولی و فلاونوئید، فعالیت آنتی‌اکسیدانی و درصد اسانس شمعدانی عطری گردید. در حالی‌که روش‌های خشک­کردن در سایه محصور، سایه هوای آزاد و آون با دمای 45 درجه، کم‌ترین کاهش را در این صفات نسبت به نمونه گیاه تازه نشان دادند.

کلیدواژه‌ها

عنوان مقاله [English]

Effect of Different Drying Methods on Drying Time and some Phytochemical Characteristic of Pelargonium (Pelargonium graveolens)

نویسندگان [English]

  • Hassan Mumivand
  • Abdolhossein Rezaei Nejad
  • Shirin Taghipour
  • Kobra Sepahvand
  • Behnam Moradi

Lorestan University

چکیده [English]

Introduction: Drying is one of the most important post-harvest techniques for medicinal plants. Pelargonium graveolens (known as geranium) is an important, high-value perennial, aromatic shrub that can reach a height up to 1.3 m and a lateral growth of 1 m. The essential oil of P. graveolens is extensively used in the perfumery and cosmetic industries. Medicinal plants produce antioxidant compounds, which defend cells against degenerative effects of reactive oxygen species produced during oxidative stress and metabolism. Antioxidants are molecules that scavenge free radicals and reduce/prevent their damages. Therefore, the identification of natural antioxidants as preservative agents plays a pivotal role for the food, cosmetic and pharmaceutical industry. This study was conducted to investigate the effect of different drying methods (microwave-drying, oven drying and ambient-drying) on drying time and some phytochemical properties of P. graveolens.
Material and Methods: In order to evaluate the effect of different drying methods on drying time and some phytochemical properties of Pelargonium, an experiment was conducted at the faculty of agriculture of Lorestan University (Khorramabad, Iran) in 2017. The experiment was carried out based on completely randomized design with 12 treatments and three replications. The drying treatments were microwave-drying (300, 600 and 900 watts), oven-drying (45, 55 and 65 °C), ambient-drying (shade-drying at room, shade-drying in the field, sun-drying for five hours and then transfer to the room shade, sun-drying for 10 hours and then transfer to the room shade, and sun-drying) and fresh samples (as control). In all drying methods, the drying process continued until the moisture content of samples reached to 12% based on dry matter.
Results and Discussion: The results of analysis of variance showed the significant effect of drying methods on total phenol and flavonoids contents, antioxidant activity and essential oil content of the plants. The minimum and maximum of drying time (4.05 min and 6 days, respectively) was related to microwave-drying (900 watts) and shade-drying in the field, respectively. The highest total phenol (14.78 mg GA per 100 g dry matter) and flavonoid (12.83 mg quercetin per 100 g dry matter) contents were observed in plants dried at room shade and field shade, while the highest antioxidant capacity (IC50=1.02) was related to the fresh samples. The plants dried in the oven (45 °C) also had a notable phenol and flavonoid contents with high antioxidant activity. On the contrary, the samples dried in the microwave and sunshine showed the lowest amount of phenol and flavonoid contents and antioxidant activity. The highest essential oil content was obtained from oven-drying at 45 °C (0.2 %w/w based on dry mater), followed by shade-drying in the field (0.17 %w/w based on dry mater), and oven-drying at 55 °C (0.15 %w/w based on dry mater). While, the lowest essential oil content occurred with microwave-drying at 900 W (0.04 w/w based on dry mater). In this study, the amount of essential oil in the microwave-drying plants was significantly reduced by increasing the power of the microwave. The decrease in essential oil content with increasing oven temperature was also observed.  The decrease in essential oil content with increasing oven temperature has also been reported in other species such as peppermint, dill, tarragon and sage and could be due to evaporation of the essential oil along with moisture losing during drying process. The results of Hamrouni Sellami et al. (2012) showed that drying in microwave at 800 w increased total phenol and flavonoid levels of sage (Salvia officinalis L.). Their results showed that as the microwave power increased from 600 to 800 watts, the total phenol content increased significantly. In research by Arslan et al., (2010), the lowest total phenol content was observed in the oven dried samples, whereas the highest total phenol content was obtained from the oven-microwave treatment and sun drying. The researchers explained that this increase was probably due to the release of phenolic compounds during drying and the reason for the decrease in phenolic compounds in the oven was attributed to the high temperature. Besbes et al., (2004) also reported that with increasing drying temperature, the amount of total phenolic compounds decreases, which may be due to the destructive effect of high temperatures on phenolic compounds. In general, it could be concluded that drying in high temperature of oven and high power of microwave reduces the amount of phenolic and flavonoid compounds, antioxidant activity and essential oil content of P. graveolens. While, shade-drying and oven-drying at 45 °C showed the least reduction in these traits compared to the fresh samples.
Conclusion: It can be concluded that shade-drying at room, shade-drying in the field and oven-drying at 45°C are more suitable for the P. graveolens .While drying treatments in the microwave and sunshine are not suitable for the species. In addition, the results showed that there was a significant relationship between total phenol content and antioxidant activity in both assays.

کلیدواژه‌ها [English]

  • Pelargonium graveolens
  • Drying
  • Phenolic compounds
  • Antioxidant activity
مراجع
1. Afrasian D. and Ozcan, M.M. 2008. Evaluation of drying methods with respect to drying rosemary leaves. Energy Con. Mana. J. 49: 5.1258-1264. Agriculture and Food Chemistry, 48: 1485- 1490.
2. Al- Farsi M., Alasalvar C., Morris A., Baron M. and Shahidi F. 2005. Comparison of antioxidant activity, anthocyanins, carotenoids, and phenolics of three native fresh and sun-dried date (Phoenix dactylifera L.) varieties grown in Oman. Food Chemistry, 53: 1752-9.
3. Arabhosseini A., Padhye S., Beek T.A., Boxtel A.J., Huisman W., Posthumus M.A. and Müller J. 2006. Loss of essential oil of tarragon (Artemisia dracunculus L.) due to drying. Journal of the Science of Food and Agriculture, 86 (15): 2543–2550.
4. Arslan D., Ozcan M.M., and Okyay Menges H. 2010. Evaluation of drying methods with respect to drying parameters, some nutritional and colour characteristics of peppermint (Mentha × piperita L.). Energy Conver and Manage, 51: 2769- 2775.
5. Ayyobi H., Peyvast G.A. and Olfati J.A., 2014. Effect of drying methods on essential oil yield, total phenol content and antioxidant capacity of peppermint and dill. Ratarstvo i povrtarstvo - Journal on Field and Vegetable Crops Research, 51 (1): 18–22.
6. Azizi M., Rahmati M., Ebadi T. and Hasanzadeh Khayyat M. 2009. The effects of different drying methods on weight loss rate, essential oil and chamazolene contents of chamomile (Matricaria recutita) flowers. Iranian Journal Of Medicinal and Aromatic Plants, 25(2): 182-192. (In Persian).
7. Benzie IFF. and Strain JJ .1996. The ferric reducing agent of plasma (FRAP) as a measure of “antioxidant power”: The FRAP assay. Analytical Biochemistry. 239:70-76.
8. Besbes S., Blecker C., Deroanne C., Bahloul N., Lognay G. and Drira N. E. 2004. Date seed oil: phenolic, tocopherol and sterol profiles. Journal Food Lipids, 11: 251- 5.
9. Brovelli E.A., Li Y. and Chui, K. 2003. Image analysis reflects drying conditions of Echinacea purpurea Herb. Journal of Herbs Spices and Medicinal Plants. 10: 2.19-24.
10. Capecka E., Marecczek A., and Leja M. 2005. Antioxidant activity of fresh and dry herbs of some Lamiaceae species. Food Chemistry, 93: 223- 226.
11. Choi CW., Kim SC., Hwang SS., Choi BK., Ah HJ., Lee MY., Park SH. and Kim, SK .2002. Antioxidant activity and free radical scavenging capacity between Korean medicinal plants and flavonoids by assay-guided comparison. Plant Science. 163:1161-1168.
12. Duchow S., Blaschek W., Classen B. 2015. Reproduction of medicinal plant Pleargonium sidoides via somatic embryogenesis. Planta Medica, 81(12-13): 1169-74.
13. Ebadi M. T., Rahmati M., Azizi M. and Hassanzadeh Khayyat, M. 2009. Effect of different drying methods (natural, oven and microwave) on drying time, percentage and essential oil components medicinal herbs (Satureja hortensis L.). Iranian Journal of Medicinal and Aromatic Plant, 26 (4): 477-489.
14. Gao X., Bjok L., Trajkovski V. and Uggla M. 2000. Evaluation of antioxidant activities of rosehip ethanol extracts in different test systems. Journal Agriculture and Food Chemistry, 80: 2021- 7.
15. Garcia-Salas P, Morales-Soto A, Segura-Carretero A, Fernandez-Gutierrez A .2010. Phenolic-compound extraction systems for fruit and vegetable samples. Molecules 15:8813-8826.
16. Hamrouni Sellami I., Zohra rahali F., Bettaieb Rebey I., Bourgou S., Limam F., and Marzouk B. 2012. Total phenolics, flavonoids, and antioxidant activity of sage (Salvia officinalis L.) plants as affected by different drying methods. Food Bioprocess Technology, 5: 2978–2989.
17. Harboune N., Marete E., Jacquier J.C., and O’Riordan D. 2009. Effect of drying methods on the phenolic constituents of meadow sweet (Filipendula ulmaria) and willow (Salix alba). Food Chemistry, 42(9): 1468- 73.
18. Hassanzadeh K., Hemmati Kh. and Mehdi Pour, M .2018. The effect of different drying methods (natural and oven) on the drying time and some secondary metabolites of Melissa (Melissa officinalis L.). Journal of Plant Production Research, 25(1), 143-137.
19. Karimian Z., Keramat A. 2014. Flushing Caused by menopause and herbal medicine in Iran. A systematic review, Women's Magazine, Midwifery and Infertility, 17: 1-11.
20. Lalli JYY, Van Zyl RL., Van Vuuren SF., Viljoen AM .2008. In vitro biological activities of South African Pelargonium (Geraniaceae) species. South African Journal of Botany, 74: 153-157.
21. Lewicki P.P. and Pawlak G. 2003. Effect of drying on the microstructure of plant tissue. Drying Technology. 12 (4), 657-683.
22. Martinov M., Oztekin S. and Muller J. 2007. Medicinal and aromatic crops. CRC Press, United States of America, 320 p.
23. Mir Mostafaei S., Azizi M., Bahraini M., Aryani M and Arrowhead F.2013. The effect of different drying methods on the rate weight loss, and microbial oils of Mentha (Mentha piperita L.), Plant Production Research Journal, Vol. 20, No. 4.
24. Nicoli M.C., Anese M., and Parpinel M. 1999. Influence of processing on the antioxidant properties of fruits and vegetables. Trends in Food Science and Technology, 10: 94- 100.
25. Piga A., Del Caro A., Corda G. 2003. From plums to prunes: influence of drying parameters on polyphenols and antioxidant activity. Journal Agricultural and Food Chemistry, 51: 3675- 3681.
26. Probhanjan D.G., Ramaswamy H.S. and Raghavan G.S., 1995. Microwave assisted convective air drying of thin layer carrots. Journal of Food Engineering, 25: 283-293.
27. Quettier-Deleu C, Gressier B, Vasseur J, Dine T, Brunet C, Luyckx M, Cazin M, Cazin J-C, Bailleul F, and Trotin F .2000. Phenolic compounds and antioxidant activities of buckweat hulls and flour. Journal of Ethnopharmacology, 72:35-42.
28. Rakic S, Petrovic S, Kukic J, Jadranin M, Tesevic V, Povrenovic D, et al. 2007. Influence of thermal treatment on phenolic compounds and antioxidant properties of oak acorns from Serbia. Food Chem; 104: 830-4.
29. Riva, M., Schirarldi, A. and Cesare, L., 1991. Drying of Agaricus bisporus mushrooms by microwave/hot.
30. Rozdar F, Azizi M., Ghani A. and Davari Nejad CH.M. 2014. Effect of different drying methods on drying time and some phytochemical properties of Mentha (Mentha piperita L.). Journal of Horticultural Science, 28(3): P. 407-415. (In Persian).
31. Shahdadi F., Mirzaie HA, Maghsadllo Y., Ghorbani. and Daraie garme khani A. 2011. Effect of drying process on the phenolic-compounds content and antioxidant activity of two varieties of date-palm fruit Kaluteh and Mazafati .(Phoenix ductylifera), Journal of Nutrition Sciences and food industry Iran, 6 (3): 67-74.
32. Soysal Y., Oztekin S., and Eren O. 2006. Microwave drying of parsley: modelling, kinetics, and energy aspects. Biosystems Engineer, 93(4): 403- 413.
33. Spanos GA, Wrolstad RE .1990. Influence of processing and storage on the phenolic composition of Thompson seedless grape juice. Journal of Agricultural and Food Chemistry, 38:1565-1571
34. Tomas J.M.G., Boot K.J., Allen L.H., Allo-Meagher M. and Davis J.M. 2003. Elevated temperature and carbon dioxide effects on Soybean seed composition and transcript abundance. Crop Science, 43: 1548- 1557.
35. Tulasidas T.N., Raghavan G.S.V. and Norris E.R. 1993. Microwave and convective drying of grapes. Transactions of the ASABE, 36: 1861-1865.
36. Vega-Galvez A., Scala K.D., KLemus-Mondaca R., Miranda M., Lopez J. and Perez-Won M. 2009. Effect of airdrying temperature on physico-chemical properties, antioxidant capacity, colour and total phenolic content of red pepper (Capsicum annuum L. var. Hungarian). Food Chemistry, 117(4): 647- 53.
37. Zargari A. Iranian Medicinal Plants. 6th ed. Tehran: Tehran University; 1997. p. 243-5.
ارسال نظر در مورد این مقاله
CAPTCHA Image
علوم باغبانی
دوره 33، شماره 4 - شماره پیاپی 4
اسفند 1398
صفحه 655-668
فایل ها
سابقه مقاله
  • تاریخ دریافت: 10 آبان 1397
  • تاریخ بازنگری: 03 مهر 1398
  • تاریخ پذیرش: 10 مهر 1398
  • تاریخ اولین انتشار: 01 اسفند 1398
هم رسانی
ارجاع به این مقاله
آمار