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Biostimulating extracts from Arctium lappa L. as ecological additives in soybean seed coating applications

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Warianty tytułu
PL
Biostymulujące ekstrakty z Arctium lappa L. jako ekologiczne dodatki do powlekania nasion soi
Języki publikacji
EN
Abstrakty
EN
This paper proposes a new biostimulant coating for soybean seeds. The aim of the study was to create a coating for Glycine max (L.) Merr. soybean seeds, using root infusion from Arctium lappa L. as a biostimulant component. The effectiveness of the produced coating was evaluated in a three-year field study. The analysis of the effectiveness of the developed coating was based on the evaluation of plant biometric traits and yield. The study showed that the designed and manufactured soybean seed coating based on the root infusion of Arctium lappa L. can be considered as a new agronomic strategy to improve the productivity of soybean Glicyne max (L.) Merr. under actual field conditions. The application of the biostimulant coating resulted in soybean plants with significantly increased biometric traits (plant height, height of the first pod set, number of pods per plant, number of seeds per pod) and productivity (yield improvement of more than 10%). Only a reduced weight of 1,000 seeds compared to control samples was noted.
PL
W pracy zaproponowano nową powłokę biostymulującą dla nasion soi. Celem badań było stworzenie powłoki dla nasion soi Glycinemax (L.) Merr. z wykorzystaniem naparu z korzenia Arctium lappa L. jako komponentu biostymulującego. Skuteczność wytworzonej powłoki oceniono w trzyletnich badaniach polowych. Analizę efektywności opracowanej powłoki oparto na ocenie cech biometrycznych roślin oraz plonu. Badania wykazały, że zaprojektowana i wyprodukowana powłoka do nasion soi na bazie naparu z korzenia Arctium lappa L. może być traktowana jako nowa strategia agronomiczna poprawiająca produktywność soi Glicyne max (L.) Merr. w rzeczywistych warunkach polowych. W wyniku zastosowania powłoki biostymulującej uzyskano rośliny soi o istotnie zwiększonych cechach biometrycznych (wysokość roślin, wysokość osadzenia pierwszego strąka, liczba strąków na roślinie, liczba nasion w strąku) i produktywności (poprawa plonu o ponad 10%). Odnotowano jedynie obniżoną masę 1000 nasion w stosunku do prób kontrolnych.
Słowa kluczowe
Rocznik
Strony
1--10
Opis fizyczny
Bibliogr. 29 poz., wykr.
Twórcy
  • Department of Agrobiotechnology, Faculty of Mechanical Engineering, Koszalin University of Technology, Koszalin, 75-620, Poland
  • Department of Plant Production, Faculty of Agriculture and Technology, University of South Bohemia in České Budějovice, České Budějovice, 370 05, Czech Republic
Bibliografia
  • Avelar, S.A.G., Sousa, F.V.D., Fiss, G., Baudet, L., & Peske, S.T. (2012). The use of film coating on the performance of treated corn seed. Revista Brasileira de Sementes, 34, 186-192.
  • Salanenka, Y.A., & Taylor, A.G. (2006). Seed coat permeability and uptake of applied systemic compounds. In IV International Symposium on Seed, Transplant and Stand Establishment of Horticultural Crops; Translating Seed and Seedling, 782 (pp. 151-154).
  • Salanenka, Y.A., & Taylor, A.G. (2011). Seedcoat permeability: uptake and post-germination transport of applied model tracer compounds. HortScience, 46(4), 622-626.
  • Pedrini, S., Merritt, D.J., Stevens, J., & Dixon, K. (2017). Seed coating: science or marketing spin? Trends in plant science, 22(2), 106-116.
  • Williams, M.I., Dumroese, R.K., Page-Dumroese, D.S., & Hardegree, S.P. (2016). Can biochar be used as a seed coating to improve native plant germination and growth in arid conditions? Journal of Arid Environments, 125, 8-15.
  • Farias, B.V., Pirzada, T., Mathew, R., Sit, T.L., Opperman, C., & Khan, S.A. (2019). Electrospun polymer nanofibers as seed coatings for crop protection. ACS Sustainable Chemistry & Engineering, 7(24), 19848-19856.
  • Afzal, I., Javed, T., Amirkhani, M., & Taylor, A.G. (2020). Modern seed technology: Seed coating delivery systems for enhancing seed and crop performance. Agriculture, 10(11), 526.
  • Maria, M.F.F., Ikhmal, W.M.K.W.M., Amirah, M.N.N.S., Manja, S.M., Syaizwadi, S.M., Chan, K.S. & Adnan, A. (2019). Green approach in anti-corrosion coating by using Andrographis paniculata leaves extract as additives of stainless steel 316L in seawater. International Journal of Corrosion and Scale Inhibition, 8(3), 644-658.
  • Hajar, H.M., Zulkifli, F., Suriani, M.J., Sabri, M.M., & Nik, W.W. (2016). Lawsonialnermis extract enhances performance of corrosion protection of coated mild steel in seawater. InMATEC Web of Conferences (78), 01091. EDP Sciences.
  • Singh, R., Iye, S., Prasad, S., Deshmukh, N., Gupta, U., Zanje, A., Patil, S. & Joshi, S. (2017). Phytochemical analysis of Muntingiacalabura extracts possessing anti-microbial and anti-fouling activities. International Journal of Pharmacognosy and Phytochemical Research, 9, 826-832.
  • Ong, G., Kasi, R., & Subramaniam, R. (2021). A review on plant extracts as natural additives in coating applications. Progress in Organic Coatings, 151, 106091.
  • Biegański, J. (1950). Herbal medicine-our herbs and treatment. Jamiołkowski i Evert Sp. z o.o., Łódź.
  • Rajapaksha, S.W., & Shimizu, N. (2021). Development and characterization of functional starch-based films incorporating free or microencapsulated spent black tea extract. Molecules, 26(13), 3898.
  • Szparaga, A. (2019). Wybrane właściwości fizyczne, mechaniczne, chemiczne i plon nasion fasoli zwykłej (Phaseolus vulgaris L.) w zależności od metody aplikacji biostymulatorów. Polskie Towarzystwo Inżynierii Rolniczej, Kraków.
  • Szparaga, A., Kocira, S., Kapusta, I., 2021. Identification of a biostimulating potential of an organic biomaterial based on the botanical extract from Arctium lappa L. roots. Materials, 14(17), 4920.
  • Rolland, F., Baena-Gonzalez, E., & Sheen, J. (2006). Sugar sensing and signaling in plants: conserved and novel mechanisms. Annual Review of Plant Biology, 57, 675-709.
  • Salwa, A.I.E., Taha, M.B., & Abdalla, M.A.M. (2011). Amendment of soil fertility and augmentation of the quantity and quality of soybean crop by using phosphorus and micronutrients. International Journal of Academic Research and Development, 3(2), 10-127.
  • Zeidan, M.S., Mohamed, M.F., & Hamouda, H.A. (2010). Effect of foliar fertilization of Fe, Mn and Zn on wheat yield and quality in low sandy soils fertility. World Journal of Agricultural Sciences, 6(6), 696-699.
  • Tanase, C., Bujor, O.C., & Popa, V.I. (2019). Phenolic natural compounds and their influence on physiological processes in plants. In Polyphenols in plants (pp. 45-58). Academic Press.
  • Reigosa, M.J., Pedrol, N., & González, L. (Eds.). (2006). Allelopathy: a physiological process with ecological implications. Springer Science & Business Media, Dordrecht, The Netherlands.
  • Amirkhani, M., Mayton, H.S., Netravali, A.N., & Taylor, A.G. (2019). A seed coating delivery system for bio-based biostimulants to enhance plant growth. Sustainability, 11(19), 5304.
  • Amirkhani, M., Netravali, A.N., Huang, W., & Taylor, A.G. (2016). Investigation of soy protein–based biostimulant seed coating for broccoli seedling and plant growth enhancement. HortScience, 51(9), 1121-1126. ISBN 978-0-12-813768-0.
  • Qiu, Y., Amirkhani, M., Mayton, H., Chen, Z., & Taylor, A. G. (2020). Biostimulant seed coating treatments to improve cover crop germination and seedling growth. Agronomy, 10(2), 154.
  • Afzal, I., Javed, T., Amirkhani, M., & Taylor, A.G. (2020). Modern seed technology: Seed coating delivery systems for enhancing seed and crop performance. Agriculture, 10(11), 526.
  • Lima, S.F., Jesus, A.A., Vendruscolo, E.P., Oliveira, T.R., Andrade, M.G.O., & Simon, C.A. (2020). Development and production of sweet corn applied with biostimulant as seed treatment. Horticultura Brasileira, 38, 94-100.
  • Hayat, S., Ahmad, H., Ali, M., Hayat, K., Khan, M.A., & Cheng, Z. (2018). Aqueous garlic extract as a plant biostimulant enhances physiology, improves crop quality and metabolite abundance, and primes the defense responses of receiver plants. Applied Sciences, 8(9), 1505.
  • Savvides, A., Ali, S., Tester, M., & Fotopoulos, V. (2016). Chemical priming of plants against multiple abiotic stresses: mission possible?. Trends in plant science, 21(4), 329-340.
  • Gupta, S., Doležal, K., Kulkarni, M.G., Balázs, E., & Van Staden, J. (2022). Role of non-microbial biostimulants in regulation of seed germination and seedling establishment. Plant Growth Regulation, 1-43.
  • Barone, V., Baglieri, A., Stevanato, P., Broccanello, C., Bertoldo, G., Bertaggia, M., Fornasier, F. & Concheri, G. (2018). Root morphological and molecular responses induced by microalgae extracts in sugar beet (Beta vulgaris L.). Journal of Applied Phycology, 30(2), 1061-1071.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-0b66040f-1d46-4e23-b064-0bb31bbd3d6b
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