Performance of the marine algae biostimulant Macrocystis sp. on soybean growth and production components
DOI:
https://doi.org/10.18378/rvads.v21i1.12069Keywords:
Glycine max, Soybean cultivars, Soybean branching, Plant growth regulator, SustainabilityAbstract
The soybean crop is an activity of significant socioeconomical importance for Brazil; however, the intensification of agricultural practices to increase productivity can lead to the excessive use of concentrated fertilizers and synthetic agrochemicals, which cause negative environmental impacts. The use of alternative inputs, such as biostimulants extracted from seaweeds, has contributed to the integration of sustainable practices, particularly regarding nutritional factors and the regulation of biotic and abiotic stresses. The objective was to analyze the effect of the Macrocystis sp. seaweed biostimulant on growth and production components in three soybean cultivars. The study was conducted on three commercial soybean fields located in the Maranhão state, Brazil. The experimental design was a randomized block design with 2 treatments and 9 replications. The treatments were applied via foliar spray at the V5 growth stage. The first treatment consisted in a no-treated (without seaweed application), while the second involved the application of biostimulant. The following parameters were analyzed: plant height; number of trifoliates, branches, nodes, and pods; chlorophyll a, b, and total indices; vegetative index (NDVI); and soybean yield. The seaweed biostimulant application of the Macrocystis sp., at the V5 stage and 750 mL ha⁻¹ dosage, increased the number of branches (33–40%), nodes (9–36%), pods (9–23%), and soybean yield (10%) in the DM 82i78 IPRO and FTR 3191 IPRO cultivars. The treatment was ineffective for BMX Domínio IPRO cultivar, causing a plant size reduction, but it not improved branching, number of pods, and yield. The results demonstrate that the use of seaweed biostimulant in soybean has complex responses. The genotype is a determinant factor in bioestimulant efficiency and soybean yield.
Downloads
References
ABD GHANI, R.; OMAR, S.; JOLÁNKAI, M.; TARNAWA, Á.; KHALID, N.; KASSAI, M. K.; KENDE, Z. Response of shoot and root growth, yield, and chemical composition to nutrient concentrations in soybean varieties grown under soilless and controlled environment conditions. Agriculture, 13(10):1925, 2023. 10.3390/agriculture13101925
ARSLANOĞLU, Ş. The effects on the root and plant development of soybean of organic fertilizer applications. Bioscience Journal, 38:1-12, 2022. 10.14393/BJ-v38n0a2022-60382
BAGALE, S. Nutrient management for soybean crops. International Journal of Agronomy, 2021(1):3304634, 2021. 10.1155/2021/3304634
BUENO, A. F.; BRAZ-ZINLI, E. C.; HORIKOSHI, R. J.; BERNARD, O.; ANDRADE, G.; SUTIL, W. P. Over 10 years of Bt soybean in Brazil: lessons, benefits, and challenges for its use in integrated pest management (IPM). Neotropical Entomology, 54(2):245-261, 2025. 10.1007/s13744-025-01275-5
BUZZELLO, G. L.; TREZZI, M. M.; BITTENCOURT, H. von H.; PATEL, F.; MIOTTO JUNIOR, E. Desenvolvimento e rendimento de soja em função da aplicação de ácido indol-butírico, ácido giberélico e cinetina. Agrarian, 10(37):225-233, 2017. 10.30612/agrarian.v10i37.3584
DOHLMAN, E.; HANSEN, J.; CHAMBERS, W.; INTERAGENCY AGRICULTURAL PROJECTIONS COMMITTEE. USDA Agricultural Projections to 2034. 2025.
EL BOUKHARI, M. E. M.; BARAKATE, M.; BOUHIA, Y.; LYAMLOULI, K. Trends in seaweed extract based biostimulants: Manufacturing process and beneficial effect on soil-plant systems. Plants, 9:359, 2020. 10.3390/plants9030359
ENGEL, D. C. H.; FELTRIM, D.; RODRIGUES, M.; BAPTISTELLA, J. L. C.; MAZZAFERA, P. Algae extract increases seed yield of soybean plants and alters nitrogen metabolism. Agriculture, 13:1296, 2023. 10.3390/agriculture13071296
HAMZA, M.; BASIT, A. W.; SHEHZADI, I.; TUFAIL, U.; HASSAN, A.; HUSSAIN, T.; SIDDIQUE, M. U.; HAYAT, H. M. Global impact of soybean production: a review. Asian Journal of Biochemistry, Genetics and Molecular Biology, 16(2):12-20, 2024. 10.9734/ajbgmb/2024/v16i2357
IPARRAGUIRRE, J.; LLANES, A.; MASCIARELLI, O.; ZOCOLO, G. J.; VILLASSUSO, A. L.; LUNA, V. Formulation technology: Macrocystis pyrifera extract is a suitable support/medium for Azospirillum brasilense. Algal Research, 69:102916, 2023. 10.1016/j.algal.2022.102916
JULIA, I.; OSCAR, M.; ANALÍA, L.; ZOCOLO, G. J.; VIRGINIA, L. Biofertilization with Macrocystis pyrifera algae extracts combined with PGPR-enhanced growth in Lactuca sativa seedlings. Journal of Applied Phycology, 32:4361-4371, 2020. 10.1007/s10811-020-02202-4
KAISER, J. F.; GONÇALVES, G. S.; D'EPIRO, R. M.; ALMEIDA, L. H. C.; NUNES, A. L. P.; MENONCIN, A. S.; TAVARES FILHO, J. Application timing of Ascophyllum nodosum extract enhances soybean growth and yield under field conditions. Agronomy Science and Biotechnology, 11:1-10, 2025. 10.33158/ASB.r233.v11.2025
KUMARI, S.; SEHRAWAT, K. D.; PHOGAT, D.; SEHRAWAT, A. R.; CHAUDHARY, R.; SUSHKOVA, S. N.; VOLOSHINA, M. S.; RAJPUT, V. D.; SHMARAEVA, A. N.; MARC, R. A.; SHENDE, S. S. Ascophyllum nodosum (L.) Le Jolis, a pivotal biostimulant toward sustainable agriculture: a comprehensive review. Agriculture, 13:1179, 2023. 10.3390/agriculture13061179
KUREPA, J.; SHULL, T. E.; SMALLE, J. A. Antagonistic activity of auxin and cytokinin in shoot and root organs. Plant Direct, 3(2):e00121, 2019. 10.1002/pld3.121
NOLI, Z. A.; SUWIRMEN; AISYAH; ALIYYANTI, P. Effect of liquid seaweed extracts as biostimulant on vegetative growth of soybean. IOP Conference Series: Earth and Environmental Science, 759:012029, 2021. 10.1088/1755-1315/759/1/012029
NUNES, B. H. di N.; LEITE, O. da C.; OLIVEIRA, L. B. de; BARROS, D. I.; NUNES, H. V.; VERAS, P. B.; VALE, K. C. L.; SILVA, J. D. da; ANDRÉ, T. B.; FREITAS, G. A. de; SILVA, R. R. da. Growth of soybeans under the influence of biostimulant doses. Caderno Pedagógico, 22(7):e16542, 2025. 10.54033/cadpedv22n7-247
POUDEL, S.; VENNA, R. R.; SHRESTHA, A.; WIEWELADANE, K. R. N. K.; REDDY, K. N.; BHEEMANAHALLI, R. Resilience of soybean cultivars to drought stress during flowering and early-seed setting stages. Scientific Reports, 13:1277, 2023. 10.1038/s41598-023-28354-0
RACHIDI, F.; BENHIMNA, R.; KASMI, Y.; SBABOU, L.; EL ARROUSSI, H. Evaluation of microalgae polysaccharides as biostimulants of tomato plant defense using metabolomics and biochemical approaches. Scientific Reports, 11:930, 2021. 10.1038/s41598-020-78820-2
REPKE, R. A.; SILVA, D. M. R.; SANTOS, J. C. C.; SILVA, M. A. Increased soybean tolerance to high-temperature through biostimulant based on Ascophyllum nodosum (L.) seaweed extract. Journal of Applied Phycology, 34:3205-3218, 2022. 10.1007/s10811-022-02821-z
SANTOS, H. G.; JACOMINE, P. K. T.; ANJOS, L. H. C.; OLIVEIRA, V. A.; LUMBRERAS, J. F.; COELHO, M. R.; ALMEIDA, J. A.; ARAUJO FILHO, J. C.; OLIVEIRA, J. B.; CUNHA, T. J. F. Sistema Brasileiro de Classificação de Solos. 5ed. Rio de Janeiro: Embrapa Solos, 2018.
SHARMA, S.; KAUR, P.; GAIKWAD, K. Role of cytokinins in seed development in pulses and oilseed crops: Current status and future perspective. Frontiers in Genetics, 13:940660, 2022. 10.3389/fgene.2022.940660
SHI, H.; GUO, J.; AN, J.; TANG, Z.; WANG, X.; LI, W.; ZHAO, X.; JIN, L.; XIANG, Y.; LI, Z.; et al. Estimation of chlorophyll content in soybean crop at different growth stages based on optimal spectral index. Agronomy, 13:663, 2023. 10.3390/agronomy13030663
SIBLE, C. N.; SEEBAUER, J. R.; BELOW, F. E. Plant biostimulants: A categorical review, their implications for row crop production, and relation to soil health indicators. Agronomy, 11(7):1297, 2021. 10.3390/agronomy11071297
SILVA, L. M.; FAGAN, E. B. Influência da associação fertilizantes e bioestimulantes na fisiologia da cultura de soja. Perquirere, 2:59-65, 2021.
SILVA, L. R. D.; ALMEIDA, E. I. B.; FREITAS, F. M.; ARAÚJO, M. B. S.; SOUSA, A. M.; VIEIRA NETO, G. F.; STROBEL, G. S.; SOUSA, W. S. Glyphosate-resistant weeds control with double-shooting in soybean pre-planting. Ensaios e Ciência: Ciências Biológicas, Agrárias e da Saúde, 29:655-669, 2025. 10.17921/1415-6938.2025v29n3p655-669
TAVARES, C. J.; RIBEIRO JUNIOR, W. Q.; RAMOS, M. L. G.; PEREIRA, L. F.; CASARI, R. A. D. C. N.; PEREIRA, A. F.; DE SOUSA, C. A. F.; DA SILVA, A. R.; NETO, S. P. D. S.; MERTZ-HENNING, L. M. Water stress alters morphophysiological, grain quality and vegetation indices of soybean cultivars. Plants, 11:559, 2022. 10.3390/plants11040559
VASCONCELOS, M. L. O.; FAGAN, E. B. Comportamento fisiológico de plantas de soja oriundas de sementes de alto e baixo vigor submetidas a bioestimulantes. Perquirere, 19:36-50, 2022.
WU, Z.; CHEN, X.; LU, X.; ZHU, Y.; HAN, X.; YAN, J.; YIN, L.; ZOU, W. Impact of combined organic amendments and chemical fertilizers on soil microbial limitations, soil quality, and soybean yield. Plant and Soil, 507:317-334, 2025. 10.1007/s11104-024-06733-4
Published
How to Cite
Issue
Section
License
Copyright (c) 2026 Francisco Neto dos Santos et al.

This work is licensed under a Creative Commons Attribution 4.0 International License.
Funding data
-
Fundação de Amparo à Pesquisa e ao Desenvolvimento Científico e Tecnológico do Maranhão
Grant numbers 1110/19

