The Potency of Ludwigia adscendens and L. octovalvis as Phytoremediator Macrophytes in Indonesia
Asian Journal of Fisheries and Aquatic Research,
Page 78-86
DOI:
10.9734/ajfar/2021/v15i630352
Abstract
The potency of Ludwigia adscendens and L. octovalvis as phytoremediator macrophytes in Indonesia was reviewed. The characteristics of these species might be essential information for operators who wanted to implement phytoremediation in their sites. Information and articles about these species in Indonesia was collected through Google-Scholar during the first week of February 2021 and reviewed. Many studies about phytoremediation focused only on the capabilities of macrophytes to remove contaminants from water and paid only little attention to their compatibility with the ecosystem leading to upset the ecosystem. To Indonesia, these two species were introduced and became weeds, with different ecological characteristics. In Indonesia, scarce phytoremediation studies using these species were detected. Therefore, although these species were classified as weeds it was, remained, worthwhile to investigate further these species to be used in the phytoremediation of water.
Keywords:
- Macrophyte
- accumulator
- weed
- rooted-floating.
How to Cite
Amin, R., Mafikalita Sari, R. A., & Rahyuni, D. (2021). The Potency of Ludwigia adscendens and L. octovalvis as Phytoremediator Macrophytes in Indonesia. Asian Journal of Fisheries and Aquatic Research, 15(6), 78-86. https://doi.org/10.9734/ajfar/2021/v15i630352
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Rosyada A, Purnomo T. Kemampuan Tapak Dara Air (Ludwigia adscendens) sebagai Fitoremediator dalam Menurunkan Logam Berat Kadmium (Cd) pada Perairan yang Tercemar Lumpur Lapindo, Sidoarjo. LenteraBio: Berkala Ilmiah Biologi. 2018;7(3).
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Rachmadiarti F, Sholikah M. Effectiveness of Ludwigia adcendens and Ludwigia grandiflora as Cadmium (Cd) Phytoremediator; 2020.
Nandra LW, Purnomo T. Potensi Tapak Dara Air (Ludwigia adscendens) dalam Menurunkan Kandungan Logam Berat Timbal (Pb) pada Perairan yang Tercemar Lumpur Lapindo, Sidoarjo. LenteraBio: Berkala Ilmiah Biologi. 2019;8(1).
Titah HS, Abdullah SRS, Idris M, Anuar N, Basri H, Mukhlisin M, Kurniawan SB. Arsenic resistance and biosorption by isolated rhizobacteria from the roots of Ludwigia octovalvis. International journal of microbiology; 2018.
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Rajoo KS, Ismail A, Karam DS, Muharam FM. Phytoremediation studies on soils contaminated with heavy metals in Malaysia: A review article. American-Eurasian Journal Agricultural & Environmental Sciences. 2016;16(8): 1504-1514.
Idris M, Abdullah SRS, Titah HS, Abasa A. R, Husin AK, Hanima RF, Ayub R. Screening and identification of plants at a petroleum contaminated site in Malaysia for phytoremediation. Journal of Environmental Science and Management. 2016;19(1).
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Al-Mansoory AF, Idris M, Abdullah SRS, & Anuar N. Phytoremediation of contaminated soils containing gasoline using Ludwigia octovalvis (Jacq.) in greenhouse pots. Environmental Science and Pollution Research. 2017;24(13):11998-12008.
Alanbary S, Abdullah S, Abu Hassan H. Screening for Resistant and Tolerable Plants (Ludwigia octovalvis and Phragmites karka) in Crude Oil Sludge for Phytoremediation of Hydrocarbons. Iranian (Iranica) Journal of Energy & Environment. 2017;8(4):288-191.
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Aung LW, Chaw DKE. Study on morphology, anatomy, preliminary phytochemical test, nutritional values and antimicrobial activities of leaves of Ludwigia octovalvis (Jacq.) Raven. Dagon Univ Commemorat 25th Anniv Silver Jubilee Res J. 2019;9(2):321-327.
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Oyuela Leguizamo MA, Fernández Gómez WD, Sarmiento MCG. Native herbaceous plant species with potential use in phytoremediation of heavy metals, spotlight on wetlands — A review. Chemosphere.2017;168:1230-1247. DOI:https://doi.org/10.1016/j.chemosphere.2016.10.075
Xu L, Cheng S, Zhuang P, Xie D, Li S, Liu, D, Xing F. Assessment of the Nutrient Removal Potential of Floating Native and Exotic Aquatic Macrophytes Cultured in Swine Manure Wastewater. International Journal of Environmental Research and Public Health. 2020;17(3):1103.
Retrieved:https://www.mdpi.com/1660-4601/17/3/1103
Baroroh F, Irawanto R. Seleksi Tumbuhan Akuatik Berpotensi Dalam Fitoremediasi Air Limbah Domestik di Kebun Raya Purwodadi. Paper presented at the Prosiding Seminar Nasional Biologi. Universitas Negeri Malang, Malang; 2016.
Delgadillo-López AE, González-Ramírez CA, Prieto-García F, Villagómez-Ibarra JR, Acevedo-Sandoval O. Fitorremediación: una alternativa para eliminar la contaminación. Tropical and subtropical agroecosystems. 2011;14(2):597- 612.
Cabi. Org. Ludwigia adscendens (water primrose); 2019.
Available:https://www.cabi.org/isc/datasheet/31668, accessed 9 February 2021
Rostini T, Abdullah L, Wiryawan K, Karti P. Production and nutrition potency of swamp local forage in South Kalimantan as ruminant feed. Glob J Anim Sci Livestock Prod Anim Breed. 2014;2(2): 107-113.
Hidayati N, Rini DS. Possible solution of cleaning up heavy metals contamination in agriculture area using accumulator plants. Paper presented at the The 7 Th International Symposium For Sustainable Humanosphere [ISSH; 2017.
Rosyada A, Purnomo T. Kemampuan Tapak Dara Air (Ludwigia adscendens) sebagai Fitoremediator dalam Menurunkan Logam Berat Kadmium (Cd) pada Perairan yang Tercemar Lumpur Lapindo, Sidoarjo. LenteraBio: Berkala Ilmiah Biologi. 2018;7(3).
Xiao L. Case Study of Baiyun and Caohai Lakes Implies How to Implement Wetland Restoration/Creation. Open Access Library Journal. 2018;5(10):1.
Dutta R, Sarma SK. Growth forms, phenology, composition and uses of the aquatic macrophytes found in the downstream of the Subansiri river ecosystem, Assam. International Journal of basic and applied research. 2018;8(8): 407-420.
Babcsányi I, Meite F, Imfeld G. Biogeochemical gradients and microbial communities in Winogradsky columns established with polluted wetland sediments. FEMS Microbiology Ecology. 2017;93(8).
DOI:10.1093/femsec/fix089
Vythilingam I, Chiang G, Lee H, Singh K. Special report on bionomics of important mosquito vectors in Malaysia. Southeast Asian J. Trop. Med. Public Health. 1992;23:581-602.
Ashour A, Mostafa B, Taha H, Azzam A. Distribution of natural populations of Lymnaea snails in some Egyptian Governorates and their natural infection with Fasciola. J. Environ. Sci. 2008;16(1):19-31.
Chakraborty BK. Status of diversify medicinal plants in floodplain basin of northern Bangladesh. Journal of Crop and Weed, India. 2014;10(2):196-204.
Ahmed F, Selim M, Shilpi J. Antibacterial activity of Ludwigia adscendens. Fitoterapia. 2005;76(5):473-475.
Lwin HH. Investigation of morphological characterization, qualitative analysis and antimicrobial activities of Jussiaea repens L. Dragon University Commemoration of 25th Anniversary Silver Jubilee Research Journal. 2019;9(9):273-279.
Krishnappa K, Baranitharan M, Elumalai K, Pandiyan J. Larvicidal and repellant effects of Jussiaea repens (L.) leaf ethanol extract and its major phyto-constituent against important human vector mosquitoes (Diptera: Culicidae). Environmental Science and Pollution Research. 2020;27(18):23054-23061.
Das A, Ghosal S, Chakraborty I, Pradhan N. Haematinic potential of Jussiaea repens L–a search for antianaemic herb. Journal of Pharmaceutical Research International. 2015;1-11.
Yan F, Li F, Liu J, Ye S, Zhang Y, Jia J Mo X. The formulae and biologically active ingredients of Chinese herbal medicines for the treatment of atopic dermatitis. Biomedicine & Pharmacotherapy. 2020; 127:110142.
DOI:https://doi.org/10.1016/j.biopha.2020.110142
Khandekar T, Roy A, Pradhan N. Aqueous extract of Jussiaea repens L. ameliorates diabetes associated complications in STZ induced diabetic male rats. International Journal of Bio-Pharma Research. 2020;9(8):2683-2690.
Irawanto R. Revitalisasi Koleksi Tumbuhan Akuatik Kebun Raya Purwodadi sebagai Taman Kolam Fitoremediasi. Prosiding Temu Ilmiah IPLBI. 2016;1.
Khankhane P, Varshney JG. Accumulation of heavy metals by weeds grown along drains of Jabalpur. Indian Journal of Weed Science. 2008;40(1&2): 55-59.
Shah AB, Rai U, Singh RP. Correlations between some hazardous inorganic pollutants in the Gomti River and their accumulation in selected macrophytes under aquatic ecosystem. Bulletin of environmental contamination and toxicology. 2015;94(6):783-790.
Larson RA, Sims GK. Atrazine Removal Using Aquatic Plants: A Kinetic Approach. Retrieved from; 2003.
Pindihama GK, Gitari MW. Uptake and growth effects of cyanotoxins on aquatic plants Ludwigia adscendens and Amaranthus hybridus in raw surface waters. International Journal of Environmental Science and Development. 2017;8(2):93.
Rachma N. Adaptasi Tumbuhan Tapak Dara Air (Jussiaea repens L.) Yang Terpapar Logam Berat Kadmium (Cd): Skripsi; 2013.
Rahma NA, Rachmadiarti F, Kuntjoro S. Kemampuan Adaptasi Tumbuhan Tapak Dara Air (Jussiaea repens) terhadap Logam Berat Kadmium (Cd). Lentera Bio. 2014;3(1):13-19.
Rachmadiarti F, Asri M, Bashri A, Pratiwi I. Consortium of Marsilea crenata and Ludwigia adscendens for Linear Alkylbenzene Sulfonate Detergent Phytoremediator. Asian Journal of Water, Environment and Pollution. 2020;17(3): 37-41.
Rachmadiarti F, Sholikah M. Effectiveness of Ludwigia adcendens and Ludwigia grandiflora as Cadmium (Cd) Phytoremediator; 2020.
Nandra LW, Purnomo T. Potensi Tapak Dara Air (Ludwigia adscendens) dalam Menurunkan Kandungan Logam Berat Timbal (Pb) pada Perairan yang Tercemar Lumpur Lapindo, Sidoarjo. LenteraBio: Berkala Ilmiah Biologi. 2019;8(1).
Titah HS, Abdullah SRS, Idris M, Anuar N, Basri H, Mukhlisin M, Kurniawan SB. Arsenic resistance and biosorption by isolated rhizobacteria from the roots of Ludwigia octovalvis. International journal of microbiology; 2018.
Titah HS, Halmi MIEB, Abdullah SRS, Hasan HA, Idris M, Anuar N. Statistical optimization of the phytoremediation of arsenic by Ludwigia octovalvis-in a pilot reed bed using response surface methodology (RSM) versus an artificial neural network (ANN). International journal of phytoremediation. 2018;20(7):721-729.
Rajoo KS, Ismail A, Karam DS, Muharam FM. Phytoremediation studies on soils contaminated with heavy metals in Malaysia: A review article. American-Eurasian Journal Agricultural & Environmental Sciences. 2016;16(8): 1504-1514.
Idris M, Abdullah SRS, Titah HS, Abasa A. R, Husin AK, Hanima RF, Ayub R. Screening and identification of plants at a petroleum contaminated site in Malaysia for phytoremediation. Journal of Environmental Science and Management. 2016;19(1).
Marrugo-Negrete J, Marrugo-Madrid S, Pinedo-Hernández J, Durango-Hernández J, Díez S. Screening of native plant species for phytoremediation potential at a Hg-contaminated mining site. Science of the Total Environment. 2016;542:809-816.
Al-Mansoory AF, Idris M, Abdullah SRS, & Anuar N. Phytoremediation of contaminated soils containing gasoline using Ludwigia octovalvis (Jacq.) in greenhouse pots. Environmental Science and Pollution Research. 2017;24(13):11998-12008.
Alanbary S, Abdullah S, Abu Hassan H. Screening for Resistant and Tolerable Plants (Ludwigia octovalvis and Phragmites karka) in Crude Oil Sludge for Phytoremediation of Hydrocarbons. Iranian (Iranica) Journal of Energy & Environment. 2017;8(4):288-191.
Alanbary SRN, Abdullah SRS, Al-Baldawi IAW, Abu Hassan H, Anuar N, Othman AR, Suja F. Phytotoxicity of contaminated sand containing crude oil sludge on ludwigia octovalvis. Journal of Ecological Engineering. 2019;20(11).
Alanbary SN, Abdullah SS, Hassan HA, Othman AR. Screening for Resistant and Tolerable Plants (Ludwigia Octovalvis and Phragmites Karka) in Crude Oil Sludge for Phytoremediation of Hydrocarbons. Iranica Journal of Energy and Environment. 2018;9(1):48-51.
Almansoory AF, Hasan HA, Abdullah SRS, Idris M, Anuar N, Al-Adiwish WM. Biosurfactant produced by the hydrocarbon-degrading bacteria: Characte- rization, activity and applications in removing TPH from contaminated soil. Environmental Technology & Innovation. 2019;14: 100347.
Lobato-de Magalhães T, Martínez M. Temporary freshwater wetlands floristics in central Mexico highlands. Botanical Sciences. 2018;96(1):138-156.
Mallick SN, Ekka NX, Kumar S, Sahu SC. Invasive Alien Flora in and around an Urban Area of India Diversity and Ecology of Invasive Plants. IntechOpen. 2019,3.
Chang CI, Kuo CC, Chang JY, Kuo YH. Three New Oleanane-Type Triterpenes from Ludwigia o ctovalvis with Cytotoxic Activity against Two Human Cancer Cell Lines. Journal of natural products. 2004;67(1):91-93.
Aung LW, Chaw DKE. Study on morphology, anatomy, preliminary phytochemical test, nutritional values and antimicrobial activities of leaves of Ludwigia octovalvis (Jacq.) Raven. Dagon Univ Commemorat 25th Anniv Silver Jubilee Res J. 2019;9(2):321-327.
Lin WS, Lo JH, Yang JH, Wang HW, Fan SZ, Yen JH, Wang PY. (Ludwigia octovalvis extract improves glycemic control and memory performance in diabetic mice. Journal of ethnopharmacology. 2017;207:211-219.
Sharma A, del Carmen Flores-Vallejo R, Cardoso-Taketa A, Villarreal ML. Antibacterial activities of medicinal plants used in Mexican traditional medicine. Journal of ethnopharmacology. 2017;208:264-329.
Holm L, Pancho JV, Herberger JP, Plucknett DL. A geographical atlas of world weeds: John Wiley and Sons; 1979.
Widyaningrum I. Pest and Weed Suppressive Mechanisms in Complex Rice System at Malang, East Java, Indonesia; 2015.
Sudhana A, Kawuryan SHE, Padmini OS. Pengaruh Aplikasi Herbisida Dan Pgpr Dalam Pengendalian Gulmauntuk Meningkatkan Pertumbuhan Tanaman Padi Sawah. Paper presented at the Seminar Nasional Inovasi Produk Pangan Lokal Untuk Mendukung Ketahanan Pangan Universitas Mercu Buana Yogyakarta; 2019.
Purnomo H. Changes Of Weed Communities In Secondary Succession On Rice Field Area With Different Water Puddle. Bioma: Jurnal Ilmiah Biologi. 2011;1.
Jayan P, Sathyanathan N. Aquatic weed classification, environmental effects and the management technologies for its effective control in Kerala, India. International Journal of Agricultural and Biological Engineering. 2012;5(1):76-91.
Sainkhediya J, Sisodiya S. International Research World Journal of Multidisciplinary Scientific Research; 2020.
Liu SH, Edwards C, Hoch PC, Raven PH, Barber JC. Complete plastome sequence of Ludwigia octovalvis (Onagraceae), a globally distributed wetland plant. Genome announcements. 2016;4(6).
Liu SH, Hoch PC, Diazgranados M, Raven PH, Barber JC. Multi‐locus phylogeny of Ludwigia (Onagraceae): Insights on infra‐generic relationships and the current classification of the genus. Taxon. 2017;66(5):1112-1127.
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