Effect of phytoremediation on the morpho-anatomical characters of some aquatic macrophytes

Napaldet, Jones T.; Buot, Inocencio Jr E; Zafaralla, Macrina T.; Lit, Ireneo Jr. L; Sotto, Rachel C.

doi:10.13057/biodiv/d200519

Cited by 4 publications

(4 citation statements)

References 6 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The aerenchyma of aquatic plant roots experienced a significant increase in heavy metal stress and metaxylem. This condition is an attempt by plants to accumulate heavy metals, so they do not enter further and become toxic to plants (Batool et al 2014;Napaldet et al 2019;Li et al 2023).…”

Section: The Growth Of E Palifoliusmentioning

confidence: 99%

Bioremediation of Mercury- Polluted Water in Free Water Surface-Constructed Wetland System by Euglena sp. and Echinodorus palifolius (Nees & Mart.) J.F. Macbr.

Siswanti,

Daryono,

Petrus

et al. 2023

J.Tropical Biodiversity Biotechnology

View full text Add to dashboard Cite

Mercury accumulation in the aquatic environment can be highly harmful. The body takes mercury vapor through the lungs, then absorbs mercury metal through the digestive system, and then the blood carries the metal to the brain. Bioremediation is the process of breaking down or converting harmful compounds into non-toxic forms, which can be accomplished through phytoremediation or phycoremediation. The goal of this study was to examine the growth and anatomy of Euglena sp. after being cultured in the mercury-containing FWS-CW waste treatment system. The ability of Euglena sp. and Echinodorus palifolius to bioremediate mercury at different concentration as well as association and non-association treatments. This study was carried out in a bioreactor known as FSW-CW (Free Water Surface-Constructed Wetlands). Plant growth (plant height and number of leaves), chlorophyll content, diameter of root and petiole, metaxylem diameter of root, petiole, and leaves, cortical thickness of root and leaves, and petiole anatomy were all measured. Water temperature, pH, salinity, and light intensity were all measured as environmental parameters. Mercury treatment reduced Euglena density (183.5 cells. mL-1103 in control and 12.6 cells. mL-1103 in 100 ppm mercury treatment) and number of E. palifolius leaves, but not plant height and chlorophyll. Root and petiole diameters were affected by the mercury treatment, petiole diameter decreased unless the concentration was 100 ppm, whereas root diameter actually increased. The diameter of the root metaxylem increased, but the petioles and leaves, as well as the thickness of the root cortex, did not provide a significant response. The growth of E. palifolius was still optimal in the presence of Euglena in mercury-containing medium.

show abstract

Section: The Growth Of E Palifoliusmentioning

confidence: 99%

Bioremediation of Mercury- Polluted Water in Free Water Surface-Constructed Wetland System by Euglena sp. and Echinodorus palifolius (Nees & Mart.) J.F. Macbr.

Siswanti,

Daryono,

Petrus

et al. 2023

J.Tropical Biodiversity Biotechnology

View full text Add to dashboard Cite

show abstract

“…Organic matter evaporates from the stems and leaves through a direct phytovolatilization mechanism or from the soil through root activity called indirect phytovolatilization mechanism (Limmer and Burken 2016;Ekta and Modi 2018). Phytoremediation agents such as A. microphylla absorb components from the environment which are then processed in the tissue metabolism to remove pollutants (Alkorta et al 2004;Tulod et al 2012;Varghese and Jacob 2016;Napaldet et al 2019). Unisah and Akbari (2020) showed that the use of A. microphylla in tofu wastewater treatment reduced 96% of BOD.…”

Section: Biochemical Oxygen Demand (Bod) Reductionmentioning

confidence: 99%

“…Phytoremediation agents such as A. microphylla are more tolerant towards pollutants in the environment because they can absorb components from the environment that are metabolized inside the tissues (Alkorta et al 2004;Tulod et al 2012;Varghese and Jacob 2016;Napaldet et al 2019 ). In this case, A. microphylla can accumulate large amounts of contaminants into the biomass (Arora et al 2006).…”

Section: Sulfides (H2s) Reductionmentioning

confidence: 99%

Azolla microphylla and Pseudomonas aeruginosa for bioremediation of bioethanol wastewater

2021

View full text Add to dashboard Cite

Abstract. Annisa K, Sutarno, Santosa S. 2021. Azolla microphylla and Pseudomonas aeruginosa for bioremediation of bioethanol wastewater. Biodiversitas 22: 1799-1805. Bioremediation is the right choice in wastewater treatment since it requires has low cost but works optimally. Azolla microphylla and Pseudomonas aeruginosa are considered to have the ability to optimize waste degradation. The aim of this study was to determine the best treatment for reducing pollutants in bioethanol waste, namely by using A. microphylla and P. aeruginosa. The twelve treatments in this experimental research included variations in the A. microphylla biomass and variations of biomass combinations with the density of the P. aeruginosa. Research method used was completely randomized design with three replications, and all 36 samples were taken on the seventh day. Research data collected were the quality parameters of bioethanol wastewater before and after the treatment. The results showed that TSS, BOD, COD were decreased during seven days of treatment, whereas pH and H2S levels were increased. The combination of 0.2 kg A. microphylla and 1010 cfu/mL P. aeruginosa showed the best result in reducing pollutants. This study showed that A. microphylla and P. aeruginosa could be used to reduce pollutants in bioethanol wastewater. Results of the research are expected to become an alternative solution to the bioethanol wastewater problem.

show abstract

“…El conocimiento de los caracteres morfoanatómicos de las plantas acuáticas puede revelar adaptaciones al ambiente y manifestar cambios ecológicos de los mismos (Sandulescu et al, 2016). A través de dichos estudios se pueden inferir manifestaciones de estrés o contaminación ambiental; y también permiten detectar el potencial fitorremediador de las plantas nativas, lo que podría derivar en resultados más eficientes en la limpieza de los ambientes contaminados (Wood & McAtamney, 1994;Baruah et al, 2014;Guittonny-Philippe et al, 2015;Napaldet et al, 2019;Olaranont et al, 2020). El uso de rasgos morfo-anatómicos vegetativos puede proporcionarnos información cuantitativa para explicar la ecología de las macrófitas (Dalla-Vecchia et al, 2020).…”

unclassified

Anatomía ecológica de especies de Bacopa (Gratioleae-Plantaginaceae): macrófitas acuáticas del Macrosistema Iberá

Gómez

González²,

Sosa³

2023

Bonplandia

View full text Add to dashboard Cite

La gran mayoría de las especies de Bacopa (Gratioleae-Plantaginaceae) son plantas macrófitas que presentan una serie de adaptaciones morfológicas, anatómicas y ecofisiológicas en sus órganos vegetativos. Se estudió la anatomía vegetativa de cinco especies de Bacopa presentes en el Iberá y una de humedales del Paraguay. Para el estudio de la anatomía foliar y caulinar se realizaron cortes paradermales y transversales a mano alzada y con micrótomo rotativo a partir de material previamente fijado. Se encontraron diferencias entre las 6 especies de Bacopa analizadas, en la hoja relacionadas a: tipos de tricomas; tipos, distribución y densidad de estomas; y en el tipo de mesofilo. Para el tallo, se caracterizaron dos patrones de aerénquima cortical que se relacionan con los ambientes que habitan las especies y sus adaptaciones al mismo. A modo de conclusión se elaboró una clave dicotómica con caracteres anatómicos vegetativos de las especies de Bacopa que crecen en los humedales.

show abstract

Effect of phytoremediation on the morpho-anatomical characters of some aquatic macrophytes

Cited by 4 publications

References 6 publications

Bioremediation of Mercury- Polluted Water in Free Water Surface-Constructed Wetland System by <i>Euglena</i> sp. and <i>Echinodorus palifolius</i> (Nees & Mart.) J.F. Macbr.

Bioremediation of Mercury- Polluted Water in Free Water Surface-Constructed Wetland System by <i>Euglena</i> sp. and <i>Echinodorus palifolius</i> (Nees & Mart.) J.F. Macbr.

Azolla microphylla and Pseudomonas aeruginosa for bioremediation of bioethanol wastewater

Anatomía ecológica de especies de Bacopa (Gratioleae-Plantaginaceae): macrófitas acuáticas del Macrosistema Iberá

Contact Info

Product

Resources

About