Your search keyword '"marine macroalgae"' showing total 17 results

1. Effect of distinct drying approach on bioactive compounds and nutritional profiling of Ulva intestinalis and Padina tetrastromatica from the Bay of Bengal, Bangladesh

Author

Abu Bakker Siddique Khan, Md. Rahamat Ullah, Mousumi Akhter, Md. Monjurul Hasan, Farhana Yasmin, Aovijite Bosu, Mohammed Ashraful Haque, Md. Mohidul Islam, Al-Amin, Md. Amirul Islam, and Md. Zulfikar Ali

Subjects

Marine macroalgae, Drying, TPC, TFC, Nutritional chemicals, Freeze drying, Food processing and manufacture, TP368-456

Abstract

Marine algae have been visualized as fostering a prevalent actuation of bioactive substances that have noteworthy therapeutic effects. The current investigations deployed a trio of separate drying methods, i.e., oven drying, freeze drying, and sun drying, to quantify the total phenolic content (TPC), total flavonoid content (TFC), and dietary vitality of Ulva intestinalis and Padina tetrastromatica. By mining and scrutinizing it to the quercetin and gallic acid standards, TPC and TFC were derived. Among three drying techniques, freeze drying asserted higher TPC (12.59 ± 1.07 in U. intestinalis and 68.74 ± 1.95 mg of GA/g in P. tetrastromatica) and TFC (7.92 ± 0.97 in U. intestinalis and 58.15 ± 2.05 mg of quercetin/g in P. tetrastromatica) values. Ulva intestinalis and P. tetrastromatica also contain a high amount of protein (18.34% and 8.7%, respectively). The findings demonstrated that green seaweed possessed higher levels of potassium (2.20%) and molybdenum (2.41%) and brown seaweed showed higher amounts of potassium (2.41%) and calcium (1.11%). Where rapid drying methods are recommended to enhance constituent levels, freeze-drying could be an attractive alternative to oven and sun drying, as it addresses the drawbacks associated with prolonged drying periods.

Published

2024

2. A pan-genomic assessment: Delving into the genome of the marine epiphyte Bacillus altitudinis strain 19_A and other very close Bacillus strains from multiple environments

Author

Natalia Beatriz Comba-González, Diego Chaves-Moreno, Johanna Santamaría-Vanegas, and Dolly Montoya-Castaño

Subjects

Bacillus altitudinis, Pan-genome, Epiphytic bacteria, Marine macroalgae, Molecular ecology, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Marine macroalgae are the habitat of epiphytic bacteria and provide several conditions for a beneficial biological interaction to thrive. Although Bacillus is one of the most abundant epiphytic genera, genomic information on marine macroalgae-associated Bacillus species remains scarce. In this study, we further investigated our previously published genome of the epiphytic strain Bacillus altitudinis 19_A to find features that could be translated to potential metabolites produced by this microorganism, as well as genes that play a role in its interaction with its macroalgal host. To achieve this goal, we performed a pan-genome analysis of Bacillus sp. and a codon bias assessment, including the genome of the strain Bacillus altitudinis 19_A and 29 complete genome sequences of closely related Bacillus strains isolated from soil, marine environments, plants, extreme environments, air, and food. This genomic analysis revealed that Bacillus altitudinis 19_A possessed unique genes encoding proteins involved in horizontal gene transfer, DNA repair, transcriptional regulation, and bacteriocin biosynthesis. In this comparative analysis, codon bias was not associated with the habitat of the strains studied. Some accessory genes were identified in the Bacillus altitudinis 19_A genome that could be related to its epiphytic lifestyle, as well as gene clusters for the biosynthesis of a sporulation-killing factor and a bacteriocin, showing their potential as a source of antimicrobial peptides. Our results provide a comprehensive view of the Bacillus altitudinis 19_A genome to understand its adaptation to the marine environment and its potential as a producer of bioactive compounds.

Published

2024

3. Biotechnologically potential genes in a polysaccharide-degrading epibiont of the Indonesian brown algae Hydroclathrus sp.

Author

Stalis Norma Ethica, Dewi Seswita Zilda, Oedjijono Oedjijono, Muhtadi Muhtadi, Gintung Patantis, Sri Darmawati, Sri Sinto Dewi, Agus Sabdono, and Agustinus Robert Uria

Subjects

Marine macroalgae, Bacterial epibiont, Genome sequencing, Biotechnologically potential genes, Ecological role, Antimicrobial activity, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background Marine bacteria have recently attracted increasing attention to be harnessed for the production of valuable enzymes, vitamins, and bioactive compounds. Bacteria associated with the surfaces of marine macroalgae, called epibionts, are particularly interesting from ecological and biotechnological points of view, as they often exhibit antimicrobial activities to compete with pathogenic bacteria for nutrients and spaces. In search for biotechnologically potential genes from marine bacteria, we sequenced and analysed the genome of the epibiont HI03-3b, a polysaccharide-degrading bacterium associated with the surface of the Indonesian brown algae Hydroclathrus sp. Results The algal epibiont HI03-3b has a genome of approximately 4,860,704 bp in size with 42.02 mol% G + C content, consisting of 5655 open reading frames (ORFs), 4409 genes coding for proteins (CDSs), 94 genes for tRNAs, and 32 genes for rRNAs. The genome sequence of HI03-3b was most closely related to that of Cytobacillus firmus NCTC10335 with the average amino acid identity (AAI) of 95.0 %, average nucleotide identity (ANI) of 94.1 %, and a recommended DNA-DNA hybridization (DDH) of 57.60 %. These scores are lower than the most frequently used standard for species demarcation (95% ANI cutoff) and the new species threshold (DDH > 70.0% for the same bacterial species). Some differences in genome features and gene composition were observed between HI03-3b and NCTC10335, such as genes encoding carbohydrate active enzymes. These suggest that HI03-3b is unique and likely a novel species within Cytobacillus genus, and we therefore proposed its name as Cytobacillus wakatobiense HI03-3b. Genome sequence analyses indicated the presence of genes involved not only in polysaccharide and protein degradation but also in vitamin and secondary metabolite biosynthesis. Some of them encode enzymes and compounds with biotechnological interest, such as protease, chitinase, subtilisin, pullulanase, and bacillolysin, which are often associated with antimicrobial or antibiofilm activities. This antimicrobial potential is supported by our finding that the extracellular protein fraction of this epibiont inhibited the growth of the bacterial pathogen Staphylococcus aureus. Conclusion The epibiont Cytobacillus HI03-3b harbours genes for polysaccharide and protein degradation as well as for natural product biosynthesis, suggesting its potential ecological roles in outcompeting other bacteria during biofilm formation as well as in protecting its algal host from predation. Due to the presence of genes for vitamin biosynthesis, it might also provide the algal host with vitamins for growth and development. Some of these metabolic genes are biotechnologically important, as they could become a platform for bioengineering to generate various seaweed-derived substances sustainably, such as antibiofilm agents and vitamins, which are beneficial for human health.

Published

2023

4. Valorisation of acid mine drainage: Studying biosorption and bioaccumulation of rare earth elements by seaweeds.

Author

Viana T, Ferreira N, Pereira E, and Henriques B

Abstract

Acid mine drainage (AMD) nature, persistence and the considerable amount of toxic elements cause significant environmental damage. Traditional passive treatment systems typically focus on neutralizing AMD using limestone and removing common toxic metal(loid)s, and often overlook the recovery of economic and strategic elements (e.g., rare earth elements (REEs)). This study is aimed at assessing for the first time the use of seaweeds to remove REEs from AMD, transforming an environmental problem into a resource. The ability of three seaweed species (Gracilaria sp., Ulva sp., and Fucus sp.) to remove REEs was studied in their dried (biosorption) and living (bioaccumulation) forms. Bioaccumulation was the most efficient process, with Gracilaria and Ulva species showing better performances (75 and 44 %, respectively), also removing over 60 % of Fe. Adjusting the pH of AMD with NaOH successfully separated unwanted elements with minimal REEs loss. After pH adjustment, REEs removal did not improve for either species, except for Dy removal. Seaweed dosage was crucial for a higher REEs removal, with Gracilaria sp. showing a higher bioconcentration factor (up to 1470). FTIR and SEM-EDS analysis identified sulphonate, carboxyl, and alkyne groups as key in binding elements to Gracilaria sp. biomass. Overall, the results demonstrate that seaweed-based biotechnologies are a promising alternative for treating AMD and recovering valuable elements, which can be easily incorporated into the current passive treatment systems., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

5. Marine macroalgae in rabbit feed - Effects on meat quality.

Author

Al-Soufi S, García J, Nicodemus N, Lorenzo JM, Cegarra E, Muíños A, Losada AP, Miranda M, and López-Alonso M

Subjects

Animals, Rabbits, Antioxidants analysis, Ulva chemistry, Male, Taste, Meat analysis, Fatty Acids analysis, Animal Feed analysis, Seaweed chemistry, Diet veterinary, Dietary Supplements, Muscle, Skeletal chemistry

Abstract

The addition of macroalgae to livestock diets has demonstrated to enhance the quality of meat by improving the muscle stability, antioxidant capacity and fatty acid profile. However, information regarding rabbit meat is scarce. This study evaluated the effect of adding 1.025% of different macroalgae, dehydrated and as extracts (Saccharina latissima, Himanthalia elongata and Ulva spp.) to the diet of growing rabbits. Dietary supplementation with the Ulva spp. extract increased the fat content (0.96% vs 0.33% in control group) and the proportion of monounsaturated fatty acids (by 22%; P ≤ 0.022), but did not affect the moisture, protein or ash contents or the physicochemical properties of the rabbit longissiumus lumborum muscle. The antioxidant status of the meat was adequate and was not affected by the dietary supplements. The sensorial properties of the meat were also not affected, and dietary supplementation with both S. latissima and H. elongata actually enhanced the flavour and juiciness of the meat (P ≤ 0.01). Altogether, the study findings indicate that the addition of these sustainable ingredients to rabbit feed did not negatively affect meat quality, and some of them may potentially improve specific characteristics, which could make this meat more attractive to consumers., Competing Interests: Declaration of competing interest The authors declare that there is no conflict of interest regarding the publication of this article., (Copyright © 2023. Published by Elsevier Ltd.)

Published

2024

6. Studies on evaluation of surfactant coupled sonication pretreatment on Ulva fasciata (marine macroalgae) for enhanced biohydrogen production

Author

A.V. Snehya, M.A. Sundaramahalingam, J. Rajeshbanu, S. Anandan, and P. Sivashanmugam

Subjects

Ulva fasciata, Marine macroalgae, Bio-surfactant, Saponin, Biohydrogen, Chemistry, QD1-999, Acoustics. Sound, QC221-246

Abstract

Biohydrogen production from marine macroalgal biomass by advanced pre-treatment strategies is considered a clean energy technology. The present study focuses on investigating the effects of sonication pre-treatment (SP) and saponin coupled sonic pre-treatment (SSP) on Ulva fasciata for enhancing the production of biohydrogen. The SP and SSP were optimized to improve the hydrolysis process during digestion. The optimized time and sonication power were found respectively as 30 min and 200 W. A high concentration of biopolymer release was noticed in SSP than SP at optimized conditions. The surfactant dosage in SSP was optimized at 0.0036 g/g TS. The effect of SSP process was assessed by estimation of COD (Chemical Oxygen Demand) and SCOD (Soluble Chemical Oxygen Demand) release. The study revealed that, at a specific energy of 36,000 KJ/Kg TS, the SCOD release was higher in SSP (1900 mg/L) than SP (1050 mg/L). The SSP process could improve the COD solubilization to 15 % more than the SP. Carbohydrate and protein release are also more in SSP than SP. The use of biosurfactants significantly reduced the energy utilization in the hydrolysis process. The SSP pre-treated Ulva fasciata biomass has yielded a higher biohydrogen of 91.7 mL/g COD which is higher compared to SP (40.5 mL/g COD) and Control (9 mL/g COD).

Published

2021

7. Insight into the mechanisms involved in the removal of toxic, rare earth, and platinum elements from complex mixtures by Ulva sp

Author

Thainara Viana, Bruno Henriques, Nicole Ferreira, Ricardo J.B. Pinto, Filipe L.S. Monteiro, and Eduarda Pereira

Subjects

Lamp effluent, Kinetic modelling, General Chemical Engineering, Biosorption, Cellular partition, Environmental Chemistry, General Chemistry, Marine macroalgae, Industrial and Manufacturing Engineering, Water remediation

Abstract

Hazardous leachate/effluent from fluorescent lamps contains potentially toxic elements such as Hg and Pb, and critical raw materials such as rare earth elements (REEs). This work evaluated the ability of the live macroalgae Ulva sp. to remediate a simulated lamp industry wastewater consisting of a complex mixture of elements (Y, Eu, La, Ce, Tb, Gd, Hg, Pb, Zn, Cu, Co, Cd, and Pt), with particular emphasis on the investigation of the sorption mechanisms. Experiments were performed with 3.0 g/L (fresh weight) of Ulva sp., salinity 25, and an initial concentration of 100 µg/L for each element. Hierarchical cluster analysis highlighted two main groups according to removal: Pt and Cd as the less removed, and all others with removals > 76 %, underlining Hg and Ce with the fastest kinetics (up to 92 %). Apart from Co, Zn and Cd, all mathematical models described sorption kinetics well, with Akaike Information Criteria identifying the Elovich model as the best for describing REEs sorption. FTIR analysis identified the sulphated polysaccharide Ulvan as intervening in binding elements to Ulva biomass. Extraction with EDTA 0.001 mol/L showed that most elements were mainly localized in the outer fraction (surface), except for Hg, which was entirely in the inner part. SEM analysis supported the EDTA analysis and showed a clean surface after washing. The results are an important contribution to the understanding of sorption mechanisms in macroalgae and demonstrate the feasibility of macroalgae-based biotechnologies with reduced costs and high efficiency for water decontamination, in complex saline mixtures. published

Published

2023

8. Bioaccumulation of gamma emitting radionuclides in red algae from the Baltic Sea under laboratory conditions

Author

Tamara Zalewska and Michał Saniewski

Subjects

Radionuclides, Marine macroalgae, Bioaccumulation, Oceanography, GC1-1581

Abstract

The bioaccumulation ability of radionuclides 51Cr, 54Mn, 57Co, 60Co, 65Zn, 85Sr, 109Cd, 110mAg, 113Sn, 137Cs and 241Am in two red algae species from the southern Baltic Sea - Polysiphonia fucoides and Furcellaria lumbricalis - was determined under laboratory conditions. P. fucoides demonstrated better bioaccumulative properties towards most of the investigated radionuclides. As a result, P. fucoides can be recommended as a good bioindicator of radioactive environmental pollution. The bioaccumulation of radionuclides in F. lumbricalis was studied during an extended laboratory experiment. The initial extensive uptake of radioisotopes was followed by the rapid removal of cations; in general, concentrations tended to decrease with time. 137Cs displayed a different behaviour, its concentration in the algae increasing over time mainly due to its large ion radius; this is a factor that could be responsible for the stronger mechanical and chemical bonding of Cs+ and that could hamper the movement of ions in both directions.

Published

2011

9. Studies on evaluation of surfactant coupled sonication pretreatment on Ulva fasciata (marine macroalgae) for enhanced biohydrogen production

Author

M. A. Sundaramahalingam, J. Rajeshbanu, A.V. Snehya, Palani Sivashanmugam, and Sambandam Anandan

Subjects

Acoustics and Ultrasonics, Sonication, Short Communication, Saponin, QC221-246, Biomass, engineering.material, Inorganic Chemistry, Hydrolysis, Bio-surfactant, Chemical Engineering (miscellaneous), Environmental Chemistry, Radiology, Nuclear Medicine and imaging, Biohydrogen, Food science, QD1-999, ComputingMethodologies_COMPUTERGRAPHICS, Chemistry, Organic Chemistry, Chemical oxygen demand, Acoustics. Sound, Carbohydrate, Ulva fasciata, engineering, Biopolymer, Digestion, Marine macroalgae

Abstract

Graphical abstract, Biohydrogen production from marine macroalgal biomass by advanced pre-treatment strategies is considered a clean energy technology. The present study focuses on investigating the effects of sonication pre-treatment (SP) and saponin coupled sonic pre-treatment (SSP) on Ulva fasciata for enhancing the production of biohydrogen. The SP and SSP were optimized to improve the hydrolysis process during digestion. The optimized time and sonication power were found respectively as 30 min and 200 W. A high concentration of biopolymer release was noticed in SSP than SP at optimized conditions. The surfactant dosage in SSP was optimized at 0.0036 g/g TS. The effect of SSP process was assessed by estimation of COD (Chemical Oxygen Demand) and SCOD (Soluble Chemical Oxygen Demand) release. The study revealed that, at a specific energy of 36,000 KJ/Kg TS, the SCOD release was higher in SSP (1900 mg/L) than SP (1050 mg/L). The SSP process could improve the COD solubilization to 15 % more than the SP. Carbohydrate and protein release are also more in SSP than SP. The use of biosurfactants significantly reduced the energy utilization in the hydrolysis process. The SSP pre-treated Ulva fasciata biomass has yielded a higher biohydrogen of 91.7 mL/g COD which is higher compared to SP (40.5 mL/g COD) and Control (9 mL/g COD).

Published

2021

10. The Macroalgal Holobiont in a Changing Sea

Author

Luna M. van der Loos, Britas Klemens Eriksson, and Joana Falcão Salles

Subjects

Microbiology (medical), Climate Change, Oceans and Seas, BLEACHING DISEASE, Biology, Environment, Microbiology, Environmental stress, FUCUS-VESICULOSUS, Ecosystem services, MARINE MACROALGAE, 03 medical and health sciences, ALGAE, Effects of global warming, Virology, Ecosystem, 14. Life underwater, Microbiome, 030304 developmental biology, 0303 health sciences, CLIMATE-CHANGE, 030306 microbiology, Ecology, Microbiota, OCEAN ACIDIFICATION, Ocean acidification, Biodiversity, 15. Life on land, Seaweed, Holobiont, Infectious Diseases, Conceptual framework, 13. Climate action, Host-Pathogen Interactions, GROWTH, BACTERIAL COMMUNITIES, NITROGEN-FIXATION, Water Microbiology

Abstract

When studying the effects of climate change on eukaryotic organisms we often oversee a major ecological process: the interaction with microbes. Eukaryotic hosts and microbes form functional units, termed holobionts, where microbes play crucial roles in host functioning. Environmental stress may disturb these complex mutualistic relations. Macroalgae form the foundation of coastal ecosystems worldwide and provide important ecosystem services - services they could likely not provide without their microbial associates. Still, today we do not know how environmental stress will affect the macroalgal holobiont in an increasingly changing ocean. In this review, we provide a conceptual framework that contributes to understanding the different levels at which the holobiont and environment interact, and we suggest a manipulative experimental approach as a guideline for future research.

Published

2019

11. Role of Fe plaque on arsenic biotransformation by marine macroalgae.

Author

Hasegawa H, Akhyar O, Omori Y, Kato Y, Kosugi C, Miki O, Mashio AS, and Papry RI

Subjects

Biotransformation, Cacodylic Acid, Arsenic, Arsenicals, Seaweed

Abstract

Macroalgae can cycle arsenic (As) in the environment. In this study, the role of iron (Fe) plaque manipulation at active sites in the As biotransformation mechanism was investigated. The strain of marine macroalgal species, Pyrophia yezoensis, was inoculated in association with arsenate (As(V)) (1.0 μmol L -1 ) and phosphate (10 μmol L -1 ) in the medium for 7 days under laboratory-controlled conditions. The Fe plaque was removed by washing the Ti(III)-citrate-EDTA solution before inoculation. The limitation of Fe plaque did not significantly (p > 0.05) affect the chlorophyll fluorescence due to cellular regeneration, which was initiated immediately after washing. However, the speciation and uptake rate of As(V) increased significantly and reduced the inhibitory effect of P on the intracellular uptake of As(V) by P. yezoensis. In the culture medium without Fe plaque, approximately 66% of As(V) was removed with V max  = 0.32 and K m  = 1.92. In the absence of Fe plaque, methylated As species, such as dimethylarsinate (DMAA(V)), was recorded 0.28 μmol L -1 , while in the presence of Fe plaque, the value was 0.16 μmol L -1 . Inorganic trivalent As (As(III)) was absent in the washed samples; however, 0.53 μmol L -1 concentration of As(III) was still found in the presence of Fe plaque on day 7 of incubation. The results indicated that the absence of Fe plaque promoted higher intracellular uptake of As species, reduced the inhibitory effect of P, mitigated the co-precipitation bond between AsFe plaque and enhanced the detoxification process by DMAA excretion from the cell., Competing Interests: Declaration of competing interest Author(s) declare there is no conflict of interests., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2022

12. Glycolipids from macroalgae: potential biomolecules for marine biotechnology?

Author

Bianca Braz Mattos, Eliana Barreto-Bergter, Guilherme L. Sassaki, Lauro Mera de Souza, and Maria Teresa Villela Romanos

Subjects

glycolipids, Chloroform, Chromatography, biology, Elution, Silica gel, marine macroalgae, lcsh:RS1-441, biology.organism_classification, lcsh:Pharmacy and materia medica, chemistry.chemical_compound, Glycolipid, Column chromatography, chemistry, Acetone, antiviral activity, Green algae, Methanol, General Pharmacology, Toxicology and Pharmaceutics

Abstract

Brown, red and green algae from the Southeastern coast of Brazil were successively extracted with chloroform/methanol 2:1 and 1:2 (v/v). The crude lipid extract was partitioned according to Folch and the lower phase enriched in glycolipids was fractionated on a silica gel column chromatography eluted with chloroform, acetone and methanol. Three major orcinol-reactive bands present in the acetone and methanol fractions were detected by thin-layer chromatography with chromatographic mobilities corresponding to sulfoglycolipids and glycosyldiacylglycerols. These fractions exhibited potent antiviral activity against HSV-1-ACVs and HSV-1-ACVr and present low toxicity for cell cultures. Purification and identification of these bioactive glycolipids will be necessary in order to elucidate their primary structures and mechanism of action.

Published

2011

13. Assessment of marine macroalgae potential for gadolinium removal from contaminated aquatic systems.

Author

Ferreira N, Ferreira A, Viana T, Lopes CB, Costa M, Pinto J, Soares J, Pinheiro-Torres J, Henriques B, and Pereira E

Subjects

Gadolinium, Mercury, Seaweed, Ulva, Water Pollutants, Chemical analysis

Abstract

Gadolinium (Gd) is a rare earth associated with hospital and urban wastewaters due to its application as a contrast agent for magnetic resonance imaging. In this work, the uptake of Gd from contaminated seawater by three living marine macroalgae, Ulva lactuca (Chlorophyta), Fucus spiralis (Phaeophyta) and Gracilaria sp. (Rhodophyta) was studied along 72 h. Surface analysis (FTIR), water content, kinetic modelling, and Gd quantification in seawater and biomass were performed. All species were able to accumulate Gd from seawater with 10, 157, and 500 μg Gd L -1 , although green and red macroalgae performed better, following the order: green > red > brown. Removal efficiencies reached 85%, corresponding to a bioconcentration factor of 1700. In more complex solutions that intended to mimic real contaminated environments, namely mixtures with other rare earth elements (Y, La, Ce, Pr, Nd, Eu, Tb, Dy), and with potentially toxic elements commonly found in wastewaters (Cr, Ni, Cu, Cd, Hg, Pb), at two salinities (10 and 30), the macroalgae kept its efficiency: 84% and 88% of removal by green and red macroalgae, respectively. Overall, findings evidence that living macroalgae could be a countermeasure to the increasing anthropogenic enrichment of Gd observed in the aquatic environment., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2020

14. Study on bioaccumulation and biosorption of mercury by living marine macroalgae: Prospecting for a new remediation biotechnology applied to saline waters

Author

Armando C. Duarte, Luciana S. Rocha, Miguel A. Pardal, Eduarda Pereira, Cláudia B. Lopes, Bruno Henriques, Rui Monteiro, and Paula Figueira

Subjects

Kinetic modeling, Environmental remediation, General Chemical Engineering, chemistry.chemical_element, Fucus vesiculosus, Bioconcentration, Industrial and Manufacturing Engineering, Environmental Chemistry, biology, business.industry, Biosorption, General Chemistry, Mercury, Organo-metallic forms, biology.organism_classification, Bioaccumulation, Mercury (element), Biotechnology, chemistry, Environmental science, Ulva lactuca, Water quality, business, Marine macroalgae

Abstract

This study aimed to assess and explore the bioaccumulation capabilities of three different macroalgae species, Ulva lactuca (green), Gracilaria gracilis (red) and Fucus vesiculosus (brown), very common on temperate coasts and estuaries, for the removal of mercury (Hg) from contaminated waters (with high salinity), using environmentally realistic concentrations of metal (10–100 μg L −1 ). Levels of Hg accumulated by all seaweeds ranged between 20.8 and 208 μg g −1 , corresponding to bioconcentration factors of c.a. 2000. A comparative evaluation of bioaccumulation (living biomass) and biosorption (dried biomass) was performed for U. lactuca , which had displayed the best performance in accumulating Hg. The removal conducted by the living seaweed ( m macroalgae / V solution ≈ 500 mg L −1 ), although slower, was more promising since all Hg levels were reduced by about 99%, fulfilling the European criteria for drinking water quality. Pseudo-second-order and Elovich models described quite well the experimental data, assuming a process essentially of chemical nature. Determination of total Hg content in algal biomass over time, allowed to confirm and to follow the uptake of this metal by the living organism. Volatilization of Hg or its conversion to organo-metallic forms (0.02–0.05%) was negligible during the decontamination process. Overall, the results are a contribution for the development of an efficient and cost-effective water remediation biotechnology, based on the use of living macroalgae to promote the removal of Hg.

Published

2015

15. Removal of Inorganic Mercury From Aqueous Solutions by Biomass of the Marine Macroalga Cystoseira Baccata

Author

Carlos Rey-Castro, Roberto Herrero, Manuel E. Sastre de Vicente, Teresa Vilariño, and Pablo Lodeiro

Subjects

Environmental Engineering, Proton binding, Cations, Divalent, Cystoseira baccata, Inorganic chemistry, chemistry.chemical_element, Marine Biology, Sodium Chloride, Phaeophyta, Dissociation (chemistry), Water Purification, Adsorption, Biomass, Waste Management and Disposal, Water Science and Technology, Civil and Structural Engineering, Aqueous solution, Nitrates, biology, Chemistry, Mercury Compounds, Ecological Modeling, Cytoseira baccata, Biosorption, Sorption, Mercury, Hydrogen-Ion Concentration, biology.organism_classification, Pollution, Mercury (element), Kinetics, Metals, Marine macroalga, Mercuric Chloride, Marine macroalgae

Abstract

The ability of Cystoseira baccata algal biomass to remove Hg(II) from aqueous solutions is investigated. The mercury biosorption process is studied through batch experiments at 25ºC with regard to the influence of contact time, initial mercury concentration, solution pH, salinity and presence of several divalent cations. The acidbase properties of the alga are also studied, since they are related to the affinity for heavy metals. The studies of the pH effect on the metal uptake evidence a sharp increasing sorption up to a pH value around 7.0, which can be ascribed to changes both in the inorganic Hg(II) speciation and in the dissociation state of the acid algal sites. The sorption isotherms at constant pH show uptake values as high as 178 mg.g -1 (at pH 4.5) and 329 mg.g -1 (at pH 6.0). The studies of the salinity influence on the Hg(II) sorption capacity of the alga exhibit two opposite effects depending on the electrolyte added; an increase in concentration of nitrate salts (NaNO3, KNO3) slightly enhances the metal uptake, on the contrary, the addition of NaCl salt leads to a drop in the sorption. The addition of different divalent cations to the mercury solution, namely Ca2+, Mg2+, Zn2+, Cd2+, Pb2+ and Cu2+, reveals that their effect on the uptake process is negligible. Finally, the equilibrium sorption results are compared with predictions obtained from the application of a simple competitive chemical model, which involves a discrete proton binding constant and three additional constants for the binding of the main neutral inorganic Hg(II) complexes, Hg(Cl) HgOHCl and Hg(OH)2, to the algal surface sites. This work was funded by the projects BQU2002-02133 (from the Ministerio de Ciencia y Tecnología of Spain) and PGDIT02TAM10302PR (from the Xunta de Galicia).

Published

2005

16. Mineral content of edible marine seaweeds

Author

Rupérez Antón, Pilar

Subjects

Atomic absorption spectrophotometry, Edible seaweeds, Mineral content, Sea vegetables, Marine macroalgae

Abstract

Mineral content was determined in several brown (Fucus vesiculosus, Laminaria digitata, Undaria pinnatifida) and red (Chondrus crispus, Porphyra tenera) edible marine sea vegetables. Seaweeds contained high proportions of ash (21.1–39.3%) and sulphate (1.3–5.9%). In brown algae, ash content (30.1–39.3%) was higher than in red algae (20.6–21.1%). Atomic absorption spectrophotometry of the ashes indicated that marine seaweeds contained higher amounts of both macrominerals (8.083–17,875 mg/100g; Na, K, Ca, Mg) and trace elements (5.1–15.2 mg/100 g; Fe, Zn, Mn, Cu), than those reported for edible land plants. Edible brown and red seaweeds could be used as a food supplement to help meet the recommended daily intake of some essential minerals and trace elements., This research work was supported by the Comisión Interministerial de Ciencia y Tecnologı́a, CICYT Project ALI98–0830.

Published

2002

17. Removal of Inorganic Mercury From Aqueous Solutions by Biomass of the Marine Macroalga Cystoseira Baccata

Author

Herrero, Roberto, Lodeiro, Pablo, Rey-Castro, Carlos, Vilariño, Teresa, Sastre de Vicente, Manuel, Herrero, Roberto, Lodeiro, Pablo, Rey-Castro, Carlos, Vilariño, Teresa, and Sastre de Vicente, Manuel

Abstract

[Abstract] The ability of Cystoseira baccata algal biomass to remove Hg(II) from aqueous solutions is investigated. The mercury biosorption process is studied through batch experiments at 25ºC with regard to the influence of contact time, initial mercury concentration, solution pH, salinity and presence of several divalent cations. The acid-base properties of the alga are also studied, since they are related to the affinity for heavy metals. The studies of the pH effect on the metal uptake evidence a sharp increasing sorption up to a pH value around 7.0, which can be ascribed to changes both in the inorganic Hg(II) speciation and in the dissociation state of the acid algal sites. The sorption isotherms at constant pH show uptake values as high as 178 mg.g-1 (at pH 4.5) and 329 mg.g-1 (at pH 6.0). The studies of the salinity influence on the Hg(II) sorption capacity of the alga exhibit two opposite effects depending on the electrolyte added; an increase in concentration of nitrate salts (NaNO3, KNO3) slightly enhances the metal uptake, on the contrary, the addition of NaCl salt leads to a drop in the sorption. The addition of different divalent cations to the mercury solution, namely Ca2+, Mg2+, Zn2+, Cd2+, Pb2+ and Cu2+, reveals that their effect on the uptake process is negligible. Finally, the equilibrium sorption results are compared with predictions 1 obtained from the application of a simple competitive chemical model, which involves a discrete proton binding constant and three additional constants for the binding of main neutral inorganic Hg(II) complexes, Hg(Cl) HgOHCl and Hg(OH)2, to the algal surface sites.

Published

2005