Use of Solid Waste from Thermoelectric Plants for the Cultivation of Microalgae

Vaz, Bruna da Silva; Costa, Jorge Alberto Vieira; Morais, Michele Greque

doi:10.1590/1678-4324-2016150452

ABSTRACT

The aim of this study was to analyze the influence of solid waste on the cultivation of the microalgae Spirulina sp. LEB 18 and Chlorella fusca LEB 111 with 0, 40, 80 and 120 ppm of mineral coal ash. The addition of the ash did not inhibit the cultivation of microalgae at the tested concentrations, showing that it could be used for the cultivation of these microalgae due to the minerals present in the ash, which might substitute the nutrients needed for their growth.

ashes; Chlorella fusca LEB 111; microalgae; mineral coal; Spirulina sp. LEB 18

INTRODUCTION

As technology and industry develops, there is increasing environmental concern about the release of industrial waste, which can damage the ecosystem. The rapid expansion of different industrial sectors has resulted in increased amounts of toxic wastes. Mineral coal ash is one of the most produced solid wastes in Brazil in terms of volume (Soares et al. 2008Soares PSM, Santos MDC, Possa MV. Carvão Brasileiro: tecnologia e meio ambiente. Rio de Janeiro: CETEM/MCT; 2008.). The burning of coal from south Brazil produces a high percentage of ash, around 53% (w/w), which is a serious environmental problem. Due to the presence of potentially toxic trace elements in this waste, it must be disposed of and used carefully, and an appropriate site for disposal must be chosen, in order to protect the ground and the surface water (Benito et al 2001Benito Y, Ruiz M, Cosmen P, Merino JL. Study of leaches obtained from the disposal of fly ash from PFBC and AFBC processes. J Chem Eng. 2001; 84: 167-171.; Soares et al. 2008).

Generally, ashes are deposited in open pit mines, or in the landfills near the plant (Depoi et al. 2008Depoi FS, Pozebon D, Kalkreuth WD. Chemical characterization of feed coals and combustion-by-products from Brazilian power plants. Int J Coal Geol. 2008; 76: 227-236.). Less than 30% of ash is reused in the construction industry; the rest is improperly dumped in landfills, which can harm human health and the environment due to the leaching of toxic metal ions present in the ash (Soares et al. 2008). Metal ions, even at low concentrations, can become toxic to living beings (Burgstaller and Schinner 1993Burgstaller W, Schinner F. Leaching of metals with fungi. J Biotechnol. 1993; 27: 91-116.). Therefore, it is essential to find methods that reduce the levels of contamination caused by these metals. One alternative to combat this type of pollution is the use of biological processes (Schmitz et al. 2012Schmitz R, Magro CD, Colla LM. Aplicações ambientais de microalgas. Revista CIATEC - UPF. 2012; 4: 48-60. ).

The use of microalgae is one such biological process with economic, nutritional and ecological importance due to a microalga's capacity to double its biomass within 24 h (Becker 2004Becker W. Microalgal in human and animal nutrition, In: Richmond, A. (ed) Handbook of Microalgal Culture: biotechnology and applied phycology. London: Blackwell Science; 2004. p. 312-351.; Antelo et al. 2010Antelo FS, Anschau A, Costa JAV, Kalil SJ. Extraction and Purification of Cphycocyanin from Spirulina platensis in Conventional and Integrated Aqueous Two-Phase Systems. J Braz Chem Soc. 2010; 21(5): 921-926.). Microalgae are capable of removing heavy metals from the environment due to their active, or mediating ability in mobilization, or immobilization processes that influence the equilibrium of metallic species between the solid and liquid phases. Mobilization is the process through which an initial insoluble state, corresponding to a solid phase, turns into a final soluble state in aqueous phase. Immobilization is the process through which an initial soluble state in aqueous phase turns into a final insoluble state in solid phase (Gadd 2004Gadd GM. Microbial influence on metal mobility and application for bioremediation. Geoderma. 2004;a: 109-119.).

The objective of this study was to analyze the influence of solid wastes at different concentrations on the cultivation of the microalgae, Spirulina sp. LEB 18 and Chlorella fusca LEB 111.

MATERIAL AND METHODS

Microorganisms and culture media

The microalgae used in this study were Spirulina sp. LEB 18, isolated from Mangueira lagoon, latitude 33º31'08"S and longitude 53º22'05"W. Chlorella fusca LEB 111 was isolated from the pond for stabilization of effluents and waste at the President Medici Thermoelectric Power Plant (UTPM), latitude 24°36'13''S and longitude 52º32'43''W (Candiota RS); (Morais et al. 2008Morais MG, Costa JAV. Isolation and selection of microalgae from coal fired thermoelectric power plant for biofixation of carbon dioxide. Energ Convers Manage. 2007; 48: 2169-2173.).

Spirulina sp. LEB 18 was cultivated in Zarrouk medium with the following composition (g L^-1): NaHCO₃ (16.8); K₂HPO₄ (0.50); NaNO₃ (2.50); K₂SO₄ (1.00); NaCl (1.00); MgSO₄.7H₂O (0.20); CaCl₂ (0.04); FeSO₄.7H₂O (0.01); EDTA (0.08); H₃BO₃ (2.86); MnCl₂.4H₂O (1.81); ZnSO₄.7H₂O (0.222); CuSO₄.5H₂O (0.079); Na₂MoO₄ (0.015); in (mg L^-1), NH₄VO₃ (22.86); K₂Cr₂(SO₄)₄.24H₂O (96); NiSO₄.7H₂O (47.85); Na₂WO₄.2H₂O (17.94); TiOSO₄.H₂SO₄.8H₂O (61.1); Co(NO₃)₂.6H₂O (43.98) (Zarrouk 1966Zarrouk C. Contribuition a Letude Cyanophycee, Influence de Divers Facteurs physiques et Chimiques sur la Croissance et photosynthese de Spirulina maxima geitler. Ph. D. Thesis University of Paris, Paris. 1966.). Chlorella fusca LEB 111 was grown in BG11 medium with the following composition (g L^-1): NaNO₃ (1.50); K₂HPO₄.3H₂O (0.04); MgSO₄.7H₂O (0.075); CaCl₂.2H₂O (0.036); ammonium ferric citrate (0.006); EDTA (0.001); Na₂CO₃ (0.02); citric acid (0.006); ZnSO₄.7H₂O (0.222); MnCl₂.4H₂O (1.81); Na₂MoO₄.2H₂O (0.390); H₃BO₃ (2.86); CuSO₄.5H₂O (0.079); Co(NO₃)₂.6H₂O (0.0494) (Rippka 1979Rippka R, Deruelles J, Waterbury JW, Herdman M, Stanier RG. Genetic assignments, strain histories and properties of pure cultures of Cyanobacteria. J Gen Microbiol. 1979; 111: 1-61.).

Cultivation conditions

The cultivations were carried out in discontinuous mode in 2 L Erlenmeyer type closed photobioreactors, with a working volume of 1.8 L (replacement of evaporation with sterile distilled water) and initial microalgal concentration of 0.2 g L ^-1. The temperature was maintained at 30°C in a thermostated chamber with a photoperiod of 12 h light/dark (Reichert et al. 2006Reichert CC, Reinehr CO, Costa JAV. Semicontinuous cultivation of the cyanobacterium Spirulina platensis in a closed photobioreactor. Braz J Chem Eng. 2006; 23: 23-28.) and 43.2 µmol m^-2 s^-1 illuminance provided by fluorescent lamps (General Electric) (Morais and Costa 2007Costa JAV, Colla LM, Duarte Filho P, Kabke K. Modelling or Spirulina platensis growth in fresh water using response surface methodology. World J Microbiol Biotechnol. 2002; 18(7): 603-607.).

The cultures were stirred using sterile compressed air. The solid wastes (coal fly ash) were provided by UTPM (Table 1), collected from Silo 1 (Phase C) and added to the culture medium of each microalga at concentrations of 0, 40, 80 and 120 ppm. The ash concentrations were selected according to the emission standard, established in UTPM's environmental licensing process. The experiments were carried out in duplicate and lasted 12 d.

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Table 1
- Chemical composition of the utilized coal fly ash

Analytical determinations

The biomass concentration was measured daily by reading the optical density at 670 nm in a spectrophotometer (QUIMIS Q798DRM), with a calibration curve that related optical density to the dry biomass weight for each microalga (Radmann et al. 2007Radmann EM, Reinehr CO, Costa JAV. Optimization of the repeated batch cultivation of microalga Spirulina platensis in open raceway ponds. Aquaculture. 2007; 265: 118-126.; Rosa et al. 2011Rosa APC, Carvalho LF, Goldbeck L, Costa JAV. Carbon dioxide fixation by microalgae cultivated in open bioreactors. Energy Convers Manage. 2011; 52: 3071-3073.). The pH of the cultures was measured using a digital pH meter every 24 h (LUTRON PH-221).The concentration of carbon, hydrogen and nitrogen in the final biomass was measured for each experiment by using the elemental analyzer CHNS/O (Perkin-Elmer 2400, USA). The acetanilide certificate standard was used to calibrate the equipment (Perkin Elmer, USA).

Kinetic parameters

The biomass concentration values were used to determine the maximum specific growth rates (μ_máx, d ^-1), maximum cell concentrations (X_máx, g L ^-1) and maximum yields (P_máx, g L ^-1 d ^-1). The maximum yield was obtained according to P = (X_t - X₀) (t - t₀)^-1, where X_t was the biomass concentration (g L^-1) at time t (d), and X₀ the biomass concentration (g L^-1) at time t₀ (d) (Schmidell et al. 2001Schmidell W, Lima AU, Aquarone E, Borzani W. Biotecnologia Industrial. São Paulo: Edgard Blücher Ltda; 2001.). The maximum specific growth rate (μ _máx, d^-1) was obtained by exponential regression applied to the logarithmic phase (Bailey and Ollis 1986Bailey JE, Ollis DF. Biochemical Engineering Fundamentals. 2nd ed., Singapore: McGraw-Hill; 1986.).

Statistical analysis

The experimental results were evaluated using the analysis of variance (ANOVA) and Tukey's test to compare the means of the kinetic parameters, with a significance level of 99% (p≤ 0.01). Thus, it was possible to analyze the influence of residues in the microalgal cultures.

RESULTS ANS DISCUSSION

The maximum biomass concentration (0.64 g L^-1) was obtained for the Spirulina sp. LEB 18 cultivated with 120 ppm ash. The kinetic parameters of growth, maximum productivity (0.04 g L ^-1 d^-1) and maximum specific growth rate (0.10 d ^-1) were also maximum in the experiment with higher ash content (Table 2). The growth curves of Spirulina sp. LEB 18 and C. fusca LEB 111 (Figs. 1 a and b) did not present a "lag", or latency phase. This phase occurs in many cultures after the inoculation of the microalga in the culture medium, with no reproduction, because the cells synthesizeenzymes required for the cultures in different conditions than those under which the initial inoculum is maintained. The duration of this phase depends on the initial inoculum concentration, the pre-cultivation time and the physiological state of the microorganism. Native species of microalgae are more tolerant of local conditions and exhibit higher rates of photosynthesis and biomass production (Salih 2011Salih, FM. Microalgae Tolerance to High Concentrations of Carbon Dioxide: A Review. J Environ Protect. 2011; 2: 648-654.). The environmental impact of the high concentrations of solid residues produced by burning the fossil fuels on such strains would be reduced compared with that on native microorganisms, eliminating the need to look for tolerant strains.

The microalgae grew immediately after inoculation (transition phase), and the onset of cell reproduction was observed in the initial phase of the experiment (Figs. 1a and 1b). There was no lag phase, despite the addition of a new factor (ash), because many of the minerals contained in the ashes (cobalt, chromium, copper, manganese, molybdenum, nickel, zinc), were also used by the culture in which the inoculum was maintained (Depoi et al. 2008). The linear phase is characteristic of the constant reproduction velocity. This behavior suggests that there are certain limitations in the transport of nutrients to the microorganism-medium interface, with respect to oxygen dissolved in the culture (Schmidell et al. 2001). The cultures might have been adversely affected and/or had a sharp linear phase, due to the influence of dissolving CO_2, because the reactors used did not enable much time for the gas to reside in the culture. The use of tubular reactors might reduce this problem.

In the growth curves of Spirulina sp. LEB 18 (Fig. 1a), a stationary phase followed by a decline and/or cell death was not observed until the end of cultivation (12 d). For C. fusca LEB 111 (Fig. 1b), the cell death phase was observed at 12 d of culture for all of the experiments (Fig. 1b), which might have occurred due to the limitation of the BG11 medium's carbon source. The Spirulina sp. LEB 18 had optimal growth (maximum) when cultivated with 120 ppm of ash. C. fusca LEB 111 did not present a maximum concentration of biomass when grown with the highest amount of ash, and there was no statistically significant difference (p <0.01) from the other experiments (Table 2).

Figure 1-
Growth curves of the microalgae Spirulina sp. LEB 18 (a) and Chlorella fusca LEB 111 (b) cultivated (●) 0 (■) 40 (♦) 80 e (+) 120 ppm ash

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Table 2
- Maximum biomass concentration (X _max)_, maximum productivity (P_max) and maximum specific growth rate (μ_max) obtained for the microalgae Spirulina sp. LEB 18 and Chlorella fusca LEB 111cultivated with different concentrations of ash (ppm)

The pH of the cultures with Spirulina sp. LEB 18 and C. fusca LEB 111 varied from 9.3 to 10.3. Figure 2a showed that the pH (alkaline) remained similar for all of the experiments of Spirulina sp. LEB 18 throughout the 12 d of culture. Figure 2b showed that C. fusca LEB 111 medium without ash had a higher pH. Low pH values in the culture with 120 ppm ash mighthave limited the form of inorganic carbon available in the culture medium (BG11) of C. fusca LEB 111. The higher the medium's pH, the more easily bicarbonate is converted into carbonate, which is the standard carbon source in BG11 medium. Thus, the maximum biomass concentration (0.58 g L^-1) was obtained in the culture with the highest pH (Fig. 2b), with no statistical difference between the experiments with the addition of ash for C. fusca. According to Lourenço (2006), controlling the pH is essential so that components of the culture medium can be effectively absorbed, directly affecting the availability of various chemical elements.

The cultivation of Spirulina requires an alkaline medium (pH 8.3 to 11.0) with high availability of carbonate, or bicarbonate as optimal growth conditions (Costa et al. 2002). This suggested that the pH did not impair the growth in the Spirulina cultures (Fig. 2a). The microalga Chlorella kept growing at neutral pH (6.5 to 7.5). The fact that C. fusca LEB 111 was isolated from UTPM's ash decantation ponds, justified its resistance to alkalinity. The pH is directly related to the form of inorganic carbon available in the culture, because alkaline media favor the bicarbonate form (HCO₃^-), which is more easily assimilated than CO₂, and accounts for more than 80% when the pH ranges from 7.0 to 9.0. The free CO₂ and carbonate (CO ₃^-2) forms predominate below, or above these values, respectively. Very low pH values (<5.0) can inhibit microalgal growth, leading to unavailability of nutrients (Kirk 1994Kirk JTO. Light and Photosynthesis in Aquatic Ecosystems. Camberra: Cambridge University Press; 1994.).

The UTPM ash is mainly made up of silica (SiO₂), alumina (Al₂O₃), iron oxide (Fe₂O₃) and calcium oxide (CaO). The sub-bituminous coal ash from Candiota produces alkaline solutions when in contact with water, and this phenomenon is associated with the existence of minerals, such as calcite, amorphous silicates, hematite, quartz, oxides and free carbon. The alkalinity depends on the CaO content, and the low pH values are due to the presence of condensed sulfuric acid in the ash particles. Over the time, the excess alkali and alkaline-earth oxides react and neutralize the acidity (Flues et al. 2013Flues M, Sato IM, Scapin MA, Cotrim MEB, Camargo IMC. Toxic elements mobility in coal and ashes of Figueira coal power plant, Brazil. Fuel. 2013; 103: 430-436.). Thus, initial pH measurements could present low values, but over the time, the final rise in pH occurred as was observed in the cultures with the studied microalgae (Fig. 2).

Figure 2-
pH curves for the experiments with the microalgae Spirulina sp. LEB 18 (a) and Chlorella fusca LEB 111 (b) cultivated with (●) 0 (+) 40 (□) 80 e (♦) 120 ppm of ash

The solubility of the minerals varies according to the particle size. The UTPM ash that is emitted from coal combustion (chimney outlet) has a mean diameter of 59.82 µm (Eletrobras/ CGTEE 2013ELETROBRAS CGTEE. <http://www.cgtee.gov.br/> Accessed in November 15th 2013.
http://www.cgtee.gov.br/... ). According to Pires and Queirol (2004)Pires M, Queirol X. Characterization of Candiota (South Brazil) coal and combustion by-product. Int J Coal Geol. 2004; 60: 57-72., some of the ash's elements are more soluble (>40%) when the particle size is smaller (arsenic, cobalt, strontium, barium, zinc and nickel). The same behavior was observed for zirconium, chromium, vanadium, hafnium, and thallium, but with low solubility (5%). On the other hand, iron, niobium, cesium, lithium and tungsten had poor solubility for all fraction sizes. Sulfur and molybdenum have different solubility profiles, and are more soluble than the other elements. Thus, the large amount of minerals in the ash, dissolved in the culture medium, can partly replace the essential nutrients required to cultivate microalgae, such as Fe (Pane et al. 2008Pane L, Solisio C, Lodi A, Mariottini GL, Converti A. Effect of extracts from Spirulina platensis bioaccumulating cádmium and zinc on L929 cells. Ecotoxicol and Environ Saf. 2008; 70: 121-126.; Ctvrtnickova et al. 2009Ctvrtnickova T, Mateo MP, Yañez A, Nicolas G. Characterization of coal fly ash components by laser-induced breakdown spectroscopy. Spectrochim Acta Part B. 2009; 64: 1093-1097.). Certain elements are essential for the growth and composition of microalgae. Carbon, nitrogen, hydrogen, oxygen, phosphorous, magnesium, copper, zinc, sulfur, potassium, calcium and molybdenum are considered necessary for all algae. Sodium, cobalt, vanadium, selenium, silicon, chlorine, iodine and boron are required only for some algae. The different nutrient elements are required in varying concentrations. Depending on the amount required for the metabolic processes, the nutrient elements can be classified into two fundamental categories: macronutrients (C, H, O, N, P, S, K, Mg, Si, Fe) and micronutrients (Mn, Cu, Zn , Mo, V, B, Co, Ca, In, Se, Ni) (Lourenço 2006).

In addition to accumulating minerals, microalgae are able to accumulate toxic metals, such as cadmium (Solisio et al. 2008Solisio C, Lodi A, Soletto D, Converti A. Cadmium biosorption on Spirulina platensis biomass. Bioresource Technol. 2008; 99: 5933-5937.). Several studies with the microalgae Chlorella and Spirulina have been carried out to remove toxic heavy metals from waste water (Lodi et al. 2008Lodi A, Soletto D, Solisio C, Converti A. Chromium (III) removal by Spirulina platensis biomass. Chem Eng J. 2008; 136: 151-155.; Pane et al. 2008; Solisio et al. 2008). The microbial biochemical mechanism does not degrade the contaminant atom, but changes the toxic metal's oxidation state, thus enabling its detoxification. Therefore, these microorganisms have the ability to concentrate, or remove metals, whether in the form of precipitates, or volatile substances, turning the species into less toxic and more readily available compounds (Singh and Cameotra 2004Singh P, Cameotra SS. Enhancement of metal bioremediation by use of microbial surfactants. Biochem Biophys Res Commun. 2004; 319: 291-297.).

CONCLUSION

The maximum biomass concentration (0.64 g L^-1) was obtained in the cultivation of Spirulina sp. LEB 18 grown with 120 ppm of ash, compared with C. fusca LEB 111 (0.58 g L^-1), with no significant difference from the standard growth medium of both microalgae. The results showed that the solid waste originating from the burning of coal did not hamper the growth of microalgae at the tested concentrations. These residues may replace part of the metals that are essential for the growth of microalgae, and these may also enable the decontamination of toxic metals by changing the oxidation state of these elements. In these processes, the microbial metabolism removes pollutants, turning it into raw materials for the generation of biomass and bioproducts that can be used for energy, biofuels and biopolymers. The costs of the culture medium can be significantly reduced by replacing the nutrients contained in the medium by low cost and difficult to dispose of alternative sources, such as ash. Thus, the biological processes combine to reduce the environmental pollution with the production of bioproducts with reduced costs

ACKNOWLEDGEMENT

The authors would like to thank CNPq (National Council of Technological and Scientific Development) and CGTEE (Company of Thermal Generation of Electric Power) for their financial support of this study.

Antelo FS, Anschau A, Costa JAV, Kalil SJ. Extraction and Purification of Cphycocyanin from Spirulina platensis in Conventional and Integrated Aqueous Two-Phase Systems. J Braz Chem Soc. 2010; 21(5): 921-926.
Bailey JE, Ollis DF. Biochemical Engineering Fundamentals. 2nd ed., Singapore: McGraw-Hill; 1986.
Becker W. Microalgal in human and animal nutrition, In: Richmond, A. (ed) Handbook of Microalgal Culture: biotechnology and applied phycology. London: Blackwell Science; 2004. p. 312-351.
Benito Y, Ruiz M, Cosmen P, Merino JL. Study of leaches obtained from the disposal of fly ash from PFBC and AFBC processes. J Chem Eng. 2001; 84: 167-171.
Burgstaller W, Schinner F. Leaching of metals with fungi. J Biotechnol. 1993; 27: 91-116.
Colla LM, Reinehr CO, Reichert C, Costa JAV. Production of biomass and nutraceutical compounds by Spirulina platensis under different temperature and nitrogen regimes. Bioresour Technol. 2007; 98(7): 1489-1493.
Costa JAV, Colla LM, Duarte Filho P, Kabke K. Modelling or Spirulina platensis growth in fresh water using response surface methodology. World J Microbiol Biotechnol. 2002; 18(7): 603-607.
Ctvrtnickova T, Mateo MP, Yañez A, Nicolas G. Characterization of coal fly ash components by laser-induced breakdown spectroscopy. Spectrochim Acta Part B. 2009; 64: 1093-1097.
Depoi FS, Pozebon D, Kalkreuth WD. Chemical characterization of feed coals and combustion-by-products from Brazilian power plants. Int J Coal Geol. 2008; 76: 227-236.
ELETROBRAS CGTEE. <http://www.cgtee.gov.br/> Accessed in November 15th 2013.
» http://www.cgtee.gov.br/
Flues M, Sato IM, Scapin MA, Cotrim MEB, Camargo IMC. Toxic elements mobility in coal and ashes of Figueira coal power plant, Brazil. Fuel. 2013; 103: 430-436.
Gadd GM. Microbial influence on metal mobility and application for bioremediation. Geoderma. 2004;a: 109-119.
Kirk JTO. Light and Photosynthesis in Aquatic Ecosystems. Camberra: Cambridge University Press; 1994.
Lodi A, Soletto D, Solisio C, Converti A. Chromium (III) removal by Spirulina platensis biomass. Chem Eng J. 2008; 136: 151-155.
Lourenço SO. Cultivo de microalgas marinhas: princípios e aplicações. São Carlos: RIMA; 2006.
Morais MG, Costa JAV. Isolation and selection of microalgae from coal fired thermoelectric power plant for biofixation of carbon dioxide. Energ Convers Manage. 2007; 48: 2169-2173.
Morais MG, Reichert CC, Dalcaton F, Durante AJ, Marins LFF, Costa JAV. Isolation and caracterization of a new Arthrospira strain. Z Naturforsch C. 2008; 63c: 144-150.
Pane L, Solisio C, Lodi A, Mariottini GL, Converti A. Effect of extracts from Spirulina platensis bioaccumulating cádmium and zinc on L929 cells. Ecotoxicol and Environ Saf. 2008; 70: 121-126.
Pires M, Queirol X. Characterization of Candiota (South Brazil) coal and combustion by-product. Int J Coal Geol. 2004; 60: 57-72.
Radmann EM, Reinehr CO, Costa JAV. Optimization of the repeated batch cultivation of microalga Spirulina platensis in open raceway ponds. Aquaculture. 2007; 265: 118-126.
Reichert CC, Reinehr CO, Costa JAV. Semicontinuous cultivation of the cyanobacterium Spirulina platensis in a closed photobioreactor. Braz J Chem Eng. 2006; 23: 23-28.
Rippka R, Deruelles J, Waterbury JW, Herdman M, Stanier RG. Genetic assignments, strain histories and properties of pure cultures of Cyanobacteria. J Gen Microbiol. 1979; 111: 1-61.
Rosa APC, Carvalho LF, Goldbeck L, Costa JAV. Carbon dioxide fixation by microalgae cultivated in open bioreactors. Energy Convers Manage. 2011; 52: 3071-3073.
Salih, FM. Microalgae Tolerance to High Concentrations of Carbon Dioxide: A Review. J Environ Protect. 2011; 2: 648-654.
Schmidell W, Lima AU, Aquarone E, Borzani W. Biotecnologia Industrial. São Paulo: Edgard Blücher Ltda; 2001.
Schmitz R, Magro CD, Colla LM. Aplicações ambientais de microalgas. Revista CIATEC - UPF. 2012; 4: 48-60.
Singh P, Cameotra SS. Enhancement of metal bioremediation by use of microbial surfactants. Biochem Biophys Res Commun. 2004; 319: 291-297.
Soares PSM, Santos MDC, Possa MV. Carvão Brasileiro: tecnologia e meio ambiente. Rio de Janeiro: CETEM/MCT; 2008.
Solisio C, Lodi A, Soletto D, Converti A. Cadmium biosorption on Spirulina platensis biomass. Bioresource Technol. 2008; 99: 5933-5937.
Zarrouk C. Contribuition a Letude Cyanophycee, Influence de Divers Facteurs physiques et Chimiques sur la Croissance et photosynthese de Spirulina maxima geitler. Ph. D. Thesis University of Paris, Paris. 1966.

Publication Dates

Publication in this collection
2016

History

Received
29 July 2015
Accepted
27 Sept 2015

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] Antelo FS, Anschau A, Costa JAV, Kalil SJ. Extraction and Purification of Cphycocyanin from Spirulina platensis in Conventional and Integrated Aqueous Two-Phase Systems. J Braz Chem Soc. 2010; 21(5): 921-926.

[2] Bailey JE, Ollis DF. Biochemical Engineering Fundamentals. 2nd ed., Singapore: McGraw-Hill; 1986.

[3] Becker W. Microalgal in human and animal nutrition, In: Richmond, A. (ed) Handbook of Microalgal Culture: biotechnology and applied phycology. London: Blackwell Science; 2004. p. 312-351.

[4] Benito Y, Ruiz M, Cosmen P, Merino JL. Study of leaches obtained from the disposal of fly ash from PFBC and AFBC processes. J Chem Eng. 2001; 84: 167-171.

[5] Burgstaller W, Schinner F. Leaching of metals with fungi. J Biotechnol. 1993; 27: 91-116.

[6] Colla LM, Reinehr CO, Reichert C, Costa JAV. Production of biomass and nutraceutical compounds by Spirulina platensis under different temperature and nitrogen regimes. Bioresour Technol. 2007; 98(7): 1489-1493.

[7] Costa JAV, Colla LM, Duarte Filho P, Kabke K. Modelling or Spirulina platensis growth in fresh water using response surface methodology. World J Microbiol Biotechnol. 2002; 18(7): 603-607.

[8] Ctvrtnickova T, Mateo MP, Yañez A, Nicolas G. Characterization of coal fly ash components by laser-induced breakdown spectroscopy. Spectrochim Acta Part B. 2009; 64: 1093-1097.

[9] Depoi FS, Pozebon D, Kalkreuth WD. Chemical characterization of feed coals and combustion-by-products from Brazilian power plants. Int J Coal Geol. 2008; 76: 227-236.

[10] ELETROBRAS CGTEE. <http://www.cgtee.gov.br/> Accessed in November 15th 2013.
» http://www.cgtee.gov.br/

[11] Flues M, Sato IM, Scapin MA, Cotrim MEB, Camargo IMC. Toxic elements mobility in coal and ashes of Figueira coal power plant, Brazil. Fuel. 2013; 103: 430-436.

[12] Gadd GM. Microbial influence on metal mobility and application for bioremediation. Geoderma. 2004;a: 109-119.

[13] Kirk JTO. Light and Photosynthesis in Aquatic Ecosystems. Camberra: Cambridge University Press; 1994.

[14] Lodi A, Soletto D, Solisio C, Converti A. Chromium (III) removal by Spirulina platensis biomass. Chem Eng J. 2008; 136: 151-155.

[15] Lourenço SO. Cultivo de microalgas marinhas: princípios e aplicações. São Carlos: RIMA; 2006.

[16] Morais MG, Costa JAV. Isolation and selection of microalgae from coal fired thermoelectric power plant for biofixation of carbon dioxide. Energ Convers Manage. 2007; 48: 2169-2173.

[17] Morais MG, Reichert CC, Dalcaton F, Durante AJ, Marins LFF, Costa JAV. Isolation and caracterization of a new Arthrospira strain. Z Naturforsch C. 2008; 63c: 144-150.

[18] Pane L, Solisio C, Lodi A, Mariottini GL, Converti A. Effect of extracts from Spirulina platensis bioaccumulating cádmium and zinc on L929 cells. Ecotoxicol and Environ Saf. 2008; 70: 121-126.

[19] Pires M, Queirol X. Characterization of Candiota (South Brazil) coal and combustion by-product. Int J Coal Geol. 2004; 60: 57-72.

[20] Radmann EM, Reinehr CO, Costa JAV. Optimization of the repeated batch cultivation of microalga Spirulina platensis in open raceway ponds. Aquaculture. 2007; 265: 118-126.

[21] Reichert CC, Reinehr CO, Costa JAV. Semicontinuous cultivation of the cyanobacterium Spirulina platensis in a closed photobioreactor. Braz J Chem Eng. 2006; 23: 23-28.

[22] Rippka R, Deruelles J, Waterbury JW, Herdman M, Stanier RG. Genetic assignments, strain histories and properties of pure cultures of Cyanobacteria. J Gen Microbiol. 1979; 111: 1-61.

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Components	Composition
Major elements (%)
SiO₂	Composition	65,8
Al₂O₃	21,5
Fe₂O₃	4,6
TiO₂	0,7
P₂O₅	<0,03
CaO	1,8
MgO	0,8
Na₂O	0,1
K₂O	1,9
SO₃	1,4
loss on ignition	1,4
Trace elements (mg kg^-1)
Co	1,4	18,0
Cr	68,8
Cu	31,5
Mn	183,0
Ni	12,5
Zn	103,8

Ash concentration(ppm)	X_{máx (}g L^-1)	P_{máx (}g L^-1d^-1)	µ_{máx (}d^-1)
Spirulina sp. LEB 18
0	X_{máx (}g L^-1)	P_{máx (}g L^-1d^-1)	µ_{máx (}d^-1)	0.51±0.03^a	0.03±0^a	0.07±0^a
40	0.56±0.09^a	0.03±0^a	0.08±0.01^a
80	0.56±0.03^a	0.03±0^a	0.07±0^a
120	0.64±0.01^a	0.04±0^a	0.10±0.01^a
Chlorella fusca LEB 111
0	0.64±0.01^a	0.04±0^a	0.10±0.01^a	0.58±0.06^a	0.03±0.01ª	0.09±0.01^a
40	0.54±0.05^a	0.03±0.01^a	0.08±0.01^a
80	0.52±0.05^a	0.03±0^a	0.07±0.01^a
120	0.43±0.01^a	0.02±0^a	0.05±0.01^b