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Characteristics and performance of Cd, Ni, and Pb bio-adsorption using Callinectes sapidus biomass: real wastewater treatment

  • Rauf Foroutan
  • Reza Mohammadi
  • Sima Farjadfard
  • Hossein Esmaeili
  • Maryam Saberi
  • Soleyman SahebiEmail author
  • Sina Dobaradaran
  • Bahman RamavandiEmail author
Research Article
  • 26 Downloads

Abstract

In the current study, the bio-adsorption potential of Callinectes sapidus biomass for control of cadmium, nickel, and lead from the aqueous stream was assessed. Spectrum analysis of FTIR, AFM, EDAX, mapping, SEM, TEM, and XRF was used to study the properties of the C. sapidus biomass. The XRF analysis revealed that C. sapidus bio-adsorbent has various effective metal oxides that can be useful to adsorb pollutants. The best model to describe the equilibrium data was Freundlich isotherm. The Langmuir bio-adsorption capacity was reported at 31.44 mg g−1, 29.23 mg g−1, and 29.15 mg g−1 for lead, cadmium, and nickel ions, respectively. Pseudo-first-order and pseudo-second-order kinetic models were studied to test the kinetic behavior of the process. An intra-particle diffusion model was used to determine the effective mechanisms involved in the bio-adsorption. Based on t1/2, it can be concluded that the equilibrium speed of the bio-adsorption process is high. The thermodynamic study showed that the metal bio-adsorption process using C. sapidus biomass is exothermic and spontaneous. The field applicability of the crab bio-adsorbent for eliminating concurrently several contaminants (metal ions, antibiotics, sulfate, nitrate, and ammonium) from an actual wastewater was successfully examined.

Keywords

Callinectes sapidus Heavy metals Kinetic study Aqueous stream Antibiotic Hospital wastewater 

Notes

Acknowledgements

The authors acknowledge the University of Tabriz for financial support (grant no. Tab-132-96) and Bushehr University of Medical Sciences for technical support to conduct this work.

Compliance with ethical standards

Declarations of interest

None.

Supplementary material

11356_2018_4108_MOESM1_ESM.docx (63 kb)
ESM 1 (DOCX 63 kb)

References

  1. Ahmad M, Usman AR, Lee SS, Kim S-C, Joo J-H, Yang JE, Ok YS (2012) Eggshell and coral wastes as low cost sorbents for the removal of Pb2+, Cd2+ and Cu2+ from aqueous solutions. J Ind Eng Chem 18(1):198–204Google Scholar
  2. Ahmadi M, Kouhgardi E, Ramavandi B (2016) Physico-chemical study of dew melon peel biochar for chromium attenuation from simulated and actual wastewaters. Korean J Chem Eng 33(9):2589–2601.  https://doi.org/10.1007/s11814-016-0135-1 Google Scholar
  3. Ahmadi M, Foladivanda M, Jaafarzadeh N, Ramezani Z, Ramavandi B, Jorfi S, Kakavandi B (2017) Synthesis of chitosan zero-valent iron nanoparticles-supported for cadmium removal: characterization, optimization and modeling approach. J Water Supply Res T 66:116–130Google Scholar
  4. Amarasinghe B, Williams R (2007) Tea waste as a low cost adsorbent for the removal of Cu and Pb from wastewater. Chem Eng J 132(1–3):299–309Google Scholar
  5. Anayurt RA, Sari A, Tuzen M (2009) Equilibrium, thermodynamic and kinetic studies on biosorption of Pb (II) and Cd (II) from aqueous solution by macrofungus (Lactarius scrobiculatus) biomass. Chem Eng J 151(1–3):255–261Google Scholar
  6. Arim AL, Guzzo G, Quina MJ, Gando-Ferreira LM (2018) Single and binary sorption of Cr(III) and Ni(II) onto modified pine bark. Environ Sci Pollut Res 25(28):28039–28049.  https://doi.org/10.1007/s11356-018-2843-z Google Scholar
  7. Baron RD, Pérez LL, Salcedo JM, Córdoba LP, do Amaral Sobral PJ (2017) Production and characterization of films based on blends of chitosan from blue crab (Callinectes sapidus) waste and pectin from orange (Citrus sinensis Osbeck) peel. Int J Biol Macromol 98:676–683Google Scholar
  8. Barros AJM, Prasad S, Leite VD, Souza AG (2007) Biosorption of heavy metals in upflow sludge columns. Bioresour Technol 98(7):1418–1425Google Scholar
  9. Birungi Z, Chirwa E (2015) The adsorption potential and recovery of thallium using green micro-algae from eutrophic water sources. J Hazard Mater 299:67–77Google Scholar
  10. Castillo-Araiza CO, Che-Galicia G, Dutta A, Guzmán-González G, Martínez-Vera C, Ruíz-Martínez RS (2015) Effect of diffusion on the conceptual design of a fixed-bed adsorber. Fuel 149:100–108.  https://doi.org/10.1016/j.fuel.2014.09.023 Google Scholar
  11. Clesceri LS, Greenberg AE, Eaton AD (1998) Standard methods for the examination of water and wastewater, 20th edn. APHA American Public Health Association, Washington, D.C.Google Scholar
  12. de Sousa DNR, Insa S, Mozeto AA, Petrovic M, Chaves TF, Fadini PS (2018) Equilibrium and kinetic studies of the adsorption of antibiotics from aqueous solutions onto powdered zeolites. Chemosphere 205:137–146Google Scholar
  13. Fawzy M, Nasr M, Adel S, Nagy H, Helmi S (2016) Environmental approach and artificial intelligence for Ni(II) and Cd(II) biosorption from aqueous solution using Typha domingensis biomass. Ecol Eng 95:743–752Google Scholar
  14. Foroutan R, Esmaeili H, Abbasi M, Rezakazemi M, Mesbah M (2017a) Adsorption behavior of Cu (II) and Co (II) using chemically modified marine algae. Environ Technol:1–9 In pressGoogle Scholar
  15. Foroutan R, Esmaeili H, Rishehri SD, Sadeghzadeh F, Mirahmadi S, Kosarifard M, Ramavandi B (2017b) Zinc, nickel, and cobalt ions removal from aqueous solution and plating plant wastewater by modified Aspergillus flavus biomass: a dataset. Data Brief 12:485–492Google Scholar
  16. Foroutan R, Mohammadi R, Ramavandi B (2018) Treatment of chromium-laden aqueous solution using CaCl2-modified Sargassum oligocystum biomass: characteristics, equilibrium, kinetic, and thermodynamic studies. Korean J Chem Eng 35(1):234–245Google Scholar
  17. Franus M, Bandura L (2014) Sorption of heavy metal ions from aqueous solution by glauconite. Fresenius Environ Bull 23(3a):825–839Google Scholar
  18. Gogoi D, Shanmugamani A, Rao S, Kumar T, Sinha P (2013) Studies on removal of cobalt from an alkaline waste using synthetic calcium hydroxyapatite. J Radioanal Nucl Chem 298(1):337–344Google Scholar
  19. Gruszecka-Kosowska A, Baran P, Wdowin M, Franus W (2017) Waste dolomite powder as an adsorbent of Cd, Pb (II), and Zn from aqueous solutions. Environ Earth Sci 76(15):521Google Scholar
  20. Kafaei R, Papari F, Seyedabadi M, Sahebi S, Tahmasebi R, Ahmadi M, Sorial GA, Asgari G, Ramavandi B (2018) Occurrence, distribution, and potential sources of antibiotics pollution in the water-sediment of the northern coastline of the Persian Gulf, Iran. Sci Total Environ 627:703–712Google Scholar
  21. Kalhori EM, Yetilmezsoy K, Uygur N, Zarrabi M, Shmeis RMA (2013) Modeling of adsorption of toxic chromium on natural and surface modified lightweight expanded clay aggregate (LECA). Appl Surf Sci 287:428–442Google Scholar
  22. Kamble SP, Jagtap S, Labhsetwar NK, Thakare D, Godfrey S, Devotta S, Rayalu SS (2007) Defluoridation of drinking water using chitin, chitosan and lanthanum-modified chitosan. Chem Eng J 129(1–3):173–180Google Scholar
  23. Karthikeyan S, Balasubramanian R, Iyer C (2007) Evaluation of the marine algae Ulva fasciata and Sargassum sp. for the biosorption of Cu (II) from aqueous solutions. Bioresour Technol 98(2):452–455Google Scholar
  24. Kyzioł-Komosińska J, Rosik-Dulewska C, Franus M, Antoszczyszyn-Szpicka P, Czupiol J, Krzyzewska I (2015) Sorption capacities of natural and synthetic zeolites for Cu (II) ions. Pol J Environ Stud 24(3):1111–1123Google Scholar
  25. Li D, Zhou L (2018) Adsorption of heavy metal tolerance strains to Pb2+ and Cd2+ in wastewater. Environ Sci Pollut Res 25:32156–32162.  https://doi.org/10.1007/s11356-018-2988-9 Google Scholar
  26. Long J, Gao X, Su M, Li H, Chen D, Zhou S (2018) Performance and mechanism of biosorption of nickel(II) from aqueous solution by non-living Streptomyces roseorubens SY. Colloids Surf A Physicochem Eng Asp 548:125–133.  https://doi.org/10.1016/j.colsurfa.2018.03.040 Google Scholar
  27. Mahmoud ME, Hassan SS, Kamel AH, Elserw MI (2018) Fast microwave-assisted sorption of heavy metals on the surface of nanosilica-functionalized-glycine and reduced glutathione. Bioresour Technol 264:228–237Google Scholar
  28. Masoumi A, Hemmati K, Ghaemy M (2016) Low-cost nanoparticles sorbent from modified rice husk and a copolymer for efficient removal of Pb (II) and crystal violet from water. Chemosphere 146:253–262Google Scholar
  29. Milonjić SK (2007) A consideration of the correct calculation of thermodynamic parameters of adsorption. J Serb Chem Soc 72(12):1363–1367Google Scholar
  30. Mohan D, Singh KP (2002) Single-and multi-component adsorption of cadmium and zinc using activated carbon derived from bagasse—an agricultural waste. Water Res 36(9):2304–2318Google Scholar
  31. Naeimi B, Foroutan R, Ahmadi B, Sadeghzadeh F, Ramavandi B (2018) Pb (II) and Cd (II) removal from aqueous solution, shipyard wastewater, and landfill leachate by modified Rhizopus oryzae biomass. Mater Res Exp 5(4):045501Google Scholar
  32. Nagy B, Szilagyi B, Majdik C, Katona G, Indolean C, Măicăneanu A (2014) Cd (II) and Zn (II) biosorption on Lactarius piperatus macrofungus: equilibrium isotherm and kinetic studies. Environ Prog Sustain Energy 33(4):1158–1170.  https://doi.org/10.1002/ep.11897 Google Scholar
  33. Pehlivan E, Altun T, Parlayici Ş (2012) Modified barley straw as a potential biosorbent for removal of copper ions from aqueous solution. Food Chem 135(4):2229–2234Google Scholar
  34. Peng W, Li H, Liu Y, Song S (2016) Adsorption of methylene blue on graphene oxide prepared from amorphous graphite: effects of pH and foreign ions. J Mol Liq 221:82–87Google Scholar
  35. Petrella A, Spasiano D, Acquafredda P, De Vietro N, Ranieri E, Cosma P, Rizzi V, Petruzzelli V, Petruzzelli D (2018) Heavy metals retention (Pb(II), Cd(II), Ni(II)) from single and multimetal solutions by natural biosorbents from the olive oil milling operations. Process Saf Environ Prot 114:79–90.  https://doi.org/10.1016/j.psep.2017.12.010 Google Scholar
  36. Rafatullah M, Sulaiman O, Hashim R, Ahmad A (2009) Adsorption of copper (II), chromium (III), nickel (II) and lead (II) ions from aqueous solutions by meranti sawdust. J Hazard Mater 170(2–3):969–977Google Scholar
  37. Saber M, Takahashi F, Yoshikawa K (2018) Characterization and application of microalgae hydrochar as a low-cost adsorbent for Cu(II) ion removal from aqueous solutions. Environ Sci Pollut Res 25:32721–32734.  https://doi.org/10.1007/s11356-018-3106-8 Google Scholar
  38. Safari M, Ramavandi B, Sanati AM, Sorial GA, Hashemi S, Tahmasebi S (2018) Potential of trees leaf/bark to control atmospheric metals in a gas and petrochemical zone. J Environ Manag 222:12–20Google Scholar
  39. Salem A, Velayi E (2012) Application of hydroxyapatite and cement kiln dust mixture in adsorption of lead ions from aqueous solution. J Ind Eng Chem 18(4):1216–1222Google Scholar
  40. Sarı A, Tuzen M (2009) Kinetic and equilibrium studies of biosorption of Pb (II) and Cd (II) from aqueous solution by macrofungus (Amanita rubescens) biomass. J Hazard Mater 164(2–3):1004–1011Google Scholar
  41. Sari A, Mendil D, Tuzen M, Soylak M (2008) Biosorption of Cd (II) and Cr (III) from aqueous solution by moss (Hylocomium splendens) biomass: equilibrium, kinetic and thermodynamic studies. Chem Eng J 144(1):1–9Google Scholar
  42. Teimouri A, Esmaeili H, Foroutan R, Ramavandi B (2017) Adsorptive performance of calcined Cardita bicolor for attenuating Hg (II) and As (III) from synthetic and real wastewaters. Korean J Chem Eng 35(2):479–488Google Scholar
  43. Tran NH, Chen H, Reinhard M, Mao F, Gin KY-H (2016) Occurrence and removal of multiple classes of antibiotics and antimicrobial agents in biological wastewater treatment processes. Water Res 104:461–472Google Scholar
  44. Venkateswarlu S, Kumar SH, Jyothi N (2015) Rapid removal of Ni (II) from aqueous solution using 3-mercaptopropionic acid functionalized bio magnetite nanoparticles. Water Res Ind 12:1–7Google Scholar
  45. Watkinson A, Murby E, Costanzo S (2007) Removal of antibiotics in conventional and advanced wastewater treatment: implications for environmental discharge and wastewater recycling. Water Res 41(18):4164–4176Google Scholar
  46. Yadav SK, Singh DK, Sinha S (2014) Chemical carbonization of papaya seed originated charcoals for sorption of Pb (II) from aqueous solution. J Environ Chem Eng 2(1):9–19Google Scholar
  47. Zheng J-C, Liu H-Q, Feng H-M, Li W-W, Lam MH-W, Lam PK-S, Yu H-Q (2016) Competitive sorption of heavy metals by water hyacinth roots. Environ Pollut 219:837–845Google Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019

Authors and Affiliations

  1. 1.Young Researchers and Elite Club, Bushehr BranchIslamic Azad UniversityBushehrIran
  2. 2.Polymer Research Laboratory, Department of Organic and Biochemistry, Faculty of ChemistryUniversity of TabrizTabrizIran
  3. 3.Department of Environmental Engineering, Graduate School of the Environment and Energy, Science and Research BranchIslamic Azad UniversityTehranIran
  4. 4.Department of Chemical Engineering, Bushehr BranchIslamic Azad UniversityBushehrIran
  5. 5.Department for Management of Science and Technology DevelopmentTon Duc Thang UniversityHo Chi Minh CityVietnam
  6. 6.Faculty of Environment and Labor SafetyTon Duc Thang UniversityHo Chi Minh CityVietnam
  7. 7.Systems Environmental Health and Energy Research Center, The Persian Gulf Biomedical Sciences Research InstituteBushehr University of Medical SciencesBushehrIran
  8. 8.Department of Environmental Health Engineering, Faculty of HealthBushehr University of Medical SciencesBushehrIran
  9. 9.The Persian Gulf Marine Biotechnology Research Center, The Persian Gulf Biomedical Sciences Research InstituteBushehr University of Medical SciencesBushehrIran

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