Investigation of sorption of lead ion from simulated body fluid solution by nanocrystalline Ca-deficient carbonated hydroxyapatite
Abstract
The aim of the paper was investigation of sorption process of nanocrystalline calcium-deficient
carbonated hydroxyapatite (CHA) for heavy metal ions on the example of Pb2+. Sorption of Pb2+ ions was
investigated in simulated body fluid solution at pH 5.5 (bone resorption) and pH 7.4 (bone formation). The
prepared samples CHA were characterized using scanning electron microscopy (SEM), method BrunauerEmmett-Teller
(BET), X-ray diffraction (XRD) and Fourier transform infrared spectroscopy (FT-IR). Total
concentration Pb2+ in the clear separated supernatant was determined by inversion voltammetry method. The
maximum Pb2+ sorption capacities of these samples CHA were determined, using a linearized Langmuir
model applied to batch sorption data collected at time of 48 h. XRD and FT-IR were used to identify the
materials present in the solid phase after sorption.
The synthesized CHA showed an excellent sorption capacity for Pb2+ ions. The maximum Pb2+
sorption capacities of CHA from model solution at pH 5.5 add up to 588 mg/g, from model solution at pH 7.4
Доан Ван Дат и др. / Сорбционные и хроматографические процессы. 2015. Т. 15. Вып. 2
270
add up to 1724 mg/g. Examination of solid phase after sorption indicated that a new crystalline phase of
hydroxylpyromorphite was formed in the sorption process. The character of changing the significance and
sign of zeta-potential of the synthesized CHA in dependence on the pH and extent of calcium deficiency in
the structure CHA was also investigated. It was concluded that the mechanism of sorption of Pb2+ ions on
CHA at pH 5.5 occurs mainly by the isomorphic substitution of Ca2+ ions into ions Pb2+
.
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References
On the mineral in collagen of human crown
dentine, Biomaterials, 2010, Vol. 31, pp.
5479-5490.
2.Vallet-Regí M., González-Calbet J.M
Calcium phosphates as substitution of bone
tissues, Progress in Solid State Chemistry,
2004, Vol. 32, pp. 1-31.
3.Suchanek W., Yoshimura M Processing
and properties of hydroxyapatite-based
biomaterials for use as hard tissue replacement
implants, Journal of Materials Research, 1998,
Vol. 13, no 1, pp. 94-117.
4.Moayyeri N., Saeb K., Biazar E. Removal
of heavy metals (lead, cadmium, zinc, nickel
and iron) from water by bio-ceramic absorbers
of hydroxyapatite microparticles, Journal of
Marine Science and Engineering, 2013, Vol.
3, no 1, pp. 13-16.
5.Donga L., Zhu Z., Qiu Y. et al. Removal
of lead from aqueous solution by
hydroxyapatite magnetite composite
adsorbent, Chemical Engineering Journal,
2010, Vol. 165, pp. 827-834.
6.Corami A., Mignardi S., Ferrini V. Copper
and zinc decontamination from single- and
binary-metal solutions using hydroxyapatite,
Journal of Hazardous Materials, 2007, vol.
146, pp.164-170.
7.Abdel-Gawad E.I., Awwad S.A. In-vivo
and in-vitro prediction of the efficiency of
Nano-Synthesized Material in Removal of
Lead Nitrate Toxicity, Journal of American
Science, 2011, Vol. 7, No 1, pp. 105-119.
Доан Ван Дат и др. / Сорбционные и хроматографические процессы. 2015. Т. 15. Вып. 2
279
8.Takeuchi Y., Susuki T., Arai H. A study
of equilibrium and mass transfer in processes
for removal of heavy metal ions by
hydroxyapatite, Journal of Chemical
Engineering of Japan, 1998, Vol. 21, No 1, pp.
98-100.
9.Mavropoulos E., Rossi A.M., Costa A.M.
et al. Studies on the mechanisms of lead
immobilization by hydroxyapatite,
Environmental Science and Technology, 2002,
Vol. 36, pp. 1625-1629.
10. Ma Q.Y., Traina S.J., Logan T.J. et al.
In situ lead immobilization by apatite,
Environmental Science and Technology, 1993,
Vol. 27, pp. 1803-1810.
11. Corami A., Mignardi S., Ferrini V.
Cadmium removal from single- and multimetal
(Cd+Pb+Zn+Cu) solutions by sorption
on hydroxyapatite // Journal of Colloid and
Interface Science, 2008, vol. 317, pp. 402-408.
12. Trubitsyn M.A., Gabruk N.G., Le V.T.
et al. The Comparative Characteristic of
Physical, Chemical and Bioactive Properties
of the Synthesized Hydroxyapatites, Global
Journal of Pharmacology, 2013, Vol. 7, No 3,
pp. 342-347.
13. Masakazu N., Koudai N., Kenji A.
Removal of Lead from Contaminated Soils
with Chelating Agents Materials Transactions,
2008, Vol. 49, No 10, pp. 2377-2382.
14. Belatik A., Hotchandani S., Carpentier
R. et al. Locating the binding sites of Pb(II)
ion with human and bovine serum albumins,
PLoS ONE, 2012, Vol. 7, No 5, pp. 36723.
DOI: 10.1371/journal.pone.0036723 available
at http://journals.plos.org/.
15. Safronova T.V., Putlyaev V.I.
Meditsinskoe neorganicheskoe
materialovedenie v Rossii: kal'tsiifosfatnye
materialy, Nanosistemy: fizika, khimiya,
matematika, 2013, Vol. 4, No 1, pp. 24-47.
16. Shraibman G.N., Serebrennikova N.V.,
Khalfina P.D. et al. Vol'tamperometricheskie
metody analiza. Kemerovo, KemGU Publ.,
2004, 31 p.
17. Kel'tsev N.V. Osnovy adsorbtsionnoi
tekhniki. Moskva, Khimiya Publ., 1984, 592
p.
18. Mikheeva E.V., Pikula N.P. Opredelenie
elektrokineticheskogo potentsiala metodom
elektroforeza. Tomsk, TPU Publ., 2009, 16 p.
19. Gorelik S.S., Skakov Yu.A., Rastorguev
L.N. Rentgenograficheskii i elektronnoopticheskii
analiz. Moskva, MISIS Publ.,
2002, 360 p.
20. Fridrikhsberg D.A. Kurs kolloidnoi
khimii. Leningrad, Khimiya Publ., 1984, 368
p.
21. Kiseleva D.V. . Osobennosti struktury
neorganicheskoi komponenty iskopaemykh i
sovremennykh kostnykh ostatkov po dannym
ik-spektroskopii i mikroskopii, Ezhegodnik
2008 IGG UrO RAN, 2009, No 156, pp. 312-
317.
