Uptake of Sr2+ and Co2+ into Biogenic Hydroxyapatite: Implications for Biomineral Ion Exchange Synthesis

Stephanie Handley-Sidhu; Joanna Renshaw; S Moriyama; Bjorn Stolpe; C Mennan; S Bagheriasl; P Yong; Artemis Stamboulis; Marion Paterson-Beedle; K Sasaki; RAD Pattrick; Jamie Lead; Lynne Macaskie

doi:10.1021/es2015132

Uptake of Sr2+ and Co2+ into Biogenic Hydroxyapatite: Implications for Biomineral Ion Exchange Synthesis

Stephanie Handley-Sidhu, Joanna Renshaw, S Moriyama, Bjorn Stolpe, C Mennan, S Bagheriasl, P Yong, Artemis Stamboulis, Marion Paterson-Beedle, K Sasaki, RAD Pattrick, Jamie Lead, Lynne Macaskie

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Abstract

Biomineral hydroxyapatite (Bio-HAp) produced by Serratia sp. has the potential to be a suitable material for the remediation of metal contaminated waters and as a radionuclide waste storage material. Varying the Bio-HAp manufacturing method was found to influence hydroxyapatite (HAp) properties and consequently the uptake of Sr2+ and Co2+. All the Bio-HAp tested in this study were more efficient than the commercially available hydroxyapatite (Com-HAp) for Sr2+ and Co2+ uptake. For Bio-HAp the uptake for Sr+2 and Co2+ ranged from 24 to 39 and 29 to 78 mmol per 100 g, respectively. Whereas, the uptake of Sr2+ and Co2+ by Com-HAp ranged from 3 to 11 and 4 to 18 mmol per 100 g, respectively. Properties that increased metal uptake were smaller crystallite size (70 m(2) g(-1)). Organic content which influences the structure (e.g., crystallite arrangement, size and surface area) and composition of Bio-HAp was also found to be important in Sr2+ and Co2+ uptake. Overall, Bio-HAp shows promise for the remediation of aqueous metal waste especially since Bio-HAp can be synthesized for optimal metal uptake properties.

Original language	English
Pages (from-to)	6985-6990
Number of pages	6
Journal	Environmental Science & Technology
Volume	45
Issue number	16
DOIs	https://doi.org/10.1021/es2015132
Publication status	Published - 1 Aug 2011

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10.1021/es2015132

Novel MR Selective Imaging of Transport and Growth in Biofilms
Macaskie, L.
Engineering & Physical Science Research Council
1/01/07 → 31/12/09
Project: Research Councils

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Handley-Sidhu, S., Renshaw, J., Moriyama, S., Stolpe, B., Mennan, C., Bagheriasl, S., Yong, P., Stamboulis, A., Paterson-Beedle, M., Sasaki, K., Pattrick, RAD., Lead, J., & Macaskie, L. (2011). Uptake of Sr2+ and Co2+ into Biogenic Hydroxyapatite: Implications for Biomineral Ion Exchange Synthesis. Environmental Science & Technology, 45(16), 6985-6990. https://doi.org/10.1021/es2015132

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title = "Uptake of Sr2+ and Co2+ into Biogenic Hydroxyapatite: Implications for Biomineral Ion Exchange Synthesis",

abstract = "Biomineral hydroxyapatite (Bio-HAp) produced by Serratia sp. has the potential to be a suitable material for the remediation of metal contaminated waters and as a radionuclide waste storage material. Varying the Bio-HAp manufacturing method was found to influence hydroxyapatite (HAp) properties and consequently the uptake of Sr2+ and Co2+. All the Bio-HAp tested in this study were more efficient than the commercially available hydroxyapatite (Com-HAp) for Sr2+ and Co2+ uptake. For Bio-HAp the uptake for Sr+2 and Co2+ ranged from 24 to 39 and 29 to 78 mmol per 100 g, respectively. Whereas, the uptake of Sr2+ and Co2+ by Com-HAp ranged from 3 to 11 and 4 to 18 mmol per 100 g, respectively. Properties that increased metal uptake were smaller crystallite size (70 m(2) g(-1)). Organic content which influences the structure (e.g., crystallite arrangement, size and surface area) and composition of Bio-HAp was also found to be important in Sr2+ and Co2+ uptake. Overall, Bio-HAp shows promise for the remediation of aqueous metal waste especially since Bio-HAp can be synthesized for optimal metal uptake properties.",

author = "Stephanie Handley-Sidhu and Joanna Renshaw and S Moriyama and Bjorn Stolpe and C Mennan and S Bagheriasl and P Yong and Artemis Stamboulis and Marion Paterson-Beedle and K Sasaki and RAD Pattrick and Jamie Lead and Lynne Macaskie",

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doi = "10.1021/es2015132",

language = "English",

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Handley-Sidhu, S, Renshaw, J, Moriyama, S, Stolpe, B, Mennan, C, Bagheriasl, S, Yong, P, Stamboulis, A, Paterson-Beedle, M, Sasaki, K, Pattrick, RAD, Lead, J & Macaskie, L 2011, 'Uptake of Sr2+ and Co2+ into Biogenic Hydroxyapatite: Implications for Biomineral Ion Exchange Synthesis', Environmental Science & Technology, vol. 45, no. 16, pp. 6985-6990. https://doi.org/10.1021/es2015132

TY - JOUR

T1 - Uptake of Sr2+ and Co2+ into Biogenic Hydroxyapatite: Implications for Biomineral Ion Exchange Synthesis

AU - Handley-Sidhu, Stephanie

AU - Renshaw, Joanna

AU - Moriyama, S

AU - Stolpe, Bjorn

AU - Mennan, C

AU - Bagheriasl, S

AU - Yong, P

AU - Stamboulis, Artemis

AU - Paterson-Beedle, Marion

AU - Sasaki, K

AU - Pattrick, RAD

AU - Lead, Jamie

AU - Macaskie, Lynne

PY - 2011/8/1

Y1 - 2011/8/1

N2 - Biomineral hydroxyapatite (Bio-HAp) produced by Serratia sp. has the potential to be a suitable material for the remediation of metal contaminated waters and as a radionuclide waste storage material. Varying the Bio-HAp manufacturing method was found to influence hydroxyapatite (HAp) properties and consequently the uptake of Sr2+ and Co2+. All the Bio-HAp tested in this study were more efficient than the commercially available hydroxyapatite (Com-HAp) for Sr2+ and Co2+ uptake. For Bio-HAp the uptake for Sr+2 and Co2+ ranged from 24 to 39 and 29 to 78 mmol per 100 g, respectively. Whereas, the uptake of Sr2+ and Co2+ by Com-HAp ranged from 3 to 11 and 4 to 18 mmol per 100 g, respectively. Properties that increased metal uptake were smaller crystallite size (70 m(2) g(-1)). Organic content which influences the structure (e.g., crystallite arrangement, size and surface area) and composition of Bio-HAp was also found to be important in Sr2+ and Co2+ uptake. Overall, Bio-HAp shows promise for the remediation of aqueous metal waste especially since Bio-HAp can be synthesized for optimal metal uptake properties.

AB - Biomineral hydroxyapatite (Bio-HAp) produced by Serratia sp. has the potential to be a suitable material for the remediation of metal contaminated waters and as a radionuclide waste storage material. Varying the Bio-HAp manufacturing method was found to influence hydroxyapatite (HAp) properties and consequently the uptake of Sr2+ and Co2+. All the Bio-HAp tested in this study were more efficient than the commercially available hydroxyapatite (Com-HAp) for Sr2+ and Co2+ uptake. For Bio-HAp the uptake for Sr+2 and Co2+ ranged from 24 to 39 and 29 to 78 mmol per 100 g, respectively. Whereas, the uptake of Sr2+ and Co2+ by Com-HAp ranged from 3 to 11 and 4 to 18 mmol per 100 g, respectively. Properties that increased metal uptake were smaller crystallite size (70 m(2) g(-1)). Organic content which influences the structure (e.g., crystallite arrangement, size and surface area) and composition of Bio-HAp was also found to be important in Sr2+ and Co2+ uptake. Overall, Bio-HAp shows promise for the remediation of aqueous metal waste especially since Bio-HAp can be synthesized for optimal metal uptake properties.

U2 - 10.1021/es2015132

DO - 10.1021/es2015132

M3 - Article

C2 - 21714547

SN - 1520-5851

VL - 45

SP - 6985

EP - 6990

JO - Environmental Science & Technology

JF - Environmental Science & Technology

IS - 16

ER -

Uptake of Sr2+ and Co2+ into Biogenic Hydroxyapatite: Implications for Biomineral Ion Exchange Synthesis

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Novel MR Selective Imaging of Transport and Growth in Biofilms

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