Ostrich Eggshell as an Alternative Source of Calcium Ions for Biomaterials Synthesis

Caliman, Lorena Batista; Silva, Sidney Nicodemos da; Junkes, Janaína Accordi; Sagrillo, Viviana Possamai Della

doi:10.1590/1980-5373-MR-2016-0368

Abstract

Ostrich eggshells are a potentially abundant and a high purity and low cost source of calcium to produce β-Tricalcium Phosphate (β-TCP) and Hydroxyapatite (HA), important calcium phosphates used as biomaterials. Here, we use a wet precipitation procedure to synthesize these phosphates using ostrich eggshells as a source of calcium ions. The biphasic precipitated powder, calcined at 800ºC, is a mixture of both Hydroxyapatite and β-Tricalcium Phosphate, also known as the biomaterial Biphasic Calcium Phosphate (BCP). Physico-chemical properties of the final powder product show water and CO₃^2- groups absorbed in the particles surface, 0.1 to 100 µm particles size distribution and 11.70 m²/g of specific surface area.

Keywords:
Hydroxyapatite; β-TCP; biomaterials; ostrich eggshells; recycling

1. Introduction

Biomaterials are synthetic or natural materials used as replacement parts of a biologic system to play a certain role in contact with a living tissue. Calcium phosphates are important bioactive and bioresorbable biomaterials. A bioactive material will slowly dissolve when in contact with a living tissue, forming a layer of biological apatite before reaching the bone, and forming a direct bond to the bone. A reabsorbable material instead will dissolve and allow that a new tissue grows inside its irregularities cavities, not necessarily interacting with the bone. Dense hydroxyapatite is an example of a bioactive material while Biphasic Calcium Phosphate (a mixture of HA and β-TCP) porous scaffolds are bioresorbable materials. That is the reason why these two phosphates are the most used biomaterial in the medical field¹1 Ribeiro C. Obtenção e caracterização de biocerâmicas porosas à base de fosfato de cálcio processadas com a utilização de albumina. [Tese de doutorado]. São Paulo: Instituto de Pesquisas Energéticas e Nucleares (IPEN); 2008..

Hydroxyapatite (HA) is the inorganic component of teeth and bones and is the most popular calcium phosphate ceramic for medical use due to its excellent biocompatibility, good corrosion resistance and chemical stability. It is especially in demand as a biomaterial to restore bone defects²2 Petrov OE, Dyulgerova E, Petrov L, Popova R. Characterization of calcium phosphate phases obtained during the preparation of sintered biphase Ca-P ceramics. Materials Letters. 2001;48:(3-4):162-167.. Although other synthetic bone substitutes have been considered, the high costs and technological challenges involved in the engineering of biomaterials are frequently prohibitive³3 Dupoirieux L. Ostrich eggshell as a bone substitute: a preliminary report of its biological behaviour in animals - a possibility in facial reconstructive surgery. British Journal of Oral and Maxillofacial Surgery. 1999;37(6):467-471.. For this reason, HA remains the most frequent choice for bone replacement.

Wet chemical precipitation is the most commonly used procedure for HA synthesis due to its simplicity and easy large-scale application⁴4 Ahmed S, Ahsan M. Synthesis of Ca-hydroxyapatite Bioceramic from Egg Shell and its Characterization. Bangladesh Journal of Scientific and Industrial Research. 2008;43(4):501-512.. In this procedure the temperature of the liquid medium does not exceed 100ºC leading to the precipitation of nanometric crystals, with crystallinity and Ca/P ratio strongly dependent on preparation conditions⁵5 Suchanek W, Yoshimura M. Processing and properties of hydroxyapatite-based biomaterials for use as hard tissue replacement implants. Journal of Materials Research. 1998;13(1):94-117.. The total cost and effectiveness of this method strongly depends on the use of quality raw materials that act as a source of calcium and phosphorus precursors⁴4 Ahmed S, Ahsan M. Synthesis of Ca-hydroxyapatite Bioceramic from Egg Shell and its Characterization. Bangladesh Journal of Scientific and Industrial Research. 2008;43(4):501-512.. One potential low cost source material is eggshell, which can be harvested after hatching with virtually no environmental impacts.

Tricalcium phosphate (Ca₃(PO₄)₂) exits in two allotropic forms: α e β. Its Ca/P ratio is 1.5, slightly smaller the HA. β-TCP can not be precipitated from aqueous solutions, it is only prepared from the calcination of Ca-deficient HA or by solid state reactions⁶6 Dorozhkin SV. Calcium Orthophosphates in Nature, Biology and Medicine. Materials. 2009;2(2):399-498..

The physic-chemical properties of eggshells have attracted scientific interest as natural calcium sources for biodiesel production⁷7 Khemthong P, Luadthong C, Nualpaeng W, Changsuwan P, Tongprem P, Viriya-empikul N, et al. Industrial eggshell wastes as the heterogeneous catalysts for microwave-assisted biodiesel production. Catalysis Today. 2012;190(1):112-116. and Chen et al. (2014) recently utilized ostrich eggshells to produce heterogeneous solid catalysts⁸8 Chen G, Shan R, Shi J, Yan B. Ultrasonic-assisted production of biodiesel from transesterification of palm oil over ostrich eggshell-derived CaO catalysts. Bioresource Technology. 2014;171:428-432.. Eggshells of different bird species have similar chemical properties, being very rich in calcium carbonate CaCO₃. The largest egg of any living bird is that of the ostrich (Struthio camelus), with medium weight of 1.5 kg, a typical size of 16 × 12 cm and shell thickness of 2mm³3 Dupoirieux L. Ostrich eggshell as a bone substitute: a preliminary report of its biological behaviour in animals - a possibility in facial reconstructive surgery. British Journal of Oral and Maxillofacial Surgery. 1999;37(6):467-471.^,⁹9 Tan TH, Abdullah MO, Nolasco-Hipolito C, Taufiq-Yap YH. Waste ostrich- and chicken-eggshells as heterogeneous base catalyst for biodiesel production from used cooking oil: Catalyst characterization and biodiesel yield performance. Applied Energy. 2015;160:58-70. about 20-25 times bigger than a chicken egg. A good breeding group of ostriches produces eggs with a fertility rate of at least 90%. During the first laying season, females lay between 10 and 30 eggs with this rate later increasing to between 40 and 70 eggs. Moreover, when kept healthy and in good conditions they can remain productive for 25-35 years⁹9 Tan TH, Abdullah MO, Nolasco-Hipolito C, Taufiq-Yap YH. Waste ostrich- and chicken-eggshells as heterogeneous base catalyst for biodiesel production from used cooking oil: Catalyst characterization and biodiesel yield performance. Applied Energy. 2015;160:58-70..

Discarded eggshells are a potential environmental issue in poultry farming, since they can occupy an enormous volume and can harbor bacteria and fungi due to the high content of organic matter. The decomposition of this matter is a potential source of diseases in addition to the terrible smell it produces¹⁰10 Rivera EM, Araiza M, Brostow W, Castaño VM, Díaz-Estrada JR, Hernández R, et al. Synthesis of hydroxyapatite from eggshells. Materials Letters. 1999;41(3):128-134.. In this study it is described the production of Biphasic Calcium Phosphate from ostrich eggshells by a wet chemical procedure with the aim of producing a high quality product and reducing agricultural waste.

2. Material and Methods

2.1. Precipitation

Ostrich eggshells were washed and milled (Marconi, MA590) for 30 minutes and calcined (EDG, FI-PQ) at 800ºC for 3 hours to decompose organic matter and calcium carbonate. The 5.6g of the resulting powder was dissolved in distilled water (150 mL) in order to obtain a Ca(OH)₂ suspension.

Wet chemical precipitation aiming HA synthesis occurs through a reaction between phosphate anion and calcium salts or an acid-base reaction:

(1)

\begin{matrix} 10 Ca {(OH)}_{2 (aq)} + 6 H_{3} {({PO}_{4})}_{2 (aq)} \to \\ {Ca}_{10} {({PO}_{4})}_{6} {(OH)}_{2 (s)} + 18 H_{2} O \end{matrix}

The acid-base precipitation was carried out by stirring and heating (40ºC) the Ca(OH)₂ suspension, while 30 mL of a 2M solution of orthophosphoric acid was added, drop by drop (1mL/min). These quantities would result in a 1.67 Ca/P ratio phosphate. The pH value was maintained at 10 by adding small aliquot of NH₄OH solution periodically. The resulting precipitate was vigorously stirred (magnetic stirrer) and heated (40ºC) for 24 hours. After vacuum filtration and drying (100ºC/24h), it was calcined (EDG, FI-PQ) at 800ºC for 3 hours.

2.2 Characterization

The powder (precipitate) was characterized using specific surface area (SSA) measurements B.E.T. method (Micromeritics Gemini III 2375 Surface Area Analyzer and VacPrep 061 unit) and by X-ray diffraction (Philips X'Pert X-ray Diffractometer with Cu Kα radiation, 40 kV and 30 mA from 3 to 120º). The surface characteristics of the particles were determined by Fourier Transform Infrared Spectroscopy using the DRIFT accessory (Thermo-Nicolet - Magna 560 from 400 to 4000 cm^-1 and 4 cm^-1 resolution). Chemical composition was analyzed by Inductively Coupled Plasma - Atomic Emission Spectroscopy (ICP) (Thermo iCAP 6300 Duo), and powders images were obtained by Scanning Electron Microscope (Leica Cambridge, Stereoscan 440, Pt-Au coat). Particle size distribution was determined by a laser diffraction analyzer after ultrasound preparation (Mastersizer 2000).

3. Results and Discussion

The ostrich eggshells were crushed manually, then milled for 30 minutes and its composition was determined by XRD (Figure 1a). The only inorganic phase present was calcium carbonate (International Centre for Diffraction Data - ICDD, 86-2334). After calcination, the XRD (Figure 1b) analysis indicated that all the carbonate had decomposed into calcium oxide (ICDD, 37-1497). This was later dissolved in distilled water to prepare a calcium hydroxide suspension for the synthesis reaction.

Figure 1
XRD patterns: (a) Milled ostrich eggshell and (b) calcined powder.

The dried final powder obtained by precipitation was analyzed by XRD and the patterns matched with HA (ICDD, 9-432). No other phases were observed (Figure 2a).

Figure 2
(a) Precipitate powder and (b) calcined powder XRD patterns.

Nevertheless, two major differences were noticed after calcination (Figure 2b): crystallinity increase (peaks became longer and thinner), and a second phase apparition, identified as β-Tricalcium Phosphate − β-TCP (ICDD, 9-169). The appearance of this phase indicates that the precipitated powder was a calcium-deficient Hydroxyapatite (d-HA). Obtaining a calcium deficient HA is a common characteristic of the wet chemical precipitation, even in ideal conditions⁶6 Dorozhkin SV. Calcium Orthophosphates in Nature, Biology and Medicine. Materials. 2009;2(2):399-498..

The β-TCP appearance results from calcium-deficient HA instability above 700ºC. As previously reported¹¹11 Mortier A, Lemaitre J, Rouxhet PG. Temperature-programmed characterization of synthetic calcium-deficient phosphate apatites. Thermochimica Acta. 1989;143:265-282.

12 Mostafa NY. Characterization, thermal stability and sintering of hydroxyapatite powders prepared by different routes. Materials Chemistry and Physics. 2005;94(2-3):333-341.^-¹³13 Raynaud S, Champion E, Bernache-Assollant D, Laval JP. Determination of Calcium/Phosphorus Atomic Ratio of Calcium Phosphate Apatites Using X-ray Diffractometry. Journal of the American Ceramic Society. 2001;84(2):359-366., d-HA (Ca/P ratio between 1.5 and 1.67), when heated to temperatures higher than 700ºC, decomposes into a biphasic powder of stoichiometric HA and β-TCP. Indeed, Mortier et al.¹¹11 Mortier A, Lemaitre J, Rouxhet PG. Temperature-programmed characterization of synthetic calcium-deficient phosphate apatites. Thermochimica Acta. 1989;143:265-282. observed that d-HA (Ca₁₀_-x (HPO₄)_x (PO₄)₆_-x (OH)₂_-x0<x<1) phase transformations occur at different temperatures, as follows:

(I)

\begin{matrix} {Ca}_{10 - x} {({HPO}_{4})}_{x} {({PO}_{4})}_{6 - x} {(OH)}_{2 - x} \cdot {nH}_{2} O \\ < 250 ° C ↓ \end{matrix}

(II)

\begin{matrix} {Ca}_{10 - x} {({HPO}_{4})}_{x} {({PO}_{4})}_{6 - x} {(OH)}_{2 - x} \cdot {(H_{2} O)}_{x} + (n - x) H_{2} O \\ 250 - 700 ° C ↓ \end{matrix}

(III)

\begin{matrix} {Ca}_{10 - x} {(P_{2} O_{7})}_{x} {({PO}_{4})}_{6 - 2 x} {(OH)}_{x} \cdot {xH}_{2} O \\ 700 - 800 ° C ↓ \end{matrix}

(1 - x) {Ca}_{10} {({PO}_{4})}_{6} {(OH)}_{2} + 3 {xCa}_{3} {({PO}_{4})}_{2} + {xH}_{2} O

Stoichiometric HA is the major phase in the final powder. The phase proportion was determined by Rietveld refinement: HA represented 79.1%w and β-TCP 20.9%w. As soon as it was evidenciated that precipitated HA was slightly calcium deficient, a chemical analysis was performed to determine the Ca/P ratio (Table 1).

Thumbnail

Table 1
Chemical analysis.

Chemical analysis of precipitated HA by ICP OES resulted in a 1.60 Ca/P ratio, which is consistent with previous works¹¹11 Mortier A, Lemaitre J, Rouxhet PG. Temperature-programmed characterization of synthetic calcium-deficient phosphate apatites. Thermochimica Acta. 1989;143:265-282.

12 Mostafa NY. Characterization, thermal stability and sintering of hydroxyapatite powders prepared by different routes. Materials Chemistry and Physics. 2005;94(2-3):333-341.^-¹³13 Raynaud S, Champion E, Bernache-Assollant D, Laval JP. Determination of Calcium/Phosphorus Atomic Ratio of Calcium Phosphate Apatites Using X-ray Diffractometry. Journal of the American Ceramic Society. 2001;84(2):359-366. that indicate that HA obtained by wet chemical routes is typically calcium deficient with a Ca/P ratio between 1.5 and 1.67.

The obtained biphasic powder has potential importance for biomedical applications combining the different behaviors of these materials when in contact with organic tissue. Specifically, the HA and β-TCP are major constituents of an extensively used biomedical material named Biphasic Calcium Phosphate (BCP). The IR analysis compared the calcined and uncalcined samples spectra (Figure 3). Bands at 1033-1038 and 1089-1094 cm^-1; a medium intensity band around 962 cm^-1; bands located at 565-567 and 601-603 cm^-1; and a low-intensity band around 472-474 cm^-1 are characteristic of phosphate group (PO₄^3-) of HA.

Figure 3
FTIR spectra of (a) calcined and (b) uncalcined samples.

Bands at 1650 and 3410 cm^-1 indicate the presence of adsorbed water in surfaces of the HA particles. Bands at 877, 1411-1421 and 1453-1467 cm^-1 were assigned as CO₃^2-, which is caused by an atmosphere-opened reaction that allows H₂O/CO₂ incorporation in the particle's surface. After calcination, it is possible to observe a decrease in the intensity of these bands because adsorbed groups tend to be eliminated at high temperatures. Biological apatites are usually carbonated and slightly calcium deficient¹⁴14 Vallet-Regí M, González-Calbet JM. Calcium phosphates as substitution of bone tissues. Progress in Solid State Chemistry. 2004;32(1-2):1-31.. Consequently, the presence of these groups does not prejudice the use of this biphasic powder as a biomaterial.

After heating to 800ºC, there is a clear transformation of d-HA into stoichiometric HA and β-TCP. Analysis of the spectrum indicates bands of both compounds: the OH- characteristics bands at 3571-3576 and 630-633 cm^-1 and the characteristic band of β-TCP at 944 cm^-1. The OH^-band at 630 cm^-1 is a well known characteristic of HA, a well defined triplet which shows the PO₄^3- bonds at 601 and 570 cm^-1 and the -OH bond to the apatite group at 630 cm^-1.

SEM images with different approximations show round shaped grains and micrometric granulometry (Figure 4). Particles shape and size are directly influent in the inflammatory response and bone formation. They should not be needle-shaped form since it is not the propitious environment for bone cells development. Round particles with smooth surfaces are preferred¹⁵15 Dalapicula SS, Vidigal Junior GM, Conz MB, Cardoso ES. Características físico-químicas dos biomateriais utilizados em enxertias ósseas. Uma revisão crítica. ImplantNews. 2006;3(5):487-491., because they induce a short-duration inflammatory response, followed by the desired incorporation of the biomaterial to the host tissue. On the other hand, needle-shaped particles cause granulomatous inflammation, accompanied by the material collapse and reabsorption by the surrounding tissues.

Figure 4
Image (a) show precipitated powders and (b) calcined powders.

Particle size was estimated by laser granulometry to vary from 0.1 to 100 µm (Figure 5) and the calcined powder specific surface area is 11.70 m²/g. Bioactive materials such as HA, which act like substrate to bone tissue growth, are desirable to present the larger contact area possible facilitating the tissue growth. Produced BCP present a higher specific surface area than most of biomaterial for odontology implants tested by Conz¹⁶16 Conz MB, Campos CN, Serrão SD, Soares GA, Vidigal Junior GM. Caracterização físico-química de 12 biomateriais utilizados como enxertos ósseos na Implantodontia. ImplantNews. 2010;7(4):541-546. as well as smallest particles size distribution, contributing to more surface to act as substrate.

Figure 5
Biphasic powder particle size distribution.

The powder's combination of physical characteristics is biomedically valuable, since effective action of bioactive materials depends on a large contact area with the biological medium (bone tissue). Thus, powders with larger surface area should be better able to promote bone growth.

4. Conclusions

Ostrich eggshell is a low cost and abundant and pure source of calcium ions for the synthesis of biomaterials, producing a biomedically valuable biphasic powder of HA and β-TCP according to the desirable features a biomaterial should present listed by the literature. It was described a procedure that could be used to transform agricultural waste (ostrich eggshells) into an economically valuable high-quality new product, directly reducing discard and associated environmental impacts. Indeed, no other wastes were produced during HA synthesis.

5. Acknowledgments

The authors thanks CAPES, for the financial support; Santa Esmeralda Struthio Farm, for the ostrich eggshell supply for this work; LABPETRO-UFES, PMT-USP, DEMAT-CEFET-MG, LEEAA-USP for the characterization analysis.

6. References

¹
Ribeiro C. Obtenção e caracterização de biocerâmicas porosas à base de fosfato de cálcio processadas com a utilização de albumina [Tese de doutorado]. São Paulo: Instituto de Pesquisas Energéticas e Nucleares (IPEN); 2008.
²
Petrov OE, Dyulgerova E, Petrov L, Popova R. Characterization of calcium phosphate phases obtained during the preparation of sintered biphase Ca-P ceramics. Materials Letters 2001;48:(3-4):162-167.
³
Dupoirieux L. Ostrich eggshell as a bone substitute: a preliminary report of its biological behaviour in animals - a possibility in facial reconstructive surgery. British Journal of Oral and Maxillofacial Surgery 1999;37(6):467-471.
⁴
Ahmed S, Ahsan M. Synthesis of Ca-hydroxyapatite Bioceramic from Egg Shell and its Characterization. Bangladesh Journal of Scientific and Industrial Research 2008;43(4):501-512.
⁵
Suchanek W, Yoshimura M. Processing and properties of hydroxyapatite-based biomaterials for use as hard tissue replacement implants. Journal of Materials Research 1998;13(1):94-117.
⁶
Dorozhkin SV. Calcium Orthophosphates in Nature, Biology and Medicine. Materials 2009;2(2):399-498.
⁷
Khemthong P, Luadthong C, Nualpaeng W, Changsuwan P, Tongprem P, Viriya-empikul N, et al. Industrial eggshell wastes as the heterogeneous catalysts for microwave-assisted biodiesel production. Catalysis Today 2012;190(1):112-116.
⁸
Chen G, Shan R, Shi J, Yan B. Ultrasonic-assisted production of biodiesel from transesterification of palm oil over ostrich eggshell-derived CaO catalysts. Bioresource Technology 2014;171:428-432.
⁹
Tan TH, Abdullah MO, Nolasco-Hipolito C, Taufiq-Yap YH. Waste ostrich- and chicken-eggshells as heterogeneous base catalyst for biodiesel production from used cooking oil: Catalyst characterization and biodiesel yield performance. Applied Energy 2015;160:58-70.
¹⁰
Rivera EM, Araiza M, Brostow W, Castaño VM, Díaz-Estrada JR, Hernández R, et al. Synthesis of hydroxyapatite from eggshells. Materials Letters 1999;41(3):128-134.
¹¹
Mortier A, Lemaitre J, Rouxhet PG. Temperature-programmed characterization of synthetic calcium-deficient phosphate apatites. Thermochimica Acta 1989;143:265-282.
¹²
Mostafa NY. Characterization, thermal stability and sintering of hydroxyapatite powders prepared by different routes. Materials Chemistry and Physics 2005;94(2-3):333-341.
¹³
Raynaud S, Champion E, Bernache-Assollant D, Laval JP. Determination of Calcium/Phosphorus Atomic Ratio of Calcium Phosphate Apatites Using X-ray Diffractometry. Journal of the American Ceramic Society 2001;84(2):359-366.
¹⁴
Vallet-Regí M, González-Calbet JM. Calcium phosphates as substitution of bone tissues. Progress in Solid State Chemistry 2004;32(1-2):1-31.
¹⁵
Dalapicula SS, Vidigal Junior GM, Conz MB, Cardoso ES. Características físico-químicas dos biomateriais utilizados em enxertias ósseas. Uma revisão crítica. ImplantNews 2006;3(5):487-491.
¹⁶
Conz MB, Campos CN, Serrão SD, Soares GA, Vidigal Junior GM. Caracterização físico-química de 12 biomateriais utilizados como enxertos ósseos na Implantodontia. ImplantNews 2010;7(4):541-546.

Publication Dates

Publication in this collection
26 Jan 2017
Date of issue
Mar-Apr 2017

History

Received
12 May 2016
Reviewed
19 Sept 2016
Accepted
02 Jan 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Ribeiro C. Obtenção e caracterização de biocerâmicas porosas à base de fosfato de cálcio processadas com a utilização de albumina [Tese de doutorado]. São Paulo: Instituto de Pesquisas Energéticas e Nucleares (IPEN); 2008.

[2] ²
Petrov OE, Dyulgerova E, Petrov L, Popova R. Characterization of calcium phosphate phases obtained during the preparation of sintered biphase Ca-P ceramics. Materials Letters 2001;48:(3-4):162-167.

[3] ³
Dupoirieux L. Ostrich eggshell as a bone substitute: a preliminary report of its biological behaviour in animals - a possibility in facial reconstructive surgery. British Journal of Oral and Maxillofacial Surgery 1999;37(6):467-471.

[4] ⁴
Ahmed S, Ahsan M. Synthesis of Ca-hydroxyapatite Bioceramic from Egg Shell and its Characterization. Bangladesh Journal of Scientific and Industrial Research 2008;43(4):501-512.

[5] ⁵
Suchanek W, Yoshimura M. Processing and properties of hydroxyapatite-based biomaterials for use as hard tissue replacement implants. Journal of Materials Research 1998;13(1):94-117.

[6] ⁶
Dorozhkin SV. Calcium Orthophosphates in Nature, Biology and Medicine. Materials 2009;2(2):399-498.

[7] ⁷
Khemthong P, Luadthong C, Nualpaeng W, Changsuwan P, Tongprem P, Viriya-empikul N, et al. Industrial eggshell wastes as the heterogeneous catalysts for microwave-assisted biodiesel production. Catalysis Today 2012;190(1):112-116.

[8] ⁸
Chen G, Shan R, Shi J, Yan B. Ultrasonic-assisted production of biodiesel from transesterification of palm oil over ostrich eggshell-derived CaO catalysts. Bioresource Technology 2014;171:428-432.

[9] ⁹
Tan TH, Abdullah MO, Nolasco-Hipolito C, Taufiq-Yap YH. Waste ostrich- and chicken-eggshells as heterogeneous base catalyst for biodiesel production from used cooking oil: Catalyst characterization and biodiesel yield performance. Applied Energy 2015;160:58-70.

[10] ¹⁰
Rivera EM, Araiza M, Brostow W, Castaño VM, Díaz-Estrada JR, Hernández R, et al. Synthesis of hydroxyapatite from eggshells. Materials Letters 1999;41(3):128-134.

[11] ¹¹
Mortier A, Lemaitre J, Rouxhet PG. Temperature-programmed characterization of synthetic calcium-deficient phosphate apatites. Thermochimica Acta 1989;143:265-282.

[12] ¹²
Mostafa NY. Characterization, thermal stability and sintering of hydroxyapatite powders prepared by different routes. Materials Chemistry and Physics 2005;94(2-3):333-341.

[13] ¹³
Raynaud S, Champion E, Bernache-Assollant D, Laval JP. Determination of Calcium/Phosphorus Atomic Ratio of Calcium Phosphate Apatites Using X-ray Diffractometry. Journal of the American Ceramic Society 2001;84(2):359-366.

[14] ¹⁴
Vallet-Regí M, González-Calbet JM. Calcium phosphates as substitution of bone tissues. Progress in Solid State Chemistry 2004;32(1-2):1-31.

[15] ¹⁵
Dalapicula SS, Vidigal Junior GM, Conz MB, Cardoso ES. Características físico-químicas dos biomateriais utilizados em enxertias ósseas. Uma revisão crítica. ImplantNews 2006;3(5):487-491.

[16] ¹⁶
Conz MB, Campos CN, Serrão SD, Soares GA, Vidigal Junior GM. Caracterização físico-química de 12 biomateriais utilizados como enxertos ósseos na Implantodontia. ImplantNews 2010;7(4):541-546.

	Ca		P
% weight	30.8073 ± 0.0001		14.8774 ± 0.0001
Atomic weight (g/mol)	40.1		31.0
Sample molar content (100g)	0.77		0.48
Ca/P ratio		1.60

Brasil