Preparation and properties of silica/hydroxyapatite whiskers porous ceramics scaffold_Chinese Journal of Reparative and Reconstructive Surgery

Authors：

WAN Yuxi ¹ , CHEN Qiangguo ¹ ,  YAN Tingting ²

1. Department of Rehabilitation Medicine, Wuhan University of Technology Hospital, Wuhan Hubei, 430070, P. R. China;
2. Faculty of Materials Science and Engineering, Kunming University of Technology, Kunming Yunnan, 650093, P. R. China;

Corresponding?author：

YAN Tingting, Email: itty@foxmail.com

Keywords：

Silica microspheres; hydroxyapatite whisker; extrusion molding; mechanical foaming; porous ceramics

DOI：

10.7507/1002-1892.202304073

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Objective To investigate the preparation and properties of the novel silica (SiO₂)/hydroxyapatite (HAP) whiskers porous ceramics scaffold. Methods The HAP whiskers were modified by the SiO₂ microspheres using the St?ber method. Three types of SiO₂/HAP whiskers were fabricated under different factors (for the No.1 samples, the content of tetraethoxysilane, stirring time, calcination temperature, and soaking time were 10 mL, 12 hours, 560℃, and 0.5 hours, respectively; and in the No.2 samples, those were 15 mL, 24 hours, 650℃, and 2 hours, respectively; while those in the No.3 samples were 20 mL, 48 hours, 750℃, and 4 hours, respectively). The phase and morphology of the self-made HAP whisker and 3 types of SiO₂/HAP whiskers were detected by the X-ray diffraction analysis and scanning electron microscopy. Taken the self-made HAP whisker and 3 types of SiO₂/HAP whiskers as raw materials, various porous ceramic materials were prepared using the mechanical foaming method combined with extrusion molding method, and the low-temperature heat treatment. The pore structure of porous ceramics was observed by scanning electron microscopy. Its porosity and pore size distribution were measured. And further the axial compressive strength was measured, and the biodegradability was detected by simulated body fluid. Cell counting kit 8 method was used to conduct cytotoxicity experiments on the extract of porous ceramics. Results The SiO₂ microspheres modified HAP whiskers and its porous ceramic materials were prepared successfully, respectively. In the SiO₂/HAP whiskers, the amorphous SiO₂ microspheres with a diameter of 200 nm, uniform distribution and good adhesion were attached to the surface of the whiskers, and the number of microspheres was controllable. The apparent porosity of the porous ceramic scaffold was about 78%, and its pore structure was composed of neatly arranged longitudinal through-holes and a large number of micro/nano through-holes. Compared with HAP whisker porous ceramic, the axial compressive strength of the SiO₂/HAP whisker porous ceramics could reach 1.0 MPa, which increased the strength by nearly 4 times. Among them, the axial compressive strength of the No.2 SiO₂/HAP whisker porous ceramic was the highest. The SiO₂ microspheres attached to the surface of the whiskers could provide sites for the deposition of apatite. With the content of SiO₂ microspheres increased, the deposition rate of apatite accelerated. The cytotoxicity level of the prepared porous ceramics ranged from 0 to 1, without cytotoxicity. Conclusion SiO₂/HAP whisker porous ceramics have good biological activity, high porosity, three-dimensional complex pore structure, good axial compressive strength, and no cytotoxicity, which make it a promising scaffold material for bone tissue engineering.

Citation： WAN Yuxi, CHEN Qiangguo, YAN Tingting. Preparation and properties of silica/hydroxyapatite whiskers porous ceramics scaffold. Chinese Journal of Reparative and Reconstructive Surgery, 2023, 37(9): 1142-1148. doi: 10.7507/1002-1892.202304073 Copy

1.	林開利, 常江, 汪正. 多孔硅酸鈣生物陶瓷的制備及體外活性和降解性研究. 無機材料學報, 2005, 20(3): 692-698.
2.	董少杰, 王旭東, 沈國芳, 等. 生物陶瓷支架的功能改性及應用研究進展. 無機材料學報, 2020, 35(8): 867-881.
3.	舒朝琴, 朱敏, 朱鈺方. 熔鹽法制備含鈷氯磷灰石及其抗氧化性能和細胞相容性研究. 無機材料學報, 2022, 37(11): 1225-1235.
4.	Zhang Z, Chen L, Liu H, et al. Preparation and budding growth of whiskers in a homogeneous system. Solid State Sciences, 2012, 14(9): 1277-1281.
5.	Mizutani Y, Hattori M, Okuyama M, et al. Large-sized hydroxyapatite whiskers derived from calcium tripolyphosphate gel. Journal of the European Ceramic Society, 2005, 25(13): 3181-3185.
6.	張勇. 羥基磷灰石晶須的水熱法制備及其針狀生長機理研究. 武漢: 武漢理工大學, 2002.
7.	Wojciech S, Hiroyuki S, Masatomo Y, et al. Biocompatible whiskers with controlled morphology and stoichiometry. Materials Research Society, 1995, 10(3): 521-529.
8.	Zastulka A, Clichici S, Tomoaia-Cotisel M, et al. Recent trends in hydroxyapatite supplementation for osteoregenerative purposes. Materials (Basel), 2023, 16(3): 1303.
9.	Park J. Photocatalytic activity of hydroxyapatite-precipitated potassium titanate whiskers. Journal of Alloys and Compounds, 2010, 492(1-2): L57-L60.
10.	Kattimani V, Kondaka S, Lingamaneni K. Hydroxyapatite-past, present, and future in bone regeneration. Bone and Tissue Regeneration Insights, 2016, 7: 9-19.
11.	Mo X, Zhang D, Liu K, et al. Nano-hydroxyapatite composite scaffolds loaded with bioactive factors and drugs for bone tissue engineering. Int J Mol Sci, 2023, 24(2): 1291.
12.	Emadi R, Roohani Esfahani S, Tavangarian F. A novel, low temperature method for the preparation of ?-TCP/HAP biphasic nanostructured ceramic scaffold from natural cancellous bone. Materials Letters, 2010, 64(8): 993-996.
13.	何春耒, 王大平, 馬經野. 骨組織工程支架材料的種類及發展趨勢. 中國組織工程研究與臨床康復, 2009, 13(25): 4905-4908.
14.	袁景, 甄平. 骨組織工程支架的研究進展. 醫學綜述, 2015, 21(12): 2126-2130.
15.	徐大朋, 王緒凱. 骨組織工程支架研究進展. 中國實用口腔科雜志, 2014, 7(3): 177-181.
16.	陳志軍. 多孔β-磷酸鈣生物陶瓷支架的研制. 武漢: 武漢理工大學, 2008.
17.	宋美玲, 李征宇, 艾子政,等. 不同比例羥基磷灰石/β-磷酸三鈣涂層支架修復骨缺損. 中國組織工程研究, 2023, 27(30): 4809-4816.
18.	Wojciech L, Masahiro Y. Preparation of fibrous, porous hydroxyapatite ceramics from hydroxyapatite whiskers. Journal of American Ceramics Society, 1998, 81(3): 765-767.
19.	Borum L, Wilson OC. Surface modification of hydroxyapatite. Part Ⅱ. Silica. Biomaterials, 2003, 24(21): 3681-3688.
20.	Aminian A, Solati-Hashjin M, Samadikuchaksaraei A, et al. Synthesis of silicon-substituted hydroxyapatite by a hydrothermal method with two different phosphorous sources. Ceramics International, 2011, 37(4): 1219-1229.
21.	黃潔, 雷云, 王立麗, 等. 發泡法制備羥基磷灰石晶須蜂窩支架材料的研究. 人工晶體學報, 2016, 45(12): 2826-2830.
22.	雷云, 黃潔, 劉金坤, 等. 改性羥基磷灰石晶須牙科復合樹脂材料的制備及研究. 人工晶體學報, 2017, 46(3): 422-427.
23.	尹研婷, 顏廷亭, 王端誠, 等. SiO₂改性超長羥基磷灰石晶須的制備及研究. 人工晶體學報, 2014, 43(10): 2747-2752.
24.	諶強國. 硅改性羥基磷灰石晶須多孔陶瓷材料的制備與性能研究. 昆明: 昆明理工大學, 2016.
25.	侯建明, 李琦. 生物活性支架材料修復骨質疏松性骨缺損. 中國組織工程研究, 2023, 27(21): 3423-3429.
26.	張鐘毓, 許燕, 張旭婧, 等. 同軸骨組織工程支架降解特性研究. 機械設計與制造, 2021, (2): 5-9.

1. 林開利, 常江, 汪正. 多孔硅酸鈣生物陶瓷的制備及體外活性和降解性研究. 無機材料學報, 2005, 20(3): 692-698.
2. 董少杰, 王旭東, 沈國芳, 等. 生物陶瓷支架的功能改性及應用研究進展. 無機材料學報, 2020, 35(8): 867-881.
3. 舒朝琴, 朱敏, 朱鈺方. 熔鹽法制備含鈷氯磷灰石及其抗氧化性能和細胞相容性研究. 無機材料學報, 2022, 37(11): 1225-1235.
4. Zhang Z, Chen L, Liu H, et al. Preparation and budding growth of whiskers in a homogeneous system. Solid State Sciences, 2012, 14(9): 1277-1281.
5. Mizutani Y, Hattori M, Okuyama M, et al. Large-sized hydroxyapatite whiskers derived from calcium tripolyphosphate gel. Journal of the European Ceramic Society, 2005, 25(13): 3181-3185.
6. 張勇. 羥基磷灰石晶須的水熱法制備及其針狀生長機理研究. 武漢: 武漢理工大學, 2002.
7. Wojciech S, Hiroyuki S, Masatomo Y, et al. Biocompatible whiskers with controlled morphology and stoichiometry. Materials Research Society, 1995, 10(3): 521-529.
8. Zastulka A, Clichici S, Tomoaia-Cotisel M, et al. Recent trends in hydroxyapatite supplementation for osteoregenerative purposes. Materials (Basel), 2023, 16(3): 1303.
9. Park J. Photocatalytic activity of hydroxyapatite-precipitated potassium titanate whiskers. Journal of Alloys and Compounds, 2010, 492(1-2): L57-L60.
10. Kattimani V, Kondaka S, Lingamaneni K. Hydroxyapatite-past, present, and future in bone regeneration. Bone and Tissue Regeneration Insights, 2016, 7: 9-19.
11. Mo X, Zhang D, Liu K, et al. Nano-hydroxyapatite composite scaffolds loaded with bioactive factors and drugs for bone tissue engineering. Int J Mol Sci, 2023, 24(2): 1291.
12. Emadi R, Roohani Esfahani S, Tavangarian F. A novel, low temperature method for the preparation of ?-TCP/HAP biphasic nanostructured ceramic scaffold from natural cancellous bone. Materials Letters, 2010, 64(8): 993-996.
13. 何春耒, 王大平, 馬經野. 骨組織工程支架材料的種類及發展趨勢. 中國組織工程研究與臨床康復, 2009, 13(25): 4905-4908.
14. 袁景, 甄平. 骨組織工程支架的研究進展. 醫學綜述, 2015, 21(12): 2126-2130.
15. 徐大朋, 王緒凱. 骨組織工程支架研究進展. 中國實用口腔科雜志, 2014, 7(3): 177-181.
16. 陳志軍. 多孔β-磷酸鈣生物陶瓷支架的研制. 武漢: 武漢理工大學, 2008.
17. 宋美玲, 李征宇, 艾子政,等. 不同比例羥基磷灰石/β-磷酸三鈣涂層支架修復骨缺損. 中國組織工程研究, 2023, 27(30): 4809-4816.
18. Wojciech L, Masahiro Y. Preparation of fibrous, porous hydroxyapatite ceramics from hydroxyapatite whiskers. Journal of American Ceramics Society, 1998, 81(3): 765-767.
19. Borum L, Wilson OC. Surface modification of hydroxyapatite. Part Ⅱ. Silica. Biomaterials, 2003, 24(21): 3681-3688.
20. Aminian A, Solati-Hashjin M, Samadikuchaksaraei A, et al. Synthesis of silicon-substituted hydroxyapatite by a hydrothermal method with two different phosphorous sources. Ceramics International, 2011, 37(4): 1219-1229.
21. 黃潔, 雷云, 王立麗, 等. 發泡法制備羥基磷灰石晶須蜂窩支架材料的研究. 人工晶體學報, 2016, 45(12): 2826-2830.
22. 雷云, 黃潔, 劉金坤, 等. 改性羥基磷灰石晶須牙科復合樹脂材料的制備及研究. 人工晶體學報, 2017, 46(3): 422-427.
23. 尹研婷, 顏廷亭, 王端誠, 等. SiO₂改性超長羥基磷灰石晶須的制備及研究. 人工晶體學報, 2014, 43(10): 2747-2752.
24. 諶強國. 硅改性羥基磷灰石晶須多孔陶瓷材料的制備與性能研究. 昆明: 昆明理工大學, 2016.
25. 侯建明, 李琦. 生物活性支架材料修復骨質疏松性骨缺損. 中國組織工程研究, 2023, 27(21): 3423-3429.
26. 張鐘毓, 許燕, 張旭婧, 等. 同軸骨組織工程支架降解特性研究. 機械設計與制造, 2021, (2): 5-9.

Chinese Journal of Reparative and Reconstructive Surgery

Preparation and properties of silica/hydroxyapatite whiskers porous ceramics scaffold

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