Development of an Anti-Bacterial Calcium Phosphate Bioceramic Orbital Implant Using Local Calcium Carbonate and Nano-Zinc Oxide

Jocelyn P. Reyes; Sharyjel R. Cayabyab-Gelilang; Johanna Marie B. Sudayon; Lumen C. Milo; Jenny Lyn H. Laga; Alvin Kim M. Collera; Mar Christian O. Que; Marianito T. Margarito

doi:10.4028/p-lH2nvd

Paper Titles

Cyclodextrin Covalent-Organic Frameworks: Bridging Host–Guest Chemistry and Porous Materials for Diverse Applications
p.35

First-Principles Study on Structural, Electronic and Optical Properties of Two-Dimensional Silicene Quantum Dots
p.59

PKS-Derived Porous Carbon/Epoxy Composites for EMI Shielding
p.73

Heat Treatment Effect on Mechanical Properties of Si3N4 Reinforced Al7075-T6 Composite
p.87

Development of an Anti-Bacterial Calcium Phosphate Bioceramic Orbital Implant Using Local Calcium Carbonate and Nano-Zinc Oxide
p.95

Preliminary Biocompatibility Studies of Nano-Zinc Bioceramic Orbital Implant for Anophthalmic Socket Application
p.101

The Impact of Gold and Silver Nanoparticles on Blood Flow Behavior in Constricted Artery
p.107

Optimization of Electrical Conductivity of Green Synthesized Metal Nanoparticle
p.119

Enhancement of Thermoplasmonic Characteristics in Hg-Au/Ag Core-Shell Nanoparticles
p.129

HomeNano Hybrids and CompositesNano Hybrids and Composites Vol. 50Development of an Anti-Bacterial Calcium Phosphate...

Development of an Anti-Bacterial Calcium Phosphate Bioceramic Orbital Implant Using Local Calcium Carbonate and Nano-Zinc Oxide

Abstract:

The search for the ideal eye implant for anophthalmic sockets continues notwithstanding the availability of orbital implants for years. This study focuses on the development of an innovative anti-bacterial calcium phosphate bioceramic orbital implant. Utilizing locally sourced calcium carbonate and kaolin clay and incorporating nano-zinc oxide, the implant aims to enhance antibacterial properties and promote bone regeneration. The primary objectives include optimizing the material composition, fabricating the bioceramic using conventional techniques, and evaluating the implant's physical and mechanical performance. The optimization involves varying calcination temperatures between 800°C and 1200°C and varying kaolin clay composition between 15% and 20%. The mineral composition was identified and determined using X-Ray Diffractometer (XRD). The physical and mechanical properties of the developed orbital were characterized using three-dimensional chromatography X-Ray scanner (3D CT-XRay), scanning electron microscope (SEM) and universal testing machine (UTM). In this study, it was found that the optimum calcination temperature yielding the desired biphasic calcium phosphate composition is 800°C. Moreover, the developed orbitals revealed a porous structure with an average pore size of 198 micrometers. The tests for compressive and flexural strength showed promising results surpassing some of the characteristics of commercially available bioceramic orbital implants. Overall, this study sought to offer a cost-effective and efficient solution for orbital implant surgeries, ultimately improving patient outcomes through enhanced material properties and localized production.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Nano Hybrids and Composites (Volume 50)

Pages:

95-100

DOI:

https://doi.org/10.4028/p-lH2nvd

Citation:

Cite this paper

Online since:

February 2026

Authors:

Jocelyn P. Reyes*, Sharyjel R. Cayabyab-Gelilang, Johanna Marie B. Sudayon, Lumen C. Milo, Jenny Lyn H. Laga, Alvin Kim M. Collera, Mar Christian O. Que, Marianito T. Margarito

Keywords:

Anti-Bacterial Property, Bioceramic Orbital, Calcium Phosphate, Nanozinc Oxide

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Information on https://www.peri.ph/philippine-eye-disease-study

Google Scholar

[2] F. Baino and I. Potestio, Materials Science and Engineering C: Materials for Biological Applications 69, 1410-1428 (2016).

Google Scholar

[3] D.M. Moshfeghi, A.A. Moshfeghi and P.T. Finger, Surv. Ophthalmol. 44 (4), 277-301 (2000).

Google Scholar

[4] A. Geirsdottir, B.A. Agnarsson, G. Helgadottir and H. Sigurdsson, Acta Ophthalmologica 92 (2), 121-125 (2012).

DOI: 10.1111/aos.12004

Google Scholar

[5] B. Cleres and H.W. Meyer-Rusenberg, Der Ophthalmologe 111, 572-576 (2014).

Google Scholar

[6] E. Saxby, R. Davies and J. Kerr, Eye 33, 1349-1351 (2019).

Google Scholar

[7] Y. Zhang, T. Shu, S. Wang, Z. Liu, Y. Cheng, A. Li and D. Pei, Front Bioeng Biotechnol 10, 1-9 (2022).

Google Scholar

[8] G.C. Gomes, F.O. Borges, F.F. Borghi, G.H. Cavalcanti, C.M.S. Martins, V. Palleschi and A. Mello, Spectrochimica Acta Part B: Atomic Spectroscopy 184 (2021).

DOI: 10.1016/j.sab.2021.106250

Google Scholar

[9] J.P. Reyes, J.R. Celorico, L.C. dela Cuesta, J.M. Filo, L.G. Daan, S.T. Bernardo and J. Abano, Philippine Journal of Science 129 (2), 93-99 (2000).

Google Scholar

[10] J.A. Tumbocon, J.P. Reyes, J.R. Celorico, et al., Philippine Technology Journal 24 (2), 27-52 (1999).

Google Scholar

[11] D. Dhiba, A. Hakam, H. El Khouki, A. Albourine and A. Nounah, J. Phys. IV France 123, 255-258 (2005).

DOI: 10.1051/jp4:2005123046

Google Scholar

[12] J.W. Karesh and S.C. Dresner, Ophthalmology 101 (10), 1688-1696 (1994).

Google Scholar

[13] R. Sarkar and G. Banerjee, International Ceramic Review 59 (2), 98-102 (2010).

Google Scholar

[14] B. Kundu, M. Sinha, S. Mitra and D. Basu, Indian Journal of Ophthalmology 53 (4), 235-241 (2005).

Google Scholar