Genipin as a Cross-linker in a Ciprofloxacin Delivery System Containing a Bovine Hydroxyapatite-Collagen Composite for Bone Infections

Authors

  • Nurul Fitriani Fakultas Farmasi Universitas Mulawarman https://orcid.org/0000-0002-8851-2208
  • Aniek Setiya Budiatin Departement of Clinical Pharmacy, Faculty of Pharmacy, Airlangga University, Dharmawangsa Dalam, Surabaya-60286, East Java, Indonesia
  • Esti Hendradi Departement of Pharmaceutics, Faculty of Pharmacy, Airlangga University, Dharmawangsa Dalam, Surabaya-60286, East Java, Indonesia

DOI:

https://doi.org/10.25026/jtpc.v7i1.465

Keywords:

Ciprofloxacin, Collagen, Bovine hydroxyapatite, Genipin, Implant

Abstract

The purpose of this research was to design an implant for a ciprofloxacin-based drug delivery system by combining bovine hydroxyapatite and collagen with genipin as the crosslinking agent. The production of ciprofloxacin implants using bovine hydroxyapatite:collagen blend (70:30). In addition, this synthetic preparation was made using three various concentrations of genipin (0.6, 0.8, and 1.0%). The pellets were created by compressing the implants. The tablets are cylindrical with a diameter of 4.0 mm and a weight of 100.0 mg. Ciprofloxacin cultures were characterized for swelling rate, porosity, density, compressive strength, morphology (SEM), dose, and drug release in vitro. The addition of genipin as a crosslinking agent may maintain ciprofloxacin release consistent with in vitro therapeutic levels of ciprofloxacin. These results are supported by compressive strength data, where the addition of genipin concentrations induces higher implant stiffness and scanning electron microscopy photomicrographs reveal small pore sizes and BHA adhere to collagen fibers so that ciprofloxacin is completely dispersed in the implant after cross-linking with genipin. As a drug delivery system for osteomyelitis, it can be concluded that the use of genipin as a cross-linking agent can sustain ciprofloxacin release commensurate with in vitro therapeutic levels of ciprofloxacin for 30 days.

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References

Calhoun JH., Manring MM. Adult Osteomyelitis. Infectious Disease Clinics of North America. 2005;19:765-786.

Li Junjie., YiPing Chen., Yuji Yin., Fanglian Yao., Kangde Yao. Modulation of nano-hydroxyapatite size via formation on chitosan–gelatin network film in situ. Biomaterials. 2007;28:781–790.

Forier, K., Raemdonck, K., Smedt, S.C., Deemester, J., Conye, T., and Brackmans, K. Lipid and polymer nanoparticles for drug delivery to bacterial biofilms. Journal of controlled release. 2014;14:1-46.

Mustaffa rusnah., Mohd Reusmaazran Yusof., Fauziah Othman., and Asmah Rahmat. Drug release study of porous hydroxyapatite coated gentamicin as drug delivery system. 2012;2:61-67.

Tsourvakas, S. Local antibiotic therapy in the treatment of bone and soft tissue infections. Selected Topics in Plastic Reconstructive Surgery. 2012:17-34.

Pundir Rakesh., Manisha Pandey., Rohit K. Verma, C.S. Pandian., Shubhini A. Saraf. Biodegradable orthopedic implant : fabrication and evaluation. International Journal of Current Pharmaceutical Research. 2009;1:1.

Jeong Young., Hee-Sam Na., Dong-Hyuk Seo., Dong-Gon Kim., Hyun-Chul Lee

Mi-Kyeong Jang., Sang-Kwon Na., Sung-Hee Roh., Sun-Il Kim., Jae-Woon Nah. Ciprofloxacin-encapsulated poly(dl-lactide-co-glycolide) nanoparticles and its antibacterial activity. International Journal of Pharmaceutics. 2008;532:317-323.

Sionkowska A., J. Kozlowska. Properties and modification of porous 3-D collagen/hydroxyapatite composites. International Journal of Biological Macromolecules. 2013;52:250–259.

Kusrini Eny, Aida R. Pudjiastuti, Sotya Astutiningsih, Sri Harjanto. Preparation of Hydroxyapatite from Bovine Bone by Combination Methods of Ultrasonic and Spray Drying. International Conference on Chemical, Bio-Chemical and Environmental Sciences. 2012.

Zhang Xiujhie, Xueying Chen, Ting Yang, Naili Zhang, Li Dong, Shaoying Ma, Xiaoming Liu, Mo Zhou, Baoxing Li. The effects of different crossing-linking conditions of genipin on type I collagen scaffolds: an in vitro evaluation. Springer-Link. Cell Tissue Bank. 2014.

Sobczak Agnieska., Zygmunt Kowalski, Zbigniew Wzorek. Preparation of hydroxyapatite from animal bones. Acta of Bioengineering and Biomechanics. 2009;11: 4.

Budiatin, S, A., Zainuddin, M., Khotib, J. Biocompatible composite as gentamicin delivery system for osteomyelities and bone regeneration. International journal of pharmacy and pharmaceutical sciences. 2014;6:1-3.

Teng SH, Lee EJ, Wang P, Jun SH, Han CM, Kim HE. Chitosan/nanohydroxyapatite composite membranes via dynamic filtration for guided bone regeneration. J Biomed Mater Res Part B 2008;88:569-579.

Stallmann HP, Faber C, Bronckers AL, Amerogen AV, Wuisman PI. In vitro gentamicin release from commercially available calcium-phosphate bone substitute influence of carrier type on duration of the release profile. BMC Musculoskeletal disorders 2006;7:1-8.

Bi Long, Zheng Cao, Yunyu Hu, Yang Song, Long Yu, Bo Yang, Jihong Mu, Zhaosong Huang, Yisheng Han. Effects of different cross-linking conditions on the properties of genipin-cross-linked chitosan/collagen scaffolds for cartilage tissue engineering. Journal of material science : material in medicine. 2011;22:51–62.

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Published

2023-01-25

How to Cite

Fitriani, N., Budiatin, A. S., & Hendradi, E. (2023). Genipin as a Cross-linker in a Ciprofloxacin Delivery System Containing a Bovine Hydroxyapatite-Collagen Composite for Bone Infections. Journal of Tropical Pharmacy and Chemistry, 7(1), 16–23. https://doi.org/10.25026/jtpc.v7i1.465

Issue

Vol. 7 No. 1 (2023): J. Trop. Pharm. Chem.

Section

Articles

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Copyright (c) 2023 Journal of Tropical Pharmacy and Chemistry

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