Chemically Bound Resorbable Ceramics as an Antibiotic Delivery System in the Treatment of Purulent–Septic Inflammation of Bone Tissue

Local drug delivery systems are an effective approach in the treatment of purulent–septic inflammation of bone tissue. Chemically bonded multiphase ceramics based on calcium-deficient carbonate-substituted hydroxyapatite combine resorbability, osteoconductivity, and the possibility of volumetric inc...

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Bibliographic Details
Published in:Ceramics 2022-07, Vol.5 (3), p.330-350
Main Authors: Lukina, Yuliya, Panov, Yuriy, Panova, Ludmila, Senyagin, Aleksandr, Bionyshev-Abramov, Leonid, Serejnikova, Natalya, Kireynov, Aleksey, Sivkov, Sergey, Gavryushenko, Nikolay, Smolentsev, Dmitriiy, Toshev, Otabek, Lemenovsky, Dmitriy, Krutko, Dmitriy
Format: Article
Language:English
Subjects:
Antibacterial agents
antibiotic
Antibiotics
Antiinfectives and antibacterials
Antimicrobial agents
Biomedical materials
Bones
Calcium carbonate
Calcium phosphates
carbonate-substituted hydroxyapatite
Carbonates
Care and treatment
Cement
Ceramic materials
Ceramics
Chemical bonds
Chemically bonded ceramics
consolidation
Diabetes
Drug delivery systems
Drugs
Gram-positive bacteria
Granular materials
Hydroxyapatite
Implantation
Infections
Inflammation
Macroporosity
PEG
Polyethylene glycol
Polyols
Porosity
Potassium
prolonged release
Sodium
System effectiveness
Vancomycin
Vehicles
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Summary:Local drug delivery systems are an effective approach in the treatment of purulent–septic inflammation of bone tissue. Chemically bonded multiphase ceramics based on calcium-deficient carbonate-substituted hydroxyapatite combine resorbability, osteoconductivity, and the possibility of volumetric incorporation of antibiotics. Macroporosity is regulated by the concentration of polyethylene glycol granules introduced into the initial powder composition, followed by their extraction. The selected conditions for the consolidation of the ceramic matrix and the extraction of PEG granules retain the activity of vancomycin, which is confirmed by the results of microbiological studies. The concentration of vancomycin and the porosity affect the local concentration and release of the antibiotic. The incorporation method provides a prolonged release of the antibiotic for up to 31 days. In vivo experiments with bone implantation have shown that chemically bound macroporous ceramics with incorporated vancomycin are a therapeutically effective carrier of the substance during the healing of bone defects in conditions of surrounding purulent–septic inflammation, and can be considered as a carrier for local antibacterial therapy, at the site of implantation.
ISSN:2571-6131
2571-6131
DOI:10.3390/ceramics5030026