Vimal Kumar Dewangan scite author profile

Calcium deficient hydroxyapatite (CDHA)‐based apatite forming bone cements are well known for their bioactivity and bioresorbability. The formulation of CDHA‐based cements with improved macroporosity, injectability, and resorbability has been investigated. The solid phase consists of nanocrystalline hydroxyapatite (HA) and tricalcium phosphate (β‐TCP). The liquid phase is diluted acetic acid with disodium hydrogen phosphate as binding accelerator along with gelatin and chitosan to improve the injectability. A porogen agent either mannitol (as solid porogen) or polysorbate (as liquid porogen) is also used to improve the porosity. All combined in fine‐tuned composition results in optimal bone cements. The cement sets within the clinically preferred setting time (≤20 min) and injectability (>70%) and also stable at physiological pH (i.e., ~7.3–7.4). The XRD and FT‐IR analysis confirmed the formation of CDHA phase on day 7 when the after‐set cement immersed under phosphate buffer solution (PBS) at physiological conditions. The cements were found to have acceptable compressive strength for trabecular bone substitute. The cements were macroporous in nature with average pore size between 50 and 150 μm and were interconnected as confirmed by SEM, micro‐CT and MIP analysis. The prepared cements are degradable up to 22% and 19% in simulated body fluid and PBS respectively within 10 weeks of immersion at physiological conditions. The cements exhibit higher viability (%) (>110%) with L929 and MG63 cells compared to the control after 3 days of incubation. They also show increased proliferation, well spreading and extended filopodia with MG63 cells. Overall, the developed apatite forming bone cements seems to be suitable for low or non‐load bearing orthopedic applications.

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Easy and affordable method for rapid prototyping of tissue models in vitro using three-dimensional bioprinting

Bandyopadhyay

Dewangan

Vajanthri

et al. 2018

Biocybernetics and Biomedical Engineering

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Fabrication of injectable antibiotic‐loaded apatitic bone cements with prolonged drug delivery for treating post‐surgery infections

Dewangan

Kumar

Doble

et al. 2023

J Biomedical Materials Res

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Antibiotic‐loaded bioactive bone substitutes are widely used for treating various orthopedic diseases and prophylactically to avoid post implantation infection. Calcium deficient hydroxyapatite (also known as apatitic bone cement) is a potential bioactive bone substitute in orthopedics due to its chemical composition similar to that of natural bone minerals. In this study, fabrication of mannitol (a solid porogen) incorporated injectable synthetic (Syn) and eggshell derived (ESD) apatitic bone cements loaded with antibiotics (gentamicin/meropenem/ rifampicin/vancomycin) was investigated. The release kinetics of the antibiotics were studied by fitting them with different kinetic models. All the antibiotics‐loaded apatitic bone cements set within clinically accepted setting time (20 ± 2 min) and with good injectability (>70%). The antibiotics released from these bone cements were found to be controlled and sustained throughout the study time. Weibull and Gompertz (applies in least initial burst and sustain drug release rate models) were the best models to predict the release behavior. They cements had acceptable compressive strength (6–10 MPa; in the range of trabecular bone) and were biodegradable (21%–27% within 12 weeks of incubation) in vitro in simulated body fluids at physiological conditions. These bone cements showed excellent antibacterial activity from day 1 onwards and no bacterial colony was found from day 3 onwards. The viability of MG63 cells in vitro after 72 h was significantly higher after 24 h (i.e., ~110%). The cells were well attached and spread over the surface of the cements with extended morphology. The ESD antibiotic‐loaded apatitic bone cements showed better injectability, degradation and cytocompatibility compared when compared to Syn antibiotic‐loaded apatitic bone cements. Thus, we believe that the ESD antibiotic‐loaded apatitic bone cements are suitable as potential injectable bone substitutes to avoid post‐operative implant associated and other acute or chronic bone infections.

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