Potential of magnetite nanoparticles with biopolymers loaded with gentamicin drug for bone cancer treatment

Objective(s): Due to the natural bone microstructure, the design and fabrication of porous ceramic scaffold nanocomposite materials coated with a thin layer of a natural polymer can provide an ideal scaffold for bone tissue engineering. This study aimed to fabricate multi-component porous magnetic scaffolds by freeze-drying (FD) technique using a gelatin polymer layer coated with a gentamicin drug. Methods: Magnetic nanoparticles (MNPs) can be manipulated and controlled by an external magnetic field gradient (EMFG) that is inherent in the magnetic field's permeability within human tissues. In the present work, unlike the usual ceramic/ polymer composite scaffold, the ceramic components and the magnet were placed together in the reaction medium from the beginning, and bioceramics were replaced in the composite polymer network and then coated with a drug-loaded polymer. To evaluate the morphology of the magnetic scaffold, scanning electron microscopy (SEM) was utilized to evaluate the microstructure and observe the porosity of the porous tissue. Results: After analyzing the SEM images, the porosity of the scaffolds was measured, which was similar to the normal bone architecture. The addition of gentamicin to the gelation was investigated to monitor the drug delivery reaction in the biological environment. The magnetic properties of the sample were evaluated using the hyperthermia test for 15 seconds at the adiabatic conditions. Also, the porosity value increased from 55% to 78% with the addition of MNPs to the based matrix. Conclusions: The results of this study showed that gentamicin-gelatin-coated on porous ceramic-magnet composite scaffolds could be used in bone tissue engineering and apply for treatment of bone tumors, because of their similarity to the bone structure with good porosity.

Automated summary

The study focused on fabricating multi-component porous magnetic scaffolds coated with gentamicin drug using freeze-drying technique, aiming to provide an ideal scaffold for bone tissue engineering with good porosity and drug delivery properties.