Biocompatible biodegradable polymeric antibacterial nanoparticles for enhancing the effects of a third-generation cephalosporin against resistant bacteria.

PURPOSE: In the present study, enhancement of the the antibacterial activity of ceftriaxone against Gram-positive (meticillin-resistant Staphylococcus aureus; MRSA) and Gram-negative (Escherichia coli) bacteria with a biodegradable polymer was attempted.

METHODOLOGY: MRSA and E. coli were collected and identified by biochemical and molecular tests. Blank and ceftriaxone-loaded chitosan nanoparticles (CNPs) were prepared by the ionic gelation method. In vitro antibiotic-susceptibility studies were performed by disc diffusion, agar well plate method, Etest and time-kill assay. In vivo activity was assessed using the neutropenic mouse thigh model and cytotoxicity was estimated by MTT (methylthiazolyldiphenyl tetrazolium bromide) assay with the MCF-7 cancer cell line.

RESULTS: MRSA showed 97 % and E. coli 83 % resistance against ceftriaxone in the disc diffusion test. The isolates showing a ≥1024 mg l-1 MIC value for ceftriaxone were selected for further evaluation. In the agar well plate method, the mean zones of inhibition for blank and ceftriaxone-loaded CNPs were 17 and 23 mm, respectively, for MRSA isolates and 15 and 25 mm, respectively, for E. coli isolates. In the time-kill assay, ~1 log10 to ~2.5 log10 reduction in viability was seen with both isolates when treated with ceftriaxone-loaded CNPs over 24 h. The in vivo studies also showed the enhanced antibacterial activity of ceftriaxone-loaded CNPs, with a 41 % reduction in MRSA and a 27 % reduction in E. coli burden. A low cytotoxicity of blank and ceftriaxone-loaded CNPs was seen, with a slight reduction in the percentage viability of cells from 87 to 83 % and from 88 to 81 %, respectively.

CONCLUSION: The synergistic effect of ceftriaxone-loaded CNPs is a useful finding for the treatment of MRSA and E. coli infections.