RESUMO
Aim: The dose response in growth inhibition of Staphylococcus aureus treated with colloidal copper oxide nanoparticles (CuO-NP) was evaluated. Methods: An in vitro microbial viability assay was conducted with CuO-NP concentrations spreading over the 0.4-848.0 µg/ml range. The dose-response curve was modeled with a double Hill equation. UV-Visible absorption and photoluminescence spectroscopies allowed tracking concentration-dependent modifications in CuO-NP. Results: Two specific phases separated by the critical concentration of 26.5 µg/ml were observed in the dose-response curve, with each exhibiting proper IC50 parameters, Hill coefficients and relative amplitudes. Spectroscopy techniques reveal the occurrence of a concentration-triggered aggregation of CuO-NP starting from this critical concentration. Conclusion: The findings demonstrate a dose-related change in S. aureus sensitivity to CuO-NP, which probably arises from the aggregation of this agent.
Antibacterial agents are often used to stop the growth of bacteria such as Staphylococcus aureus (S. aureus). Copper oxide nanoparticles (CuO-NP) stand as a promising candidate for this purpose. Generally, the agent´s effectiveness is inspected following a dose-response curve in which de agent´s antibacterial response is plotted against its dose (concentration). In this work, employing an extended mathematical interpretation we were capable of discerning experimentally the existence of two stages of dose-response (biphasic dose-response) in the treatment of S. aureus with CuO-NP. These results in combination with insights from spectroscopic techniques lead to the understanding that the biphasic behavior arises from the aggregation of CuO-NP at high concentrations. Therefore, according to the adopted concentration to treat S. aureus, the agent can behave as a dispersed nanoparticle or as an aggregated nanoparticle. In summary, understanding whether antibacterial agents transform as a function of concentration is important in determining their practical applications.
