A quality by design approach for optimization of Lecithin/Span® 80 based nanoemulsions loaded with hydrophobic drugs

Lately, nanoemulsions loaded with hydrophobic drugs have been successfully developed to improve the treatment of several global diseases. On this subject, a detailed study of the crucial role of the excipients and the experimental conditions used for these nanosystems is still required. Thus, the aim of this work was the development of nanoemulsions of Benzidazole (Class I, log P = 0.91), Praziquantel (Class II, log P = 2.44), Pyrimethamine (Class II/IV, log P = 2.69), Nidosamide (Class II/N, log P = 4.5), and Tridabendazole (Class II/IV, log P = 5.9) using Span (R) 80, soybean lecithin and Miglyol (R) 812 as excipients. A Placket-Burman design was selected to identify the main parameters that influence in the desirable characteristics of such formulations. Then, a full factorial design was built to analyze the effect of the factors identified in the screening phase. Plackett-Burman design indicated that Miglyol (R) 812 and lecithin were the two most influencing factors on the hydrodynamic diameter of the systems. In addition, the association efficiency was influenced by the log P of each drug while the response stability in PBS was modified by Span (R) 80 and log P. The results of the full factorial design revealed that concentration of Miglyol (R) 812 and log P values of each drug have a remarkable impact on the stability of the nanosystems. The optimal conditions for the preparation of nanoemulsions were verified by other independent experiment and the results were in agreement with the predicted optimum values.Thus, this methodology could serve as an attracttive platform to deliver other hydrophobics compounds in stable nanoemulsions. (C) 2020 Elsevier B.V. All rights reserved.

Automated summary

The study focuses on developing nanoemulsions loaded with hydrophobic drugs and investigating the roles of excipients and experimental conditions. By conducting experiments and analyzing parameters, the study identifies key factors influencing the characteristics of the formulations and optimal conditions for stable nanoemulsions. The results suggest that concentration of excipients and log P values of drugs have a significant impact on the stability of nanosystems.