LAUSR

INTRODUCTION Side effects associated with using antibodies as therapeutics can limit their systemic administration at the high concentrations often needed for therapeutic impact. Thus, therapeutic antibodies are usually considered for targeted delivery. Antibody encapsulation in polymeric nanoparticles via the emulsion-based nanofabrication methods typically yields low loading efficiencies. Therefore, the fabrication techniques need to be modified to maximize the loading efficiency of antibodies. In this work, we utilized various cosolvents with the emulsion solvent evaporation technique to improve the loading efficiency of anti-CD47, a therapeutic antibody used to block CD47 activity in atherosclerotic plaques and cancer lesions. METHODS AND RESULTS Double emulsion solvent evaporation technique was used to fabricate anti-CD47-loaded polymeric nanoparticles. The primary oil phase solvent, chloroform, was doped with different cosolvents, including ethyl acetate, acetonitrile, ethanol, and methanol, to investigate the impact of cosolvents on the loading efficiency of anti-CD47. The release profile and loading efficiency were quantified by measuring the fluorescence signal of the released antibody. The activity of the antibody released from particles fabricated in the presence of the cosolvent was confirmed via quantifying its adherence to red blood cells. Ethyl acetate was found to be the optimum cosolvent, improving the loading efficiency of anti-CD47 in poly(lactic-co-glycolic acid), PLGA, nanoparticles to 90% or higher, and the antibody was found to retain its activity after being released from nanoparticles. CONCLUSION Our results demonstrate that a minimum amount of a cosolvent with minimal hydrophilicity can stabilize the antibody in the oil phase; thus, improving the antibody's loading efficiency significantly.