_1695542085 20230924075445000 Rovedar Daryoushbabazadeh@gmail.com Rovedar Journal of World’s Poultry Science J. World's Poult. Sci. 2980-7999 09 12 2023 2 3 Fatemeh Heshmati Shimen Gevargiz Sangar Amirmehdi Amoozadehsamakoosh Elham Azadi Nima Komeili https://orcid.org/0009-0001-9675-5322 The development of nanotechnology for the treatment of parasitic diseases is still in its infancy. However, it is expected that this new field can provide a solution to parasitic diseases and compensate for the lack of vaccines to prevent them. It can also provide new treatment options for parasitic diseases resistant to current treatments. Nanomaterials have been developed for antibacterial and anticancer therapies. However, it is important to determine their antiparasitic potential due to the wide variety of their physicochemical properties. When designing metallic nanoparticles (MeNPs) and specialized nanosystems like MeNPs encapsulated within a drug shell, it is essential to consider several key physicochemical properties. Shape, size, surface charge, and type of surfactant control are some of these physicochemical properties. In addition to interacting with parasite cells’ target molecules, shell molecules are also important. 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