AbstractBetulinic acid (BA) is a promising natural anti‐tumor agent renowned for its activity against various tumor cell types. Despite its favorable profile of low cytotoxicity to normal cells, BA's inherent hydrophobic nature and relatively short systematic half‐life impose hurdles for clinical application. This study introduces a strategy to surmount these obstacles by developing a drug delivery system employing poly(lactic‐co‐glycolic acid) (PLGA)‐encapsulated BA nanoparticles (PLGA‐BA NPs). Rigorous characterization techniques such as dynamic light scattering (DLS), x‐ray diffraction (XRD), and scanning electron microscopy (SEM) analyses are employed to confirm the integrity of the drug within the nanocarriers. The PLGA‐BA NPs demonstrated a mean particle size of 196 ± 6.80 nm. XRD analysis demonstrated the amorphous state of the PLGA‐BA formulation, a characteristic vital for sustained drug release and enhanced bioavailability. The PLGA‐BA NPs exhibited spherical morphology with encapsulation and loading efficiency of 83 ± 9.24% and 7.0 ± 0.4%, respectively, highlighting efficient encapsulation of the drug within the PLGA NPs. In vitro, cytotoxicity assessments demonstrated enhanced anti‐proliferative efficacy against breast and lung tumor cells when utilizing PLGA‐BA NPs in comparison to free BA. This research underlines the potential of employing the developed PLGA‐based nanocarrier to optimize the therapeutic efficacy of BA.
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