Meta-analysis of nano-phytosomes: unleashing the potential of plant-derived compounds for advancing cancer therapy.

Nano-phytosomes are considered as an efficient drug delivery system for phytochemicals. Phytosomes enhance stability and significantly improves phytochemicals bioavailability and therapeutic efficacy. Thorough meta-analysis of 93 articles, phytochemical versus phytosomes size, charge, polydispersity index (PDI) and IC50 values were investigated. Multivariate Analysis of Covariance revealed significant phytochemicals type effects, even when accounting for cancer cell type and phospholipid type as covariates. Least Significant Difference (LSD) post hoc tests described unique attributes among various phytosomes. Flavonoid-based phytosomes exhibited larger particle sizes than others. In contrast, terpenoid-based phytosomes displayed significantly lower charges. Flavonoids demonstrated higher poly dispersity index (PDI) values than alkaloids and polyphenols. Alkaloids exhibited more extensive PDI values, while polyphenols had lower PDI values than terpenoids. Furthermore, flavonoid-containing nanoparticles exhibited higher IC50 values than terpenoids. In conclusion, nano-phytosomes offer promising prospects for revolutionising drug delivery methodologies and advancing the development of innovative therapeutic solutions in the domain of cancer therapy.

Development of Pegylated Nano-Phytosome Formulation with Oleuropein and Rutin to Compare Anti-Colonic Cancer Activity with Olea Europaea Leaves Extract.

Olive leaf extract is a valuable source of phenolic compounds; primarily, oleuropein (major component) and rutin. This natural olive leaf extract has potential use as a therapeutic agent for cancer treatment. However, its clinical application is hindered by poor pharmacokinetics and low stability. To overcome these limitations, this study aimed to enhance the anticancer activity and stability of oleuropein and rutin by loading them into PEGylated Nano-phytosomes. The developed PEGylated Nano-phytosomes exhibited favorable characteristics in terms of size, charge, and stability. Notably, the anticolonic cancer activity of the Pegylated Nano-phytosomes loaded with oleuropein (IC50=0.14 µM) and rutin (IC50=0.44 µM) surpassed that of pure oleuropein and rutin alone. This outcome highlights the advantageous impact of Nano-phytosomes to augment the anticancer potential of oleuropein and rutin. These results present a promising pathway for the future development of oleuropein and rutin Nano-phytosomes as effective options for passive tumor-targeted therapy, given their improved stability and efficacy.