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Enhanced Loading of Paclitaxel in Cationic Liposomes by Replacement of Oleoyl with Linoleoyl Lipid Tails with Benefits in Cancer Therapeutics from In Vitro Studies

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https://www.biorxiv.org/content/biorxiv/early/2020/10/12/2020.10.12.336412.full.pdf
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Creative Commons 'BY-NC-ND' version 4.0 license
Abstract

Lipid-based carriers of the hydrophobic drug paclitaxel (PTX) are used in clinical trials as next-generation agents for cancer chemotherapy. Improving the loading capacity of these carriers requires enhanced PTX solubilization. We compared the solubility of PTX in cationic liposomes (CLs) with lipid tails containing one (oleoyl; C18:1 Δ 9 ; DOTAP/DOPC) or two (linoleoyl; C18:2 Δ 9 ; DLinTAP/DLinPC) cis double bonds with newly synthesized cationic DLinTAP (2,3-dilinoleoyloxypropyltrimethylammonium methylsufate). We used differential-interference-contrast microscopy to directly observe PTX crystal formation and generate kinetic phase diagrams representing the time-dependence of PTX solubility as a function of PTX content in the membrane. Replacing tails bearing one cis double bond (DO lipids) with those bearing two (DLin lipids) significantly increased PTX membrane solubility in CLs. Remarkably, 8 mol% PTX in DLinTAP/DLinPC CLs remained soluble for approximately as long as 3 mol% PTX (the membrane solubility limit which has been the focus of most previous fundamental studies and clinical trials) in DOTAP/DOPC CLs. The large increase in solubility is likely caused by enhanced molecular affinity between lipid tails and PTX upon replacement of oleoyl by linoleoyl tails, rather than by the transition in membrane structure from lipid bilayers to inverse cylindrical micelles observed in small-angle X-ray scattering. Importantly, the efficacy of PTX-loaded CLs against human prostate cancer (PC3) cells from measurements of the IC50 of PTX cytotoxicity was unaffected by changing the lipid tails, and toxicity of the CL carrier alone was negligible. Moreover, efficacy was approximately doubled against human melanoma (M21) cells for PTX-loaded DLinTAP/DLinPC over DOTAP/DOPC CLs. The findings demonstrate the potential of chemical modifications of the lipid tails to increase the PTX membrane loading well over the typically used 3 mol% while maintaining (and in some cases even increasing) the efficacy of CLs. The increased PTX solubility will aid the development of liposomal PTX carriers that require significantly less lipid to deliver a given amount of PTX, reducing side effects and costs.

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