Temperature-dependent bifurcation of cooperative interactions in pure and enriched in β-carotene DPPC liposomes

Gold nanoparticles decorated FOLFIRINOX loaded liposomes for synergistic therapy of pancreatic cancer

Pancreatic cancer is predicted to be the second highest cause of cancer deaths by 2030, with a mortality rate of 98 % and a 5-year survival rate of only 4-8 %. FOLFIRINOX which consists of four main ingredients has shown superior efficacy in treating patients with pancreatic cancer compared to other agents and combinations. However, toxicities have prevented full-dose use of FOLFIRINOX. In this study, we present the design of a liposome nanosystem that enables the sequential release of a drug combination that is called FOLFIRINOX using lipid-based nanosystem synergistic chemo/photothermal therapy approaches. The co-eccentric liposome allowed us to locate the drug molecules in different locations giving us the flexibility to release them in a selected order. Core liposome (L2) has a melting temperature of 53.63 °C, it was decorated by gold nanoparticle (L2@AuNP) to bring photothermal responsiveness. The outer liposome structure had a lower melting temperature, which facilitated the sequential release process. The efficacy of photothermal therapy for nanosystem was calculated. The results indicate that coating L2@AuNP nanostructure with L1 liposomes improves efficacy by stabilizing gold nanoparticles. FOLFIRINOX components are encapsulated in a concentric liposome structure according to the order of administration into the body. The concentric liposome structure enables the sequential release of multiple drugs due to the varying phase transition temperatures of the liposomes. The cytotoxic effect of these formulations was evaluated on Panc-1 pancreatic cancer cells; the lowest cell viability was obtained in 4 Liposome(L) under 5 min NIR irradiation. Combination therapy has a higher therapeutic efficacy (70.45 %) when compared to chemotherapy and photothermal therapy used separately. The study's results show the potential of combination therapies to improve therapeutic outcomes, providing a promising path for future research and clinical application.

A novel tumor-targeted thermosensitive liposomal cerasome used for thermally controlled drug release

Drug carriers with tumor targeting and controlled release have strong prospects for application in safe and efficient chemotherapy. Among various carriers, liposomes have good biocompatibility and can enhance the uptake of drugs by cancer cells. However, traditional liposomes have no specific targeting to cancer cells and are prone to insufficient stability, causing early leakage of the drug. Accordingly, organic-inorganic hybrid phospholipid and thermosensitive phospholipid are deliberately introduced into a liposome system to enhance the morphological and structural stability of the liposomes while realizing thermally controlled drug release. Furthermore, modification with a targeting ligand (WSG-peptide) can endow liposomes with active targeting to ovarian carcinoma cells. First, WSG-peptide was grafted onto the hydrophilic terminal of phospholipid molecules, and the organic-inorganic hybrid cerasome-forming lipid (CFL) was synthesized via a two-step chemical reaction. Then, the WSG-grafted thermosensitive liposomal cerasome (c-LIP-WSG) was prepared by thin-film hydration method. The results showed that the c-LIP-WSG had excellent structural stability both in storage and in a simulated circulation environment. In vitro drug release confirmed that the liposomes exhibited thermally controlled release. Cell uptake experiments and living fluorescence imaging of SKOV-3 tumor-bearing nude mice confirmed that the WSG-peptide modified liposomes were provided with specific targeting properties for ovarian carcinoma.

Effects of novel triple-stage antimalarial ionic liquids on lipid membrane models

Primaquine-based ionic liquids, obtained by acid-base reaction between parent primaquine and cinnamic acids, were recently found as triple-stage antimalarial hits. These ionic compounds displayed significant activity against both liver- and blood-stage Plasmodium parasites, as well as against stage V P. falciparum parasites. Remarkably, blood-stage activity of the ionic liquids against both chloroquine-sensitive (3D7) and resistant (Dd2) P. falciparum strains was clearly superior to those of the respective covalent (amide) analogues and of parent primaquine. Having hypothesized that such behaviour might be ascribed to an enhanced ability of the ionic compounds to permeate into Plasmodium-infected erythrocytes, we have carried out a differential scanning calorimetry-based study of the interactions between the ionic liquids and membrane models. Results provide evidence, at the molecular level, that the primaquine-derived ionic liquids may contribute to an increased permeation of the parent drug into malaria-infected erythrocytes, which has relevant implications towards novel antimalarial approaches based on ionic liquids.

Control of interface interactions between natural rubber and solid surfaces through charge effects: an AFM study in force spectroscopic mode

Adhesion of nanoparticles (natural rubber) is monitored by slight changes in the surface charge state of the contacting solid surfaces.