A Potent Cancer Vaccine Adjuvant System for Particleization of Short, Synthetic CD8+ T Cell Epitopes.

Short major histocompatibility complex (MHC) class I (MHC-I)-restricted peptides contain the minimal biochemical information to induce antigen (Ag)-specific CD8+ cytotoxic T cell responses but are generally ineffective in doing so. To address this, we developed a cobalt-porphyrin (CoPoP) liposome vaccine adjuvant system that induces rapid particleization of conventional, short synthetic MHC-I epitopes, leading to strong cellular immune responses at nanogram dosing. Along with CoPoP (to induce particle formation of peptides), synthetic monophosphoryl lipid A (PHAD) and QS-21 immunostimulatory molecules were included in the liposome bilayer to generate the "CPQ" adjuvant system. In mice, immunization with a short MHC-I-restricted peptide, derived from glycoprotein 70 (gp70), admixed with CPQ safely generated functional, Ag-specific CD8+ T cells, resulting in the rejection of multiple tumor cell lines, with durable immunity. When cobalt was omitted, the otherwise identical peptide and adjuvant components did not result in peptide binding and were incapable of inducing immune responses, demonstrating the importance of stable particle formation. Immunization with the liposomal vaccine was well-tolerated and could control local and metastatic disease in a therapeutic setting. Mechanistic studies showed that particle-based peptides were better taken up by antigen-presenting cells, where they were putatively released within endosomes and phagosomes for display on MHC-I surfaces. On the basis of the potency of the approach, the platform was demonstrated as a tool for in vivo epitope screening of peptide microlibraries comprising a hundred peptides.

A surfactant-stripped cabazitaxel micelle formulation optimized with accelerated storage stability.

Pluronic (Poloxomer) micelles can solubilize cabazitaxel (CTX), a second-generation taxane, and then be subjected to low-temperature "surfactant-stripping" to selectively remove loose and free surfactant, thereby increasing the drug-to-surfactant ratio. We previously found that the addition of certain other co-loaded hydrophobic cargo to the micelles can result in stabilized, surfactant-stripped cabazitaxel (sss-CTX) micelles, which resist drug aggregation in aqueous storage, a common challenge for taxanes. Here, we show that elevated temperatures can accelerate the aggregation of sss-CTX micelles, thereby enabling rapid optimization of formulations with respect to the type and ratio of co-loader used for stabilization. A sss-CTX micelle formulation was developed using mifepristone as the co-loader, at a 60% mass ratio to the CTX. Drug release, hemolysis and complement activation were investigated in vitro. Microtubule stabilization and in vitro cytotoxicity were similar for sss-CTX and a conventional Tween-80 micelle formulation. In vivo pharmacokinetics also revealed similar blood circulation of the two formulations. In subcutaneous Lewis lung carcinoma tumors, as well as in an aggressive mouse model of malignant pleural effusion, sss-CTX showed a similar therapeutic effect as the Tween-80 based formulation. Altogether, these data show that sss-CTX can achieve similar efficacy as conventional Tween-80 formulations, albeit with substantially higher drug-to-surfactant ratio and with capability of extended aqueous storage.

Indocyanine green binds to DOTAP liposomes for enhanced optical properties and tumor photoablation.

Indocyanine green (ICG) is a clinically-approved near infrared (NIR) dye used for optical imaging. The dye is only slightly soluble in water and is prone to aggregation in saline solutions, so that alternative formulations can improve photophysical performance. Numerous nanoscale formulations of ICG have been described in the literature, but we sought to develop an approach that does not require additional purification steps. Pre-formed liposomes incorporating 45 mol% of the cationic lipid 1,2-dioleoyl-3-trimethylammonium-propane (DOTAP) rapidly bind ICG, resulting in enhanced NIR optical properties. ICG binding is dependent on the amount of DOTAP incorporated in the liposomes. A dye-to-lipid mass ratio of [0.5 : 25] is sufficient for full complexation, without additional purification steps following mixing. NIR absorption, fluorescence intensity, and photoacoustic signals are increased for the liposome-bound dye. Not only is the optical character enhanced by simple mixing of ICG with liposomes, but retention in 4T1 mammary tumors is observed following intratumor injection, as assessed by fluorescence and photoacoustic imaging. Subsequent photothermal therapy with 808 nm laser irradiation is effective and results in tumor ablation without regrowth for at least 30 days. Thus, ICG optical properties and photothermal ablation outcomes can be improved by mixing the dye with pre-formed DOTAP liposomes in conditions that result in full dye-binding to the liposomes.

Inhalable lactoferrin-chondroitin nanocomposites for combined delivery of doxorubicin and ellagic acid to lung carcinoma.

AIM: The use of inhalable nanomedicines can overcome the Enhanced permeation and retention effect (EPR)-associated drawbacks in lung cancer therapy via systemic nanomedicines. METHODS: We developed a lactoferrin-chondroitin sulfate nanocomplex for the co-delivery of doxorubicin and ellagic acid nanocrystals to lung cancer cells. Then, the nanocomplex was converted into inhalable nanocomposites via spray drying. RESULTS: The resulting 192.3 nm nanocomplex exhibited a sequential faster release of ellagic acid, followed by doxorubicin. Furthermore, the nanocomplex demonstrated superior cytotoxicity and internalization into A549 lung cancer cells mediated via Tf and CD44 receptors. The inhalable nanocomposites exhibited deep lung deposition (89.58% fine particle fraction [FPF]) with powerful antitumor efficacy in lung cancer bearing mice. CONCLUSION: Overall, inhalable lactoferrin-chondroitin sulfate nanocomposites would be a promising carrier for targeted drug delivery to lung cancer.

Inhalable particulate drug delivery systems for lung cancer therapy: Nanoparticles, microparticles, nanocomposites and nanoaggregates.

There is progressive evolution in the use of inhalable drug delivery systems (DDSs) for lung cancer therapy. The inhalation route offers many advantages, being non-invasive method of drug administration as well as localized delivery of anti-cancer drugs to tumor tissue. This article reviews various inhalable colloidal systems studied for tumor-targeted drug delivery including polymeric, lipid, hybrid and inorganic nanocarriers. The active targeting approaches for enhanced delivery of nanocarriers to lung cancer cells were illustrated. This article also reviews the recent advances of inhalable microparticle-based drug delivery systems for lung cancer therapy including bioresponsive, large porous, solid lipid and drug-complex microparticles. The possible strategies to improve the aerosolization behavior and maintain the critical physicochemical parameters for efficient delivery of drugs deep into lungs were also discussed. Therefore, a strong emphasis is placed on the approaches which combine the merits of both nanocarriers and microparticles including inhalable nanocomposites and nanoaggregates and on the optimization of such formulations using the proper techniques and carriers. Finally, the toxicological behavior and market potential of the inhalable anti-cancer drug delivery systems are discussed.