Liposome formulation of co-encapsulated vincristine and quercetin enhanced antitumor activity in a trastuzumab-insensitive breast tumor xenograft model.

Hormone- and trastuzumab-insensitive breast cancer has limited and ineffective clinical treatment options. This study sought to develop a liposome formulation containing a synergistic combination of vincristine and quercetin, with prolonged drug circulation times and coordinated drug release in vivo, to develop effective treatments against this subtype of breast cancer. The 2:1 molar ratio of vincristine/quercetin showed strong synergism in the hormone- and trastuzumab-insensitive JIMT-1 cells. Liposome co-encapsulation prolonged plasma circulation of the two drugs and maintained the synergistic drug ratio in vivo. Furthermore, the co-encapsulated liposome formulation demonstrated the most effective tumor growth inhibition in the JIMT-1 human breast tumor xenograft in comparison with vehicle control, free quercetin, free vincristine and free vincristine/quercetin combinations. Specifically, only the co-encapsulated liposome formulation exhibited significant antitumor activity at two-thirds of the maximum tolerated dose of vincristine, without significant body weight loss in the animals. FROM THE CLINICAL EDITOR: In this study, a novel liposome formulation containing a synergistic combination of vincristine and quercetin was utilized in the treatment of breast cancer. Prolonged drug circulation times and coordinated drug release characterize this effective treatment, which may find its way to clinical applications in the near future.

Liposomal M-V-05: formulation development and activity testing of a novel dihydrofolate reductase inhibitor for breast cancer therapy.

In the management of metastatic breast cancer, fewer recognized therapeutic standards are available as compared to the early stages of the disease. Thus, it is pertinent to search for new, effective therapy to improve survival, tolerability and quality of life of patients. In this study, a liposomal formulation was developed for a novel dihydrofolate reductase (DHFR) inhibitor, M-V-05. Drug encapsulation into liposomes was achieved by the citrate-based, pH gradient loading technique, with a final drug-to-lipid weight ratio of 0.1:1. The liposome formulation exhibited a sustained release profile of the encapsulated drug that followed first order release kinetics. Liposomal M-V-05 was found to be more effective than the standard DHFR inhibitor, methotrexate, and its activity was comparable to liposomal doxorubicin, with IC50 values of 37 and 59 microM achieved in MDA-MB-231 and JIMT-1 cells, respectively. Similar cytotoxicity was observed in primary patient samples of invasive ductal carcinoma of the breast. The combination of liposomal M-V-05 and liposomal doxorubicin in fixed molar ratio of 3:1 was additive in cytotoxicity, allowing the concentrations of liposomal doxorubicin and liposomal M-V-05 to be reduced by 62 and 46%, respectively. Taken together, liposomal M-V-05 represents a promising agent and offers a potential new adjuvant therapy for breast cancer treatment.

Syndecan-2 and decorin: proteoglycans with a difference--implications in keloid pathogenesis.

BACKGROUND: Growth factors and cytokines involved in the wound healing process seem to be immobilized at the cell surface and extracellular matrix via binding with proteoglycans, making them important modulators of cell dynamics. Our aim was to investigate the expression of two proteoglycans, namely syndecan-2 and decorin, and to elucidate their role in the pathogenesis of an aberrant wound healing process leading to keloid scar. METHODS: Intrinsic expression of syndecan-2, fibroblast growth factor (FGF)-2, and decorin in keloid tissue was investigated using Western blotting and immunohistochemistry. Normal and keloid fibroblasts were treated with serum to see the effects of serum growth factors on the expression of syndecan-2 and decorin. The role of epithelial-mesenchymal interactions in modulating syndecan-2, FGF-2, and decorin expression was investigated using an established two-chamber serum-free coculture model. Finally, the antifibrotic effect of decorin was investigated by studying its effect on the expression of extracellular matrix components. RESULTS: Syndecan-2 and FGF-2 were upregulated in keloid tissue; decorin was downregulated. Normal and keloid fibroblasts treated with serum led to increase in syndecan-2 and decrease in decorin expression. Under coculture conditions, syndecan-2 was shed in the conditioned media. FGF-2 was also upregulated under coculture conditions and, when added to fibroblast monocultures, increased shedding of syndecan-2. Decorin levels were upregulated under coculture conditions only in normal cocultures. Decorin was also able to decrease extracellular matrix proteins, highlighting its importance as an antifibrotic agent. CONCLUSION: Syndecan-2 and FGF-2 are not only overexpressed in keloid tissues but may interact with each other resulting in the shedding of syndecan-2, which in turn might activate a whole cascade of events responsible for a keloidic phenotype. In addition, decorin had an antifibrotic effect and could well be used as a potential therapeutic agent for keloids.

Simultaneous liposomal delivery of quercetin and vincristine for enhanced estrogen-receptor-negative breast cancer treatment.

Breast cancers are either estrogen receptor-positive (ER) or negative (ER). ER breast cancers are clinically more aggressive and have fewer effective treatment options. Quercetin and vincristine are both active against ER breast cancers and exhibit synergism in vitro. However, the clinical use of quercetin is hampered by its low water solubility. In addition, optimal synergism can only be achieved at a particular ratio of the drugs. Therefore, the objectives of this study are to develop a liposomal formulation to solubilize quercetin, and to co-encapsulate and coordinate the release of quercetin and vincristine in their synergistic ratios to maximize anticancer activity. The optimal synergistic molar ratio of quercetin/vincristine was found to be 1 : 2 by in-vitro MTT assay. Quercetin liposomes were prepared by the film hydration method followed by extrusion, and vincristine was subsequently loaded into the core of the liposomes by remote loading with manganese sulfate and the ionophore A23187. The optimal liposome formulation co-encapsulating quercetin and vincristine comprised egg sphingomyelin/cholesterol/PEG2000 ceramide/quercetin (72.5 : 17.5 : 5 : 5 mol ratio). This formulation was physically stable, enhanced quercetin solubility 8.6 times, co-encapsulated quercetin and vincristine with efficiencies of 78.3 and 78.5%, respectively, and displayed coordinated release of both drugs to maintain the synergistic molar ratio. In-vitro MTT assays of this liposomal formulation showed significant synergism, with a combination index of 0.113 and a dose-reduction index value of 115 at ED50 for vincristine. Therefore, liposomal delivery represents a strategy to solubilize poorly soluble drugs and coordinate the release of two drugs in their synergistic ratio for optimal anticancer effect.

Lipid-based nanoparticulate systems for the delivery of anti-cancer drug cocktails: Implications on pharmacokinetics and drug toxicities.

The use of drug cocktails has become a widely adopted strategy in clinical cancer therapy. Cytotoxic drug cocktails are often administered based on maximum tolerated dose (MTD) of each agent, with the belief of achieving maximum cell kill through tolerable toxicity level. Yet, MTD administration may not have fully captured the therapeutic synergism that exists among the individual agents in the drug cocktail, as the response to a cocktail regimen, that is, whether the effect is synergistic or not, could be highly sensitive to the concentration ratios of the individual drugs at the site of action. It is important to realize that the inherently different pharmacokinetic profiles of the individual agents could have significant influence on the response to an anti-cancer drug cocktail by dictating the amount of the individual agents reaching the tumor site and therefore the concentration ratios. Furthermore, the individual agents may have unfavorable pharmacokinetic interactions that add to the difficulty in determining the therapeutic and/or toxicological effects of the drug cocktail. In this review, we will focus on how lipid-based nanoparticulate systems could address the above issues associated with anti-cancer drug cocktails. Specifically, we will highlight the use of liposome systems as the means to control and coordinate the delivery of various anti-cancer drug cocktails, encompassing conventional chemotherapeutics, chemosensitizing agents and molecularly targeted agents.