In vitro tumor cell culture models have illuminated the potential therapeutic utility of elevating the intracellular concentration of the antimitogenic and proapoptotic sphingolipid, ceramide. However, although cell-permeable, short-chain ceramide is an effective apoptotic agent in vitro, its use as an in vivo, systemically delivered therapeutic is limited by its inherent lipid hydrophobicity and physicochemical properties. Here, we report that the systemic i.v. delivery of C 6 -ceramide (C 6 ) in a pegylated liposomal formulation significantly limited the growth of solid tumors in a syngeneic BALB/c mouse tumor model of breast adenocarcinoma. Over a 3-week treatment period, a well-tolerated dose of 36 mg/kg liposomal-C 6 elicited a >6-fold reduction in tumor size compared with empty ghost liposomes. Histologic analyses of solid tumors from liposomal-C 6 -treated mice showed a marked increase in the presence of apoptotic cells, with a coincident decrease in cellular proliferation and in the development of a microvessel network. Liposomal-C 6 accumulated within caveolae and mitochondria, suggesting putative mechanisms by which ceramide induces selective cancer cell cytotoxicity. A pharmacokinetic analysis of systemic liposomal-C 6 delivery showed that the pegylated liposomal formulation follows first-order kinetics in the blood and achieves a steady-state concentration in tumor tissue. Confirming the therapeutic utility of i.v. liposomal-C 6 administration, we also shown diminution of solid tumor growth in a human xenograft model of breast cancer. Together, these results indicate that bioactive ceramide analogues can be incorporated into pegylated liposomal vehicles for improved solubility, drug delivery, and antineoplastic efficacy.Sphingolipids not only serve a structural role in membranes but also are substrates for the generation of bioactive second messengers that influence mitogenesis and apoptosis. Metabolism of sphingomyelin, the major sphingolipid in membranes, forms ceramide, a potent lipid-derived second messenger that modulates the induction of cell differentiation, cell cycle arrest, and/or apoptosis (1 -4). In addition, chemotherapeutic agents (5 -7) and ionizing radiation (8, 9) are two of the multiple cellular stressors (10 -16) that lead to the accumulation of ceramide within membranes. We and others have shown that ceramide-mediated signaling cascades induce apoptosis in part via the inhibition of Akt prosurvival pathways, mitochondrial dysfunction, and the stimulation of caspase activity, which ultimately leads to DNA fragmentation and cell death (17 -21).Although short-chain, cell-permeable ceramides, such as C 6 -ceramide (C 6 ), have been shown to be antiproliferative and proapoptotic in numerous cancer cell types in vitro (22, 23), there are obstacles to the delivery of ceramide for systemic applications, such as cancer chemotherapy. Despite being more efficacious than physiologic long-chain ceramides (C 18 -C 24 -ceramide), the effectiveness of cell-permeable ceramide analogues re...
