Novel therapeutic nano-particles (lipocores): trapping poorly water soluble compounds.

The development of stable spherical lipid-coated drug particles that are termed 'lipocores' is reported here. Unlike conventional lipid-based particles (i.e. liposomes, emulsions, micelles), these particles are comprised solely of a core of a poorly water soluble drug surrounded by polyethyleneglycol conjugated lipid (PEG-lipid) and are formed via a 'kinetic' trapping process. These lipocore particles were made with the acyl chain of 16 carbon length (C16) acyl-chain derivatives of paclitaxel or vinblastine and with the polyene antifungal hamycin. Formation of the particles occurred regardless of the type of PEG-phospholipid used (i.e. acyl chain length, chain saturation, and polymer length) and could also be formed with the negatively charged lipid N-glutaryl-dioleoyl-phosphatidylethanolamine (DOPE-GA). Images from both freeze-fracture electron microscopy and electron cryo-microscopy revealed solid spherical structures with no internal lamellae for the PEG-lipid particles made with the C16 derivatives of paclitaxel (BrC16-T) or vinblastine (C16-Vin). From a solute distribution study of lipocores made with BrC16-T and distearoyl-phosphatidylethanolamine-PEG2000 (DSPE-PEG2000), the particles were found to have no measurable aqueous captured volume. Fluorescence anisotropy and order parameter measurements revealed the core material of these particles to be highly immobilized. The mole ratio of BrC16-T:lipid in the lipocores was typically > 90: < 10 and as high as 98:2, and the refrigerated lipocores were stable for several months. BrC16-T/DSPE-PEG2000 lipocores of 50-100 nm particle size were far less toxic than paclitaxel (Taxol) after intraperitoneally (i.p.) or intravenously (i.v.) administration in mice and were active against i.p. and subcutaneously (s.c.) planted human (OvCar3) ovarian carcinoma grown in SCID mice. It is believed the high drug:lipid ratio, the stability, and therapeutic efficacy of these novel particles make them a paradigm for delivery of poorly water soluble drugs and/or their hydrophobic derivatives.

Growth inhibition of a human ovarian tumor by a novel paclitaxel derivative in SCID mice.

We report here the toxicity and therapeutic effects of 2'-alpha-bromohexadecanoyl paclitaxel (BrC16HT), a prodrug form of paclitaxel, in mice. Paclitaxel is the active ingredient of Taxol. The maximum tolerated dose, at a one dose per day for 5-day schedule, was 37.5 mg/kg for BrC16HT compared to 12.5 for Taxol administered IP, and was 12.5-25 mg/kg for either agent administered IV. Dose-dependent therapeutic effects were found for BrC16HT against a human ovarian tumor (OVCAR-3) grown in SCID mice. IP treatments with BrC16HT against early or established IP-implanted OVCAR-3 tumor increased mean survival times more than treatment with Taxol. Long-term survivors were found only in groups treated with BrC16HT. Intravenously administered BrC16HT was more effective than Taxol against SC OVCAR-3 tumor. Early treatment (25 mg/kg x 5) completely inhibited tumor growth through 120 days after tumor implantation. Pharmacokinetic studies suggest that BrC16HT is slowly hydrolyzed to paclitaxel and circulates longer than paclitaxel from Taxol. Thus, BrC16HT may provide sustained levels of paclitaxel, which may contribute to the increased efficacy of BrC16HT compared to Taxol.

Enhanced therapeutic effects of liposome-associated 1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphocholine.

The ether-lipid 1-O-octadecyl-2-O-methyl-sn-glycero-3-phosphocholine (ET-18-OCH3) has anticancer activity, but systemic toxicity has restricted its therapeutic use. In this report "free" ET-18-OCH3 and a stable, well-characterized, liposome-based formulation of ET-18-OCH3 (ELL-12) were compared for in vivo toxicity in normal mice and for therapeutic efficacy in three mouse tumor model systems. The entrapment of ET-18-OCH3 in liposomes decreased the acute toxicity of ET-18-OCH3 after i.v. administration. The maximum tolerated dose for a single i.v. dose of free ET-18-OCH3 was found to be approximately 25 mg/kg, whereas the maximum tolerated dose for ELL-12 was approximately 200 mg/kg. ELL-12 was much less hemolytic in vivo than ET-18-OCH3. The therapeutic efficacy of free ET-18-OCH3 and ELL-12 was investigated against i.p. P388 leukemia, Lewis lung cancer lung metastases, and B16/F10 melanoma (lung tumor nodules) in mice. Although ET-18-OCH3 had some anticancer activity, it was found that ELL-12 was more effective than ET-18-OCH3 in all three tumor models at lower and nontoxic dose schedules. These results suggest that association of ET-18-OCH3 in stable, well-characterized liposomes transforms it into an effective antitumor agent.