Polymeric micelles modified by folate-PEG-lipid for targeted drug delivery to cancer cells in vitro.

A novel technique was developed for the formation of ligand-targeted polymeric micelles that can be applicable to various ligands. For tumor-specific drug delivery, camptothecin (CPT)-loaded polymeric micelles were modified by folate to produce a folate-receptor-targeted drug carrier. Folate-linked PEG5000-distearoylphosphatidylethanolamine (folate-PEG5000-DSPE) was added when preparations of drug-loaded polymeric micelles, resulting in folate ligands exposed to the surface. Folate-modified CPT-loaded polymeric micelles (F-micelle) were evaluated by measuring cellular uptake using a flow cytometer, fluorescence microscopy, and confocal laser scanning microscopy, and by cytotoxicity measurement. The results revealed that F-micelle showed higher cellular uptake in KB cells overexpressing folate receptor (FR) and higher cytotoxicity compared with non-folate modified CPT-loaded polymeric micelles (plain micelles) in KB cells, but not in FR-negative HepG2 cells. This result indicated that polymeric micelles were successfully modified by the folate-linked lipid.

Artificial lipids stabilized camptothecin incorporated in liposomes.

Camptothecin (CPT) has anticancer activity. While only the lactone form of CPT is biologically active, this form exhibits poor aqueous solubility. Pharmaceutical formulation of CPT incorporated in liposomes is of significant importance to develop the therapeutic utilization of CPT. The aim of this study was to increase incorporation efficiency and stability of CPT in liposomes composed of hydrogenated soybean phosphatidylcholine, cholesterol, and oleic acid (7 : 3 : 1, molar ratio), by incorporating three kinds of artificial lipids (DBs) (DB-liposome); 4-n-(M12B), 3,5-bis(B12B) and 3,4,5-tris(dodecyloxy)benzoic acid (T12B). The interaction of CPT with DB in the state of liposomes, was examined. In DB-liposomes presenting mean diameters of 150 nm, incorporation efficiency of CPT up to 55% and final drug to lipid molar ratio up to 0.07 were obtained when the liposomes were prepared at a feeding ratio of 1/30 (w/w) CPT/total lipid. However, in the optimal formulations, incorporated DB mol% was different; T12B and D12B were incorporated about one third and half mol% of M12B, respectively. Moreover, we demonstrated that T12B stabilized CPT in liposomes significantly compared with other DBs as measured by CPT release, and by steady state fluorescence polarization degree of CPT using intrinsic fluorescence of CPT. These findings suggested that in addition of contribution of phenyl group of DB, dodecyloxy group may interact strongly with lactone ring of CPT. The capacity to contain CPT interacted with DBs may be limited in liposomes. T12B may be incorporated in the interior of the bilayers, resulting in increase of incorporation stability of CPT. This finding demonstrates a potential application of the novel liposome formulation of CPT in drug delivery.

What are determining factors for stable drug incorporation into polymeric micelle carriers? Consideration on physical and chemical characters of the micelle inner core.

Partially benzyl-esterified poly(ethylene glycol)-b-poly(aspartic acid) (PEG-P(Asp(Bzl))) having different hydrophobic inner-core structure were synthesized and analyzed. We obtained two types of the block copolymers for formation of polymeric micelle drug carriers; one had an amide-bond ratio of 1:3 (alpha/beta) in the poly(aspartic acid) residues through alkaline hydrolysis, and the other one had 100% of the alpha-amide through acid hydrolysis. Subsequently, we prepared partially benzyl-esterified block copolymers with an esterification degree of 40 to 100% in the aspartic acid residue. Regarding camptothecin (CPT) incorporation into polymeric micelles, we evaluated effects that block copolymers' inner hydrophobic block structures have on CPT behavior. Regarding CPT-incorporation stability, PEG-P(alpha,beta-Asp(Bzl) block copolymers with the alpha and beta-amides were found to exhibit higher CPT-incorporation stability. Using fluorescent probes, we evaluated the properties of inner-core blocks such as hydrophobicity and mobility/rigidity, and the findings implied that stable CPT incorporation could be obtained by an adequate balance between the micelle inner core's hydrophobicity and the micelle inner core's rigidity or between the micelle inner core's hydrophobicity and steric configuration of the hydrophobic block chain.