Kumi Kawano

Block copolymer design for camptothecin incorporation into polymeric micelles for passive tumor targeting.

AbstractPurpose. Polymeric micelles were designed for targeting of a water-insoluble anticancer agent, camptothecin (CPT). Chemical structures of inner core segment were optimized to achieve high incorporation efficiency and stable CPT-loaded micelles. Methods. Poly(ethylene glycol)-poly(β-benzyl L-aspartate) block copolymer (PEG-PBLA) was synthesized. The PBLA chain was modified by alkaline hydrolysis of its benzyl group followed by esterification with benzyl, n-butyl, and lauryl groups. Incorporation of CPT into micelles was carried out by an evaporation method. The stability of drug-loaded micelles was studied by gel-permeation chromatography (GPC), and their in vitro release behaviors were analyzed. Results. CPT was incorporated into polymeric micelles constructed by various block copolymers. Among the esterified groups, block copolymers with high benzyl ester contents showed high CPT loading efficiency and stable CPT-loaded micelles. In chain lengths, 5-27 Bz-69 showed the highest incorporation efficiency. In contrast, 5-52 Bz-67, which had a longer hydrophobic chain, showed low incorporation efficiency. Release of CPT from the micelles was dependent on the benzyl contents and chain lengths. Sustained release was obtained when the benzyl content was high. Conclusions. CPT was successfully incorporated into polymeric micelles with high efficiency and stability by optimizing chemical structures of the inner core segment.

Design of Folate-Linked Liposomal Doxorubicin to its Antitumor Effect in Mice

Purpose: Tumor cell targeting is a promising strategy for enhancing the therapeutic potential of chemotherapy agents. Polyethylene glycol (PEG)-coated (sterically stabilized) liposomes show enhanced accumulation on the surface of tumors, but steric hindrance by PEGylation reduces the association of the liposome-bound ligand with its receptor. To increase folate receptor (FR) targeting, we optimized the concentration and PEG spacer length of folate-PEG-lipid in liposomes. Experimental Design: Three types of folate-linked liposomal doxorubicin were designed and prepared by optimizing the concentration and PEG spacer length of folate-PEG-lipid in PEGylated or non-PEGylated liposomes and by masking folate-linked liposomes where the folate ligand is “masked” by adjacent PEG spacers. The liposome targeting efficacy was evaluated in vitro and in vivo. Results: In human oral carcinoma KB cells, which overexpress FR, modification with sufficiently long PEG spacer and a high concentration of folate ligand to non-PEGylated liposomes increased the FR-mediated association and cytotoxicity more than with PEGylated and masked folate-linked liposomes. On the contrary, in mice bearing murine lung carcinoma M109, modification with the folate ligand in PEGylated and masked folate-linked liposomes showed significantly higher antitumor effect than with non-PEGylated liposomes irrespective of the length of time in the circulation after intravenous injection. Conclusions: The results of this study will be beneficial for the design and preparation of ligand-targeting carriers for cancer treatment.

Preparation and in vivo imaging of PEG-poly(L-lysine)-based polymeric micelle MRI contrast agents.

A polymeric micelle drug carrier system was applied to the targeting of an MRI (magnetic resonance imaging) contrast agent. A block copolymer, PEG-b-poly(L-lysine), was used for conjugation of gadolinium ions through chelating moieties, DOTA. The DOTA moieties were successfully conjugated to all primary amine groups of the lysine residues. The obtained block copolymer, PEG-b-poly(L-lysine-DOTA), formed a polymeric micelle. The polymeric micelle structure was maintained even after partial gadolinium chelation ( approximately 40%) to the DOTA moieties. The prepared polymeric micelle MRI contrast agent was injected into a mouse tail vein at a dose of 0.05 mmol Gd/kg. The polymeric micelle-based MRI contrast agent exhibited stable blood circulation. A considerable amount (6.1+/-0.3% of ID/g of the polymeric micelle) was found to accumulate at solid tumors 24 h after intravenous injection by means of the EPR effect. An MRI analysis revealed that the signal intensity of the tumor was enhanced 2.0-fold by the use of this contrast agent.

Effect of Polyethylene Glycol Linker Chain Length of Folate-Linked Microemulsions Loading Aclacinomycin A on Targeting Ability and Antitumor Effect In vitro and In vivo

Purpose: To establish a novel formulation tumor-targeted drug carrier of lipophilic antitumor antibiotics, aclacinomycin A (ACM), folate-linked microemulsions were prepared and investigated both in vitro and in vivo. Experimental Design: Three kinds of folate-linked microemulsions with different polyethylene glycol (PEG) chain lengths loading ACM were formulated with 0.24 mol% folate-PEG2000-distearoylphosphatidylethanolamine (DSPE), folate-PEG5000-DSPE, and folate-lipid (without PEG linker) in microemulsions. In vitro studies were done in a human nasopharyngeal cell line, KB, which overexpresses the folate receptor (FR), and a human hepatoblastoma cell line, [FR(−)] HepG2. In vivo experiments were done in a KB xenograft by systemic administration of folate-linked microemulsions loading ACM. Results: The association of folate-linked microemulsions to KB cells could be blocked by 2 mmol/L free folic acid. Selective FR-mediated cytotoxicity of folate-linked microemulsions loading ACM was obtained in KB but not in HepG2 cells. The association of the folate-PEG5000-linked microemulsion and folate-PEG2000-linked microemulsion with the cells was 200- and 4-fold higher, whereas their cytotoxicity was 90- and 3.5-fold higher than those of nonfolate microemulsion, respectively. The folate-PEG5000-linked microemulsions showed 2.6-fold higher accumulation in solid tumors 24 hours after i.v. injection and greater tumor growth inhibition than free ACM. Conclusion: These findings suggest that a folate-linked microemulsion is feasible for tumor-targeted ACM delivery. This study shows that folate modification with a sufficiently long PEG chain on emulsions is an effective way of targeting emulsion to tumor cells.

Polymer Design and Incorporation Methods for Polymeric Micelle Carrier System Containing Water-insoluble Anti-cancer Agent Camptothecin

A water-insoluble anti-cancer agent, camptothecin (CPT) was incorporated to a polymeric micelle carrier system forming from poly(ethylene glycol)–poly(aspartate) block copolymers. Incorporation efficiency and stability were analyzed in correlation with chemical structures of the inner core-forming hydrophobic blocks as well as with incorporation methods. Among three incorporation methods (dialysis, emulsion and evaporation methods), an evaporation method brought about much higher CPT yields with less aggregation than the other two methods. By the evaporation method, CPT was incorporated to polymeric micelles in considerably high yields and with high stability using block copolymers possessing high contents of benzyl and methylnaphtyl ester groups as hydrophobic moieties. This indicates importance of molecular design of the hydrophobic block chain to obtain targeting using polymeric micelle carriers as well as importance of the drug incorporation method.

In vivo antitumor activity of camptothecin incorporated in liposomes formulated with an artificial lipid and human serum albumin

Camptothecin (CPT) is a strong antitumor agent, but its use limited by its low solubility and the instability of the active lactone form. To overcome these difficulties, liposomes incorporating CPT (CPT liposomes) were designed and tested. CPT liposomes were formulated by the addition of 3,5-bis(dodecyloxy)benzoic acid (DB) to polyethylene glycol-containing liposomes, and by coating the surface of the liposomes with human serum albumin (HSA, HSA-DB-L). HSA-DB-L successfully entrapped CPT with about 80% efficiency and with a particle size of about 150 nm. HSA-DB-L showed attenuated drug release and storage stability. Pharmacokinetics studies in mice showed that i.v. injection of HSA-DB-L (2.5 mg/kg) led to prolonged circulation in the plasma; the area under the curve was 22-fold higher than that of CPT solution. The tumor growth in mice with subcutaneous transplantation of colon 26 tumor cells was significantly inhibited after a single i.v. injection of HSA-DB-L at a dose of 15 mg/kg without any significant body weight loss. HSA-DB-L increased the accumulation of CPT in tumor tissue significantly (9.6-fold) more efficiently than CPT solution 24 h after i.v. injection. These findings suggest that HSA-DB-L could increase the stability and the antitumor effect of CPT. CPT delivery by novel liposome formulations is a potential approach for effective treatment of cancer.

Hydrophobic blocks of PEG-conjugates play a significant role in the accelerated blood clearance (ABC) phenomenon.

Injections of poly(ethylene glycol)-modified liposomes (PEG-liposomes) cause rapid clearance of the second dose of PEG-liposomes. This phenomenon is known as the accelerated blood clearance (ABC) phenomenon. Previous studies have suggested that PEG-specific IgM (anti-PEG IgM) can play a major role in the ABC phenomenon. In our previous study, however, a PEG-shell-possessing polymeric micelle with hydrophilic inner core (PEG-P(Lys-DOTA-Gd) micelle) did not induce the ABC phenomenon nor the IgM responses, and exhibited no change in its plasma concentration in PEG-liposome-injected mice. In the present paper, we studied the ABC-phenomenon in more detail by comparing the behaviors between PEG-liposomes, PEG-P(Lys-DOTA-Gd) micelle, and hydrophobic-core-possessing PEG-PBLA micelles. We demonstrated that the PEG-PBLA micelle induced similar IgM responses as observed in PEG-liposome; however, the second dose of PEG-PBLA micelle exhibited no decreases in their plasma concentration, while the second dose of PEG-liposome did exhibit rapid clearances. Furthermore, we did not observe any PEG main chain specific IgM in PEG-liposome injected mice by sandwich ELISA which can measure more specific IgM to the PEG main chain theoretically. These results suggested that the induced IgM recognizes an interface between PEG chain and hydrophobic chain, rather than PEG main chain, and the anti-PEG IgM hypothesis should be re-evaluated.

Novel irinotecan-loaded liposome using phytic acid with high therapeutic efficacy for colon tumors.

Phytic acid (IP-6) is a polyphosphorylated carbohydrate with antitumor activity for many kinds of tumors. In this study, we developed a novel method of loading irinotecan (CPT-11) into liposomes using IP-6, and evaluated its antitumor effect on colon tumors in vivo. Liposomal CPT-11 was prepared by loading CPT-11 to distearoylphosphatidylcholine/cholesterol/methoxy-poly(ethyleneglycol)-distearylphosphatidylethanolamine liposomes prepared in IP-6 solution, CuSO(4) solution and citrate buffer, respectively (IP6-, Cu- and Cit-L). CPT-11 loading efficiency for IP6-L (90-100%) was higher than that for Cit-L (less than 40%), and similar to Cu-L when CPT-11 to total lipid weight ratio was increased from 0.2 to 0.6. Plasma elimination and biodistribution of liposomal CPT-11 and its metabolite SN-38 were measured after intravenous administration. IP6-L following i.v. injection showed 1.3- and 1.7-fold higher plasma area under the curves of CPT-11 and SN-38, respectively, than Cu-L. Finally, therapeutic activity was determined in mouse Colon 26 and human COLO 320DM tumor xenografts in mice. IP6-L significantly exhibited superior anticancer activity to Cu-L and free CPT-11 in Colon 26 tumor. Using IP-6 as a drug-trapping agent in liposome, IP6-L improved CPT-11 pharmacokinetics and increased antitumor activity in colon tumors.

Development of High Boron Content Liposomes and Their Promising Antitumor Effect for Neutron Capture Therapy of Cancers

Mercaptoundecahydrododecaborate (BSH)-encapsulating 10% distearoyl boron lipid (DSBL) liposomes were developed as a boron delivery vehicle for neutron capture therapy. The current approach is unique because the liposome shell itself possesses cytocidal potential in addition to its encapsulated agents. BSH-encapsulating 10% DSBL liposomes have high boron content (B/P ratio: 2.6) that enables us to prepare liposome solution with 5000 ppm boron concentration. BSH-encapsulating 10% DSBL liposomes displayed excellent boron delivery efficacy to tumor: boron concentrations reached 174, 93, and 32 ppm at doses of 50, 30, and 15 mg B/kg, respectively. Magnescope was also encapsulated in the 10% DSBL liposomes and the real-time biodistribution of the Magnescope-encapsulating DSBL liposomes was measured in a living body using MRI. Significant antitumor effect was observed in mice injected with BSH-encapsulating 10% DSBL liposomes even at the dose of 15 mg B/kg; the tumor completely disappeared three weeks after thermal neutron irradiation ((1.5-1.8) × 10(12) neutrons/cm(2)). The current results enabled us to reduce the total dose of liposomes to less than one-fifth compared with that of the BSH-encapsulating liposomes without reducing the efficacy of boron neutron capture therapy (BNCT).

Selective delivery of folate–PEG-linked, nanoemulsion-loaded aclacinomycin A to KB nasopharyngeal cells and xenograft: Effect of chain length and amount of folate–PEG linker

To investigate the use of folate-targeted nanoemulsion-loaded aclacinomycin A (ACM) to folate receptor (FR)-positive cells, we attempted to optimize the targeting ability of nanoemulsions by modifying the chain length and amount of the folate–PEG linker. Folate-linked, nanoemulsion-loaded ACM were formulated with 0.24 mol% of folate-poly (ethylene glycol)3400- (folate–PEG3400-) and folate–PEG5000-distearoylphosphatidylethanolamine (DSPE), and 0.03 mol% of folate–PEG5000–DSPE in nanoemulsions. Selective FR-mediated uptake was achieved in a human nasopharyngeal tumor cell line, KB, which overexpresses FR, but not in a human hepatoblastoma cell line, (FR(-)) HepG2. At the same amount of folate modification, the association with KB cells was increased with increasing the PEG-chain length. The association of 0.03 and 0.24 mol% folate–PEG5000-linked nanoemulsions with cells was 5- and 3.3-fold higher than that of non-folate nanoemulsion, respectively, while their cytotoxicity was similar. Both 0.03 and 0.24 mol% folate–PEG5000-linked nanoemulsions and non-folate nanoemulsion following intravenous injection inhibited tumor growth more significantly than ACM solution on day 24 following tumor inoculation (p < 0.01). This study demonstrates that a folate-linked nanoemulsion is feasible for tumor-targeted ACM delivery, and that folate modification with a sufficiently long PEG-chain and a small amount of nanoemulsion is an effective way of targeting nanoemulsion to tumor cells.