Kosuke Shimizu

PET imaging of brain cancer with positron emitter-labeled liposomes

Since nanocarriers such as liposomes are known to accumulate in tumors of tumor-bearing animals, and those that have entrapped a positron emitter can be used to image a tumor by PET, we applied (18)F-labeled 100-nm-sized liposomes for the imaging of brain tumors. Polyethylene glycol (PEG)-modified liposomes, which are known to accumulate in tumors by passive targeting and those modified with Ala-Pro-Arg-Pro-Gly, which are known to home into angiogenic sites were used. Those liposomes labeled with DiI fluorescence accumulated in a glioma implanted in a rat brain 1h after the injection, although they did not accumulate in the normal brain tissues due to the protection afforded by the blood-brain barrier. Preformed liposomes were easily labeled with 1-[(18)F]fluoro-3,6-dioxatetracosane, and enabled the imaging of gliomas by PET with higher contrast than that obtained with [(18)F]deoxyfluoroglucose. In addition, the smallest tumor among those tested, having a diameter of 1mm was successfully imaged by the liposomal (18)F. Therefore, nanocarrier-based imaging of brain tumors is promising for the diagnosis of brain cancer and possible drug delivery-based therapy.

A novel DDS strategy, “dual-targeting”, and its application for antineovascular therapy

Dual-targeting liposomes modified with Ala-Pro-Arg-Pro-Gly (APRPG) and Gly-Asn-Gly-Arg-Gly (GNGRG) peptides were developed. They remarkably associated to growing human umbilical vein endothelial cells (HUVECs) compared with single-targeting liposomes modified with APRPG or GNGRG. Doxorubicin (DOX) encapsulated in the dual-targeting liposomes significantly suppressed the growth of HUVECs compared with that in single-targeting liposomes. The dual-targeting liposomes containing DOX strongly suppressed tumor growth in Colon26 NL-17 carcinoma-bearing mice. Confocal microscopic data indicated that this anticancer effect was brought by the association of these liposomes to angiogenic vessels in the tumor. These findings suggest that dual-targeting would be a hopeful method for targeting therapies.

In Vivo Distribution of Liposome‐Encapsulated Hemoglobin Determined by Positron Emission Tomography

Positron emission tomography (PET) is a noninvasive imaging technology that enables the determination of biodistribution of positron emitter-labeled compounds. Lipidic nanoparticles are useful for drug delivery system (DDS), including the artificial oxygen carriers. However, there has been no appropriate method to label preformulated DDS drugs by positron emitters. We have developed a rapid and efficient labeling method for lipid nanoparticles and applied it to determine the movement of liposome-encapsulated hemoglobin (LEH). Distribution of LEH in the rat brain under ischemia was examined by a small animal PET with an enhanced resolution. While the blood flow was almost absent in the ischemic region observed by [(15)O]H(2)O imaging, distribution of (18)F-labeled LEH in the region was gradually increased during 60-min dynamic PET scanning. The results suggest that LEH deliver oxygen even into the ischemic brain from the periphery toward the core of ischemia. The real-time observation of flow pattern, deposition, and excretion of LEH in the ischemic rodent brain was possible by the new methods of positron emitter labeling and PET system with a high resolution.

Antiangiogenic cancer therapy using tumor vasculature-targeted liposomes encapsulating 3-(3,5-dimethyl-1H-pyrrol-2-ylmethylene)-1,3-dihydro-indol-2-one, SU5416

Previously, we identified angiogenic vessel-homing peptide Ala-Pro-Arg-Pro-Gly (APRPG), and showed that APRPG-modified liposomes could selectively target to tumor neovasculature. Here, we designed an APRPG-modified liposome encapsulating SU5416, an angiogenesis inhibitor, to overcome the solubility problem, and to enhance the antiangiogenic activity of SU5416. Liposomal SU5416 appeared to have the appropriate characteristics, such as particle size and stability in serum. It showed a significantly lower hemoglobin release than SU5416 dissolved in a Cremophor EL-containing solvent. Compared with peptide-unmodified liposomal SU5416, the APRPG-modified liposomal SU5416 significantly suppressed tumor growth and with no remarkable side effects. Thus, targeted delivery of antiangiogenic drugs with tumor vasculature-targeted liposomes may be useful for antiangiogenic cancer therapy.

Antineovascular therapy with angiogenic vessel-targeted polyethyleneglycol-shielded liposomal DPP-CNDAC.

Causing damage to angiogenic vessels is a promising approach for cancer chemotherapy. The present study is a codification of a designed liposomal drug delivery system (DDS) for antineovascular therapy (ANET) with 2′‐C‐cyano‐2′‐deoxy‐1‐β‐D‐arabino‐pentofuranosylcytosine (CNDAC). The authors have previously reported that liposomalized 5′‐O‐dipalmitoylphosphatidyl CNDAC (DPP–CNDAC), a phospholipid derivative of the novel antitumor nucleoside CNDAC, is quite useful for ANET. DPP–CNDAC liposomes modified with APRPG, a peptide having affinity toward angiogenic vessels, efficiently suppressed tumor growth by damaging angiogenic endothelial cells. In the present study, the authors masked the hydrophilic moiety of DPP–CNDAC, namely, CNDAC, on the liposomal surface with APRPG–polyethyleneglycol (PEG) conjugate to improve the availability of DPP–CNDAC liposomes. The use of the APRPG–PEG conjugate attenuated the negative ζ‐potential of the DPP–CNDAC liposomes and reduced the agglutinability of them in the presence of serum. These effects improved the blood level of DPP–CNDAC liposomes in colon 26 NL‐17 tumor‐bearing BALB/c male mice, resulting in enhanced accumulation of them in the tumor. Laser scanning microscopic observations indicated that APRPG–PEG‐modified DPP–CNDAC liposomes (LipCNDAC/APRPG–PEG) colocalized with angiogenic vessels and strongly induced apoptosis of tumor cells, whereas PEG‐modified DPP–CNDAC liposomes (LipCNDAC/PEG) did not. In fact, LipCNDAC/APRPG–PEG suppressed the tumor growth more strongly compared to LipCNDAC/PEG and increased significantly the life span of the mice. The present study is a good example of an effective liposomal DDS for ANET that is characterized by: (i) phospholipid derivatization of a certain anticancer drug to suit the liposomal formulation; (ii) PEG‐shielding for masking undesirable properties of the drug on the liposomal surface; and (iii) active targeting to angiogenic endothelial cells using a specific probe. (Cancer Sci 2008; 99: 1029–1033)

Temperature-dependent transfer of amphotericin B from liposomal membrane of AmBisome to fungal cell membrane

Liposomal amphotericin B (AMPH-B), also known as AmBisome, exhibits a potent antifungal effect through its binding to ergosterol contained within the fungal cell membrane. However, the mechanism responsible for the movement of AmBisome-derived AMPH-B to the fungal cell membrane through the cell wall is not yet clear. Therefore, in the present study we aimed at elucidating this mechanism operating in Saccharomyces cerevisiae. AmBisome showed its antifungal effect against S. cerevisiae at 35 degrees C but not at 4 degrees C, whereas free AMPH-B was effective at both temperatures. A significant difference in the amount of AMPH-B transferred to the fungal cells between incubation at 4 and 35 degrees C was also observed when AmBisome was used. Confocal microscopic study, however, indicated that NBD-labeled AmBisome was localized on the surface of the fungal cells at either temperature. To decrease the affinity of AMPH-B for the liposomal membrane, we entrapped AMPH-B in fluid liposomes containing egg yolk phosphatidylcholine (EPC) instead of hydrogenated soy PC (HSPC). These liposomes showed the antifungal effect even at 4 degrees C. On the contrary, AMPH-B in liposomes containing ergosterol (Erg-AmB) instead of cholesterol showed a significantly weaker antifungal effect at 35 degrees C with reduced transfer of AMPH-B to the fungal cells. These results suggest that not the binding of AmBisome to target cells but the transfer of AMPH-B from liposomal membrane of AmBisome to the cell membrane is critical for the antifungal activity of AmBisome. This transfer is dependent on the temperature, fluidity of the liposomal membrane, and the affinity of AMPH-B for the fungal cell membrane.

Anti-obesity effect of phosphatidylinositol on diet-induced obesity in mice.

The aim of this study is to investigate the biodistribution of phosphatidylinositol (PI) after oral administration and its anti-obesity effect. When a suspension of radiolabeled PI was orally administered to mice and the biodistribution was examined, PI radioactivity accumulated in the liver compared to myo-inositol radioactivity at 48 h or later after administration. Then, a PI suspension was orally administered to diet-induced obesity (DIO) mice every 4 days, and the anti-obesity effect of PI was examined. As a result, PI suppressed the body weight increase of DIO mice and significantly reduced the plasma levels of aspartate aminotransferase (AST) and cholesterol. Furthermore, PI regulated the expression of some genes in the liver involved in lipid synthesis and metabolism. The present study demonstrated that PI accumulated in the liver after oral administration and exerted its anti-obesity effect on DIO by regulating the expression of certain genes involved in lipid metabolism in the liver.