Michiaki Kumagai

Enhanced photodynamic cancer treatment by supramolecular nanocarriers charged with dendrimer phthalocyanine.

Photodynamic therapy (PDT) is a promising method for the localized treatment of solid tumors. In order to enhance the efficacy of PDT, we have recently developed a novel class of photosensitizer formulation, i.e., the dendrimer phthalocyanine (DPc)-encapsulated polymeric micelle (DPc/m). The DPc/m induced efficient and unprecedentedly rapid cell death accompanied by characteristic morphological changes such as blebbing of cell membranes, when the cells were photoirradiated using a low power halogen lamp or a high power diode laser. The fluorescent microscopic observation using organelle-specific dyes demonstrated that DPc/m might accumulate in the endo-/lysosomes; however, upon photoirradiation, DPc/m might be promptly released into the cytoplasm and photodamage the mitochondria, which may account for the enhanced photocytotoxicity of DPc/m. This study also demonstrated that DPc/m showed significantly higher in vivo PDT efficacy than clinically used Photofrin (polyhematoporphyrin esters, PHE) in mice bearing human lung adenocarcinoma A549 cells. Furthermore, the DPc/m-treated mice did not show skin phototoxiciy, which was apparently observed for the PHE-treated mice, under the tested conditions. These results strongly suggest the usefulness of DPc/m in clinical PDT.

Three-layered polyplex micelle as a multifunctional nanocarrier platform for light-induced systemic gene transfer

Nanocarriers responding to light have great potential for pinpoint therapy, and recent studies have revealed promising in vivo activity. However, light-selective gene transfer still remains challenging in the systemic application. Here we report systemic light-responsive nanocarriers for gene delivery developed through the sequential self-assembly of ABC-type triblock copolymer/DNA/dendrimeric photosensitizer, forming polyplex micelles with three-layered functional nanocompartments. The DNA-packaged core is covered by the photosensitizer-incorporated intermediate layer, which is encompassed by an outer shielding shell. This three-layered structure permits multistep photosensitizer and DNA delivery into a solid tumour by a systemic route: the shielding layer minimizes unfavourable interactions with blood components, and the photosensitizer is delivered to endo-/lysosomal membranes to facilitate light-selective cytoplasmic translocation of the micelles, accomplishing DNA delivery into the nucleus to exert gene expression. The polyplex micelles display >100-fold photoenhanced gene expression in cultured cells and exhibit light-induced in vivo gene transfer in solid tumours following systemic administration.

Visible Drug Delivery by Supramolecular Nanocarriers Directing to Single-Platformed Diagnosis and Therapy of Pancreatic Tumor Model

Nanoparticle therapeutics are promising platforms for cancer therapy. However, it remains a formidable challenge to assess their distribution and clinical efficacy for therapeutic applications. Here, by using multifunctional polymeric micellar nanocarriers incorporating clinically approved gadolinium (Gd)-based magnetic resonance imaging contrast agents and platinum (Pt) anticancer drugs through reversible metal chelation of Pt, simultaneous imaging and therapy of an orthotopic animal model of intractable human pancreatic tumor was successfully performed without any serious toxicity. The strong tumor contrast enhancement achieved by the micelles correlated with the 24 times increase of r(1) of the Gd chelates, the highest for the formulations using clinically approved Gd chelates reported to date. From the micro-synchrotron radiation X-ray fluorescence spectrometry scanning of the lesions, we confirmed that both the Gd chelates and Pt drugs delivered by the micelles selectively colocalized in the tumor interior. Our study provides new insights for the design of theranostic micelles with high contrast enhancement and site-specific clinical potential.

Enhanced in vivo Magnetic Resonance Imaging of Tumors by PEGylated Iron-Oxide-Gold Core-Shell Nanoparticles with Prolonged Blood Circulation Properties

High-density poly(ethylene glycol) (PEG)-coated iron-oxide-gold core-shell nanoparticles (AuIONs) were developed as T(2) -weighted magnetic resonance imaging (MRI) contrast agents for cancer imaging. The PEG-coated iron-oxide-gold core-shell nanoparticles (PEG-AuIONs) were approximately 25 nm in diameter with a narrow distribution. Biodistribution experiments in mice bearing a subcutaneous colon cancer model prepared with C26 murine colon adenocarcinoma cells showed high accumulation of the PEG-AuIONs within the tumor mass and low nonspecific accumulation in the liver and spleen, resulting in high specificity to solid tumors. T(2) -weighted MR images following intravenous injection of PEG-AuIONs showed selective negative enhancement of tumor tissue in an orthotopic pancreatic cancer model prepared with MiaPaCa-2 human pancreatic adenocarcinoma cells. These results indicate that PEG-AuIONs are a promising MRI contrast agent for diagnosis of malignant tumors, including pancreatic cancer.

Hydrothermally synthesized PEGylated calcium phosphate nanoparticles incorporating Gd-DTPA for contrast enhanced MRI diagnosis of solid tumors.

Organic-inorganic hybrid nanoparticles with calcium phosphate (CaP) core and PEGylated shell were developed to incorporate magnetic resonance imaging (MRI) contrast agent diethylenetriaminepentaacetic acid gadolinium (III) (Gd-DTPA) for noninvasive diagnosis of solid tumors. A two-step preparation method was applied to elaborate hybrid nanoparticles with a z-average hydrodynamic diameter about 80nm, neutral surface ξ-potential and high colloidal stability in physiological environments by self-assembly of poly(ethylene glycol)-b-poly(aspartic acid) block copolymer, Gd-DTPA, and CaP in aqueous solution, followed with hydrothermal treatment. Incorporation into the hybrid nanoparticles allowed Gd-DTPA to show significant enhanced retention ratio in blood circulation, leading to high accumulation in tumor positions due to enhanced permeability and retention (EPR) effect. Moreover, Gd-DTPA revealed above 6 times increase of relaxivity in the nanoparticle system compared to free form, and eventually, selective and elevated contrast enhancements in the tumor positions were observed. These results indicate the high potential of Gd-DTPA-loaded PEGylated CaP nanoparticles as a novel contrast agent for noninvasive cancer diagnosis.

Disulfide crosslinked polyion complex micelles encapsulating dendrimer phthalocyanine directed to improved efficiency of photodynamic therapy

Dendrimer phthalocyanine (DPc)-loaded polyion complex micelle (DPc/m) has been developed as photosensitizer (PS) formulation in photodynamic therapy (PDT). Incorporation of DPc into the micelle showed significant enhancement in the in vitro photocytotoxicity. Also, introduction of disulfide crosslinking in the micellar core further improved the in vitro PDT effect of DPc/m. Here, we aim to analyze the mechanism of the enhanced photocytotoxicity of DPc/m, particularly focusing on the photochemical reactions during photoirradiation. As a result, DPc/m has been shown to protect DPc from photobleaching induced by the reactions with serum proteins, although DPc were considerably quenched in the micellar core. Furthermore, the introduction of disulfide crosslinking into the micellar core has demonstrated to improve the efficiency of reactive oxygen species (ROS) production by DPc in the micellar core as well as more effectively prevent the photobleaching of DPc. These effects might lead to effective photochemical reactions by DPc/m, which may account for the enhanced photocytotoxicity. Our findings provide useful knowledge in designing PS formulations for effective PDT.

Enhanced magnetic resonance imaging of experimental pancreatic tumor in vivo by block copolymer-coated magnetite nanoparticles with TGF-β inhibitor

Early detection of solid tumors, particularly pancreatic cancer, is of substantial importance in clinics. Enhanced magnetic resonance imaging (MRI) with iron oxide nanoparticles is an available way to detect the cancer. The effective and selective accumulation of these nanoparticles in the tumor tissue is needed for improved imaging, and in this regard, their longevity in the blood circulation time is crucial. We developed here block copolymer-coated magnetite nanoparticles for pancreatic cancer imaging, by means of a chelation between the carboxylic acid groups in poly(ethylene glycol)-poly(aspartic acid) block copolymer (PEG-PAsp) and Fe on the surface of the iron oxide nanoparticles. These nanoparticles had considerably narrow distribution, even upon increased ionic strength or in the presence of fetal bovine serum. The PEG-PAsp-coated nanoparticles were further shown to be potent as a contrast agent for enhanced MRI for an experimental pancreatic cancer, xenografts of the human-derived BxPC3 cell line in BALB/c nude mice, with combined administration of TGF-beta inhibitor. Iron staining of tumor tissue confirmed the accumulation of the nanoparticles in tumor tissue. Use of the PEG-PAsp-coated magnetite nanoparticles, combined with the TGF-beta inhibitor, is of promising clinical importance for the detection of intractable solid cancers, including pancreatic cancer.

Effective transgene expression without toxicity by intraperitoneal administration of PEG-detachable polyplex micelles in mice with peritoneal dissemination

Block copolymer of poly(ethylene glycol)-block-poly{N-[N-(2-aminoethyl)-2-aminoethyl]aspartamide} (PEG-P[Asp(DET)]) has been originally introduced as a promising gene carrier by forming a nanomicelle with plasmid DNA. In this study, the polyplex micelle of PEG-SS-P[Asp(DET)], which disulfide linkage (SS) between PEG and cationic polymer can detach the surrounding PEG chains upon intracellular reduction, was firstly evaluated with respect to in vivo transduction efficiency and toxicity in comparison to that of PEG-P[Asp(DET)] in peritoneally disseminated cancer model. Intraperitoneal (i.p.) administration of PEG-SS-P[Asp(DET)] polyplex micelles showed a higher (P<0.05) transgene expression compared with PEG-P[Asp(DET)] in tumors. In contrast, the delivered distribution of the micelles was not different between the two polyplex micelles. PEG-SS-P[Asp(DET)] micelle encapsulating human tumor necrosis factor α (hTNF-α) gene exhibits a higher antitumor efficacy against disseminated cancer compared with PEG-P[Asp(DET)] or saline control. No hepatic and renal toxicities were observed by the administration of polyplex micelles. In conclusion, PEG-detachable polyplex micelles may represent an advantage in gene transduction in vivo over PEG-undetachable polyplex micelles after i.p. administration for peritoneal dissemination of cancer.

Impaired activities of cyclic adenosine monophosphate-responsive element binding protein, protein kinase A and calcium-independent phospholipase A2 are involved in deteriorated regeneration of cirrhotic liver after partial hepatectomy in rats.

Aims:  This study is to elucidate whether cyclic adenosine monophosphate (cAMP)‐mediated signal is involved in lower regenerative potential of cirrhotic liver.

Abstract 5235: Fluorometric imaging system for visualizing submillimeter level tumors using an ultrathin endoscope

[Background and purpose] Direct observation of pathological lesions by a relatively noninvasive approach is important for understanding pathophysiological mechanism and for assessing the objective response to therapeutic interventions. On the other hand, it is very difficult to perform direct and relatively noninvasive observation of minimal lesions inside a diseased model using a small live animal. However, recent technological developments in imaging, especially significant progress in fluorescent methods and in endoscopic examinations, have enabled detection and tracing of micro-lesions inside small animal models. We have developed a fluorescence imaging technique using high-resolution ultrathin endoscope, which is accessible to hollow organs of small animals. In addition, we have established an orthotopic rat bladder cancer model in which the cancer cells express a fluorescent protein. The aim of this study was to establish a high-resolution imaging method for visualizing the vascular distribution and mucosal morphology of a bladder tumor. [Materials and Methods] GFP-expressing bladder tumor in a rat orthotopic model: Firstly, we established a cell line with stable integration of GFP constructs that were produced by transfection of pTurboGFP into rat bladder cells (AY27). The stable AY27+tGFP populations were purified by repeated selections using Geneticin (G418). AY27-tGFP cells were implanted in the bladders of female Fischer F344 rats, resulting in development of submillimeter-sized bladder tumors. Development of fluorescence ultrathin endoscopy: We developed a fluorescence ultrathin endoscopic system installed with a 180 W Xenon lamp with excitation filters and 3CCD camera with emission filters. The outer diameter of the ultrathin endoscopic fiber is only 0.8 mm, but its number of pixels reaches 15,000, resulting in a spatial resolution of 50μm. [Results] Fluorescence from AY27-tGFP cells implanted in the bladder was clearly visualized by the ultrathin endoscope placed in the bladder by the transurethral approach. Furthermore, when fluorescence-probed tumor-directive micelles were injected (i.v.) into the animals as a model of drug delivery, fluorescence from the probe agents was visualized in accordance with tumor distribution. In both cases, we detected fluorescence from tumors of less than 1 mm in size. [Conclusion] We established an orthotopic GFP-tumor rat model using a GFP-expressing tumor cell line (AY27-tGFP). Submillimeter tumors in this model were visualized by the newly developed ultrathin endoscopic system. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 5235.