Hiroyuki Honda scite author profile

Heat shock proteins (HSPs) are highly conserved proteins whose syntheses are induced by a variety of stresses, including heat stress. Since the expression of HSPs, including HSP70, protects cells from heat-induced apoptosis, HSP expression has been considered to be a complicating factor in hyperthermia. On the other hand, recent reports have shown the importance of HSPs, such as HSP70, HSP90 and glucose-regulated protein 96 (gp96), in immune reactions. If HSP expression induced by hyperthermia is involved in tumor immunity, novel cancer immunotherapy based on this novel concept can be developed. In such a strategy, a tumor-specific hyperthermia system, which can heat the local tumor region to the intended temperature without damaging normal tissue, would be highly advantageous. To achieve tumor-specific hyperthermia, we have developed an intracellular hyperthermia system using magnetite nanoparticles. This novel hyperthermia system can induce necrotic cell death via HSP expression, which induces antitumor immunity. In the present article, cancer immunology and immunotherapy based on hyperthermia, and HSP expression are reviewed and discussed.

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Magnetite nanoparticle-loaded anti-HER2 immunoliposomes for combination of antibody therapy with hyperthermia

Ito

et al. 2004

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Novel Methodology for Fabrication of Tissue-Engineered Tubular Constructs Using Magnetite Nanoparticles and Magnetic Force

et al. 2005

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Novel technologies for creating three-dimensional constructs with complex shapes would be highly useful in tissue engineering. In the present study, tubular structures were constructed using magnetic force. Magnetite nanoparticles in cationic liposomes were taken up by target cells. The magnetically labeled cells were seeded onto ultralow-attachment plates, and a magnet was placed under the wells. After 24 h of culture, the magnetically labeled cells formed a cell sheet. Subsequently, when a cylindrical magnet was rolled onto the cell sheet, the cell sheet was attracted to the magnet and formed a tube around it. The magnet was then removed, leaving behind a tubular structure. Two types of tissue were used to create tubular structures: urinary tissue, consisting of a monotypic urothelial cell layer; and vascular tissue, consisting of heterotypic layers of endothelial cells, smooth muscle cells, and fibroblasts. The present results suggest that this novel methodology using magnetite nanoparticles and magnetic force, which we have termed "magnetic force-based tissue engineering" (Mag-TE), is a promising approach to constructing tissue-engineered tubular structures.

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Tissue Engineering Using Magnetite Nanoparticles and Magnetic Force: Heterotypic Layers of Cocultured Hepatocytes and Endothelial Cells

Ito

Takizawa²,

Honda³

et al. 2004

Tissue Engineering

190

140

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Novel technologies to establish three-dimensional, in vivo-like tissue consisting of various types of cells are required for tissue engineering. We applied magnetic force to construct a heterotypic, layered coculture system of rat hepatocytes and human aortic endothelial cells (HAECs) that was not limited by cell type. Magnetite cationic liposomes carrying a positive surface charge to improve adsorption accumulated in HAECs at a concentration of 38 pg of magnetite per cell. Magnetically labeled HAECs specifically accumulated onto hepatocyte monolayers at sites where a magnet (4000 G) was positioned, and then adhered to form a heterotypic, layered construct with tight and close contact. This cocultured construct significantly (p < 0.05) enhanced albumin secretion by hepatocytes compared with that in homotypic cultures of hepatocytes or heterotypic cocultures of hepatocytes and HAECs without magnets. These results suggest that this novel use of magnetite nanoparticles and magnetic force, which we refer to as "magnetic force-based tissue engineering" (Mag-TE), offers a major advancement in tissue engineering.

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Construction and Harvest of Multilayered Keratinocyte Sheets Using Magnetite Nanoparticles and Magnetic Force

Ito

Hayashida²,

Honda³

et al. 2004

Tissue Engineering

145

135

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Novel technologies to establish three-dimensional constructs are desired for tissue engineering. In the present study, magnetic force was used to construct multilayered keratinocyte sheets and harvest the sheets without enzymatic treatment. Our original magnetite cationic liposomes, which have a positive surface charge in order to improve adsorption, were taken up by human keratinocytes at a concentration of 33 pg of magnetite per cell. The magnetically labeled keratinocytes (2x10(6) cells, which corresponds to 5 times the confluent concentration against the culture area of 24-well plates, in order to produce 5-layered keratinocyte sheets) were seeded into a 24-well ultralow-attachment plate, the surface of which was composed of a covalently bound hydrogel layer that is hydrophilic and neutrally charged. A magnet (4000 G) was placed under the well, and the keratinocytes formed a five-layered construct in low-calcium medium (calcium concentration, 0.15 mM) after 24 h of culture. Subsequently, when the five-layered keratinocytes were cultured in high-calcium medium (calcium concentration, 1.0 mM), keratinocytes further stratified, resulting in the formation of 10-layered epidermal sheets. When the magnet was removed, the sheets were detached from the bottom of the plates, and the sheets could be harvested with a magnet. These results suggest that this novel methodology using magnetite nanoparticles and magnetic force, which we have termed "magnetic force-based tissue engineering" (Mag-TE), is a promising approach for tissue engineering.

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Intracellular Hyperthermia for Cancer Using Magnetite Cationic Liposomes: Ex vivo Study

Yanase

Shinkai

Honda

et al. 1997

Japanese Journal of Cancer Research

130

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Heating properties of magnetite cationic liposomes (MCL) were investigated in ex vivo experiments using implanted cell pellets. The cell pellets, which consisted of rat glioma T9 cells into which MCL had been incorporated in a petri dish, were implanted subcntaneously in the left femoral region of female F344 rats. The rats were placed in a magnetic field generating coil and irradiated with an alternating magnetic field (384 Oe, 118 kHz) for 60 min. The cell pellets were heated to over 43°C by MCL in the magnetic field, hut other body parts of the rats were not heated. After 3 cycles of magnetic heating, all glioma cells were killed and no tumor take was observed.

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Hiroyuki Honda

Medical application of functionalized magnetic nanoparticles

Intracellular hyperthermia for cancer using magnetite cationic liposomes

Cancer immunotherapy based on intracellular hyperthermia using magnetite nanoparticles: a novel concept of “heat-controlled necrosis” with heat shock protein expression

Magnetite nanoparticle-loaded anti-HER2 immunoliposomes for combination of antibody therapy with hyperthermia

Novel Methodology for Fabrication of Tissue-Engineered Tubular Constructs Using Magnetite Nanoparticles and Magnetic Force

Tissue Engineering Using Magnetite Nanoparticles and Magnetic Force: Heterotypic Layers of Cocultured Hepatocytes and Endothelial Cells

Construction and Harvest of Multilayered Keratinocyte Sheets Using Magnetite Nanoparticles and Magnetic Force

Intracellular Hyperthermia for Cancer Using Magnetite Cationic Liposomes: Ex vivo Study

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