Rie Utoh scite author profile

Human hepatocytes were transplanted into urokinase-type plasminogen activator-transgenic SCID mice (uPA/SCID mice), which are immunodeficient and undergo liver failure. The transplanted cells were characterized in terms of their in vivo growth potential and functions. The human hepatocytes progressively repopulated the murine host liver. However, the recipients died when the replacement index (RI) of the human hepatocytes exceeded 50%. The hosts (chimeric mice) survived at RI >50% when treated with a drug that has anti-human complement factor activity, and these mice developed livers with RI values as high as 96%. In total, 36 chimeric mice were generated, and the rate of successful engraftment was as high as 92%. The yield of chimeric mice with RI >70% was 32%. The human hepatocytes in the murine host liver expressed mRNAs for a variety of human cytochrome P450 (hCYP) subtypes, in a manner that was similar to the donor liver. The mRNAs for hCYP3A4 and hCYP1A1/2 were induced in the liver in a CYP type-specific manner when the mice were treated with rifampicin and 3-methylcholanthrene, respectively. These results indicate that human hepatocytes that propagate in mice retain their normal pharmacological responses. We conclude that the chimeric mouse developed in the present study is a useful model for assessing the functions and pharmacological responses of human hepatocytes.

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Controlled formation of heterotypic hepatic micro-organoids in anisotropic hydrogel microfibers for long-term preservation of liver-specific functions

Yamada

et al. 2012

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Tissue factor triggers procoagulation in transplanted mesenchymal stem cells leading to thromboembolism

Tatsumi

Ohashi

Matsubara

et al. 2013

Biochemical and Biophysical Research Communications

175

161

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Cell sheet approach for tissue engineering and regenerative medicine

Matsuura

Utoh

Nagase

et al. 2014

Journal of Controlled Release

203

162

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Preserved liver-specific functions of hepatocytes in 3D co-culture with endothelial cell sheets

et al. 2012

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Bioengineering of a functional sheet of islet cells for the treatment of diabetes mellitus

et al. 2009

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Cell-sized condensed collagen microparticles for preparing microengineered composite spheroids of primary hepatocytes

et al. 2015

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The reconstitution of extracellular matrix (ECM) components in three-dimensional (3D) cell culture environments with microscale precision is a challenging issue. ECM microparticles would potentially be useful as solid particulate scaffolds that can be incorporated into 3D cellular constructs, but technologies for transforming ECM proteins into cell-sized stable particles are currently lacking. Here, we describe new processes to produce highly condensed collagen microparticles by means of droplet microfluidics or membrane emulsification. Droplets of an aqueous solution of type I collagen were formed in a continuous phase of polar organic solvent followed by rapid dissolution of water molecules into the continuous phase because the droplets were in a non-equilibrium state. We obtained highly unique, disc-shaped condensed collagen microparticles with a final collagen concentration above 10% and examined factors affecting particle size and morphology. After testing the cell-adhesion properties on the collagen microparticles, composite multicellular spheroids comprising the particles and primary rat hepatocytes were formed using microfabricated hydrogel chambers. We found that the ratio of the cells and particles is critical in terms of improvement of hepatic functions in the composite spheroids. The presented methodology for incorporating particulate-form ECM components in multicellular spheroids would be advantageous because of the biochemical similarity with the microenvironments in vivo.

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Preparation of stripe-patterned heterogeneous hydrogel sheets using microfluidic devices for high-density coculture of hepatocytes and fibroblasts

Kobayashi

Yamakoshi

Yajima

et al. 2013

Journal of Bioscience and Bioengineering

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Rie Utoh

Near Completely Humanized Liver in Mice Shows Human-Type Metabolic Responses to Drugs

Controlled formation of heterotypic hepatic micro-organoids in anisotropic hydrogel microfibers for long-term preservation of liver-specific functions

Tissue factor triggers procoagulation in transplanted mesenchymal stem cells leading to thromboembolism

Cell sheet approach for tissue engineering and regenerative medicine

Preserved liver-specific functions of hepatocytes in 3D co-culture with endothelial cell sheets

Bioengineering of a functional sheet of islet cells for the treatment of diabetes mellitus

Cell-sized condensed collagen microparticles for preparing microengineered composite spheroids of primary hepatocytes

Preparation of stripe-patterned heterogeneous hydrogel sheets using microfluidic devices for high-density coculture of hepatocytes and fibroblasts

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