about
Method for isolation of mouse pancreatic stem cells.Regeneration of pancreatic islets in vivo by ultrasound-targeted gene therapy.Pancreatic stem/progenitor cells for the treatment of diabetes.Isolation and propagation of a human CD133(-) colon tumor-derived cell line with tumorigenic and angiogenic properties.A new approach to develop a biohybrid artificial liver using a tightly regulated human hepatocyte cell line.Novel positively charged nanoparticle labeling for in vivo imaging of adipose tissue-derived stem cellsIn vivo imaging of transplanted islets labeled with a novel cationic nanoparticle.Cluster analysis of self-monitoring blood glucose assessments in clinical islet cell transplantation for type 1 diabetesTissue-Specific Stem Cells Obtained by Reprogramming of Non-Obese Diabetic (NOD) Mouse-Derived Pancreatic Cells Confer Insulin Production in Response to Glucose.Pancreatic islet transplantation for treating diabetes.Protein transduction technology: a novel therapeutic perspective.Long-Expected New Start.ER Stress and β-Cell Pathogenesis of Type 1 and Type 2 Diabetes and Islet Transplantation.Observation of Positively Charged Magnetic Nanoparticles Inside HepG2 Spheroids Using Electron MicroscopyChoice of Feeders Is Important When First Establishing iPSCs Derived From Primarily Cultured Human Deciduous Tooth Dental Pulp CellsSpheroid Formation and Evaluation of Hepatic Cells in a Three-Dimensional Culture Device.Organ Biology-New Development.Maintenance of Viability and Function of Rat Islets With the Use of ROCK Inhibitor Y-27632.Development of Canine Models of Type 1 Diabetes With Partial Pancreatectomy and the Administration of StreptozotocinSTO Feeder Cells Are Useful for Propagation of Primarily Cultured Human Deciduous Dental Pulp Cells by Eliminating Contaminating Bacteria and Promoting Cellular Outgrowth.Protein transduction technology offers a novel therapeutic approach for diabetes.Stem cells for the treatment of diabetes.Activation of c-Jun NH2-terminal kinase during islet isolation.Role of PDX-1 and MafA as a potential therapeutic target for diabetes.Islet transplantation at the Diabetes Research Institute Japan.Generation of functional insulin-producing cells from mouse embryonic stem cells through 804G cell-derived extracellular matrix and protein transduction of transcription factors.Novel Positive-Charged Nanoparticles for Efficient Magnetic Resonance Imaging of Islet TransplantationEnhanced Adipogenic Differentiation of Human Adipose-Derived Stem Cells in an In Vitro Microenvironment: The Preparation of Adipose-Like Microtissues Using a Three-Dimensional Culture.Production of pancreatic beta-cells from stem cells.Implication of pancreatic image findings in total pancreatectomy with islet autotransplantation for chronic pancreatitis.Pancreatic islet transplantation.Recent progress in pancreatic islet transplantation.Stem cell applications in diabetes.Cancer stem cell-like characteristics of a CD133(+) subpopulation in the J82 human bladder cancer cell line.Creating a Future of Transplantation.A Combined Continuous Density/Osmolality Gradient for Supplemental Purification of Human Islets.Preclinical biodistribution and safety study of reduced expression in immortalized cells/Dickkopf-3-encoding adenoviral vector for prostate cancer gene therapy.A novel gene expression system for detecting viable bladder cancer cells.In vitro generation of insulin-secreting cells from human pancreatic exocrine cells.Tumor suppressor REIC/Dkk-3 interacts with the dynein light chain, Tctex-1.
P50
Q33326179-CEBE467C-646B-4B6E-A8D5-9CB2D9E805CAQ34101722-47235329-6821-482A-8F67-580066E5B9E5Q34148810-7E4DEEDC-72E2-4F96-BFEE-8E38B83EB0D7Q34213324-58D5C5E8-6C4E-48BA-A44F-4C31C87A556CQ34236684-1DF467EE-7F0C-42B1-A6DA-10B5DC4F6AE2Q34443753-01B7903B-6CAB-48EF-AFBE-1EE3FC9FD550Q34602931-5FECB6FB-9C3A-4953-AE7D-08AC2F38F77CQ35123321-69752BBB-AD84-45CE-8E68-6D4A4AB61958Q36143021-8987C8CB-6E4F-4456-B79C-807C3A42F1C7Q36349557-4F257FB5-0E72-4994-BD80-EFF1B583ACC8Q36409999-A9F7D1C1-468D-4DF1-BF0F-45F37F0455E8Q36523553-24062205-FE76-4572-BE74-663CA1092998Q36523562-0A3E0A1A-FFE5-4AEB-A9DD-EFE88FDD6079Q36523581-98C0E470-7C56-4483-9E50-FF22F6DAABD7Q36523729-F53F3983-DCA4-4F34-8AA8-AB4DF22B68B6Q36523738-D4AA7097-EB96-41F8-AD2A-E05BA5A9331DQ36528678-EFFCD6F9-E6A2-4AC1-A3D3-B4E32B61CFD0Q36528697-4FED659F-B5A7-4F04-A8EE-2456E5BB837CQ36528702-A340915D-3BB5-4A53-AD71-960AF1FB7527Q36528734-7CCE2792-DD18-4676-88A8-A3D04F31DDF7Q36542840-3AAF2425-C6D0-45FA-8A7A-5378824D4936Q36629110-5A3135FE-8693-4586-B76F-A4159E32AA99Q36662394-EF9FE692-0DC4-4721-934B-D662BE17B3A9Q36797850-015540E0-308B-4D7B-9A82-894CF3E0F4DFQ37184123-7EF52888-5081-453D-9210-1E2960126AEBQ37516473-9B0D2584-9D70-43A4-AE04-B02801D42616Q37541902-802BED92-21CC-4E0E-AA6D-CE726BE6CF41Q37579235-9369D31A-B8C4-4C69-A34A-45C4A3811128Q37728027-D05B9076-D1BF-4FE7-B702-DE273CF2DCD2Q37794755-24294E67-C49E-4EA2-A539-44F4C932EE67Q37821262-323524AF-0F25-4430-9434-193DE8D84AFDQ38156830-015DD00F-2558-4F8B-AC4A-3DF2DCAA43B0Q38160332-03BEFE43-8867-4DFA-9A03-725E63162A41Q38292083-427B3FE5-9595-4986-AC73-226724681A71Q38910493-43C3882A-C2F9-4CC3-91EE-C17484C2EF1DQ39037123-A3FC9B6A-BEC7-4960-97ED-E3B50A288CA5Q39286737-10974A01-9D92-4A62-916F-687C29A7766AQ39370365-27AF94AF-8EB2-4D29-8510-34E4AE8C0325Q39404491-DEAC4148-12EA-42AF-AA70-71FEF7555E51Q39491645-90F1619A-66C6-438B-8872-564447CDE305
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Hirofumi Noguchi
@ast
Hirofumi Noguchi
@en
Hirofumi Noguchi
@es
Hirofumi Noguchi
@nl
Hirofumi Noguchi
@sl
type
label
Hirofumi Noguchi
@ast
Hirofumi Noguchi
@en
Hirofumi Noguchi
@es
Hirofumi Noguchi
@nl
Hirofumi Noguchi
@sl
prefLabel
Hirofumi Noguchi
@ast
Hirofumi Noguchi
@en
Hirofumi Noguchi
@es
Hirofumi Noguchi
@nl
Hirofumi Noguchi
@sl
P106
P31
P496
0000-0002-0880-6805