Abstract: A sensor for detecting material to be tested 100 having small variations in electrochemical measurement values includes a work electrode 1 and a counter electrode 2 integrated into one via an insulator 3. As a result of contact between the material to be tested and the work electrode 1, output voltage changes. The work electrode 1 smaller than the counter electrode 2 and the insulator 3 is installed on a part of the surface of the insulator 3, and a peripheral wall 4 for surrounding the work electrode 1 is formed on the insulator 3 to operate as a storage part.
Abstract: The conductive polyrotaxane of the present invention contains an electron-accepting cyclic molecule in each of its repeating unit. Since the electron-accepting cyclic molecule remains stable because of molecular interaction with a ?-conjugated oligomer molecule, the electron-accepting cyclic molecule is not dissociated during rotaxane polymerization reaction, and thus a conductive polyrotaxane of stable quality can be obtained.
Type:
Application
Filed:
April 22, 2010
Publication date:
April 5, 2012
Applicant:
NAT'L INSTITUTE FOR MATERIALS SCIENCE
Inventors:
Taichi Ikeda, Masayoshi Higuchi, Kurth Dirk G
Abstract: [Object] A medical material that improves therapeutic effects in epithelial cells such as keratoconjunctival epithelial cells with the use of an amnion, and a process for producing the same are provided. [Solving Means] A medical material includes an amnion, which is a placental tissue, a polymer film bonded to one surface of the amnion and crosslinked, and cells adhered to the other surface of the amnion. A process for producing the medical material includes the steps of preparing an amnion from which the spongy layer is removed, bonding a biocompatible polymer film to one surface of the amnion followed by crosslinking, adhering epithelial stem cells to the other surface of the amnion, and proliferating epithelial cells from the epithelial stem cells on the surface of the amnion.
Abstract: The present invention is effective for causing charge separation by complexing zinc oxide crystals in different states one another when a zinc oxide semiconductor is used as an electronic element. The present invention provides a zinc oxide-based laminated structure comprising two layers of a zinc oxide or zinc oxide solid solution layer with a lattice volume of Va and a donor concentration of Na, and a zinc oxide or zinc oxide solid solution layer with a lattice volume of Vb and a donor concentration of Nb, wherein the relationships of Va<Vb and Na>Nb being satisfied between both layers of the laminated structures; and the layer with the lattice volume Va serves as a charge-supplying layer and the layer with the lattice volume Vb serves as a charge-receiving layer in the laminated structure.