Abstract: An objective of the present invention is to provide a measuring chip for a surface plasmon resonance sensor that can detect a small amount of target substances in high sensitivity. The present invention provides a measuring chip for a surface plasmon resonance sensor comprising a metal layer, one or more plasma polymerization layers formed on said metal layer, and a biologically active substance immobilized on the surface of said plasma polymerization layer.

Abstract: An objective of the present invention is to provide a measuring chip for a surface plasmon resonance sensor that can detect a small amount of target substances in high sensitivity. The present invention provides a measuring chip for a surface plasmon resonance sensor comprising a metal layer, one or more plasma polymerization layers formed on said metal layer, and a biologically active substance immobilized on the surface of said plasma polymerization layer.

Abstract: An object of the present invention is to provide a method for detecting a target nucleotide sequence using the hybridization method, which has a remarkably improved sensitivity of detection. The method comprises the steps of hybridizing a target nucleotide sequence with a PNA that is complementary to the whole or a part of the target nucleotide sequence and measuring the degree of hybridization at the presence of a denaturing agent.

Abstract: An object of the present invention is to provide a method for detecting a target nucleotide sequence using a complementary nucleotide sequence that has an excellent sensitivity of detection. The method comprises the steps of converting the target nucleotide sequence to a partially double-stranded nucleotide sequence which is double-stranded at one part and single-stranded in the remaining part and detecting said partially double stranded nucleotide sequence using a nucleotide sequence that is complementary to the target nucleotide sequence.

Abstract: The microbial electrode is constructed having a substrate(3) made of an insulating material, an electric conductor(2) which is fixed on the substrate and a membrane containing microorganism cells(1) which is fixed on the conductor. The microbial sensor(20) is constructed having the microbial electrode above described and a conductor(11) to act as a counter electrode fixed on the insulating material of the surface of the substrate of the electrode which is opposite to the surface where the membrane containing microorganism cells is fixed.

Abstract: An enzyme sensor system capable of quantitatively determining a particular component contained in a biological sample in a rapid and easy manner is disclosed. More particularly, an electrically conductive enzyme, an enzyme-immobilized electrode using the same and a composition for use in the preparation of the enzyme electrode are disclosed. The composition for an enzyme-immobilized electrode according to the present invention enables electrodes of various patterns to be produced by screen printing.

Abstract: Miniaturized Clark-type oxygen electrodes includes a substrate having at least one recess groove formed on a surface thereof for receiving an electrolyte solution, and two electrodes acting as a cathode and an anode formed through an insulating layer on the surface of the substrate. Each of the electrodes is at least partially disposed in a bottom area of the recess. A solid or semi-solid, porous, electrolyte solution-containing material fills the recess, and an oxygen gas-permeable membrane covers and seals the recess and porous material received therein. Miniaturized biosensors are made using the oxygen electrode as a transducer. The oxygen electrodes and biosensors, which are extremely accurate, can be mass-produced and can be widely used in various fields such as clinical analysis, industrial processing, and in the determination of environmental conditions. The biosensors can be particularly used in clinical diagnosis and in monitoring devices for both in vivo and in vitro measurements.