Abstract: By the conventional technique for dispensing more than one reagents accurately, the system is complicated and thus a compact and inexpensive system is difficult to realize. In the present invention, the pressurized dispensing system utilizing a capillary is realized, and in addition, in order to reduce the leakage of reagents different from the reagent dispensed, by forming air layers at the tips of the capillaries after dispensing, a compact, simple, inexpensive analysis apparatus is realized.

Abstract: The present invention provides an inexpensive DNA sequencing method with high-sensitivity. The method of the present invention comprising the steps of, adding an given amount of dATP for step by step complementary strand synthesis and subtracting the background luminescence intensity caused by dATP from the measured luminescence intensity to obtain the luminescence intensity involved in complementary strand synthesis.

Abstract: The present invention provides a method for analyzing a nucleotide sequence comprising the steps of: carrying out complementary strand synthesis by adding at least one of four kinds of ddNTP corresponding to nucleotides A, G, T, and C, or derivatives thereof to a reaction vessel containing a nucleic acid sample to extend one nucleotide at a target site; performing a bioluminescent reaction with the use of ATP formed from released pyrophosphate as a reaction substrate; and typing the target site by determining the presence or absence of the complementary strand synthesis based on a result of the bioluminescent reaction.

Abstract: An object of the present invention is to provide a luminescence detection apparatus compact in size which is capable of conveniently determining DNA base sequences at a low cost. According to the present invention, a luminescence detection apparatus 1 is provided comprising: a plurality of reaction cells 6 each having a transparent bottom portion; a solution-dispensing portion 19 equipped with capillaries 18 positioned above the reaction cells 6 and put into a one-to-one correspondence with the reaction cells 6; and a light-detecting portion 29 having a plurality of light-sensing elements 24 put into a one-to-one correspondence with the reaction cells 6 and arranged in proximity to the bottom surfaces of the reaction cells 6, wherein the a plurality of light-sensing elements 24 of the light-detecting portion 29 detect respective luminescences in the reaction cells 6 generated by injecting reagent solutions from the solution-dispensing portion 19 to the reaction cells 6.

Abstract: This invention provides a method of genetic testing that enables testing of a plurality of variation sites (SNPs) in a cost-effective and simple manner, allowing realization of genetic diagnosis in clinical settings. The SNP type of the nucleic acid sample is evaluated by: allowing a nucleic acid sample having an anchor sequence at its 5? end to hybridize to a support having, immobilized on its surface, a probe containing a sequence that is complementary to the target sequence (the SNP region); extending a complementary strand from the probe utilizing the nucleic acid sample as a template; dissociating and removing the nucleic acid sample from the extended probe; extending a complementary strand using the extended probe as a template and a primer having a sequence identical to the anchor sequence; and detecting pyrophosphoric acid generated via the primer extension, based on bioluminescence.

Abstract: A biochemical reaction detection chip capable of controlling the temperature for biochemical reactions including hybridizations and its substrate. The function of the chip is performed by comprising a plurality of islands of a heat conducting material on the membrane of the substrate, the islands being spaced from each other and individually provided with temperature controllers, and the probes immobilized on the substrate.

Abstract: There are beforehand prepared a monomer having a reaction residue and a polynucleotide probe set comprising plural kinds of polynucleotide probes having a residue bonded to the reaction residue. The monomer is mixed with each kind of polynucleotide probes comprising any plural probes selected from the polynucleotide probe set. Each kind of the resultant mixtures is added to each of different small holes to make the mixture into gel matrix. Thus, a polynucleotide probe chip is produced. Sample DNA is forcibly migrated in the gels by electrophoresis. Laser light is projected onto the side face of the chip. The fluorescence emitted from the whole surface of the chip is collectively detected with a high-sensitive two-dimensional detector. Thus, the polynucleotide probe chip, holding various kinds of DNA probes, for detecting DNA can be provided. This chip has high hybridization-efficiency and makes high-sensitivity and high-speed DNA detection possible.

Abstract: A biochemical reaction detection chip capable of controlling the temperature for biochemical reactions including hybridizations and its substrate. The function of the chip is performed by comprising a plurality of islands of a heat conducting material on the membrane of the substrate, the islands being spaced from each other and individually provided with temperature controllers, and the probes immobilized on the substrate.

Abstract: A polynucleotide detecting cell provided with a first electrode (111) to which different DNA probes (13, 14, 15, 16) are fixed in luminous areas (3, 4, 5, 6) differing with the type of DNA probe and a second electrode (113-1, 113-2) opposite to the first electrode is used; target polynucleotides are trapped through hybridization of DNA probes fixed to luminous areas with target polynucleotides; an extending reaction is carried out using an ECL-labeled base (dNTP) to extend the hybridized DNA probes; ECL generated by the application of a voltage between the first electrode and the second electrode is detected; and the presence or absence of any extended chain generated by the extending reaction is detected. The DNA detecting cell of simple apparatus configuration and the assay apparatus using it according to the invention are capable of high speed detection of hybridization between target DNA fragments and DNA probes, and a large volume of probe assaying can be accomplished in a short period of time.

Abstract: A biochemical reaction detection chip capable of controlling the temperature for biochemical reactions including hybridizations and its substrate. The function of the chip is performed by comprising a plurality of islands of a heat conducting material on the membrane of the substrate, the islands being spaced from each other and individually provided with temperature controllers, and the probes immobilized on the substrate.

Abstract: A biochemical reaction detection chip capable of controlling the temperature for biochemical reactions including hybridizations and its substrate. The function of the chip is performed by comprising a plurality of islands of a heat conducting material on the membrane of the substrate, the islands being spaced from each other and individually provided with temperature controllers, and the probes immobilized on the substrate.

Abstract: There are beforehand prepared a monomer having a reaction residue and a polynucleotide probe set comprising plural kinds of polynucleotide probes having a residue bonded to the reaction residue. The monomer is mixed with each kind of polynucleotide probes comprising any plural probes selected from the polynucleotide probe set. Each kind of the resultant mixtures is added to each of different small holes to make the mixture into gel matrix. Thus, a polynucleotide probe chip is produced. Sample DNA is forcibly migrated in the gels by electrophoresis. Laser light is projected onto the side face of the chip. The fluorescence emitted from the whole surface of the chip is collectively detected with a high-sensitive two-dimensional detector. Thus, the polynucleotide probe chip, holding various kinds of DNA probes, for detecting DNA can be provided. This chip has high hybridization-efficiency and makes high-sensitivity and high-speed DNA detection possible.

Abstract: In order to image an object larger than a field of view for observation, imaging is effected by dividing it into several times and pictures thus imaged are synthesized to constitute a whole image. In order to image several times, only a detecting unit is moved and an X-ray source is substantially fixed with respect to the object. Images thus obtained include a common part of the object and are joined so that the common part are overlapped on each other. In case where an image pick-up tube is included in the detecting unit, the image pick-up tube is made operable, after a period of time necessary for attenuation of microphonic noise has lapsed, measured from a point of time where the detecting unit has been stopped.