Tsutomu Inoue
Tsutomu Inoue, Chigasaki JP
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20110034688 | OPTICALLY ACTIVE DIBENZAZEPINE DERIVATIVES - It is to provide a novel optically active dibenzazepine derivative having a high utility value as an asymmetric phase-transfer catalyst. It is an optically active 6,7-dihydro-5H-dibenzo[c,e]azepine derivative represented by the following formula (1′), (wherein R represents a divalent organic group for cross-linking the 1 | 02-10-2011 |
Tsutomu Inoue, Chigasaki-Shi JP
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20100174081 | PRODUCTION PROCESS OF OPTICALLY ACTIVE 3-QUINUCLIDINOL DERIVATIVE - A process is provided for efficiently producing an optically active 3-quinuclidinol derivative of high optical purity using a readily available ruthenium compound as an asymmetric reduction catalyst. This process is a process for producing an optically active 3-quinuclidinol derivative represented by the following formula (III) comprising asymmetrically hydrogenating a 3-quinuclidinone derivative represented by the following formula (I) in the presence of a ruthenium compound (II) represented by formula (II): Ru(X)(Y)(Px) | 07-08-2010 |
20100280284 | OPTICALLY ACTIVE 2,2'-BIPHENOL DERIVATIVE AND PRODUCTION METHOD OF SAME - An optically active 2,2′-biphenol derivative and a production method that enables simple and efficient production of this compound. More specifically, an optically active biphenol derivative represented by the following formulas (1) and (2), a method for optically resolving a biphenol derivative represented by formula (2′), a production method of an optically active biphenol derivative (1) comprising a step for reacting a Brønsted acid with a biphenol derivative (2), and a production method of an optically active biphenol derivative (3) comprising a step for reacting a Lewis acid with an optically active biphenol derivative (1) or an optically active biphenol derivative (2). In the following formulas, R represents, for example, a primary or secondary alkyl group having 1 to 10 carbon atoms, * represents an axially asymmetric center, X represents a halogen atom, and R | 11-04-2010 |
20110028749 | RUTHENIUM COMPOUND AND METHOD FOR PRODUCING OPTICALLY ACTIVE AMINOALCOHOL COMPOUND - A novel ruthenium compound that is useful as an asymmetric reduction catalyst for carbonyl compounds. The ruthenium compound of the present invention is represented by a formula (I): (Ru(X) | 02-03-2011 |
20130225824 | PRODUCTION PROCESS OF OPTICALLY ACTIVE 3-QUINUCLIDINOL DERIVATIVE - A process is provided for efficiently producing an optically active 3-quinuclidinol derivative of high optical purity using a readily available ruthenium compound as an asymmetric reduction catalyst. This process is a process for producing an optically active 3-quinuclidinol derivative represented by the following formula (III) comprising asymmetrically hydrogenating a 3-quinuclidinone derivative represented by the following formula (I) in the presence of a ruthenium compound (II) represented by formula (II): Ru(X)(Y)(P | 08-29-2013 |
Tsutomu Inoue, Saitama-Shi JP
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20120184587 | NOVEL PHENOL DERIVATIVE - Disclosed are a novel compound and a pharmaceutical product, each having a remarkable uricosuric effect. Specifically disclosed are: a novel phenol derivative represented by general formula (1) that is shown in FIG. | 07-19-2012 |
Tsutomu Inoue, Toyama JP
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20120251800 | TOUCH PANEL GLASS SUBSTRATE AND METHOD FOR MANUFACTURING SAME - A touch panel glass substrate which can be manufactured simultaneously with other touch panel glass substrates, is free of microcracks in edges, and has predetermined strength, and a method for manufacturing the same are provided. An original glass plate as large as to cut out a plurality of glass substrates is prepared. Detection electrode traces and lead wiring traces on each glass substrate are simultaneously formed on the original glass plate. The original glass plate is then chemically etched to separate the touch panel glass substrates. The separation by chemical etching produces no microcracks in edges. | 10-04-2012 |
Tsutomu Inoue, Tokyo JP
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20130108133 | MEDICAL IMAGE PROCESSING APPARATUS, METHOD AND PROGRAM | 05-02-2013 |
20140079306 | REGION EXTRACTION APPARATUS, METHOD AND PROGRAM - A three-dimensional medical image obtainment unit that obtains a three-dimensional medical image of a chest, a bronchial structure extraction unit that extracts a bronchial structure from the three-dimensional medical image, a divided lung region obtainment unit that divides, based on the divergence of the bronchial structure, the bronchial structure into plural bronchial structures, and obtains plural divided lung regions based on the plural divided bronchial structures, a distance image generation unit that generates, based on the plural divided lung regions, a distance image based on a distance between each voxel in an entire region excluding at least one of the plural divided lung regions and each of the plural divided lung regions, and a border non-existing region extraction unit that extracts, based on the distance image generated by the distance image generation unit, a border non-existing region, which does not include any borders of the divided lung regions, are provided. | 03-20-2014 |
20140267269 | IMAGE PROCESSING APPARATUS, METHOD AND PROGRAM - When a virtual-endoscopic-image is generated from a three-dimensional-image representing a tubular-organ, a predetermined range is set in the vicinity of a viewpoint set in advance in the three-dimensional-image, and each of a lumen-region and a wall-region of the tubular-organ in the set range is identified. A voxel-value or a voxel-value-interval constituting a boundary between a range of voxel values in the identified lumen-region and a range of voxel values in the identified wall-region is obtained based on information about voxel-values in the identified lumen-region and information about voxel-values in the identified wall-region, and an opacity-curve representing a relationship between voxel values and opacity is set in such a manner that the opacity changes from a value representing a transparent-state to a value representing an opaque-state at the voxel-value or in the voxel-value-interval. The virtual-endoscopic-image is generated from the three-dimensional-image by volume rendering using the set viewpoint and the set opacity-curve. | 09-18-2014 |