Abstract: A medical information system includes a patient server that retains vital information received from a patient terminal. The patient server transmits the vital information to a medical care provider server through a network. The vital information retained in the medical care provider server can then be browsed from a doctor terminal.

Abstract: A communication system for providing information of a medical doctor's questions to patients includes a medical doctor terminal apparatus, a patient terminal apparatus, and a database server apparatus for storing question sets for the medical doctor's questions to patients, where the medical doctor terminal apparatus, patient terminal apparatus and database server apparatus are connected through a communication network. The patient terminal apparatus generates question programs for making inquiries about the medical doctor's questions to patients in accordance with the question sets received from the database server apparatus, displays the questions for the medical doctor's questions to patients by execution of the generated question programs, enters answer data to the displayed questions, transmits the entered answer data to the database server apparatus, and stores the transmitted answer data in the database server apparatus.

Abstract: A scalable tele-care monitoring device has a plurality of physiological sensors adapted to collect patient physiological data. The device also has an interface adapted to connect with a personal computer, and an expansion module adapted to communicate patient physiological data to the personal computer via the interface. In further aspects, the device has an output adapted to communicate the patient physiological data over a communications network when the device is not interfaced with the personal computer.

Abstract: The invention is intended for making it possible for the user to get appropriate advice not only based on biological information, but also considering the situation of health care to be taken by the user as for article intake. Food information of food ingredients, food-contained calories, etc., described on a package, etc., of food incepted by the user is input to a patient terminal 4 through food information input means 3 for inputting the food information and the food information is transmitted to a server 1 via a communication line 2.

Abstract: A communication system for information of medical doctor's questions to patients includes a terminal apparatus for medical doctor, a terminal apparatus for patient, and a database server apparatus for storing question sets for medical doctor's questions to patients, which are connected through a communication network. The terminal apparatus for patient generates question programs for making inquiries about medical doctor's questions to patients in accordance with the question sets received from the database server apparatus, displays the questions for medical doctor's questions to patients by execution of the generated question programs, enters answer data to the displayed questions, transmits the entered answer data to the database server apparatus, and stores the transmitted answer data in the database server apparatus. The terminal apparatus for medical doctor receives the stored answer data by accessing the database server apparatus, and displays the received answer data thereon.

Abstract: A scalable tele-care monitoring device has a plurality of physiological sensors adapted to collect patient physiological data. The device also has an interface adapted to connect with a personal computer, and an expansion module adapted to communicate patient physiological data to the personal computer via the interface. In further aspects, the device has an output adapted to communicate the patient physiological data over a communications network when the device is not interfaced with the personal computer.

Abstract: A medical information system has a patient terminal device, a server, and an administrator terminal device, characterized in that:

Abstract: A medical information system has a patient terminal device, a server, and an administrator terminal device. The patient terminal device, the server, and the administrator terminal device are connected together on a network. The patient terminal device includes sensors for measuring information used as indices of the condition of a patient's health; a part for transferring measured data obtained by the sensors to the patient terminal device; a part for transferring the measured data from the sensors to the server via the network; a part for accepting control information from the server, and a part for taking action based on the control information. The server includes a part for transmitting the control information to the patient terminal device; and a part for storing and sorting out the measured data transferred from the patient terminal device. The administrator terminal includes a part for reviewing the measured data stored and sorted out in the server.

Abstract: A medical information system has a patient server firstly retains vital information received from a patient terminal. The patient server transmits the vital information to a medical care provider server through a network. The vital information retained in the medical care provider server can be browsed from a doctor terminal.

Abstract: A system simply capable of browsing data, such as vital information of patients, was not available.

Abstract: A fluorescence polarization method for analyzing an assay-object in a sample is provided. The fluorescence polarization method includes the steps of: (a) providing a fluorescent-labeled protein in which a protein is covalently bound to a fluorochrome(s), wherein the protein is capable of specifically binding to the assay-object; (b) allowing the fluorescent-labeled protein to bind to the assay-object; and (c) measuring a change in the degree of fluorescence polarization which has taken place in the fluorescent-labeled protein by its binding to the assay-object.

Abstract: A method of the present invention is a fluorescence polarization method at multiple wavelengths for analyzing two or more different assay-objects in a sample. The method includes the steps of: (a) providing two or more different fluorescent-labeled substances, each being a substance which is capable of specifically binding to respective one of the assay-objects and is covalently bound to a fluorochrome, wherein the fluorochromes of the fluorescent-labeled substances are different from one another; (b) allowing the fluorescent-labeled substances to bind to the two or more different assay-objects, respectively; and (c) measuring a change in the degree of fluorescence polarization which has taken place in each of the fluorescent-labeled substances by its binding to one of the assay-objects.

Abstract: An vital sign box has a plurality of vital sensors measuring predetermined biological, chemical, or physical conditions of a living body; an camera taking a picture of a predetermined object; and a housing containing the plurality of vital sensors and the camera.

Abstract: A fluorescence polarization method for analyzing an assay-object in a sample is provided. The fluorescence polarization method includes the steps of: (a) providing a fluorescent-labeled protein in which a protein is covalently bound to a fluorochrome(s), wherein the protein is capable of specifically binding to the assay-object; (b) allowing the fluorescent-labeled protein to bind to the assay-object; and (c) measuring a change in the degree of fluorescence polarization which has taken place in the fluorescent-labeled protein by its binding to the assay-object.

Abstract: A fluorescence polarization method for analyzing an assay-object in a sample is provided. The fluorescence polarization method includes the steps of: (a) providing a fluorescent-labeled protein in which a protein is covalently bound to a fluorochrome(s), wherein the protein is capable of specifically binding to the assay-object; (b) allowing the fluorescent-labeled protein to bind to the assay-object; and (c) measuring a change in the degree of fluorescence polarization which has taken place in the fluorescent-labeled protein by its binding to the assay-object.

Abstract: The present invention provides a dye-labeled protein conjugate in which a protein conjugate is labeled with a large number of dye molecules. In the dye-labeled protein conjugate, a protein conjugate that includes a protein and an antibody bound thereto via a disulfide bond is labeled with a cyanine dye represented by the formula (1) or the formula (2) given below: where R1 and R2 denote hydrogen or an alkyl group, X denotes a halogen, M denotes hydrogen or an alkali metal, and n represents an integer in a range of 1 to 4.

Abstract: The present invention provides a highly sensitive dye-labeled and polymerized antibody that can detect a target substance even when the target substance has a low concentration. The dye-labeled and polymerized antibody of the present invention comprises a polymerized antibody, which has been polymerized with a polyfunctional reagent, and a cyanine dye for labeling the polymerized antibody represented by the formula (1) given below: where R1 and R2 denote hydrogen or an alkyl group, X denotes a halogen, M denotes hydrogen or an alkali metal, and n represents an integer in a range of 1 to 4.

Abstract: The present invention provides a highly sensitive dye-labeled and polymerized antibody that can detect a target substance even when the target substance has a low concentration. The dye-labeled and polymerized antibody of the present invention comprises a polymerized antibody, which has been polymerized with a polyfunctional reagent, and a cyanine dye for labeling the polymerized antibody represented by the formula (1) or the formula (2) given below: where R1 and R2 denote hydrogen or an alkyl group, X denotes a halogen, M denotes hydrogen or an alkali metal, and n represents an integer in a range of 1 to 4.

Abstract: A high-sensitive indirect polymerized and labelled antibody is disclosed. The antibody facilitates detection of a low concentration of antigen as an analyte in a sample solution. The indirect polymerized and labelled antibody of the present invention is prepared by polymerizing an antibody using a multi-functional reagent, binding the polymerized antibody with a protein via a disulfide bond of the antibody to form a polymerized antibody conjugate, and labelling the conjugate with a cyanine dye represented by the following formula: where R1 and R2 represent hydrogen or an alkyl group, X represents a halogen, M represents hydrogen or an alkali metal, and n represents an integer of 1 to 4.

Abstract: The present invention provides a dye-labeled protein conjugate in which a protein conjugate is labeled with a large number of dye molecules. In the dye-labeled protein conjugate, a protein conjugate that includes a protein and an antibody bound thereto via a disulfide bond is labeled with a cyanine dye represented by the formula (1) given below. where R1 and R2 denote hydrogen or an alkyl group, X denotes a halogen, M denotes hydrogen or an alkali metal, and n represents an integer in a rage of 1 to 4.