JP2008237642A - Hemodynamics monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a hemodynamics measuring sensor capable of noninvasively and long-term continuously or intermittently measuring a body temperature and a blood pressure; and a monitoring system using the same. <P>SOLUTION: This hemodynamics monitoring system is characterized in having a device, which has a body temperature-measuring temperature sensor and a blood pressure-measuring pressure sensor at a stent or an artificial blood vessel, radio supplying an electric power from the outside, and executing radio communication. Also, the device for radio supplying the electric power from the outside and executing the radio communication is characterized in measuring the temperature and the pressure according to the power supply and a read signal from an external power communication module, and radio communicating the body temperature value and the blood pressure value. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

The present invention relates to a hemodynamic measurement sensor embedded in a body and a hemodynamic monitoring system using the same.

An open-type hemodynamic monitor that monitors the blood pressure and body temperature of the patient (subject) directly in the blood vessel is an effective means for obtaining accurate measurement values. A catheter is inserted into the blood vessel to measure blood pressure. In this case, blood pressure is guided into a blood pressure transducer, or a blood pressure sensor is mounted to insert a guide wire to measure blood pressure (Patent Document 1: Japanese Patent Laid-Open No. 3-1178075). In the case of body temperature measurement, a body temperature is measured by inserting a guide wire on which a body temperature sensor is mounted (Patent Document 2: JP-A-5-309137).

Japanese Patent Application Laid-Open No. 3-118075 JP-A-5-309137

  However, when monitoring open-type hemodynamics, a large-scale measuring device is required, and since it is performed only in a clean environment such as a catheter room or an ICU to prevent infection, it can be easily monitored. Can not. The measurement time is about one day, and there is a problem that long-term continuous or intermittent measurement cannot be performed.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a hemodynamic measurement sensor capable of continuously or intermittently measuring body temperature and blood pressure for a long period of time and a hemodynamic monitoring system using the same. It is said.

In order to achieve the above object, the present invention is a stent having a device that wirelessly communicates by supplying power wirelessly from the outside, which includes a sensor for measuring biological information.
In addition, the present invention is an artificial blood vessel including a device that includes a sensor for measuring biological information and wirelessly communicates by supplying power from outside.
In addition, the hemodynamic monitoring system has a device that wirelessly communicates by supplying power wirelessly from the outside, including a temperature sensor for body temperature measurement and a pressure sensor for blood pressure measurement on the stent, and wirelessly supplies power from the outside. The hemodynamic monitoring system is characterized in that a device that performs wireless communication measures temperature and pressure according to power supply from an external power communication module and a read signal, and wirelessly communicates a body temperature value and a blood pressure value.
In the hemodynamic monitoring system, wherein the stent is provided with a temperature sensor for measuring body temperature and a pressure sensor for measuring blood pressure, and wirelessly communicates by supplying power from the outside. The device that wirelessly communicates by supplying power from the external power communication module continuously measures the temperature and pressure according to the read signal and wirelessly communicates the body temperature value and blood pressure value in real time. This is a hemodynamic monitoring system.
The external power communication module includes a power supply unit, a communication unit that wirelessly supplies power from outside and communicates with a device that performs wireless communication, and a computer communication unit, and wirelessly communicates by supplying power from outside. The hemodynamic monitoring system described above, wherein a signal wirelessly transmitted from a device is received by a communication unit that communicates with a device that wirelessly communicates by supplying power wirelessly from the outside.
The external power communication module includes a power supply unit, a communication unit that wirelessly supplies power from outside and communicates with a device that performs wireless communication, and a computer communication unit. A hemodynamic monitoring system characterized in that a signal transmitted wirelessly from a device to be received is received by a communication unit, wherein the computer communication unit and a computer are connected to supply power wirelessly from the outside. The hemodynamic monitoring system is characterized in that a signal wirelessly transmitted from a communicating device is transmitted to a computer and displayed on a computer screen in real time.
The external power communication module includes a power supply unit, a communication unit that wirelessly supplies power from outside and communicates with a device that performs wireless communication, a battery, a storage device, and a computer communication unit. Connecting to a computer by receiving a signal wirelessly transmitted from a device that supplies and wirelessly communicates with a communication unit that wirelessly supplies power from outside and communicates with the device that wirelessly communicates and stores the signal in a storage device The hemodynamic monitoring system is characterized in that long-term continuous measurement is performed.
The external power communication module also includes a power supply unit, a communication unit that wirelessly supplies power from the outside and communicates with a device that performs wireless communication, a battery, a storage device, and a computer communication unit, and supplies power from the outside wirelessly Then, a signal wirelessly transmitted from a device that communicates wirelessly is received by a communication unit that wirelessly supplies power from outside and communicates with the device that communicates wirelessly, and is stored in a storage device without being connected to a computer. A hemodynamic monitoring system characterized by long-term continuous measurement, characterized in that a computer communication unit and a computer are connected to transmit a signal stored in a storage device to the computer and display the computer screen The hemodynamic monitoring system described above.

According to the present invention, signals measured by a blood pressure sensor and a body temperature sensor placed in a blood vessel can be acquired wirelessly using an external power communication module without using a catheter or a needle. Direct contact with the blood vessel from the outside is only at the time of placement of the sensor, and thereafter, since the signals measured by the blood pressure sensor and the body temperature sensor can be acquired non-invasively, infection can be prevented, The place to measure is not limited.
Further, when blood pressure and body temperature signals are measured in real time, blood pressure and body temperature signals can be displayed on the computer in a non-invasive manner by connecting an external power communication module to the computer.
In addition, when blood pressure and body temperature signals are continuously measured without connecting to a computer, an external power communication module having a battery and a storage device is used to continuously record blood pressure and body temperature signals in the storage device in a non-invasive manner. Can be increased and portability is increased. Further, by connecting the external power communication module to the computer, the blood pressure and body temperature signals recorded in the storage device of the external power communication module can be transferred to the computer and displayed on the computer.

Example 1
Hereinafter, the present invention will be specifically described based on embodiments shown in the drawings. FIG. 1 is a diagram showing an example of a real-time continuous (or intermittent) hemodynamic monitoring system using the stent 4-1 according to the invention. In the figure, a blood pressure sensor 1 preferably including a piezo element and preferably a semiconductor (C-MOS) body temperature sensor 2 wirelessly supply power from an external power communication module 5 of an external communication module 7 having a communication function. And mounted on an IC tag 3 (see FIG. 7), which is a device for wireless communication. The IC tag (RFID) 3 is mounted on the stent 4-1, and is fixed to the site P-2 in the blood vessel.
As shown in FIG. 5, the external power communication module 5 includes a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power control unit 7-5, a power supply unit 7-6, and a transmission / reception circuit. 6 and antenna 7-7. Further, as a power supply unit for supplying power to the IC tag 3, the power supply unit 7-6, the transmission / reception circuit 6, and the antenna 7-7 perform their functions. As a communication unit for transmitting and receiving signals to and from the IC tag 3, the transmission / reception circuit 6 and the antenna 7-7 fulfill their functions. In addition, since it is connected to a computer (personal computer) 8, a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power control unit 7-5, etc. fulfill the functions of the communication module 7.
When measuring the blood pressure in the blood vessel P-2, the external power communication module 5 is brought into contact with the vicinity of the stent 4-1 implanted from the body surface P-1 of the subject P. Power is supplied from the computer 8 to the IC tag 3 wirelessly (preferably at a frequency of 13.56 MHz) via the communication module 7 of the external power communication module 5, the power supply unit and the communication unit 6, and the blood pressure value and the body temperature value. A signal for receiving information is transmitted wirelessly. The IC tag 3 to which power is supplied measures the blood pressure value and the body temperature value in the blood vessel P-2 by the blood pressure sensor 1 and the body temperature sensor 2, and transmits the measurement result to the external power communication module 5 wirelessly.
The external power communication module 5 transmits the received measurement result to the computer 8, and the computer 8 stores the received measurement result in the storage unit 8-1 and displays it on the display unit 8-2 in real time. Transmission from the external power communication module 5 to the computer 8 is performed by wire such as serial, USB, or wireless.
As shown in FIG. 7, the IC tag 3 includes an antenna 3-1, a transmission / reception circuit 3-2, a power supply unit 3-3, an A / D conversion unit 3-4, a control unit (CPU) 3-5, and an EEPROM 3-7. RAM 3-6 are included. The RAM 3-6 is a computer-readable storage medium that stores a program that receives a signal from the external communication module 5 and operates the control unit (CPU) 3-5 in a predetermined flow. The EEPROM 3-7 stores offset values, temperature correction values, and the like corresponding to the blood pressure sensor 1 and the body temperature sensor 2, respectively. The stent is preferably provided in the aorta. As the material of the base of the stent, nickel-titanium superelastic alloy, titanium, and stainless steel are preferably used. The stent may be coated on the surface so that the drug is released gradually. It is also possible to provide a sensor for blood ions can be measured (pH, O _2, CO _2, etc.).
(Example 2)
FIG. 2 is a diagram showing an example of a real-time continuous hemodynamic monitoring system using the artificial blood vessel 4-2 according to the present invention. In the figure, a blood pressure sensor 1 preferably having a piezoelectric element and preferably a semiconductor (C-MOS) body temperature sensor 2 are mounted on an IC tag (RFID) 3 (see FIG. 7) having a communication function. The IC tag 3 is mounted on the artificial blood vessel 4-2 and is fixed to a site in the blood vessel.
As shown in FIG. 5, the external power communication module 5 includes a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power control unit 7-5, a power supply unit 7-6, and a transmission / reception circuit. 6 and antenna 7-7. Further, as a power supply unit for supplying power to the IC tag 3, the power supply unit 7-6, the transmission / reception circuit 6, and the antenna 7-7 perform their functions. As a communication unit for transmitting and receiving signals to and from the IC tag 3, the transmission / reception circuit 6 and the antenna 7-7 fulfill their functions. In addition, since it is connected to a computer (personal computer) 8, a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power control unit 7-5, etc. fulfill the functions of the communication module 7.
When measuring the blood pressure in the blood vessel P-2, the external power communication module 5 is brought into contact with the vicinity of the artificial blood vessel 4-2 from the body surface P-1. Power is supplied from the computer (personal computer) to the IC tag 3 wirelessly (preferably at a frequency of 13.56 MHz) via the communication module 7 of the external power communication module 5, the power supply unit, and the communication unit 6, and the blood pressure value And the signal for receiving body temperature value information is transmitted by radio. The IC tag 3 to which power is supplied measures the blood pressure value and the body temperature value in the blood vessel P-2 by the blood pressure sensor 1 and the body temperature sensor 2, and transmits the measurement result to the external power communication module 5 wirelessly.
The external power communication module 5 transmits the received measurement result to the computer 8, and the computer 8 stores the received measurement result in the storage unit 8-1 and displays it on the display unit 8-2 in real time. Transmission from the external power communication module 5 to the computer 8 is performed by serial, USB or other wired or wireless (infrared or the like).
(Example 3)
FIG. 3 is a diagram showing an example of a 24-hour continuous hemodynamic monitoring system using the stent 4-1 according to the present invention. In the figure, a blood pressure sensor 1 preferably having a piezoelectric element and preferably a semiconductor (C-MOS) body temperature sensor 2 are mounted on an IC tag (RFID) 3 (see FIG. 7) having a communication function. The IC tag 3 is mounted on a stent and is fixed to a site of intravascular P-2.
Further, as shown in FIG. 6, the external power communication module 5 includes a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power supply control unit 7-5, a power supply unit 7-6, and a power storage unit. 7-8, a transmission / reception circuit 6, and an antenna 7-7. Further, as a power supply unit for supplying power to the IC tag 3, the power supply unit 7-6, the transmission / reception circuit 6, and the antenna 7-7 perform their functions. As a communication unit for transmitting and receiving signals to and from the IC tag 3, the transmission / reception circuit 6 and the antenna 7-7 fulfill their functions. In addition, since it is connected to a computer (personal computer) 8, a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power control unit 7-5, etc. fulfill the functions of the communication module 7. Furthermore, a storage unit (flash memory) 7-4 for temporarily storing and storing body temperature values and blood pressure values is provided.
When measuring the blood pressure in the blood vessel P-2, the external power communication module 5 is brought into contact with the vicinity of the stent 4-1 from the body surface P-1. A signal for wirelessly supplying power to the IC tag 3 via the power supply unit and the communication unit 6 of the external power communication module 5 and receiving blood pressure value and body temperature value information is wireless (preferably a frequency of 13.56 MHz). ) The IC tag 3 supplied with power measures the blood pressure value and the body temperature value in the blood vessel by the blood pressure sensor 1 and the body temperature sensor 2, and transmits the measurement result to the external power communication module 5 wirelessly.
The external power communication module 5 stores the received measurement result in the flash memory (storage unit) 7-4, and is connected to the computer 8 by a wired or wireless (infrared or the like) serial or USB 9 or the like with the communication module 7. All measurement results stored in the storage unit are transferred to the computer 8. The computer 8 stores the received measurement result in the storage unit 8-1, and displays the measurement result on the display unit 8-2 in real time. As the material of the base of the stent, nickel-titanium superelastic alloy, titanium, and stainless steel are preferably used. The stent may be coated on the surface so that the drug is released gradually. It is also possible to provide a sensor for blood ions can be measured (pH, O _2, CO _2, etc.).
Example 4
FIG. 4 is a diagram showing an example of a 24-hour continuous (intermittent) hemodynamic monitoring system using the artificial blood vessel 4-2 according to the present invention. In the figure, a blood pressure sensor 1 preferably having a piezo element and preferably a semiconductor (C-MOS) body temperature sensor 2 are mounted on an IC tag (RFID) (see FIG. 7) 3 having a communication function. The IC tag 3 is mounted on the artificial blood vessel 4-2 and is fixed to the site of intravascular P-2.
Further, as shown in FIG. 6, the external power communication module 5 includes a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power supply control unit 7-5, a power supply unit 7-6, and a power storage unit. 7-8, a transmission / reception circuit 6, and an antenna 7-7. Further, as a power supply unit for supplying power to the IC tag 3, the power supply unit 7-6, the transmission / reception circuit 6, and the antenna 7-7 perform their functions. As a communication unit for transmitting and receiving signals to and from the IC tag 3, the transmission / reception circuit 6 and the antenna 7-7 fulfill their functions. In addition, since it is connected to a computer (personal computer) 8, a control unit (CPU) 7-1, a transmission / reception circuit 7-2, a RAM 7-3, a power control unit 7-5, etc. fulfill the functions of the communication module 7. Furthermore, a storage unit (flash memory) 7-4 for temporarily storing and storing body temperature values and blood pressure values is provided.
When measuring the blood pressure in the blood vessel P-2, the external power communication module 5 is brought into contact with the vicinity of the artificial blood vessel 4-2 from the body surface P-1. Via the power supply unit and the communication unit 6 of the external power communication module 5, power is supplied to the IC tag 3 wirelessly (preferably at a frequency of 13.56 MHz), and a signal for receiving blood pressure value and body temperature value information is received. Send wirelessly. The IC tag 3 to which power is supplied measures the blood pressure value and the body temperature value in the blood vessel P-2 by the blood pressure sensor 1 and the body temperature sensor 2, and transmits the measurement result to the external power communication module 5 wirelessly.
The external power communication module 5 stores the received measurement results in the storage unit, and all the data stored in the flash memory (storage unit) 7-4 by serial communication, wired communication such as USB9, or wireless (infrared, etc.). Transfer the measurement results to the computer. The computer 8 stores the received measurement result in the storage unit 8-1, and displays the measurement result on the display unit 8-2 in real time.

It is the schematic of the hemodynamic monitoring system using a stent. 1 is a schematic diagram of a hemodynamic monitoring system using an artificial blood vessel. It is the schematic of the long-term hemodynamic monitoring system using a stent. 1 is a schematic diagram of a long-term hemodynamic monitoring system using an artificial blood vessel. It is a schematic block diagram of an external power communication module. It is a schematic block diagram of an external power communication module. It is a schematic block diagram of an IC tag.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Blood pressure sensor, 2 ... Body temperature sensor, 3 ... IC tag, 4-1 ... Stent, 4-2 ... Artificial blood vessel, 5 ... External power communication module

Claims (8)

A stent having a device for wirelessly communicating by wirelessly supplying power from the outside, including a sensor for measuring biological information. An artificial blood vessel having a device that wirelessly communicates by supplying power wirelessly from the outside, including a sensor for measuring biological information. A hemodynamic monitoring system comprising a stent and a temperature sensor for body temperature measurement, a pressure sensor for blood pressure measurement, and a device that wirelessly communicates by supplying power wirelessly from the outside,
The device that wirelessly communicates by supplying power wirelessly from the outside measures the temperature and pressure according to the power supply from the external power communication module and the read signal, and wirelessly communicates the body temperature value and blood pressure value A hemodynamic monitoring system characterized by this. In the hemodynamic monitoring system, comprising a device that wirelessly communicates by supplying power from the outside wirelessly equipped with a temperature sensor for body temperature measurement, a pressure sensor for blood pressure measurement on a stent,
The device that wirelessly communicates by supplying power wirelessly from the outside continuously measures the temperature and pressure according to the power supply from the external power communication module and the read signal, and wirelessly communicates the body temperature value and blood pressure value in real time A hemodynamic monitoring system characterized by that. The external power communication module includes a power supply unit, a communication unit that wirelessly supplies power from outside and communicates with a device that performs wireless communication, and a computer communication unit, and wirelessly communicates by supplying power from the outside wirelessly. The hemodynamic monitoring system according to claim 1, wherein a signal wirelessly transmitted from the device is received by a communication unit that communicates with a device that wirelessly communicates by supplying power wirelessly from the outside. The external power communication module includes a power supply unit, a communication unit that wirelessly supplies power from outside and communicates with a device that performs wireless communication, and a computer communication unit, and wirelessly communicates by supplying power from the outside wirelessly. A hemodynamic monitoring system characterized in that a signal wirelessly transmitted from a device is received by a communication unit,
By connecting the computer communication unit and a computer, a signal wirelessly transmitted from a device that wirelessly communicates by supplying power from the outside is transmitted to the computer and displayed on a computer screen in real time. The hemodynamic monitoring system according to claim 1 or 2. The external power communication module includes a power supply unit, a communication unit that wirelessly supplies power from outside and communicates with a device that performs wireless communication, a battery, a storage device, and a computer communication unit, and supplies power from the outside wirelessly Then, a signal wirelessly transmitted from a device that communicates wirelessly is received by a communication unit that wirelessly supplies power from outside and communicates with the device that communicates wirelessly, and is stored in a storage device without being connected to a computer. 3. The hemodynamic monitoring system according to claim 1 or 2, wherein long-term continuous measurement is performed. The external power communication module includes a power supply unit, a communication unit that wirelessly supplies power from outside and communicates with a device that performs wireless communication, a battery, a storage device, and a computer communication unit, and supplies power from the outside wirelessly Then, a signal wirelessly transmitted from a device that communicates wirelessly is received by a communication unit that wirelessly supplies power from outside and communicates with the device that communicates wirelessly, and is stored in a storage device without being connected to a computer. The hemodynamic monitoring system according to claim 1 or 2, characterized in that long-term continuous measurement is performed,
3. The hemodynamic monitoring system according to claim 1, wherein the computer communication unit and the computer are connected to transmit a signal stored in a storage device to the computer and display the computer screen.

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