KR20200009365A - Continuous biological signal measuring device and method - Google Patents

Abstract

The present invention relates to a continuous blood pressure measurement apparatus and a method thereof, and more particularly, to an apparatus capable of continuously measuring blood pressure by allowing a user to wear the same easily while minimizing discomfort of the user. The continuous blood pressure measurement apparatus comprises: a band part which can be attached, in a ring shape, to a part of a body of a subject; an air pocket placed inside the ring-shaped band part and being in close contact with the body of the subject to apply pressure thereto; a pressure sensor detecting pressure inside the air pocket and measuring a blood pressure waveform of the subject; and a pressure adjusting part adjusting the pressure applied to the body of the subject by the air pocket.

Description

Continuous blood pressure measuring device and method {CONTINUOUS BIOLOGICAL SIGNAL MEASURING DEVICE AND METHOD}

The present invention relates to an apparatus and method for continuously measuring blood pressure, and more particularly, to an apparatus and method for continuously measuring blood pressure with simple wearing while minimizing user's discomfort.

Blood pressure management of patients is a very important technology in medical technology. Understanding whether hypertension or hypotension is essential for the condition management of patients, and the method of measuring blood pressure has been developed in various ways.

The most basic method of measuring blood pressure is to put a cuff on the arm of the subject and apply a high pressure to the blood through the cuff. The cuff then slowly decreases the pressure on the arm, detecting the Korotkoff sound, the systolic blood pressure at which the Korotkoff sound begins to be heard, and the point at which the Korotkoff sound begins to be inaudible. How to measure.

The oscillometric method is the same as the Korotkoff sound method in that it uses a cuff wound around the subject's upper arm, but it is a statistical and empirical regression formula for the vibration (oscillometric waveform) of blood pressure caused by cuff pressure rather than sound. It is used to measure systolic and diastolic blood pressure.

Another method of measuring blood pressure of a subject is to measure blood pressure by measuring pulse waves of a finger. In this method, the measuring device is inserted into the finger of the subject, and the measuring device extracts the pulse wave of the capillary finger of the finger capillary using an infrared light source sensor and a light receiving sensor. The blood pressure of the subject is measured using the extracted pulse wave of the subject.

First, pressure is applied to the arm using a cuff, and then blood pressure measurement using Korotkoff sound is inconvenient to be measured by a person with high accuracy but expertise, and it is only a temporary blood pressure measurement. There is a disadvantage that it is not possible to know how the blood pressure changes in real time, and the subject may feel uncomfortable by pressing the subject's arm.

The oscillometric method uses automated blood pressure estimation algorithms to measure blood pressure on the subject's own hands without the help of others, but like the Korotkoff sound, only a temporary blood pressure measurement is possible. In addition, the upper arm is tightly pressed by the cuff, causing pain when measuring, which may cause discomfort.

In order to measure blood pressure by measuring pulse wave from finger, pulse wave is used to measure blood pressure, not only temporary blood pressure but continuous blood pressure measurement. It is possible to feel pulse wave measurement using infrared sensor. When the subject's movement occurs, the noise is too high, so the actual measurement is impossible. And because the size of the equipment is not portable, it can only be measured in certain places.

Therefore, there is a need for a technology capable of automatically measuring continuous blood pressure while minimizing the discomfort of the subject.

Accordingly, an object of the present invention is to provide a method and apparatus for continuously measuring blood pressure that can measure blood pressure continuously regardless of the movement of the subject while minimizing the discomfort of the subject.

Continuous blood pressure measuring apparatus according to an embodiment of the present invention for solving the above problems is located in the band portion, the ring-shaped band portion that can be attached to the body portion of the subject, the close contact with the body of the subject And an air pocket for applying pressure, a pressure sensor for detecting an air pressure inside the air pocket to measure a blood pressure waveform of the subject, and a pressure controller for adjusting the pressure applied by the air pocket to the body of the subject. .

According to one embodiment of the present invention, the pressure sensor may further include an analysis unit for analyzing the blood pressure waveform measured.

According to an embodiment of the present disclosure, the body part may be a wrist.

According to an embodiment of the present disclosure, the non-measurement of the air pocket may further include a correction unit that maintains the internal pressure at a predetermined level.

According to an embodiment of the present disclosure, the correction unit may charge or discharge gas into the air pocket according to the internal pressure when the air pocket is not measured.

According to an embodiment of the present invention, the blood pressure data of the subject measured by the pressure sensor may include a communication unit for transmitting to the outside.

According to an embodiment of the present disclosure, the pressure sensor may measure the blood pressure waveform of the subject as a continuous waveform.

According to an embodiment of the present invention, the pressure adjusting unit checks the optimum pressure having the maximum size of the blood pressure waveform measured by the pressure sensor while increasing or decreasing the pressure of the air pocket, The pressure can be fixed at the optimum pressure.

According to an embodiment of the present disclosure, the air pocket may be included in plural and gas may move between each other.

Continuous blood pressure measurement method according to an embodiment of the present invention for solving the above problem is a step of fixing the blood pressure monitor to the body part of the subject in the state in which the air pocket is in close contact with the body part of the subject, the air pocket Pre-measuring the blood pressure of the subject while increasing or decreasing the internal pressure of the body; analyzing the measured blood pressure waveform of the measured subject to derive an optimal value of the internal pressure of the air pocket; Setting a value and measuring the blood pressure of the subject as a continuous waveform.

According to an embodiment of the present disclosure, the method may further include analyzing the measured waveform.

According to an embodiment of the present disclosure, the body part may be a wrist.

According to an embodiment of the present invention, the pre-measuring step includes checking an internal pressure value of the air pocket, filling a gas into the air pocket when the internal pressure value is less than a specific value, and inside the air pocket. And increasing the pressure to pre-measure the blood pressure waveform of the subject while increasing the pressure applied to the body part of the subject by the air pocket.

According to one embodiment of the invention, the specific value may be atmospheric pressure.

According to an embodiment of the present invention, the gas filling step may be to adjust the internal pressure to the atmospheric pressure level by opening the air pocket when the internal pressure value is below atmospheric pressure.

According to an embodiment of the present disclosure, the method may further include transmitting the measured blood pressure waveform data to an external system.

According to an embodiment of the present disclosure, the air pocket may be included in plural and gas may move between each other.

According to the present invention, the measurement of the subject can be accurately performed while minimizing the discomfort caused by the measurement of the subject.

In addition, unlike the conventional blood pressure measurement method, it is possible to provide a continuous blood pressure measurement method by measuring the blood pressure by applying a pressure that is not excessive enough to the discomfort of the user's wrist.

In addition, by calculating the optimal pressure applied to the user's body to measure the blood pressure of the subject can be obtained by measuring the blood pressure by simply obtaining the best pulse wave.

On the other hand, the effects of the present invention is not limited to the above-mentioned effects, various effects may be included within the scope apparent to those skilled in the art from the following description.

1 is a cross-sectional view of a wrist of a subject wearing a continuous blood pressure measuring device according to an embodiment of the present invention.
2 is a block diagram of a measuring unit of the continuous blood pressure measuring apparatus according to an embodiment of the present invention.
3 is an example of pulse wave measured by a continuous blood pressure measuring device according to an embodiment of the present invention.
4 is a diagram illustrating a subject wearing a continuous blood pressure measuring apparatus according to an embodiment of the present invention.
5 is a flowchart illustrating a method of continuously measuring blood pressure according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail the 'continuous blood pressure measuring apparatus and method' according to the present invention. The described embodiments are provided to enable those skilled in the art to easily understand the technical spirit of the present invention, and the present invention is not limited thereto. In addition, matters represented in the accompanying drawings may be different from those actually implemented in the schematic drawings in order to easily explain the embodiments of the present invention.

On the other hand, each component expressed below is only an example for implementing the present invention. Thus, other implementations may be used in other implementations of the invention without departing from the spirit and scope of the invention.

In addition, each component may be implemented in purely hardware or software configurations, but may also be implemented in a combination of various hardware and software configurations that perform the same function. In addition, two or more components may be implemented together by one hardware or software.

In addition, the expression "comprising" certain components merely refers to the presence of the components as an 'open' expression, and should not be understood as excluding additional components.

In addition, the body part of the subject of the present invention may include the wrist of the subject.

1 is a cross-sectional view of a wrist of a subject wearing a continuous blood pressure measuring device according to an embodiment of the present invention.

Referring to FIG. 1, a continuous blood pressure measuring apparatus according to an embodiment of the present invention may include a band unit 101 and a measuring unit 102.

The band unit 101 may fix the continuous blood pressure measuring device to the body part of the subject. The band unit 101 may fix the continuous blood pressure measuring device by completely wrapping a body part of the subject in a ring shape. The band unit 101 may fix the continuous blood pressure measuring apparatus by wrapping a part of the body of the subject in an open form. The band portion 101 may have a form that can be adjusted in length. The band unit 101 adjusts the length to position the band unit 101 outside the body part of the subject, and then adjusts the length of the band unit 101 to measure the continuous blood pressure on the body part of the subject. Can be fixed. The band unit 101 may automatically fix the continuous blood pressure measuring device when the band unit 101 is positioned around the body part of the subject. The band unit 101 may recognize the body part of the subject and fix the continuous blood pressure measuring device to a part of the entity of the subject through automatic length adjustment. The band unit 101 may be made of a flexible material so that the continuous blood pressure measuring device may be fixed to the body part of the subject. The band portion 101 may be adjusted in length by the measuring unit 102 to increase or decrease the length. The band unit 101 senses the pressure applied to a part of the user's body and stops adjusting the length when a force greater than a predetermined pressure is applied and the continuous blood pressure measuring device is fixed to minimize the discomfort to the body part of the subject. can do. The body part may include all human body parts such as arms, wrists, fingers, legs, ankles and abdomen. In the present specification, a wrist will be described as an example. However, embodiments of the present invention are not limited to the wrist.

The measuring unit 102 may be fixed, attached or in close contact with the body part of the subject by the band unit 101. The measurement unit 102 may measure the blood pressure of the subject in contact with the body part of the subject. The measurement unit 102 may be fixed to the body part of the subject by the band unit 101 to stably measure blood pressure by minimizing the occurrence of noise in daily movement. The measuring unit 102 may be located in contact with or in close contact with a blood vessel in a body part of the subject. The measuring unit 102 may measure the blood pressure of the subject in the blood vessel of the subject. The measurement unit 102 may measure blood pressure by measuring the pulse wave of the subject. The measuring unit 102 may adjust the length of the band unit 101. The measuring unit 102 reduces the length of the band unit 101 and detects the pressure applied by the band unit 101 to a part of the body of the subject to stop adjusting the length of the band unit 101 before excessive pressure is applied. And the length of the band portion 101 can be adjusted. The measuring unit 102 may include an air pocket. The measuring unit 102 may detect the pressure change of the air pocket to detect the blood pressure of the subject. The measuring unit 102 may measure or measure blood pressure, pulse wave and blood pressure of the subject by detecting a change in pressure of the air pocket caused by the pulse wave of the vessel by contacting or contacting with the position of the blood vessel of the subject. The measurement unit 102 may be worn in contact with or in close contact with the radial artery of the subject.

2 is a block diagram of a measuring unit of the continuous blood pressure measuring apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the measuring unit 102 includes an air pocket, a connecting unit 203, a pressure sensor 204, a pressure adjusting unit 205, an analyzing unit 206, a communication unit 207, and a correcting unit (not shown). ) May include at least one or more.

The air pocket may protrude from the measuring unit 102 to the outside. The air pocket may contact a part of the body of the subject. The air pocket may include a gas therein. The air pocket may be a flow amount of gas contained therein. The air pocket may change an internal pressure by changing the amount of gas contained therein. The force applied from the outside may change the volume of the air pocket and the internal pressure may change due to the volume change. The air pocket may be made of an elastic material. The air pocket may increase in volume or increase in internal pressure as the amount of injected gas increases, or increase in volume and increase in internal pressure. The air pocket may increase in pressure applied to a part of the body of the subject as the volume increases or the internal pressure increases. The air pocket may be made of various materials such as vinyl, silicon, PDMS, plastic, and the like, but is not limited thereto and may include all elastic materials. The air pocket may be worn in contact with or in close contact with a portion where the radial artery of the subject is located. The air pocket may have a length of 0 ~ 4cm in the direction perpendicular to the blood circulation of the radial artery. The air pocket may have a length of 2 cm in the direction perpendicular to the blood circulation of the radial artery. The air pocket may be included in plurality. The air pocket may be separated into a first air pocket 201 and a second air pocket 202. The air pocket may include an air pocket form including a gas therein.

The first air pocket 201 may protrude to the outside from the measuring unit 102. The first air pocket 201 may contact a part of the body of the subject. The first air pocket 201 may include a gas therein. The first air pocket 201 may have a flow amount of gas contained therein. The first air pocket 201 may change an internal pressure by changing an amount of gas included therein. Force applied from outside may change the volume of the first air pocket 201 and the internal pressure may change due to the volume change. The first air pocket 201 may be made of an elastic material. The first air pocket 201 may increase in volume or increase in internal pressure as the amount of injected gas increases, or may increase in volume and increase in internal pressure. The first air pocket 201 may increase in pressure applied to a part of the body of the subject while the volume increases or the internal pressure increases. The first air pocket 201 may be made of various materials such as vinyl, silicon, PDMS, plastic, and the like, but is not limited thereto and may include all elastic materials. The first air pocket 201 may be worn in contact with or in close contact with a portion where the radial artery of the subject is located. The first air pocket 201 may have a length of 0 to 4 cm in a direction perpendicular to the blood circulation of the radial artery. The first air pocket 201 may have a length of 2 cm in the direction perpendicular to the blood circulation of the radial artery.

The first air pocket 201 may be disposed to surround a part of the body of the subject over the entire inside of the band unit 101 in a plurality of separate forms. The blood pressure may be measured by specifying an air pocket in which the blood pressure of the subject is measured among the plurality of first air pockets 201.

The connection part 203 may connect the first air pocket 201 and the second air pocket 202. The connection part 203 may enable the movement of gas between the first air pocket 201 and the second air pocket 202. The connection part 203 connects the first air pocket 201 and the second air pocket 202 such that gas cannot be moved between the first air pocket 201 and the second air pocket 202. Can be shielded individually. The connection part 203 may be open to cause gas movement between the first air pocket 201 and the second air pocket 202, and may be shielded to shield the first air pocket 201 and the second air pocket. The gas flow of 202 can be prevented, and the pressure of the first air pocket 201 and the second air pocket 202 can be kept constant when there is no external force. The connection unit 203 may connect the air pocket to the second air pocket 202 so that gas movement is possible when the air pocket in which the blood pressure of the subject is measured is specified among the plurality of first air pockets 201. .

The second air pocket 202 may include a gas therein. The second air pocket 202 may have a flow amount of gas contained therein. The second air pocket 202 may change the internal pressure by changing the amount of gas contained therein. An external force may change the volume of the second air pocket 202 and the internal pressure may change due to the volume change. The second air pocket 202 may be made of an elastic material. The second air pocket 202 may be made of various materials such as vinyl, silicon, PDMS, plastic, and the like, but is not limited thereto and may include all elastic materials. The second air pocket 202 may send gas to the first air pocket 201 to increase the internal pressure of the first air pocket 201. The second air pocket 202 receives the gas from the first air pocket 201 to lower the pressure of the first air pocket 201.

The air pocket may be included as a single air pocket capable of simultaneously performing the functions of the first air pocket 201 and the second air pocket 202.

The pressure sensor 204 may measure the internal pressure of the first air pocket 201. The pressure sensor 204 may continuously measure a change in the internal pressure of the first air pocket 201. The pressure sensor 204 may continuously measure the change in the internal pressure of the first air pocket 201 and display the waveform. The pressure sensor 204 may continuously extract the pulse wave by continuously measuring the internal pressure change of the first air pocket 201. The pressure sensor 204 may obtain a waveform of the blood pressure of the subject using the extracted pulse wave, and the pressure sensor 204 may be located inside the first air pocket 201. The pressure sensor 204 may generate a change in pressure as an electrical signal. The pressure sensor 204 may continuously measure the internal pressure of the first air pocket 201 in contact with or in close contact with a part of the body of the subject under external force due to the pulse wave of the blood vessel of the subject. . The pressure sensor 204 may derive the blood pressure of the subject by using the measured continuous change in internal pressure, and calculate the blood pressure value of the subject. The pressure sensor 204 may calculate the highest point of the blood pressure waveform of the subject as the highest blood pressure and the lowest point as the lowest blood pressure. The pressure sensor 204 has a relationship between a pressure applied by the first air pocket 201 to a part of the body of the subject and a pulse wave generated by external force applied to the first air pocket 201 by the pulse wave of the subject. The blood pressure value of the subject can be calculated.

The pressure adjusting unit 205 may adjust the pressure of the first air pocket 201. The pressure adjusting unit 205 may adjust the pressure by moving the gas between the first air pocket 201 and the second air pocket 202 through the connecting portion 203. The pressure adjusting unit 205 may increase or decrease the internal pressure of the first air pocket 202 by moving the gas. The pressure adjusting unit 205 analyzes the pulse wave or the blood pressure wave of the subject obtained by measuring the internal pressure of the first air pocket 201 measured by the pressure sensor 204 and the first air pocket 201. The internal pressure of the may have a specific pressure value or the pressure may be adjusted so that the amount of gas injected into the inside of the first air pocket 201 corresponds to a specific amount. The pressure adjusting unit 205 blocks the gas movement between the first air pocket 201 and the second air pocket 202 when the internal pressure of the first air pocket 201 reaches a specific value, You can have a pressure reading. When the amount of gas injected into the first air pocket 201 reaches a target amount, the pressure adjusting unit 205 between the first air pocket 201 and the second air pocket 202 Gas movement can be blocked. The specific pressure value or the target amount of gas may be the pressure or gas amount at the point where the blood pressure, pulse wave or blood pressure wave of the subject has a maximum magnitude. The specific amount of pressure or the target amount of gas may be a pressure or gas amount at a point where blood pressure, pulse wave or blood pressure wave is measured without disturbing blood flow of the subject.

The analyzer 206 may analyze the pressure data measured by the pressure sensor. The analyzer 206 may analyze the pressure data to generate blood pressure data. The analyzer 206 may find the diastolic and systolic blood pressures of the subject using the blood pressure data. The analyzer 206 may calculate the diastolic and systolic blood pressure of the subject as a numerical value. The analyzer 206 may analyze the pressure data to generate a blood pressure waveform of the subject. The analysis unit 206 may generate a vibration that the subject can feel when a change occurs in blood pressure, pulse wave or blood pressure wave measured by the pressure sensor 204. The change may include a case in which the magnitude of the blood pressure, pulse wave or blood pressure wave is decreased, and the blood pressure, pulse wave or blood pressure wave shows an abnormal shape.

The communication unit 207 may transmit a result measured by the pressure sensor 204 to an external system. The communication unit 207 may transmit blood pressure, pulse wave or blood pressure wave information of the subject measured by the pressure sensor 204 to an external system. The communication unit 207 may transmit blood pressure, blood pressure data, and the highest and lowest blood pressure data analyzed by the pressure sensor 204 to an external system. The external system may include a display system capable of displaying the data, a storage system capable of storing the data, and an analysis system capable of further analyzing the data.

When a change occurs in the blood pressure, pulse wave or blood pressure wave measured by the pressure sensor 204, the communication unit 207 may transmit a signal for the change generation to an external system. The change may include a case in which the magnitude of the blood pressure, pulse wave or blood pressure wave is decreased, and the blood pressure, pulse wave or blood pressure wave shows an abnormal shape. The external system may include an emergency system that notifies the medical staff of the emergency when an emergency occurs in the state of the subject. The communication unit 207 may allow the continuous blood pressure measuring device to transmit blood pressure information of the subject through wireless communication without wire connection. The communication method used by the communication unit 207 may include a communication method such as Bluetooth, infrared, LTE, etc., but may include all kinds of communication methods capable of transferring data.

The correction unit may correct the internal pressure of the air pocket. The correction unit may charge or discharge a gas into the air pocket according to the internal pressure during the non-measurement of the air pocket. The correction unit may check the internal pressure value of the air pocket. The corrector may fill gas into the air pocket when the internal pressure value of the air pocket is equal to or less than a specific value. The specific value can include atmospheric pressure. The correction unit may shield after opening the sensing pocket when the internal pressure of the air pocket is less than atmospheric pressure. Through the opening and shielding, the internal pressure of the air pocket can be adjusted to atmospheric pressure. The correction unit may adjust the internal pressure of the air pocket to a specific value. The correction unit may adjust the internal pressure of the air pocket by filling or discharging the gas in the air pocket.

3 is an example of pulse wave measured by a continuous blood pressure measuring device according to an embodiment of the present invention.

Referring to FIG. 3, in the continuous blood pressure measuring apparatus according to an embodiment of the present disclosure, the pressure regulating unit 205 may be configured such that the first air pocket 201 is in contact with or in close contact with the radial artery of the subject. The internal pressure of the air pocket 201 may be increased. In this case, as the internal pressure of the first air pocket 201 increases, the blood pressure, internal pressure, pulse wave, or blood pressure wave of the subject measured by the first air pocket 201 may change. The blood pressure, internal pressure, pulse wave or blood pressure wave of the subject increases in size at first, but decreases in size when the pressure applied to the body of the subject by the first air pocket 201 increases to hinder blood circulation. You can start. The pressure adjusting unit 205 may determine the pressure or gas amount when the measured blood pressure or the like corresponds to the highest point 301 as an optimum pressure or an optimum gas amount. The pressure controller 205 may adjust and fix the pressure or the gas amount of the first air pocket to the optimum pressure or the optimum gas amount. The optimum pressure or optimum gas amount may be 80% of the pressure or gas amount of the highest point 301.

4 is a diagram illustrating a subject wearing a continuous blood pressure measuring apparatus according to an embodiment of the present invention.

Referring to FIG. 4, a continuous blood pressure measuring apparatus according to an embodiment of the present invention may be worn on a part of a body of a subject. In the continuous blood pressure measuring device, the measuring unit 102 is in close contact with or in contact with the body part of the subject to measure blood pressure, and the band unit 101 fixes the measuring unit 102 to the body part of the subject. Can be. The band portion 101, the measuring unit 102 may adjust the length. The band portion 101 may be adjusted in length by itself. The person to be measured may place the measurement unit 102 at a portion to measure blood pressure. The continuous blood pressure measuring device positioned in the blood pressure measuring part is fixed to the body of the subject by adjusting the length of the band part 101, and the measuring part 102 adjusts the internal pressure of the first air pocket 201. Afterwards, the blood pressure of the subject can be measured continuously.

5 is a flowchart illustrating a method of continuously measuring blood pressure according to an embodiment of the present invention.

Referring to FIG. 5, in the continuous blood pressure measuring method according to an embodiment of the present disclosure, the blood pressure measuring device is fixed to the body of the subject by adjusting the length of the band in a state in which the first air pocket is in close contact with the body of the subject. Step S501 may be included.

In operation S501, the band unit 101 may fix the continuous blood pressure measuring device to the body part of the subject. The band unit 101 may fix the continuous blood pressure measuring device by completely wrapping a body part of the subject in a ring shape. The band unit 101 may fix the continuous blood pressure measuring apparatus by wrapping a part of the body of the subject in an open form. The band portion 101 may have a form that can be adjusted in length. The band unit 101 adjusts the length to position the band unit 101 outside the body part of the subject, and then adjusts the length of the band unit 101 to measure the continuous blood pressure on the body part of the subject. Can be fixed. The band unit 101 may automatically fix the continuous blood pressure measuring device when the band unit 101 is positioned around the body part of the subject. The band unit 101 may recognize the body part of the subject and fix the continuous blood pressure measuring device to a part of the entity of the subject through automatic length adjustment. The band unit 101 may be made of a flexible material so that the continuous blood pressure measuring device may be fixed to the body part of the subject. The band portion 101 may be adjusted in length by the measuring unit 102 to increase or decrease the length. The band unit 101 senses the pressure applied to a part of the user's body and stops adjusting the length when a force greater than a predetermined pressure is applied and the continuous blood pressure measuring device is fixed to minimize the discomfort to the body part of the subject. can do. The body part may include all human body parts such as arms, wrists, fingers, legs, ankles and abdomen. In the present specification, a wrist will be described as an example. However, embodiments of the present invention are not limited to the wrist.

Continuous blood pressure measurement method according to an embodiment of the present invention to move the gas between the second air pocket and the first air pocket to increase the internal pressure of the first air pocket and to measure the blood pressure of the subject (S502) It may include.

In operation S502, the pressure sensor 204 may measure an internal pressure of the first air pocket 201. The pressure sensor 204 may continuously measure a change in the internal pressure of the first air pocket 201. The pressure sensor 204 may continuously measure the change in the internal pressure of the first air pocket 201 and display the waveform. The pressure sensor 204 may continuously extract the pulse wave by continuously measuring the internal pressure change of the first air pocket 201. The pressure sensor 204 may obtain a waveform of the blood pressure of the subject using the extracted pulse wave, and the pressure sensor 204 may be located inside the first air pocket 201. The pressure sensor 204 may generate a change in pressure as an electrical signal. The pressure sensor 204 may continuously measure the internal pressure of the first air pocket 201 in contact with or in close contact with a part of the body of the subject under external force due to the pulse wave of the blood vessel of the subject. . The pressure sensor 204 may derive the blood pressure of the subject by using the measured continuous change in internal pressure, and calculate the blood pressure value of the subject. The pressure sensor 204 may calculate the highest point of the blood pressure waveform of the subject as the highest blood pressure and the lowest point as the lowest blood pressure. The pressure sensor 204 is a relation between the pressure applied by the first air pocket 201 to a part of the body of the subject and the pulse wave at which the pulse wave of the subject is subjected to an external force on the first air pocket 201. The blood pressure value of the subject can be calculated.

S502 checking the internal pressure value of the air pocket, if the internal pressure value is less than a specific value, filling the air pocket with the gas and increasing the internal pressure of the air pocket, the air pocket is the body of the subject And pre-measuring the blood pressure waveform of the subject while increasing the pressure applied to the portion.

In step S502, the pressure adjusting unit 205 may adjust the pressure of the first air pocket 201. The pressure adjusting unit 205 may adjust the pressure by moving the gas between the first air pocket 201 and the second air pocket 202 through the connecting portion 203. The pressure adjusting unit 205 may increase or decrease the internal pressure of the first air pocket 202 by moving the gas. The pressure adjusting unit 205 may move the gas to allow the pressure sensor 204 to measure the blood pressure of the subject while increasing or decreasing the internal pressure of the first air pocket 202.

Continuous blood pressure measurement method according to an embodiment of the present invention may include the step (S503) of analyzing the measured blood pressure waveform of the measured subject to derive an optimal value of the internal pressure of the first pocket.

In operation S503, the pressure adjusting unit 205 may increase the internal pressure of the first air pocket 201 while the first air pocket 201 is in contact with or in close contact with the radial artery of the subject. In this case, as the internal pressure of the first air pocket 201 increases, the blood pressure, internal pressure, pulse wave, or blood pressure wave of the subject measured by the first air pocket 201 may change. The blood pressure, internal pressure, pulse wave or blood pressure wave of the subject increases in size at first, but decreases in size when the pressure applied to the body of the subject by the first air pocket 201 increases to hinder blood circulation. You can start. The pressure adjusting unit 205 may determine the pressure or gas amount when the measured blood pressure or the like corresponds to the highest point 301 as an optimum pressure or an optimum gas amount. The pressure controller 205 may adjust and fix the pressure or the gas amount of the first air pocket to the optimum pressure or the optimum gas amount. The optimum pressure or optimum gas amount may be 80% of the pressure or gas amount of the highest point 301.

Continuous blood pressure measurement method according to an embodiment of the present invention may include the step of setting the internal pressure of the first air pocket to the optimum value (S504).

In step S504, the pressure adjusting unit 205 analyzes the pulse wave or the blood pressure wave of the measured object obtained by measuring the internal pressure of the first air pocket 201 measured by the pressure sensor 204, the first air. The pressure may be adjusted such that the internal pressure of the pocket 201 has a specific pressure value or the amount of gas injected into the first air pocket 201 corresponds to a specific amount. The pressure adjusting unit 205 blocks the gas movement between the first air pocket 201 and the second air pocket 202 when the internal pressure of the first air pocket 201 reaches a specific value, You can have a pressure reading. When the amount of gas injected into the first air pocket 201 reaches a target amount, the pressure adjusting unit 205 between the first air pocket 201 and the second air pocket 202 Gas movement can be blocked. The specific amount of pressure or the target amount of gas may be the pressure or amount of gas at the point where the pulse wave or blood pressure wave of the subject has a maximum magnitude. The specific amount of pressure or the target amount of gas may be the pressure or gas amount at the point where the pulse wave or blood pressure wave is measured without disturbing blood flow of the subject.

Continuous blood pressure measurement method according to an embodiment of the present invention may include the step of measuring the blood pressure of the subject to a continuous waveform (S505).

In operation S505, the pressure sensor 204 may measure an internal pressure of the first air pocket 201. The pressure sensor 204 may continuously measure a change in the internal pressure of the first air pocket 201. The pressure sensor 204 may continuously measure the change in the internal pressure of the first air pocket 201 and display the waveform. The pressure sensor 204 may continuously extract the pulse wave by continuously measuring the internal pressure change of the first air pocket 201. The pressure sensor 204 may obtain a waveform of the blood pressure of the subject using the extracted pulse wave, and the pressure sensor 204 may be located inside the first air pocket 201. The pressure sensor 204 may generate a change in pressure as an electrical signal. The pressure sensor 204 may continuously measure the internal pressure of the first air pocket 201 in contact with or in close contact with a part of the body of the subject under external force due to the pulse wave of the blood vessel of the subject. . The pressure sensor 204 may derive the blood pressure of the subject by using the measured continuous change in internal pressure, and calculate the blood pressure value of the subject. The pressure sensor 204 may calculate the highest point of the blood pressure waveform of the subject as the highest blood pressure and the lowest point as the lowest blood pressure. The pressure sensor 204 has a relationship between a pressure applied by the first air pocket 201 to a part of the body of the subject and a pulse wave generated by external force applied to the first air pocket 201 by the pulse wave of the subject. The blood pressure value of the subject can be calculated.

In step S505, the analysis unit 206 may analyze the pressure data measured by the pressure sensor. The analyzer 206 may analyze the pressure data to generate blood pressure data. The analyzer 206 may find the diastolic and systolic blood pressures of the subject using the blood pressure data. The analyzer 206 may calculate the diastolic and systolic blood pressure of the subject as a numerical value. The analyzer 206 may analyze the pressure data to generate a blood pressure waveform of the subject. The analysis unit 206 may generate a vibration that the subject can feel when a change occurs in blood pressure, pulse wave or blood pressure wave measured by the pressure sensor 204. The change may include a case in which the magnitude of the blood pressure, pulse wave or blood pressure wave is decreased, and the blood pressure, pulse wave or blood pressure wave shows an abnormal shape.

In operation S505, the communication unit 207 may transmit a result measured by the pressure sensor 204 to an external system. The communication unit 207 may transmit pulse wave or blood pressure wave information of the subject measured by the pressure sensor 204 to an external system. The communication unit 207 may transmit the blood pressure data analyzed by the pressure sensor 204 and the data of the highest and lowest blood pressure to an external system. The external system may include a display system capable of displaying the data, a storage system capable of storing the data, and an analysis system capable of further analyzing the data.

In operation S505, when a change occurs in the pulse wave or the blood pressure wave measured by the pressure sensor 204, the communication unit 207 may transmit a signal about the change to the external system. The change may include a case where the magnitude of the pulse wave or the blood pressure wave is reduced, or when the pulse wave or the blood pressure wave shows an abnormal shape. The external system may include an emergency system that notifies the medical staff of the emergency when an emergency occurs in the state of the subject. The communication unit 207 may allow the continuous blood pressure measuring device to transmit blood pressure information of the subject through wireless communication without wire connection. The communication method used by the communication unit 207 may include a communication method such as Bluetooth, infrared, LTE, etc., but may include all kinds of communication methods capable of transferring data.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will understand that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

Claims (17)

Band portion that can be attached to the body portion of the subject in the form of a ring;
An air pocket located inside the annular band part and in close contact with the body of the subject;
A pressure sensor for detecting a pressure inside the air pocket and measuring a blood pressure waveform of the subject; And
And a pressure control unit for adjusting the pressure applied to the body of the air pocket by the air pocket. The method of claim 1,
And a analyzing unit analyzing the blood pressure waveform measured by the pressure sensor.
The method of claim 1,
Continuous blood pressure measuring device, characterized in that the body part is a wrist.
The method of claim 1,
And a correction unit for maintaining an internal pressure at a predetermined level when the air pocket is not measured.
The method of claim 4, wherein
The correction unit,
Continuous blood pressure measuring device for filling or discharging gas in the air pocket in accordance with the internal pressure during the non-measurement of the air pocket.
The method of claim 1,
And a communication unit for transmitting the blood pressure data of the subject measured by the pressure sensor to the outside.
The method of claim 1,
The pressure sensor,
Continuous blood pressure measurement device for measuring the blood pressure waveform of the subject as a continuous waveform.
The method of claim 1,
The pressure control unit,
A continuous blood pressure measuring device for checking an optimum pressure having a maximum magnitude of a blood pressure waveform of the subject measured by the pressure sensor while increasing or decreasing the pressure of the air pocket, and fixing the pressure of the air pocket to the optimum pressure.
The method of claim 1,
The air pocket,
Continuous blood pressure measurement device that is included in the plurality, the gas movement between each other.
Fixing the blood pressure monitor to the body part of the subject while the air pocket is in close contact with the body part of the subject;
Pre-measuring the blood pressure of the subject while increasing or decreasing the internal pressure of the air pocket;
Analyzing the measured blood pressure waveform of the subject to derive an optimal value of the internal pressure of the air pocket;
Setting the internal pressure of the air pocket to the optimum value; And
And measuring blood pressure of the subject as a continuous waveform.
The method of claim 10,
Analyzing the measured waveform; further comprising a blood pressure measurement method.
The method of claim 10,
The body part is a continuous blood pressure measuring method, characterized in that the wrist.
The method of claim 10,
The pre-measuring step,
Checking an internal pressure value of the air pocket;
Filling gas into the air pocket when the internal pressure value is lower than a specific value; And
And pre-measuring the blood pressure waveform of the subject while increasing the pressure applied to the body part of the subject by increasing the internal pressure of the air pocket.
The method of claim 13,
And said specific value is atmospheric pressure.
The method of claim 14,
The gas filling step,
And open the air pocket to adjust the internal pressure to the atmospheric pressure level when the internal pressure value is below atmospheric pressure.
The method of claim 10,
And transmitting the measured blood pressure waveform data to an external system.
The method of claim 10,
The air pocket,
Continuous blood pressure measurement method comprising a plurality of gas movement between each other.

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