KR20200128816A - Bodily Fluid Diagnosis Strip System - Google Patents

Abstract

According to an embodiment of the present invention, a body fluid diagnosis strip system comprises: a leading-in path in which a body fluid including a target is provided; a reaction part reacting with the target, and changing an electric property by the reaction; a display part changing a display state so as to correspond to the electric property which is changed by the reaction; and a power providing part providing driving power of the display part. According to the diagnosis strip and diagnosis system, after the body fluid is introduced into the leading-in path, a test result can be immediately checked by using a portable terminal.

Description

Bodily Fluid Diagnosis Strip System

The technique described below relates to a bodily fluid diagnostic strip system.

Existing test strips consist only of strip products, so they were buried with body fluids such as collected blood and used as a separate measuring device to analyze the components in the blood. Conventional strips do not only function as a carrier to provide a separate measuring device by burying body fluids such as blood, or to provide inaccurate analysis results. Therefore, there are cases in which the accuracy of measurement cannot be guaranteed for reasons such as contamination of foreign substances until the body fluid is transported and provided to the measuring device.

After collecting bodily fluids, it provides a strip system that can perform a quantitative test immediately using a portable terminal and check the test results.

The diagnostic strip according to an embodiment includes an inlet path for delivering a bodily fluid including a target to the reaction unit, a reaction unit that reacts with the target and changes electrical characteristics by the reaction, a power supply unit providing driving power, and a reaction And a display unit whose city state changes to correspond to the changed electrical characteristics.

The diagnostic system according to an embodiment includes a diagnostic strip including a reaction unit in which electrical characteristics change according to a reaction with a target contained in a bodily fluid, and a display unit that displays a code whose city state changes to correspond to the changed electrical characteristics. And a terminal that provides driving power to the diagnostic strip and reads a code of the diagnostic strip and displays information formed by a reaction with a target.

A diagnostic strip according to an embodiment includes: a power supply unit for providing driving power to the diagnostic strip, an inlet path for delivering a bodily fluid including a target, a first reaction unit in which electrical characteristics change by reacting with the target and the bodily fluid, From the difference between the changed electrical characteristics of the first reaction unit and the changed electrical characteristics of the second reaction unit by receiving driving power from the reaction unit including the second reaction unit in which the electrical characteristics reacting with the body fluid changes and the power supply unit It includes a display unit in which the city state changes to correspond to the electrical characteristics by the reaction.

According to the above-described diagnostic strip and diagnostic system, after the bodily fluid is introduced into the inflow path, the detection result can be immediately confirmed using a portable terminal.

1 is a block diagram showing an outline of a diagnostic strip according to an embodiment.
2 is an exploded perspective view showing an outline of a diagnostic strip according to an embodiment.
3 is a top perspective view showing an outline of a diagnostic strip according to an embodiment.
4 is a flowchart for schematically explaining the operation of the diagnostic system.
5 and 6 are perspective views for explaining the operation of the diagnostic system.
7 is a schematic circuit diagram of a reaction unit and a display unit.
8 is a diagram schematically illustrating a diagnostic strip including a display unit and an outline display unit.

Hereinafter, a diagnostic strip according to an embodiment and a diagnostic system 1 using the same will be described with reference to the accompanying drawings. 1 is a block diagram showing an outline of a diagnostic strip 10 according to an embodiment. Referring to FIG. 1, a diagnostic strip 10 according to an embodiment includes an inlet path 100 through which a bodily fluid including a target is provided, a reaction unit 200 that reacts with the target and changes electrical characteristics by the reaction. , And a display unit 300 whose city state is changed to correspond to an electrical characteristic changed by the reaction, and a power supply unit 400 providing driving power of the display unit.

2 is an exploded perspective view showing an outline of the diagnostic strip 10 according to an embodiment, and FIG. 3 is a top perspective view showing an outline of the diagnostic strip 10 according to an embodiment. 2 and 3, the inlet path 100 provides a bodily fluid to the reaction unit 200. The introduction path 100 may have a shape for introducing a body fluid into the diagnostic strip. As in the embodiment illustrated in FIGS. 2 and 3, the lead-in path 100 is formed of a capillary tube, and a body fluid is introduced into the reaction part 200 inside the diagnostic strip 10 by using a capillary phenomenon. According to an embodiment not shown, the inlet path 100 is formed to expose the reaction unit 200, and the body fluid may be dropped into the reaction unit. According to another embodiment not shown, the inlet path may have a tube shape into which the tip of a carrying member, such as a dropper containing body fluid, is inserted.

The reaction unit 200 may include a first reaction unit 210 that reacts with a target, which is a detection target, and a second reaction unit 220 that reacts with a body fluid. The first reaction unit 210 may further include a reactant whose electrical resistance value is changed by reacting with a target to be detected. The first reaction unit 210 and the second reaction unit 220 may be formed of the same material or a similar material, except that a reaction material that reacts with the target material is further formed in the first reaction unit 210.

In one embodiment, when the target to be detected is glucose, the first reaction unit 210 reacts with blood sugar contained in the body fluid as a reactive substance to form hydrogen peroxide (H2O2) to change the electrical resistance value. It may include glucose oxidase. The first reaction unit 210 may react not only with a target in the bodily fluid, but also with a bodily fluid, and thus electrical characteristics may be changed. If the difference between the reaction occurring in the first reaction unit 210 and the reaction occurring in the second reaction unit 220 is obtained by placing a second reaction unit 220 that is the same or similar to the first reaction unit 210, the body fluid and the reaction unit are It is possible to remove the result of the reaction of the target and detect the change in the electrical properties caused by the reaction of the reactant.

In an embodiment, the reaction unit 200 may be formed by performing a printing process. The printing process of forming the reaction part includes transfer printing to print after the material forming the reaction part is buried in a mold, and inkjet printing in which the material forming the reaction part is discharged with a nozzle. , Gravure printing and roll-to-roll printing processes of printing a material forming a reaction part using a roller may be used. In addition, in the process of printing the reaction unit 200, one or more of the reaction unit 200, the display unit 300, and the power supply unit 400 may be formed.

In the embodiment illustrated in FIGS. 2 and 3, the display unit 300 may display a machine readable code through a device. The code displayed by the display unit 300 is a code capable of reading reaction information through a device by displaying reaction information between a target and a reaction substance according to a predetermined coding convention.

In an embodiment, the display unit 300 includes a variable code display unit 310 in which information displayed by the reaction between the bodily fluid and the reaction unit 200 changes, and the information displayed even when a reaction between the bodily fluid and the reaction unit 200 occurs. It may include a fixed code display unit 320 that does not change.

In an embodiment, the code displayed by the display unit 300 is a QR code (Quick Response code), and the QR code changes according to the reaction result to display information according to the reaction. In an embodiment not shown, the code displayed by the display unit is a barcode. In another embodiment not shown, the code displayed by the display unit 300 may be a display bar that can change color according to a quantitative value.

In one embodiment, the variable code display unit 310 may include a light emitting device such as a light emitting diode or OLED, and emits light by a voltage provided by a reaction between the target and the reaction unit 200, or does not emit light, so that the variable code display unit You can change the code displayed by (310).

In another embodiment, the variable code display unit 310 may include a color change element. For example, the color-changing device may be implemented as a device in which colloid particles are dispersed in the device, and the position of the colloid particles is changed by a voltage applied to the device, so that the color displayed on the outside changes.

As another example, the color-changing device may be implemented as an electrochromism device. The electrochromic device refers to a device including an electrochromic material that changes color by causing electrochemical oxidation and reduction reactions when a voltage is applied, and the color changes as voltage is applied.

For example, the electrochromic device may include WO3, Nb2O5, MoO3, and TiO3, which are cathodic coloration materials that change from an oxidized state to colorless, as an electrochromic material. As another example, it may include V2O5, IrO2, and NiO, which are anodic coloration materials that develop color in an oxidized state.

Accordingly, the code displayed by the variable code display unit 310 is changed according to the voltage provided by the reaction between the target and the reaction unit 200.

In another embodiment, the variable code display unit 310 may be implemented with electronic ink (e-ink). Electronic ink includes a capsule and pigments charged with different charges injected into the capsule. If the voltage formed by the reaction of the target and the reaction part 200 is provided between one side and the other side of the capsule, the magnitude and polarity of the voltage Accordingly, the charged dyes move to change the code displayed by the variable code display unit 310.

The fixed code display unit 320 displays a predetermined code irrespective of the reaction between the target and the reactant material. Since the display content of the fixed code display unit 330 does not change, it can be printed and displayed. For example, if the code displayed by the display unit 300 is a QR code, the variable code display unit 310 encodes and displays the reaction information according to the QR code protocol, and the fixed code display unit 320 indicates the direction of the QR code. The element to be displayed. As another example, if the code displayed by the display unit 300 is a bar code, the fixed code display unit 320 may be a guard bar displayed on the left, right, and center of the bar code to distinguish reaction information. The variable code display unit 310 may be positioned between the fixed code display units 320 to encode and display reaction information as a combination of bars having different thicknesses.

The power supply unit 400 provides power to the diagnostic strip 10. In one embodiment, the power providing unit 400 may include an inductive coupling device for receiving power by inductive coupling with a terminal. As an example, the inductive coupling device may include a rectenna that collects, rectifies, and outputs radio waves provided by the terminal. The rectenna may include an antenna 410 formed of a coil to receive power transmitted by the terminal 20 wirelessly, and a rectifying device 420 that rectifies the received signal. In an embodiment not shown, the power supply unit 400 may further include a capacitor that smoothes the pulsating wave output from the rectenna and stores energy. In one embodiment, the power supply unit 400 may be formed by performing a printing process of forming the reaction unit 200 and the display unit 300 as described above.

In another embodiment, the power supply unit may include a button cell and a coin cell, and allow a user to use a button cell or a coin cell together with the inductive coupling device described above. have.

In another embodiment, the power providing unit may include an energy conversion device and an electrical energy storage device. The energy conversion element is an element that converts provided mechanical energy into electrical energy. The user provides mechanical energy to the energy conversion element, and the energy conversion element converts mechanical energy into electrical energy and outputs it to the electrical energy storage element. As an example, the energy conversion element may be a piezoelectric element that converts mechanical energy provided by a user to be pressed into electrical energy. As another example, the energy conversion element may be a element that converts mechanical energy due to friction into electrical energy.

The diagnostic strip 10 may be driven using energy stored in an electrical energy storage device.

Hereinafter, the operation of the diagnostic system 1 will be described. 4 is a flow chart for schematically explaining the operation of the diagnostic system 1. Referring to FIG. 4, in an embodiment, a bodily fluid including a target is provided through the inlet path 100 of the diagnostic strip 10 (S100). When a bodily fluid is provided, the first reaction unit 210 including a reactant that reacts with the target may react with the bodily fluid and the target to change electrical characteristics. In the second reaction unit 220 provided with the bodily fluid, electrical characteristics may be changed by reacting the bodily fluid and the reaction unit.

In one embodiment, the terminal 20 may be inductively coupled to the diagnostic strip 10 to provide driving power to the diagnostic strip 10. In another embodiment, the diagnostic strip 10 may receive driving power from an internal primary battery. The process of providing driving power to the diagnostic strip 10 may be performed after, for example, a process of providing a bodily fluid to the diagnostic strip 10, and in another example, prior to a process of providing the bodily fluid to the diagnostic strip 10. Can be done.

The diagnostic strip 10 provided with driving power may display a code corresponding to the reaction result on the display unit 300, and the terminal 20 may read the code and provide the reaction result to the user (S200). In one embodiment, the display unit 300 obtains a difference between the reaction result in the first reaction unit 210 and the reaction result in the second reaction unit 220 to form and display a code corresponding thereto.

In one embodiment, the terminal 20 may store the read result in a server through a communication network, and in another embodiment, the terminal 20 may store the read result in the terminal 20 itself. When a long-term monitoring of the reaction result is required, the terminal 20 may display the stored information in the form of a graph and provide it to the user.

5 and 6 are perspective views for explaining the operation of the diagnostic system 1, and FIG. 7 is a schematic circuit diagram of the reaction unit 200 and the display unit 300. 5 to 6, when a bodily fluid is provided to the inlet path 100, the bodily fluid is provided to the reaction unit 200. In one embodiment, when the user executes the application on the portable terminal 20, the application displays the portable terminal 20 so that the frame F and the display unit 300 of the diagnostic strip are displayed on the screen of the portable terminal 20. Can be controlled. In one embodiment, the application acquires an image of the display unit 300 of the diagnostic strip 10 using a camera (not shown) included in the portable terminal, and displays the acquired image together with the frame F on the screen of the portable terminal. Can be marked on.

In an embodiment, the application may provide power by maintaining a distance between the portable terminal 20 and the diagnostic strip 10 at a predetermined distance. Since the distance between the portable terminal 20 and the diagnostic strip 10 is short, the portable terminal 20 can provide a voltage greater than necessary to the diagnostic strip 10, and between the portable terminal 20 and the diagnostic strip 10 If the distance is large, the portable terminal 20 may not be able to provide a sufficient voltage to drive the display unit 300.

For example, as in the example shown in FIG. 5, the size of the frame F displayed on the screen of the portable terminal 20 and the display unit 300 is compared, and the size of the frame F and the display unit 300 is When corresponding to each other, power can be wirelessly supplied to the portable terminal through the portable terminal.

As another example, as shown in FIG. 6, one or more light emitting elements L1, L2, and L3 may be placed on the diagnostic strip 10 to display the level of voltage provided by the portable terminal. As an example, in an embodiment including one light-emitting element, the light-emitting element may be controlled to emit light only when the voltage supplied from the portable terminal 20 is appropriate. As another example, in an embodiment including a plurality of light-emitting elements, any one light-emitting element is lit when the voltage provided by the portable terminal 20 is greater than the desired voltage, and the other light-emitting element is the portable terminal. It turns on when the voltage provided by 20 is smaller than the target voltage, and another light emitting element can be turned on when the voltage provided by the portable terminal 20 is within the range of the target voltage.

Accordingly, the user adjusts the separation distance between the portable terminal 20 and the diagnostic strip 10, and accordingly, the portable terminal 10 provides an appropriate driving voltage to the diagnostic strip 10.

In another embodiment, the application may control the terminal to transmit power wirelessly when the user drives the application. In one embodiment, the portable terminal 20 may provide power to the diagnostic strip 10 by means of NFC (Near Field Communication), RFID (Radio Frequency IDentification), or the like.

In an embodiment, the power providing unit 300 may further include a Zener diode (not shown) clamping the magnitude of the supplied voltage. When the distance between the portable terminal 20 and the diagnostic strip 10 is narrow, a voltage greater than or equal to a voltage required for driving may be provided to the diagnostic strip 10. When a voltage higher than the voltage required for driving is provided, the Zener diode may clamp it so that an overvoltage is not applied to the internal circuit.

When driving power is provided to the diagnostic strip 10 from the portable terminal 20, the display unit 300 may show a target detection result. When the amount of the target in the body fluid is to be detected, the reactant material included in the first reaction unit 210 and reacting with the target reacts with the target, thereby changing an electrical resistance value. In addition, the first reaction unit 210 may react with a component other than the target to change the electrical resistance value, but the second reaction unit 220 can compensate for the effect of the reaction with the component other than the target. have.

In an embodiment of detecting blood glucose (glucose), blood drawn through the inlet path 100 may be provided to the first reaction unit 210 and the second reaction unit 220. The change in the electrical characteristics of the first reaction unit 210 is a change formed by the reaction between blood sugar in the blood and the first reaction unit 210, and the change formed by the reaction between blood other than blood sugar and the first reaction unit 210 It is a combination of changes. Since the second reaction unit 210 does not contain glucose oxidase that reacts with blood sugar, the electrical characteristics of the second reaction unit 210 may change by reacting with components other than blood sugar in the blood.

As shown in FIG. 7, the electrical resistance formed by the reaction between blood sugar and the first reaction part 210 is R2, and the electrical resistance formed by the reaction of the body fluid other than the target and the first reaction part 210 is R4. And, let the electrical resistance formed by the reaction between the body fluid and the second reaction unit 220 is R3. Further, a voltage V provided from the portable terminal 10 is provided at one end of the illustrated closed loop, and since R2, R4 and R3 are included in the same closed loop, the same current i flows.

The first reaction unit 210 may be the same as or similar to the second reaction unit 220 except that the first reaction unit 210 further includes a reaction material whose electrical properties are changed by reacting with the target. Accordingly, the voltage drop Vb formed by the electrical resistance R3 formed by the second reaction unit 220 reacting with the body fluid and the electrical resistance formed by the reaction of the body fluid excluding the target and the first reaction unit 210 The magnitudes of the voltage drop Va formed by (R4) are the same. Accordingly, since the magnitudes of Va and Vb are the same and cancel each other, the voltage provided to both ends of the display unit 300 is caused by a voltage drop formed by the reaction between the target and the reactant in the body fluid.

The display unit 300 may include a resistance array RA. The resistance array RA includes resistors having different resistance values. In FIG. 7, resistors Rd1, Rd2, ..., Rd5 connected to resistors included in the resistor array RA are modeled by a display element included in the variable code display unit 310 as a resistor. When voltage is provided to both ends of the display unit 300, voltage dividing is performed to correspond to a resistance value included in the resistance array and an equivalent resistance value of the variable code display unit.

The voltage provided to both ends of the equivalent resistances of the variable code display unit 310 corresponds to the resistances included in the resistance array and the equivalent resistance and resistance ratio of the variable code display unit 310. For example, Ra1 included in the resistance array is 0.5Ω, Ra2 is 1Ω, Ra3 is 1.5Ω, Ra4 is 2Ω, Ra5 is 2.5Ω, and Rd1 to Rd5 are all 1Ω, and are provided to display devices modeled as Rd1 to Rd5. Assume that the voltages are V1, V2, ..., V5, and that the display elements modeled as Rd1 to Rd5 are turned on at a voltage of 1.3 V or more.

Assuming that the voltage provided to the display unit 300 is 3V according to the resistance change formed by the reaction between the target and the reactive substance in the body fluid, the voltage V1 at both ends of Rd1 formed by voltage distribution is 2V, and the voltage V2 at both ends of Rd2 is 1.5 V, the voltage V3 across Rd3 is 1.2V, the voltage V4 across Rd4 is 1V, and the voltage V5 across Rd5 approximates 0.86V. Accordingly, it can be seen that both V1 and V2 are above the turn-on voltage, and the display elements modeled as Rd1 and Rd2 are turned on, and the other display elements are turned off.

As another example, if the voltage provided to the display unit 300 is 6V, the voltage V1 at both ends of Rd1 formed by voltage distribution is 4V, the voltage V2 at both ends of Rd2 is 3V, the voltage V3 at both ends of Rd3 is 2.4V, and Rd4 The voltage V4 at both ends of is 2V, and the voltage V5 at both ends of Rd5 is approximated to 1.71V. Accordingly, all of the display elements modeled as Rd1 to Rd5 are turned on with more than the turn-on voltage.

Accordingly, the code displayed by the variable code display unit 310 may be different according to the voltage formed according to the resistance change due to the reaction between the target and the reactant material, and accordingly, the display unit 300 provides the target concentration in the body fluid and the presence or absence of the target. You can display codes corresponding to etc.

The portable terminal 20 may read a code displayed by the display unit 300 and display the read result on a screen. Referring to FIG. 5, when a blood sugar concentration in blood is to be detected, the display unit 300 displays a code corresponding to the blood sugar concentration in the blood, and the portable terminal 20 reads the code and displays the read result on the screen. Shown as. In one embodiment, the portable terminal may store individual measurement results by providing the reading result to the server.

According to another embodiment of the diagnostic strip 10, the diagnostic strip 10 may further include an overview display unit that outlines a reaction result between the target and the reaction unit to the user. 8 is a diagram schematically illustrating a diagnostic strip 10 including a display unit 300 and an outline display unit 500. For example, referring to FIG. 8, as illustrated in FIG. 8A, the display unit 300 and the outline display unit 500 may be separately disposed on the surface of the diagnostic strip 10. Ten pixels may be horizontally arranged in a row, and each row may be arranged vertically. As in the illustrated example, since two lines formed by horizontally arranging 10 pixels horizontally are arranged vertically, and three pixels display codes in the uppermost line, the code displayed by the variable code unit corresponds to 23 . Therefore, you can easily grasp the measurement result by reading it.

As another example, as shown in FIG. 8B, the outline display unit 500 may be displayed by being superimposed on the display unit 300. For example, in the outline display unit 500, 10 pixels may be horizontally arranged in a row and each row may be arranged vertically, and a value corresponding to one pixel is 5. As in the illustrated example, since two lines formed by horizontally arranging 10 pixels horizontally are arranged vertically, and three pixels display codes in the uppermost line, the code displayed by the variable code unit corresponds to 23 . Since the value corresponding to one pixel is 5, if the code is read to correspond to this, it can be seen that it corresponds to 115.

Like the variable code display unit 310, the outline display unit 500 is a light-emitting diode, a light-emitting element such as OLED, a color change element, an electrochromic element, and an electronic ink whose city state changes so that the reaction unit reacts with the target to correspond to the changed electrical characteristics. It can be implemented with (e-ink), etc.

Although it has been described with reference to the embodiment shown in the drawings in order to help understand the present invention, this is an embodiment for implementation, is only illustrative, and a person having ordinary knowledge in the art therefrom various modifications and equivalent It will be appreciated that other embodiments are possible. Accordingly, the true technical scope of the present invention should be determined by the appended claims.

10: diagnostic strip 20: portable terminal
100: inlet path 200: reaction part
210: first reaction unit 210: second reaction unit
300: display unit 310: fixed code display unit
320: variable code display unit 400: power supply unit
410: antenna 420: rectifying element
500: outline display

Claims (4)

A diagnostic strip including a reaction unit that changes electrical characteristics by a reaction with a target contained in bodily fluid, and a display unit that displays a code whose city state changes to correspond to the changed electrical characteristics;
Including a terminal for reading the code of the diagnostic strip and displaying information formed by a reaction with the target,
The diagnostic strip,
An energy conversion element that converts mechanical energy into electrical energy
Further comprising an electrical energy storage device for storing electrical energy provided by the energy conversion device,
The diagnostic strip is a diagnostic strip system that is driven by electrical energy converted from mechanical energy provided by a user. The method of claim 1,
The terminal is a diagnostic system for transmitting the information formed by the reaction with the target to the server. The method of claim 1,
The terminal is a diagnostic system including a camera that obtains the code provided by the diagnostic strip. The method of claim 1,
The diagnostic strip is a diagnostic system that receives driving power from a battery.

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