JP2564302B2 - Biochemical measuring device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a biochemical measurement device, for example, a urine test device for testing urine for sugar, protein, occult blood, urobilinogen, and the like. The present invention relates to a biochemical measuring device for testing items (sugar, protein, occult blood, urobilinogen, etc.) at once.

(B) Conventional technology Conventionally, as a biochemical measuring device for testing a plurality of test items (sugar, protein, occult blood, urobilinogen, etc. in urine) at one time, those shown in FIGS. 8 and 9 have been used. Exists.

In the biochemical measuring device shown in FIG. 8, an inspection unit is configured by exposing a light receiving / light emitting surface of a reflection sensor 74 composed of a light receiving element 72 and a light emitting element 73 at one end of an inspection main body case 71. A test paper stick (having a plurality of test papers impregnated with a reagent adhered on a resin sheet) 75 is inserted and arranged in the section. The reflection sensor 74 is a single light receiving element.
A plurality of pairs of sensors, each consisting of 72 and a single light emitting element 73, are provided in correspondence with the number of test papers 76.

For urinalysis, test paper stick (test paper 76) 75
Impregnate it with urine and insert it into the examination area. At this time, each test paper
76 is located corresponding to each of the light receiving / light emitting elements 72, 73. Then, light is emitted from each light emitting element 73 onto the surface of the test paper 76, and the test paper 76
The corresponding light receiving element 72 receives the light reflected by the surface, and each test item is inspected based on the color reaction light amount.

In the biochemical measuring apparatus shown in FIG. 9, a reflection sensor 81 composed of a light-receiving / light-emitting element is brought out to a proper position in the case of the inspection body, and this reflection sensor 81 has a plurality of light-emitting elements centering on a single light-receiving element 82. It is configured by arranging 83 in a circle. Although not shown, each light emitting element 83 is set so as to have its own wavelength, and each test paper 85 of the test paper stick 84 inserted and arranged in the inspection section is sequentially positioned corresponding to each light emitting element 83. A movement control mechanism for controlling the movement is provided.

In the urine test, when the test strip stick (test strip 85) 84 impregnated with urine is inserted into the test section, the test strip stick 84 moves by the movement control mechanism (moving table) and becomes the first test target. The test paper 85 is located on the light receiving element 82. Here, light is projected from the light emitting element (light emitting element having a peculiar wavelength) 83 for the earliest inspection object onto the corresponding test paper 85, and the reflected light is received by the light receiving element 82. When one inspection item is completed, the test paper stick 84 is moved again, the test paper 85 corresponding to the next test item is moved to the position of the light receiving element 82, and light is projected from the corresponding light emitting element 83. , Perform sequential inspection.

(C) Problems to be Solved by the Invention Among the biochemical measuring devices described above, the former (method having a plurality of pairs of light-receiving / light-emitting elements corresponding to the number of test strips) has a number corresponding to the number of test strips. A light receiving element is required, and when the number of inspection items increases, the number of light receiving elements increases, and there is a disadvantage that the product cost cannot be increased and the size cannot be reduced.

Also, in the latter (a method in which multiple light emitting elements are arranged in a circle with respect to a single light receiving element), the number of light receiving elements is single, so the disadvantages of the former are eliminated, but on the other hand, a test paper stick is used for each inspection item. The test paper has to be moved and controlled to move to the corresponding light emitting element position. This movement control mechanism is complicated, requires a large space, and cannot be downsized.

An object of the present invention is to provide a compact biochemical measuring device having a simple and inexpensive structure and capable of testing a plurality of test items at once.

(D) Means and Actions for Solving Problems In order to achieve this object, the biochemical measuring device of the present invention has the following configuration.

That is, the biochemical measuring device is configured such that a plurality of different types of test paper sticked to each other are fixedly attached to the inspection unit so that the test paper stick can be inserted and removed. Is a biochemical measuring device for inspecting the amount of color reaction light of the test paper, wherein the inspecting section is provided at one end of the main body case so that at least two light emitting elements sandwich one light receiving element. And a stick holder having a rotatable stick cover for positioning and holding the inserted test paper stick, wherein the stick holder is the reflection sensor of the main body case. The light emitting element, the light receiving element, and the test strip are configured to be detachable from the test piece, and the stick holder is attached to the reflection sensor section. Is held at a predetermined position by a stick cover, the light emitted from both light emitting elements at the symmetrical position is reflected by another corresponding test paper and enters the light receiving element. It is configured by providing control means for lighting the light emitting elements at symmetrical positions in a time division manner.

In the biochemical measuring device having such a configuration, each test strip is positioned corresponding to each light emitting element in a state where the test strip stick is inserted and arranged in the inspection section where the light receiving / light emitting surface of the reflection sensor is exposed. . Therefore, inspection of a plurality of items can be performed with the test paper stick fixed. Also,
The reflected light emitted from each of the plurality of light emitting elements and reflected by the corresponding test paper is received by a single light receiving element, and is inspected based on the amount of color reaction light. Therefore, since a single light receiving element is arranged corresponding to a plurality of light emitting elements, the number of light receiving elements can be small and miniaturization can be achieved.
Further, since the plurality of light emitting elements are set to light up in a time-division manner, when performing a plurality of inspection items,
The light-receiving element can properly receive the reflected light without the adjacent light-emitting elements being influenced by the projected light from each other, and the inspection of a plurality of items can be accurately executed.

(E) Embodiment FIG. 2 is a perspective view showing a specific embodiment of the urine test apparatus according to the present invention.

The urine test apparatus includes a main body case 1 in which a control circuit unit such as a CPU (central processing unit) and a power supply battery unit are internally housed, a stick holder 2 detachably fitted to one end of the main body case 1, and It is composed of a stick cover 3 rotatably attached to the stick holder 2.

A power switch section 11 and an inspection result display section 12 are provided on the front surface of the body case 1 at appropriate places.

FIG. 1 is a perspective view showing a state in which the stick holder 2 is removed from the main body case 1.

At one end of the main body case 1, a reflection sensor section 4 composed of a light-receiving / light-emitting element is temporarily arranged. This reflection sensor section 4
As shown in the enlarged perspective view of FIG.
Mounting pieces 46 are provided on both side walls of the main body case 1, and the mounting pieces 46 are attached to the open ends of the main body case 1 (see FIG. 4). A light receiving / light emitting element is provided inside the sensor case 41.
In the embodiment, the light emitting element 43 is provided on each side of the light receiving element 42,
43a are arranged in parallel, and the light receiving / light emitting surfaces of the light receiving element 42 and the light emitting elements 43, 43a are exposed to the window hole 45 of the sensor case 41.
The light emitting elements 43 and 43a are set and arranged at intervals corresponding to the plurality of test papers 51 attached to the test paper stick 5. That is, with the test paper stick 5 inserted and arranged in the inspection unit (which is composed of the reflection sensor unit 4 and the stick holder 2 to be described later), each light emitting element 43, 43a is set to properly correspond to each test paper 51. And each light emitting element 4
It is set that 3, 43a project light on the surface of each test paper 51 and each reflected light is received by a single light receiving element 42. In the embodiment, the inspection items are set to four items, that is, four test papers 51.
Assuming that the two light emitting elements 43, 43a and one light receiving element 42
Two pairs of light receiving and emitting portions, each consisting of and, are arranged.

On the upper surface of one end of the main body case 1 (the protruding portion of the sensor case 4), an opening button portion 14 having a claw portion 13 for holding the closed state of the stick cover 3 described later is provided, and
On both sides of the one end, locking piece portions 15 that engage with and disengage from slide groove portions of the stick holder 2 described later are provided.

The stick holder 2 includes a flat plate portion 21 corresponding to the front surface (window hole portion 45) of the sensor case 4, and slide groove portions 22 slidably fitted to the locking piece portions 15 of the main body case 1 on both sides of the flat plate portion 21. The mounting portion 23 provided with (see FIG. 4) is provided,
The stick holder 2 is arranged so that it can be slidably inserted into and removed from the main body case 1 in the vertical direction. The light emitting elements 43, 43 exposed to the sensor case 4 are provided in the plane of the flat plate portion 21.
Window holes 24 corresponding to a are opened. That is,
When the stick holder 2 is slidably attached to the main body case 1, the window holes 45 of the light emitting elements 43 and 43a and the test paper window hole 24 are set to communicate with each other.

The stick cover 3 is a vertical piece which is rotatably attached to the lower end of the flat plate portion 21 of the stick holder 2.
31 and a horizontal piece 32 that integrally projects inward from the upper end of the vertical piece 31. An inclined stick pressing plate portion 33 is provided between the vertical piece 31 and the horizontal piece 32. ing.
In addition, at both ends of the horizontal piece portion 32, locking claw portions 34 that engage and disengage with the claw portions 13 of the opening / closing button portion 14 are provided to project downward, and at the center of the horizontal piece portion 32, that is, the locking claw portion. A notch 35 is opened between 34. The test paper stick (test paper 51) is clamped and fixed between the stick cover (stick pressing plate portion 33) 3 and the flat plate portion (window hole 24) 21.

FIG. 5 is a block diagram showing a circuit configuration of the urine test apparatus according to the embodiment.

A ROM (Read Only Memory) 61 is a memory that stores an inspection program, and a RAM (Random Access Memory) 62 is a storage memory for calculation. LED driver 6
Reference numeral 3 denotes a drive circuit that receives a command from the CPU 64 and turns on the light emitting elements 43 and 43a. The LED selector 65 receives an output signal from the LED driver 63 and selectively turns on the respective light emitting elements 43 and 43a. Further, an AMP (amplifier) 66 amplifies the amount of light received by the light receiving element 42 and outputs the amplified light to an A / D converter 67, and an A / D converter (A / D
The D converter) 67 converts the analog output amount of the amplifier 66 into a digital value that the CPU 64 can easily process. In addition, the timer 68 is a CPU 64
Connected to and measure the required time settings for inspection measurements. Further, the reset circuit 69 forcibly resets the instrument when the switch 11 is turned on.

The CPU 64 has a function of controlling the LED selector 65 to turn on the plurality of light emitting elements 43, 43a in a time division manner, and at the same time, A / D
Calculate the measurement result from the information acquired from the converter 67,
It has a function of displaying on the display unit 12.

FIG. 6 is a schematic explanatory perspective view showing another embodiment of the reflection sensor section (light receiving / light emitting element) 4.

In the previous embodiment, an example was shown in which two light emitting elements 43, 43a were arranged in parallel on both sides of a single light receiving element 42, but in this embodiment, four light emitting elements centering on the single light receiving element 42 are shown.
An example is shown in which 43, 43a, 43b, and 43c are arranged 90 degrees apart. In this case, the test paper stick 5 uses four test papers 51 arranged (attached to a sheet) corresponding to the arrangement state of the four light emitting elements 43 (43a, 43b, 43c). This embodiment is characterized in that the single light receiving element 42 receives the projection light which is time-divisionally turned on from the four light emitting elements.

FIG. 7 is a schematic explanatory plan view showing another embodiment of the reflection sensor section (light receiving / light emitting element) 4.

In this embodiment, an example in which eight light emitting elements 43, 43a, 43b, 43c, 43d, 43e, 43f, 43e are arranged around a single light receiving element 42 via a 45-degree angled shield plate 47, respectively. Shows. In this case, the eight test papers 51 of the test paper stick 5
Are eight light emitting elements 43 (43a, 43b, 43c, 43d, 43e, 43
Use the ones arranged according to the array state of f). This embodiment is characterized in that the single light receiving element 42 receives the projection light which is time-divisionally turned on from the eight light emitting elements.

In the urine test device having such a configuration, each test paper 51 of the test paper stick 5 is impregnated with urine and sandwiched between the stick cover (stick pressing plate part 33) 3 and the stick holder (flat plate part 21) 2. Fix it in place. In this state, each test paper 51 is attached to each light emitting element 43, 43a of the reflection sensor unit 4.
Is located corresponding to. Here, the light emitting elements 43 and 43a are turned on in a time division manner. For example, the light emitting element 43 is turned on for a predetermined time, the light emitted from the light emitting element 43 is projected onto the corresponding test paper 51, and the reflected light is received by the light receiving element 42. Then, the light emitting element 43a is turned on to project the light onto the corresponding test paper 51, and the reflected light is received by the light receiving element 42. That is, with the single light receiving element 42,
It is possible to receive the reflected light of the plurality of light emitting elements 43 and 43a which are respectively turned on in a time-division manner and execute the inspection of a plurality of items. Therefore, the same number of light receiving elements 42 corresponding to the number of test papers 51 can be used for inspection of a plurality of items.
Is unnecessary, and downsizing of the instrument can be achieved. Also, the test paper stick 5 does not need to be moved during the inspection,
The moving mechanism and the positioning control mechanism for the test paper 51 and the light emitting element 43 are unnecessary. In the example, assuming four test papers 51,
An example is shown in which two pairs of a pair of light receiving and emitting portions each including one light receiving element 42 and two light emitting elements 43 and 43a are adopted, but in this example, two pairs of light emitting elements, that is, different It is also possible to perform time-division lighting control in which the respective light emitting elements 43, 43 of the optical system are turned on at the same time, and the light emitting elements 43a, 43a are turned on at the next time point. Even in this case, accurate measurement can be achieved because the optical regions are different and there is no influence of simultaneous lighting.

(F) Effects of the Invention In the present invention, as described above, a single light receiving element is arranged for a plurality of light emitting elements arranged corresponding to a plurality of different types of test papers of a test paper stick, and The light emitting elements are turned on in a time division manner, the light emitted from each light emitting element is projected onto the test paper, and different types of optical information are received by a single light receiving element in a time division manner according to the lighting of each light emitting element. Therefore, when the test paper stick is inserted into the inspection unit (reflection sensor unit), each test paper is positioned corresponding to each light emitting element, and the light emitted from each light emitting element is projected onto each test paper. The light is received by one light receiving element, and the inspection of a plurality of items can be easily executed.

Therefore, the light receiving element corresponding to the number of test strips is not required as in the past, and the test strip stick moving mechanism for associating each test strip with each light emitting element is unnecessary for the inspection. It is possible to achieve downsizing and product cost reduction. Moreover, in the present invention, since the plurality of light emitting elements are turned on in a time-division manner, the accurate inspection can be performed without being affected by the projection light of the other adjacent light emitting elements.

Also, since the stick holder can be attached to and detached from the main body case, the reflection sensor portion of the main body case can be easily cleaned and cleaned. Moreover, since the stick holder has no electric circuit element, there is no adverse effect on the electric circuit due to dirt removal or cleaning of the stick holder. Moreover, since the stick cover rotates to hold the test strip stick, the test strip stick can be easily inserted, positioned and held.

[Brief description of drawings]

FIG. 1 is an exploded perspective view showing a urine test apparatus according to an embodiment, FIG. 2 is a perspective view showing a urine test apparatus according to an embodiment, FIG. 3 is an enlarged perspective view showing a sensor case, and FIG. FIG. 5 is a partially cutaway cross-sectional view of the example urine test device, FIG. 5 is a block diagram showing a circuit configuration example of the example urine test device, and FIG. 6 is an enlarged perspective view of essential parts showing another embodiment of the reflection sensor unit. , FIG. 7 is an enlarged plan view of an essential part showing still another embodiment of the reflection sensor section, and FIG.
FIG. 9 is an enlarged plan view of an essential part of a conventional biochemical measuring device, and FIG. 9 is an enlarged plan view of an essential part of a conventional biochemical measuring device. 1: Main body case, 2: Stick holder, 3: Stick cover 4: Reflection sensor part, 42: Light receiving element, 43 / 43a: Light emitting element, 64: CPU.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Tamio Miyake, No. 3, Hanazono Nakamimon-cho, Ukyo-ku, Kyoto City, Tateishi Life Science Institute, Inc. (56) References JP-A-61-130859 (JP, A) JP-A-SHO 61-13136 (JP, A)

Claims (1)

(57) [Claims] 1. A test strip sticked with a plurality of different types of test strips is fixedly arranged so that it can be inserted into and removed from the inspection section, and a reflection sensor composed of a light-receiving element of the inspection section is used.
In the biochemical measurement device for inspecting the amount of color reaction light of a plurality of test papers, the inspection unit includes at least two light emitting elements at one end of the main body case so as to sandwich one light receiving element. It is composed of a reflection sensor unit arranged at symmetrical positions on both sides and a stick holder having a rotatable stick cover for positioning and holding the inserted test paper stick, wherein the stick holder is the reflection sensor unit of the main body case. With respect to the light emitting element, the light receiving element, and the test paper, the stick holder is attached to the reflection sensor unit, and the test paper stick is held at a predetermined position by a stick cover. At this time, the light emitted from both the light emitting elements at the symmetrical positions is reflected on another corresponding test paper and enters the light receiving element. Ri, further, the biochemical measurement apparatus characterized in that a control means for time-division lighting the light emitting elements in the symmetrical position.