KR101118804B1 - centrifugal force bloodrheology-tester - Google Patents

Abstract

The present invention is to artificially measure and determine the fluidity of the blood, including various blood cells, such as red blood cells and white blood cells in the human body in vitro, and to form a micro-pass (112, 113, 114, 115, 116, 117, 118) for a special blood passage on the flat glass plate 110 By generating the centrifugal force designed by rotating the glass plate 110 in the rotating plate 240 to rotate while varying the speed within a certain rotational speed and centrifugal force range by receiving blood cells such as red blood cells, white blood cells, plasma Designed to determine whether to pass through the micro-path (112, 113, 114, 115, 116, 117, 118), the characteristic structure is the main body 300 including the rotating plate 240 and the rotating portion 240 protruding on the upper portion of the main body 300 of the main body DC It is connected to the motor 242 and the connector 245, and controls the DC motor unit 242 installed inside, the rotating unit 240, DC motor 242 connected to the motor unit Small microcomputer unit 220 for generating the calculated centrifugal force, an operation panel unit 210 for operating the small microcomputer unit 220, an LED lamp 250, a power supply device of the device. 260 and a switch 261 for cutting off and supplying power.

Blood fluidity, rotational centrifugal force, blood pressure, artificial fine passage, glass plate, DC motor, small microcomputer

Description

Extracorporeal blood flow measurement device using centrifugal force {centrifugal force bloodrheology-tester}

The present invention applies the physical phenomena generated by applying a certain centrifugal force to the collected blood in a device that generates artificial centrifugal force with human blood collected by other methods, thereby artificially simplifying the degree of blood viscosity and fluidity in vitro. The present invention relates to a device for carrying out, and more specifically, the micro-channels 112, 113, 114, 115, 116, 117 and 118, which are similar to the diameters of capillaries, arterioles, and lavage veins in the human body, are formed in a circular shape defined in the flat glass plate 110, and collected in the central portion 120. Spread the blood and cover the cover made of glass so that the blood of the glass flat plate 110 does not dry, and then rotated forward and back in the rotating part 240 for a predetermined time during the rotation of the prepared blood is subjected to the centrifugal force to the micro-path (112, 113, 114, 115, 116, 117, 118) It is to judge whether it passes.

In general, in order to measure the viscosity or fluidity of blood, blood is collected and a special liquid is dropped into a container to measure the time for red blood cells to descend to the bottom of the container.

The method of dropping blood in the solution is a widely used method, but the measurement time is very long and uncomfortable. In addition, the blood flow tester is a device with a different purpose and method from the blood centrifuge commonly used in hospitals.

It is already known that the viscosity of blood is increased due to the change of blood viscosity caused by the rapid dietary change and severe stress of modern people and lifestyle diseases such as diabetes, hypertension and hyperlipidemia, and the fluidity of the blood is hindered to prevent blood circulation. This is a known fact in the medical community.

Blood flow is also associated with worsening of diseases such as cardiovascular disease, hyperlipidemia and diabetic cell necrosis and obstruction of healthy life.

Although the medical community needs reference information to measure blood flow quickly and easily to prevent disease and maintain health in terms of preventive medicine and health care, there is no such cheap, simple and rapid blood flow measuring device, and the existing methods are for various reasons. The situation is not used much realistically. Background Art of the present invention is the realization of a device which artificially generates a force present in the natural world and provides the result of that force.

In order to easily measure blood flow in vitro, the rotational part 240 that generates physical force similar to the physical pressure of blood cells transmitted from the heart in blood vessels in the body through an automatic centrifugal force generator and rotates due to the centrifugal force regulator. The blood collected above is placed on a device that has formed artificial micropaths (112,113,114,115,116,117,118) similar to the diameters of capillaries and fibrillation veins in the human body, and the method of generating high and low centrifugal force, which is a source of force that passes the blood through the artificial microchannels (112,113,114,115,116,117,118). The purpose is to realize the device.

In addition, the blood pressure in the human body varies from person to person depending on the type of blood vessel, so that various centrifugal forces are generated by using a software program. The type is divided into six types and the centrifugal force generation mode is divided into blood pressure of capillaries and fibrillation veins. The purpose is to realize a device for calculating and generating similar forces.

According to the present invention for achieving the above object, the DC motor 242 is stationary for a certain period of time according to a control signal generated from the small microcomputer unit 220 that calculates and generates the force by dividing the centrifugal force into six types using a small microcomputer. Power supply to the DC motor 242 to rotate while repeating the rotation and the rotating unit 240 to accommodate the blood, the operation panel 210 to control the small microcomputer, the DC motor 242 and the small microcomputer 220 Power supply for supplying the power supply 260 is included in the main device and the main body.

In addition, in order to facilitate the rotation, and to easily collect the blood collected centrifugal force to use a light flat glass 110, using a flat glass plate 110 of about 26mm length 77mm thickness 1.5mm thickness artificial artificial It is assumed that the passages 112, 113, 114, 115, 116, 117 and 118 are formed. The method of forming the artificial microchannels 112, 113, 114, 115, 116, 117, 118 may be any method, but the shape of the artificial microchannels 112, 113, 114, 115, 116, 117, 118, the micropaths 112, 113, 114, 115, 116, 117, 118, and the interval between the passages are determined and constant.

The formula for calculating the centrifugal force of the rotating plate applies the following formula.

    F = mv ^ 2 / r

 F = centrifugal force, m = mass, v = speed, 2 / r = radius of rotation

The present invention as described above can be a reference for determining the cause of the medical abnormal symptoms caused by problems in the fluidity of the blood can be easily measured in vitro the fluidity of the blood collected from the human body, his blood flowability You can expect a variety of preventive activities by acquiring and utilizing the information necessary to keep your health constant or to maintain your health or to alleviate the symptoms of the disease. It can also be provided as information needed for more advanced medical research.

In the present invention, the method for efficiently realizing artificial centrifugal force generation and measurement of blood flow using the force will be described in detail.

The present invention is a small microcomputer unit 220, DC motor unit 242, the rotating unit 240, the operation panel unit 210, artificial micropaths 112, 113, 114, 115, 116, 117, 118 flat glass plate (110), the blood collected by It is applied to the center 120 of the micro-pass (112, 113, 114, 115, 116, 117, 118) formed in 110 to cover the glass lid, and starts the rotation of the rotating plate 240 by the method selected by the operation panel 210. After completion of the rotation, it is characterized by simply determining whether the blood has passed through the artificial fine passages 112, 113, 114, 115, 116, 117, 118, the flow of the blood.

Artificial fine passages 112, 113, 114, 115, 116, 117, 118 formed on the plate glass plate 110 forms a circular diameter of 15 mm on the glass plate 110 of the size described above and forms five compartments 121 therein. The intervals of the micropaths 112, 113, 114, 115, 116, 117, and 118 for each compartment are: A compartment 114, 30 micrometers, B compartment 115, 50 micrometers, C compartment 116, 100 micrometers, D compartment 117, 150 micrometers, and E compartment. (118) It is spaced at 200 micrometer intervals, and micropaths (112, 113, 114, 115, 116, 117, 118) have three stages, and 30 micrometers (112) and 50 micrometers (113) in a circular (111) diameter of 15 mm in both positions of the glass plate. Fine passages 112, 113, 114, 115, 116, 117, and 118 with the interval of) are formed one by one each. When the glass plate 110 is rotated to have a circular spatial structure formed so that blood does not flow out of the glass plate 110.

The small microcomputer unit 220 uses a small microcomputer capable of electrically mounting software developed independently, and the small microcomputer unit 220 starts and stops the rotation of the DC motor 242 and reverses the normal rotation. It automatically detects and adjusts the software and automatically controls the rotation and stop for a fixed time.

While the small microcomputer unit 220 automatically rotates and stops the DC motor 242, and abnormality occurs in the small microcomputer unit 220 or an abnormality occurs in the program while monitoring, the normal program is executed. In difficult electrical situations, the automatic reset function built into the small microcomputer unit 220 is operated, and programming for safety such as stopping the rotation is built to promote safety of operation.

On the other hand, the six types of rotations are based on the principle of applying centrifugal force to the red blood cells instantaneously or continuously for a predetermined period of time. Therefore, it is supposed to select one of six types of rotation.

When the rotation type is described in detail, the rotation is started through the push switch 213, so that it can be selected as a short centrifugal force generating rotation mode of about 30 seconds and a long time centrifugal force generating rotation mode of about 1 minute, and the most powerful of all rotations. When the rotational strength is 100%, the power supply 260 of the DC motor 242 is DC12V, and the rotation speed is 5000 rpm.

Based on the above conditions, the magnitude of the six centrifugal forces and the rotational method are as follows.

In the first rotation method, the strongest rotational strength was started at 30% rotational strength based on 100%, up to 40%, 65%, and 80% rotational strength, and the forward and reverse rotation was repeated while increasing the rotational strength in four steps. Centrifugal force was applied to the blood cells.

In the second rotation method, centrifugal force is applied to the blood cells by repeating the normal and reverse rotations, increasing the rotational intensity by four stages starting from 90% rotational strength to 25% rotational strength, 70% rotational strength, and 50% rotational strength. To be added.

In the third rotation method, centrifugal force is applied to the blood cells by repeating the normal and reverse rotation, increasing the rotational intensity by four stages starting from 20% rotational strength, 80% rotational strength, 55% rotational strength, and 45% rotational strength. Let this be added.

In the fourth rotation method, centrifugal force is applied to blood cells while the rotational direction is repeated while increasing the rotational intensity by four stages starting from 30% rotational strength, 70% rotational strength, 60% rotational strength, and 80% rotational strength. Let this be added.

In the fifth rotation method, centrifugal force is applied to the blood cells by repeating the forward and reverse rotation, increasing the rotational intensity by four stages starting from 75% rotational strength, 55% rotational strength, 45% rotational strength, and 65% rotational strength. Let this be added.

The sixth rotation method starts with 50% rotational strength, increases the rotational strength by four stages from 85% rotational strength, 40% rotational strength, and 55% rotational strength as the basis of the first stage, and repeats the normal and reverse rotations as above. Allow centrifugal force to be applied to the cells.

The rotating part 240 has a structure for accommodating the flat glass plate in the rotating part 240 made of plastic, and the cover and the rotating part 240 to prevent the flat glass plate 110 from popping out during high-speed rotation are safe when the rotating part 240 rotates. It is desirable to install a safety cap 244 for.

The small microcomputer controller 220 is composed of a microcomputer, an oscillator, other peripheral parts, and a power supply 260. When the rotation mode is selected and the pushbutton 213 is pressed, a signal is applied to the DC motor 242 to start operation. . In addition, the electronic sound and the LED lamp 250 are used to indicate whether or not to start.

The start and stop buttons of the operation are used by the push switch 213, and the display of the remaining revolution number is numerically displayed using the FND 251 indicator.

After selecting one of the six types displayed on the front operation panel 210 using the push switch 213 installed, and pressing the push switch 213, the small microcomputer unit 220 rotates according to the selected mode. After calculating the numerical value, start the rotation. At this time, the selected rotation mode is indicated by the LED lamp 250 and the start and end of the rotation is notified to the operator by electronic sound.

1 is a block diagram of a centrifugal force generating device according to the spirit of the present invention

2 is a cross-sectional view and a perspective view of a centrifugal force generating device according to the spirit of the present invention

3 is a cross-sectional view and a perspective view of the centrifugal force generating device and the rotating plate according to the present invention

Figure 4 is a view of a glass plate fine passage that rotates in the rotating plate according to the present invention

Claims (7)

Artificial fine passages 112, 113, 114, 115, 116, 117 and 118 formed on the glass plate 110; The first rotation method: centrifugal force is applied to the blood cells by repeating the normal and reverse rotations starting from the 30% rotational strength based on 100% and increasing the rotational strength to the rotational strengths of 40%, 65% and 80%. A DC motor 242 controlled rotation method controlled by a small microcomputer 220 to be applied; Second rotation method: Small microcomputer applying centrifugal force to blood cells while repeating the forward and reverse rotations starting from 90% rotational strength to 25% rotational strength, 70% rotational strength and 50% rotational strength based on the first rotational method. A DC motor 242 controlled rotation method controlled by the unit 220; Third rotation method: A small microcomputer that applies centrifugal force to blood cells while repeating forward and reverse rotations starting from 20% rotational strength, increasing to 80% rotational strength, 55% rotational strength, and 45% rotational strength based on the first rotational method. A DC motor 242 controlled rotation method controlled by the unit 220; Fourth Spinning Method: A small microcomputer that applies centrifugal force to blood cells by repeating the normal and reverse rotations starting at 30% rotational strength and increasing to 70% rotational strength, 60% rotational strength, and 80% rotational strength based on the first rotational method. A DC motor 242 controlled rotation method controlled by the unit 220; Fifth rotation method: Compact microcomputer applying centrifugal force to blood cells while repeating forward and reverse rotations starting from 75% rotational strength, increasing to 55% rotational strength, 45% rotational strength, and 65% rotational rotation based on the first rotational method. A DC motor 242 controlled rotation method controlled by the unit 220; Sixth rotation method: Centrifugal force is applied to the blood cells by repeating the normal and reverse rotation as described above, starting at 50% rotational strength and increasing to 85% rotational strength, 40% rotational strength and 55% rotational strength based on the first rotational method. A DC motor 242 controlled rotation method controlled by the small microcomputer unit 220; The first to sixth rotation methods described above include a small microcomputer unit 220 for generating the centrifugal force by forward and reverse rotation of the 12V DC motor 242 controlled by the small microcomputer unit 220. Extracorporeal blood flow measurement apparatus using centrifugal force, characterized in that consisting of. The method of claim 1, Extracorporeal blood flow measurement apparatus using centrifugal force, characterized in that the artificial fine passage (112, 113, 114, 115, 116, 117, 118) is formed on the glass plate 110, one each in the center, left and right. The method of claim 1,  The spacing of the artificial paths 112, 113, 114, 115, 116, 117 and 118 is 30 micrometers for Zone A (114), 50 micrometers for Zone B (115), 100 micrometers for Zone C (116), and 150 micrometers for Zone D (117). Zone 118 is an extracorporeal blood flow measurement instrument using centrifugal force, characterized in that a special microcapillary passage of 200 micrometers formed on the glass plate 110. The method of claim 1, Extracorporeal blood flow measurement apparatus using a centrifugal force characterized in that it comprises a cover 244 and the rotating part 240 for feeding the glass plate 110. delete delete delete

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