KR101190889B1 - Diagnosis device for operation range of cervical vertebrae joint - Google Patents

Abstract

PURPOSE: A diagnosis device for examining an operation range of the cervical vertebral joint is provided to perform a precise diagnosis by minimizing an error in a manual muscle test. CONSTITUTION: A cranium rotation support(100) is a cylindrical member having elasticity. A rotation measuring plate(120) includes a rotation measuring plate controlling unit(130) to vertically move the rotation measuring unit. Other end of a rotation support supporting shaft(110) is combined with a cranium right and left leaning device(200). A cranium horizontal position control device(400) is combined with a support frame(530) and controls a horizontal position using a horizontal position control unit(410).

Description

Cervical joint movement range inspection diagnostic device {DIAGNOSIS DEVICE FOR OPERATION RANGE OF CERVICAL VERTEBRAE JOINT}

The present invention relates to a portable cervical joint movable range test diagnostic device and to an apparatus for objectively inspecting the movable range of the cervical joint to be used for diagnosis of cervical joint subluxation.

The spine is made up of 33 bones, which play an important role in supporting and moving our bodies and protecting our spinal cord. The cervical spine is composed of the seven vertebrae at the top of the spine and is C-shaped, making it much more mobile than other parts of the spine, the thoracic or lumbar spine. Unlike other parts of the spine, the cervical spine is connected to the brain, and when a structural disorder of the cervical spine occurs, it may cause a movement disorder that reaches the whole body. The first cervical spine, the second cervical spine, the seventh cervical spine is called. The two vertebral bodies at the top of the cervical spine are called atlas (C1) and axis (Axis, C2), and the atlas (the Atlas) supports the weight of the head. Named after Atlas.

Atlases and shafts are designed to function primarily in the head. At the fore, the front is thick and the back has a thin ring shape. The axis is just below the atrium and has a node called a dendrite that looks like a fingertip in the hole of the atrium. This serves as an axis that can turn the head to the side. Between these two bones is a special ligament, such as a cervical ratator, which helps the two bones rotate and rotate the head.

    The spinal cavity in the cervical spine is passed through the spinal cord and cervical nerves and is transmitted from the brain to the limbs. Nerve stimulation and excitement are transmitted. This function leads to the homeostasis of the body to keep the living body healthy. However, it is known that the following diseases may occur if structural disorders of the cervical spine occur and abnormalities occur in the neurostimulatory transmission process of the cervical spine.

One . Cervical spine 1: headache, nervousness, insomnia, cold, high blood pressure, chronic fatigue

2 . Cervical spine 2: optic nerve, eye disease, ear disease, migraine, dizziness

3. Cervical spine 3: teeth, neuralgia, acne, back pain

4 . Cervical spine 4: nose, mouth, lips, migraine, hearing loss

5. Cervical spine 5: vocal cords, pharyngitis, hoarseness

6. Cervical spine 6: Root muscles, tonsillitis of the shoulder, stiff neck

7. Cervical spine 7: thyroid, shoulder pain, cold, stomach pain, upper limb disease

Various methods such as X-ray and MRI have been used in diagnosing cervical spine abnormalities, and the method of diagnosing dystrophic muscle without using a machine or a device has also been used. In 1974, Goodheart JG observed changes in the frequency of histologic findings when he touched a patient's dysfunction area and named it a therapeutic or therapeutic contact test. This is a phenomenon in which a muscle that has been examined is weakened and examined when a patient touches a malfunctioning part, and it is currently used in various fields in clinical practice. In clinical practice, it is defined as dysfunction at the site of subluxation and positive reaction on the therapeutic contact test.

In particular, to assess therapeutic contact tests, certain muscles are known that are not known to relate to any reflexes or other factors, which are called index muscles. The use of index muscles to assess therapeutic contact tests is a common approach and is often useful when screening for a variety of patient problems.

Here, look at the various muscle test of the cervical spine that is currently used in clinical practice.

Maigne test: The patient takes the seat and the examiner rotates the patient's head. Keep patient's eyes open and observe eye concussion or other related clinical symptoms

Hautant test: The patient takes the seat and extends his hand with his arms extended forward. The patient closes his eyes and the examiner rotates and rotates the patient's head. The arm may fall off due to the occurrence of related clinical symptoms

Kle Dekleyn test: The patient is lying on the supine position, placing the head outside the end of the table to maximize the extension of the cervical spine. The investigator supports the patient's head, rotates the neck and observes the occurrence of eye concussion and related clinical symptoms.

Burger Underburger test: The patient stands, closes his eyes and stretches his arms forward. Have the patient walk with his head and neck extended and rotated. Positive reactions are shaking or staggering, so the examiner should stand by the patient and avoid sudden falls

⑸ Traction Test: Reduces pain by widening the intervertebral cavity, which causes nerve root compression, and traction relaxes the muscles in the muscles by relaxing the built muscles.

Compression Test: Intervertebral stenosis, intervertebral joint compression, and muscle spasms cause increased pain. Knowing the pain of the upper limbs makes it easy to locate the neurological level of the lesion.

S Swalling Test: It is used to check the protrusion of bone, proliferation of bone, hyperemia, infection, and tumor.

⑻ Adson Test: Determination of circulation of subclavian artery

  -Hold the vein of the radial artery and abduction, extension, and rotation of the arm to catch the vein.

Turn your head to the test. If the pulse is significantly reduced or does not run at this time, it is abnormal.

George's Test: The first test before cervical spine correction. At 30 degrees of cervical spine, the vertebral artery on the opposite side is blocked. At 45 degrees rotation, both vertebral arteries are blocked. At this time, when the symptoms of dizziness, vomiting, eyeball protrusion, etc., the abnormality of the vertebral artery is suspected and correction is absolutely contraindicated.

On the other hand, when the cervical rotation test method is used, the cervical spine moving range test should be evaluated more thoroughly than the conventional formal test. First of all, there is an active test method and a passive test method. The active test method is to examine the cervical spine joint by actively rotating the head. The passive test method relaxes the muscles and lie down in a comfortable state. In this case, the examiner rotates the subject's head from side to side or up and down to identify whether the joint of the subject's cervical spine is in operation. Cervical spine joint mobility is evaluated by lateral rotation of the head, extension, and lateral flexion. If the head movement of the subject differs from side to side, it means that the range of motion of the cervical joint is limited due to subluxation of cervical spine, imbalance due to shortening or relaxation of cervical spine, pelvic problem or scapular problem. Reevaluate In addition, there should be no difference between the results of the active and passive inspection methods.

In addition, postural abnormality-induced examination method has been performed for a long time in applied neuroscopy, and it is used to identify disagreement, structural abnormality, active reflection, and other factors when it is examined in the same postural abnormality state when the subject is standing. It is a way. The specific method is relatively simple. When the examinee is standing, the postural anomaly is observed, and then the subject is exaggerated further with the supine or abdominal stomach lying down. For example, the pelvis may be tilted to one side and the head may be tilted to the opposite side. The pelvis and shoulders may be rotated in opposite directions. When the subject is lying on the examination table, the postural abnormality such as the inclination or rotation when standing is further exaggerated. The examiner manually bends the pelvis or neck of the subject lying on the examination table to exaggerate the posture when the subject is standing. To rotate your pelvis or shoulder, you can put a DeJarnette block or pillow on one side. After that, when the surface muscle test is performed again, different surface muscle test values are produced according to the postural abnormality causing state. This method is used to identify the condition of the examinee.

Current diagnostic devices for musculoskeletal disorders include diagnostic equipment such as X-rays, CT, and MRI. This diagnostic equipment can accurately diagnose the bone condition of the skeletal disease, but it is too expensive equipment that is difficult to equip the general clinic and has been problematic in that it is not effective in detecting muscle function problems.

The present invention, in response to the above problems, in examining and diagnosing cervical abnormalities, minimizes errors in diagnosis according to subjective evaluation of pain, and improves the accuracy of the diagnosis by minimizing and inspecting and minimizing surface muscles in case of cervical abnormalities. It aims to present a means to make it possible.

In particular, by replacing relatively expensive diagnostic equipment, it provides a cost-effective medical service, better in terms of effectiveness, and suggests a method for improving the reliability of test results by suggesting a general test diagnostic method. The purpose.

To this end, the present invention comprises a skull pivot support (100); and the skull left and right deflector 200; and the skull up and down deflector 300; and the skull horizontal adjustment device (400). The cranial pivot support 100 is provided with a member having a cylindrical elasticity provided as a group, presenting a cervical joint movable range test diagnostic device supported by the pivot support shaft 110, the pivot support shaft ( One end of the 110 is provided with a skull rotation measuring plate 120 having a scale for measuring the rotation of the skull, and in the center of the rotation measuring plate 120 is further added a rotation reference unit 121 which is a standing measurement standard. To present the cervical joint operating range inspection diagnostic device, including

The rotation measuring plate 120 presents a cervical joint movable range test diagnostic apparatus further comprising a rotation measuring plate upper and lower adjusting unit 130 to enable vertical adjustment of the measuring plate at the lower end thereof, and supports the rotation support. The shaft 110 presents a cervical joint movable range inspection diagnostic device which is fixedly coupled with the right and left cranial deflection device 200 through the other end thereof, and the cranial left and right deflection device 200 is capable of deflecting the cranial pivot support left and right. It is configured, provided with a cylindrical shaft, and presenting a cervical joint movable range test diagnostic device configured by having an adjustment lever 210 for the left and right deflection on its outer surface.

On the other hand, the lower surface of the cranial left and right deflector 200 presents a cervical joint movable range test diagnostic device having a bearing 240 placed inside the cranial upper and lower deflector 300, the cranial left and right deflector One end of the outer surface of the 200 further includes a left and right deflection measurement unit 230 as a reference for measuring the degree of left and right deflection, the upper and lower deflection apparatus 300 as the lower predetermined region of the left and right deflection measurement unit 230 The upper surface of the present invention provides a cervical joint movable range test diagnostic device configured by having a left and right deflection measuring plate 220 that can display the degree of left and right deflection at an angle.

In addition, the skull up and down deflector 300 is coupled to the skull left and right deflector 200 so as to be able to deflect left and right, the upper and lower deflection control unit 310 is configured to move up and down through the vertical range of the diagnostic device At the same time, the side of the vertical deflector 300 further includes a vertical deflection measurement unit 330 as a reference for measuring the degree of vertical deflection, and as a predetermined side end region of the vertical deflection measurement unit 330, the skull One side surface of the horizontal position control device 400 presents a cervical joint movable range test diagnostic device configured by having a vertical deflection measuring plate 320 capable of displaying the degree of vertical deflection at an angle.

On the other hand, the skull horizontal position adjustment device 400 is coupled to the support frame 530 so as to adjust the horizontal position up and down, the cervical joint movable range test configured to adjust the horizontal position through the horizontal position control unit 410 Presenting a diagnostic device, the cranial pivot support 100 is provided as a group, but in the center of the cervical joint movement range test diagnostic device further comprises a pivot shaft 101 to facilitate the natural left and right rotation of the skull do.

According to the present invention, by providing a generalized and objective diagnosis based on a relatively simple device, it is possible to increase the reliability according to the diagnosis to the inspector, the examinee, and the caregiver.

In particular, the conventional test method improves most of the test methods based on palpation or doctor's experience, and excludes the gravitational muscle supporting the cervical spine, thereby minimizing errors that may occur during the manual muscle test, and preferably the least accurate index muscle. By examining only the precise diagnosis can be made.

Furthermore, it is possible to inspect and diagnose through relatively inexpensive equipment, thereby enabling early treatment by eliminating the avoidance of diagnosis due to the burden of cost.

1 is a conceptual view of the cervical joint movable range test diagnostic device according to an embodiment of the present invention
Figure 2 is a plan view of the cervical joint movable range test diagnostic device according to an embodiment of the present invention
Figure 3 is a conceptual diagram of the skull rotation measuring device of the cervical joint movable range test diagnostic apparatus according to an embodiment of the present invention
Figure 4 is a state of operation of the skull horizontal positioning device of the cervical spine joint movement range test diagnostic apparatus according to an embodiment of the present invention
Figure 5 is a state diagram of the operation of the cranial left and right deflection apparatus of the cervical joint movable range test diagnostic apparatus according to an embodiment of the present invention
Figure 6 is an operating state of the skull up and down deflection apparatus of the cervical joint movable range test diagnostic apparatus according to an embodiment of the present invention

Hereinafter, with reference to the accompanying drawings will be described the invention. 1 is a conceptual view of the cervical joint movable range test diagnostic device according to an embodiment of the present invention, Figure 2 is a plan view of the cervical joint movable range test diagnostic device according to an embodiment of the present invention.

As shown, the present invention includes a skull pivot support 100; and a skull left and right deflector 200; and a skull up and down deflector 300; and a skull leveling device 400. The skull pivot support 100 is provided with a member having a cylindrical elasticity provided in a pair, is supported by the pivot support shaft 110.

On the other hand, one end of the pivot support shaft 110 is provided with a skull rotation measuring plate 120 with a scale for measuring the rotation of the skull, the center of the rotation measuring plate 120 is a measurement standard It is configured to further include a rotation reference unit 121.

In addition, the rotation measuring plate 120 is configured to further include a rotation measuring plate vertical adjustment unit 130 to enable vertical adjustment of the measuring plate at the lower end thereof.

On the other hand, the pivot support shaft 110 is fixed to the skull left and right deflector 200 through the other end thereof.

The cranial left and right deflection apparatus 200 is configured to be capable of deflecting the cranial pivot support from side to side, and is provided with a cylindrical shaft, and is provided by providing an adjustment lever 210 for left and right deflection on its outer surface.

In addition, the lower surface of the skull left and right deflecting device 200 is provided with a bearing 240 is inserted into the skull upper and lower deflecting device 300 to facilitate the left and right deflection according to the operation of the control lever.

On the other hand, one end of the outer surface of the skull left and right deflector 200 further includes a left and right deflection measurement unit 230 as a reference for measuring the degree of left and right deflection, as the lower predetermined area of the left and right deflection measurement unit 230 The upper and lower deflection apparatus 300 is configured to include a left and right deflection measurement plate 220 capable of displaying the degree of left and right deflection at an angle.

The skull up and down deflector 300 is coupled to the skull left and right deflector 200 so as to be deflectable, it is configured to be vertically deflected through the up and down deflection control unit 310.

On the other hand, the side of the vertical deflector 300 further includes a vertical deflection measurement unit 330 as a reference for measuring the degree of vertical deflection, and as a predetermined side end area of the vertical deflection measurement unit 330, the skull horizontal position One side surface of the adjusting device 400 is configured by having a vertical deflection measurement plate 320 that can display the degree of vertical deflection at an angle.

The skull level control device 400 is coupled to the support frame 530 to adjust the horizontal position up and down, but is configured to adjust the horizontal position through the horizontal position control unit 410.

On the other hand, if necessary, the support frame 530 may be coupled to the bed 500 and the like through the fastening portion 510.

Furthermore, the bed may include a bed support that can be adjusted in height as needed.

Figure 3 is a conceptual diagram of the skull tilt measurement device of the cervical joint movable range test diagnostic apparatus according to an embodiment of the present invention. As shown, the skull pivot support 100 is provided as a group, the central portion is configured to further include a pivot shaft 101 to facilitate the natural left and right rotation of the skull.

On the other hand, the skull left and right deflector 200, the skull up and down deflector 300 and the skull horizontal position control device 400, as required, of course, can be driven by electric rather than manual.

Furthermore, the rotation measuring plate 120, the left and right deflection measuring plate 220, and the up and down deflection measuring plate 320 may be provided to measure by a digital instrument as necessary.

In addition, the individual data measured by the measurement plate can be linked to a separate system for analysis by the wired or wireless transmission device.

Hereinafter, the operation principle of the present invention will be described in detail with reference to FIGS. 3 to 6. 3 is a conceptual diagram of the device for measuring the cervical rotation of the cervical joint movable range test diagnostic apparatus according to an embodiment of the present invention, Figure 4 is the horizontal adjustment of the skull of the cervical joint movable range test diagnostic apparatus according to an embodiment of the present invention Figure 5 is an operating state of the device, Figure 5 is a cervical joint movable range test according to an embodiment of the present invention is a diagram showing the operating state of the cranial left and right deflection device of the diagnostic device, Figure 6 is a cervical joint movable range test according to an embodiment of the present invention This is the operation state of the cranial upper and lower deflector of the diagnostic device.

As shown in FIG. 3, when the skull 600 is located on the skull pivot support 100, the nose tip 610 is matched to the pivot reference section 121. In such a state, when the skull located on the rotation support 100 provided to be rotatable by the rotation shaft 101 rotates left and right, the rotation angle can measure the angle displayed on the vertical line of the nose tip 610.

In this case, unlike the case of measuring the angle of rotation standing up, the rotation range of the cervical spine can be accurately determined because the rotation is performed only by the movement of the ground muscle involved only in the rotation without the support muscle supporting the skull.

In addition, since the size or the center of the skull for each person is various, the rotation measuring plate through the rotation measuring plate upper and lower control unit 130 to enable the upper and lower adjustment of the measuring plate to the lower end of the above-described rotation measuring plate 120 as necessary It is possible to match the criteria for moving to Shanghai.

On the other hand, as shown in Figure 4 skull horizontal positioning device 400 may be deflected up and down a predetermined width while fixing the skull upper and lower deflector 300 fixed. This may cause tension in the support muscles of the skull placed in the skull pivot support 100 when lying on the bed, etc. according to the body type of the test subject, so as to adjust the horizontal position of the body by deflecting a predetermined width up and down to cope with various body shapes. Will be.

On the other hand, as shown in Figure 5 through the skull left and right deflector 200 is provided with a rotatable pivot by the above-described pivot shaft 101 in a state in which the skull placed on the skull pivot support 100 is deflected from side to side By rotating the skull located on the support 100 to the left and right alternately to measure the angle displayed on the vertical line of the nose end 610. Through this, the rotational examination of the cervical spine can be performed not only in an upright position but also in a left and right rotational state, so that the root canal can be closely inspected. In addition, the degree of the left and right deflection may be measured through the above-described skull left and right deflection measurement plate.

In addition, as shown in FIG. 6, a pivot provided by the pivot shaft 101 in a state in which the skull placed on the skull pivot support 100 is vertically deflected through the skull upper and lower deflector 300 is rotated. By rotating the skull located on the support 100 to the left and right alternately to measure the angle displayed on the vertical line of the nose end 610. Through this, the rotational examination of the cervical spine can be performed not only in an upright position but also in a left and right rotational state, so that the root canal can be closely inspected. In addition, the degree of up and down deflection may be measured through the above-described skull up and down deflection measuring plate.

It is possible to comprehensively diagnose cervical spine abnormalities in various postures by measuring the degree of rotation, the degree of left and right deflection as well as the degree of diagnosis in the upper and the left and right deflected states.

Furthermore, it is possible to diagnose the entire spine through the diagnosis of the cervical spine, and based on the connectivity between the spine (Rovette reaction system), the correlation between the spine and the lumbar spine in the same direction during walking is described in applied muscle neurology. It is. This association applies to the entire spine, so the cervical spine 2 has the same motion as the lumbar spine 4 and the cervical spine 3 is the same as the lumbar spine 3. From this point, the movements of the cervical spine 4 and the lumbar spine begin to reverse, and the movement of the entire spine is reversed, from the middle spine of the spine to the 5 th and 6 th vertebrae. In clinical cases, the vertebrae of the Rhobet response system often show a relationship between primary and compensatory subluxation. If there is a primary subluxation in the lumbar spine 4 and there is a compensatory subluxation in the cervical spine 2. The association of this behavior is supported by Inman et al. They observed movement with a metal pin inserted in the spinal spine of the body. At the seventh thoracic spine, there was the least rotation, and from there it was found that the more reverse the rotation was towards the scapula and pelvis.

When walking, the legs of the stance phase move forward together to keep the stride forward. At the same time, the shoulder blades on the same side move back. At this time, the shoulder blades on the same side move backwards, and the head moves backwards with the shoulder blades, ie, in the same direction as the pelvis, to maintain the head's forward position when walking. Thus, the lumbar and lower thoracic vertebrae need to move in reverse to the upper thoracic vertebrae.

This fact explains the intervertebral dynamics and can be used to identify the problem of the entire spinal column at the cervical spine.

100: skull pivot support 110: skull pivot support shaft
120: skull rotation measuring plate 121: rotation reference unit
130: upper and lower rotation control plate
200: left and right skull deflector 210: control lever
220: left and right deflection measurement plate 230: left and right deflection measurement unit
240: bearing 300: skull up and down deflection device
310: up and down deflection control unit 320: up and down deflection measuring plate
330: vertical deflection measurement unit 400: skull horizontal positioning device
410: horizontal position control unit 530: support frame

Claims (11)

In the device for examining and diagnosing cervical spine abnormalities,
Skull rotation support (100); and the skull left and right deflector 200; and the skull up and down deflector 300; and the skull horizontal adjustment device 400, but the skull rotation support 100 is provided as a group It is provided with a member having a cylindrical elasticity, and is supported by the pivot support shaft 110, the left and right deflection measuring unit as a reference for measuring the degree of left and right deflection at one end of the outer surface of the skull left and right deflector 200 Further comprising a 230, the left and right deflection measuring unit 230 as a lower predetermined area, the upper and lower deflection measuring device 220, the left and right deflection measurement plate 220 capable of displaying the degree of left and right deflection at an angle Cervical joint movable range test diagnostic device configured by providing. In the device for examining and diagnosing cervical spine abnormalities,
Skull rotation support (100); and the skull left and right deflector 200; and the skull up and down deflector 300; and the skull horizontal adjustment device 400, but the skull rotation support 100 is provided as a group It is provided with a member having a cylindrical elasticity, and is supported by the rotation support shaft 110, the upper and lower deflection measuring unit 330 as a reference for measuring the degree of vertical deflection on the side of the vertical deflector 300 Further comprising, as a side end predetermined area of the vertical deflection measurement unit 330, by having a vertical deflection measurement plate 320 capable of displaying the degree of vertical deflection at an angle on one side end surface of the skull horizontal positioning device 400 Cervical joint movement range examination diagnostic device. 3. The method according to any one of claims 1 to 3,
One end of the rotation support support shaft 110 is provided with a skull rotation measuring plate 120 with a scale for measuring the rotation of the skull, and the rotation reference which is a standing criterion in the center of the rotation measuring plate 120 Cervical joint operation range inspection diagnostic device further comprising a portion (121). The method of claim 3, wherein
The rotation measuring plate 120 is further provided with a rotation measuring plate vertical adjustment unit 130 to enable the vertical adjustment of the measuring plate at the lower end of the cervical spine joint operating range inspection diagnostic device. 3. The method according to any one of claims 1 to 3,
The pivot support shaft 110 is the cervical joint movable range inspection diagnostic device is fixed to the left and right cranial deflection device 200 through the other end thereof. 3. The method according to any one of claims 1 to 3,
The cranial left and right deflection device 200 is configured to be capable of deflecting the cranial pivot support from side to side, and is provided with a cylindrical shaft, and the cervical joint movement is configured by providing a control lever 210 for the left and right deflection on its outer surface. Range Check Diagnostic Device. The method according to claim 6,
Cervical joint movable range test diagnostic device is provided on the bottom of the cranial left and right deflecting device 200 is provided with a bearing 240 placed inside the cranial upper and lower deflecting device 300. 3. The method according to any one of claims 1 to 3,
The cranial vertical deflection device 300 is coupled to the cranial left and right deflection device 200 so as to be able to deflect left and right, the upper and lower deflection control unit is configured to move up and down via the vertical deflection adjusting unit 310. delete 3. The method according to any one of claims 1 to 3,
The cranial horizontal level adjusting device 400 is coupled to the support frame 530 to adjust the horizontal position up and down, cervical joint movable range test diagnostic device configured to adjust the horizontal position through the horizontal position control unit 410 .
3. The method according to any one of claims 1 to 3,
The cranial pivot support 100 is provided as a group, the central portion of the cervical joint movable range test diagnostic device further comprises a pivot shaft 101 to facilitate the natural left and right rotation of the skull.

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