KR101534182B1 - Dental implant capable of measuring blood glucose - Google Patents

Abstract

In the present invention, disclosed is a dental implant capable of measuring blood sugar, comprising a fixture implanted in an alveolar bone; an abutment which is connected to the fixture attached with an artificial crown and accordingly supports the artificial crown; and a blood sugar sensor unit which is in contact with gingival sulcus as installed on the abutment, and and measures blood sugar of liquid from gingival sulcus liquid flowed from the gingival sulcus.

Description

[0001] DENTAL IMPLANT CAPABLE OF MEASURING BLOOD GLUCOSE [0002]

The present invention relates to a dental implant capable of measuring blood glucose. More particularly, the present invention relates to a dental implant capable of measuring blood glucose level from a gingival fissure discharged from a gingival fissure in the oral cavity, Implants.

In general, diabetes is a chronic disease in which glucose is excreted through the urine and insufficiency of insulin secreted from the pancreas of the body or abnormal function of the secreted insulin makes the body unable to absorb sugar. do.

And, in the diabetic state, the concentration of blood glucose, that is, blood glucose, becomes high, and various complications may occur in various parts of the body.

Recently, diabetes is continuously increasing in Korea due to economic development and lifestyle changes. Approximately 2 million people, approximately 5.1% of the population, are estimated to be diabetic.

Here, diabetes is divided into two major types, insulin-dependent diabetes, usually occurring in childhood or before the age of 30. This is a problem due to abnormal secretion of insulin, which requires the supply of insulin externally.

The second is non-insulin dependent diabetes mellitus, which usually occurs after the age of 40 and is 80-90% of all diabetic patients. In the case of non-insulin dependent diabetes mellitus, it is strongly associated with obesity and requires insulin supply .

On the other hand, diabetes patients can be treated by dietary therapy to regulate food intake and aerobic exercise to reduce blood sugar by saving insulin in the body.

 Alternatively, there is a insulin supply method that controls the blood glucose level through forced insulin supply. Here, the measured blood glucose level is 70-130 mg / dl in the fasting state, hypoglycemia in the case of below 70 mg / dl, If it is above 200 mg / dl, the body will see the sugar excreted through the urine. If it is over 400 mg / dl, it will need insulin supply and supply insulin.

Here, the insulin supply to the diabetic patient can be judged through the measurement of blood glucose. Normally, blood glucose is measured through blood sampling.

That is, a blood glucose measurement device capable of measuring blood glucose through blood collection is used to measure the blood glucose of the blood collected from the measurement subject.

However, conventionally, in the method of measuring blood glucose through blood collection, when a blood glucose is measured, a needle must be inserted into the body every time the blood is drawn, so that a diabetic patient feels pain, and there is a risk of infection at a blood collection site. There is a problem that blood glucose measurement is inconvenient as a whole.

Korea Registered Patent Registration No: 10-1288400 (Registered Date: July 16, 2013)

Therefore, the technical problem to be solved by the present invention is to measure blood glucose from the gingival crevicular fluid discharged from the gingival fissures in the oral cavity without a process of blood collection from the diabetic patient, thereby reducing the pain of the diabetic patient and preventing the risk of infection And to provide a dental implant capable of measuring blood glucose with improved convenience of blood glucose measurement.

According to an aspect of the present invention, there is provided a fixture, which is placed in an alveolar bone; An abutment coupled to the fixture and having an artificial crown for supporting the artificial crown; And a blood glucose sensor unit installed in the abutment and contacting the gingival fissure in the mouth to measure blood glucose from the gingival fissure outflowed from the gingival fissure.

The abutment may further include: a fixture coupling unit coupled to the fixture; And an upper extending portion extending upward from the fixture coupling portion.

The upper extension portion may be formed with an inclined portion whose diameter increases from the lower side toward the upper side.

The blood glucose sensor unit may be coupled to the upper extension.

The blood glucose sensor unit may be installed around the outer periphery of the upper extension.

In addition, the abutment may further include a hollow portion formed therein, and a power supply unit installed in the hollow portion to supply power to the blood glucose sensor unit.

The abutment may include a screw portion detachably attached to the fixture for charging or replacing the power supply unit.

The blood glucose sensor unit may further include a data receiver unit for receiving the measured data from the blood glucose sensor unit.

The control unit may further include a control unit installed in the abutment and connected to the blood glucose sensor unit, for controlling the data measured from the blood glucose sensor unit to be transmitted to the data receiver unit.

The data receiver unit may be provided in a mobile communication terminal.

The control unit may include a communication module for transmitting the data to the mobile communication terminal.

Embodiments of the present invention can measure blood sugar from the gingival crevicular fluid discharged from a gingival fissure in the oral cavity without a process of blood collection from a diabetic patient, thereby reducing the pain of the diabetic patient, preventing the risk of infection, The convenience of the apparatus can be improved.

1 is a schematic structural view of a dental implant capable of measuring blood glucose according to an embodiment of the present invention.
FIG. 2 is a view showing the attachment and detachment of an abutment to a fixture in a dental implant capable of measuring blood glucose according to an embodiment of the present invention. FIG.
3 is a cross-sectional view of an abutment in a dental implant capable of measuring blood glucose according to an embodiment of the present invention.
4 is a view illustrating a gingival fissure in a dental implant capable of measuring blood glucose according to an embodiment of the present invention.
FIG. 5 is a graph showing an experimental result of a related paper in a dental implant capable of measuring blood glucose according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

The terms " one side " and " other side " used in this specification may mean a specified side, or do not mean a specified side, but any side of a plurality of sides may be referred to as one side, And the other side is referred to as the other side.

The term " bond " or " connection ", as used herein, is intended to encompass not only the case where one member directly joins or connects another member, And the like.

FIG. 1 is a schematic structural view of a dental implant capable of measuring blood glucose according to an embodiment of the present invention. FIG. 2 is a schematic view of a dental implant capable of measuring blood glucose according to an embodiment of the present invention. FIG. 3 is a cross-sectional view of an abutment in a dental implant capable of measuring blood glucose according to an embodiment of the present invention, and FIG. 4 is a cross- FIG. 5 is a graph showing an experimental result of a related paper in a dental implant capable of measuring blood glucose according to an embodiment of the present invention. FIG.

Referring to FIG. 1, a dental implant 100 capable of measuring blood glucose according to this embodiment includes a fixture 200 placed in an alveolar bone 930, a fixture 200 coupled to a fixture 200, An abutment 300 which is mounted on the abutment 300 and which is in contact with the oral gingival fins 920 and which is attached to the gingival fins 920 And a blood glucose sensor unit 400 for measuring blood glucose from the released gingival crevicular fluid.

As described above, conventionally, in the method of measuring blood glucose through blood collection, since a diabetic patient feels pain due to needles inserted into the body during blood glucose measurement and there is a risk of infection at a blood collection site during blood collection, The implantable dental implant 100 is configured to measure blood glucose from the gingival crevice fluid discharged from the gingival fissure 920 in the oral cavity without drawing blood.

4, the gingival fissure 920 refers to a small gap formed in the interface between the tooth 940 and the gum 910. The normal depth of the gingival fissure 920 is about 3 mm, Numerous germs are multiplying.

The germs propagating in the gap of the gingival fissure 920 attack the gum 910 supporting the tooth 940, the alveolar bone 930 corresponding to the gum bone, and the periodontal ligament (not shown).

However, the exudate flowing out through the epithelium of the gingival fissure 920 serves to protect the gum 910 from the germs. The exudate discharged through the epithelium of the gingival fissure 920 corresponds to the gingival fissure.

In this paper, we propose a non-invasive monitoring of gingival crevicular fluid for estimation of blood glucose levels and a thesis by Dr. Masaki Yamazuchi et al. In Medical & Biological Engineering & Computing 2004, Vol. 2 (refer to 'Error Grid Analysis of Noninvasive Glucose Monitoring Via Gingival Crevicular Fluid' published in 'IEEE TRANSACTIONS ON BIOMEDICAL ENGINEERING, VOL. 52, NO. 10, OCTOBER 2005' by Masaki.Yamaguchi et al. , It can be seen that there is a close correlation between the blood glucose concentration and the gingival crevicular fluid according to the experimental results.

Refer to Article 3 ('Evaluation of Time-Course Changes in Gingival Crevicular Fluid Glucose Levels in Diabetics' published in 'Biomedical Microdevices 7: 1, 53-58, 2005' by Masaki.Yamaguchi et al. , There is also a close correlation between blood sugar concentration and gingival crevicular fluid.

In other words, referring to FIG. 5, which is a graph of the result of the publication in the thesis 3, it can be seen that glucose changes in blood glucose (BG) and gingival thrum fluid (GCF) are similar to each other over time, But it is possible to measure blood glucose at any time and continuously through the gingival crevicular fluid.

The relationship between blood glucose concentration and gingival perfusion fluid in diabetic patients is similar to that between normal and healthy subject's blood glucose concentration and gingival perfusion fluid, and between blood glucose concentration and gingival perfusion fluid It has been proved that the influence of disease on the relationship is small, so that it is possible to measure blood glucose level in the gingival fissure even in normal people as well as diabetics.

Therefore, the dental implant 100 capable of measuring blood glucose according to an embodiment of the present invention can measure blood sugar through the gingival perfusate, and will be described in detail below.

Generally, a large number of teeth 940 are arranged in the gum 910. Tooth (940) is a primary means of digesting food by crushing it into the stomach, which can vary from person to person, but usually comes in about 28 pieces.

If one of the teeth 940 is lost, the lost tooth 940 will not only deteriorate the sensation of aesthetics but will be inconvenient for chewing the food. In order to compensate for loss of the tooth 940, Normal prostheses, dentures, or implants are used.

Here, in the case of a normal prosthesis or a denture, after the passage of time, the surrounding tooth 940 and the bone are damaged, but the implant does not injure the tissue of the surrounding tooth 940, Therefore, there is an advantage that it can be used semi-permanently.

Generally, implants are replacements that restore when human tissue is lost, but dental implants are artificial tooth implants. A replacement root that can replace the lost root (root) is planted in the alveolar bone 930 where the tooth is removed, and then the artificial tooth is fixed to restore the function of the tooth.

In addition, implants improve the function of dentures in patients with single missing teeth restoration, as well as in partial and total toothless patients, and improve the aesthetic aspects of dental prosthesis restoration. Furthermore, it helps to stabilize the dentition as well as to disperse the excessive stress applied to the surrounding supporting bone tissue.

The dental implant procedure is a surgical procedure for placing the fixture 200 on the gum bone, that is, the alveolar bone 930, and the abutment 300 by combining the inserted fixture 200 with the abutment 300 300 to a prosthetic crown (800).

Here, the abutment 300 is provided so that the artificial crown 800 can be supported. The fixture 200 may be made of titanium (Ti, Titanium) or titanium alloy which does not have a rejection reaction to the human body.

The procedure of such an implant may be various, and one embodiment thereof will be briefly described as follows.

First, a drilling and tapping process is performed on the alveolar bone 930 to form a groove conforming to the dimension of the fixture 200, and a mount (not shown) is fastened to the upper portion of the fixture 200 . Then, the fixture 200 and the mount (not shown) are placed in the alveolar bone 930 using a surgical handpiece (not shown), and then the mount (not shown) is removed from the fixture 200, 930, the fixture 200 is placed.

The first operation is completed by fastening a cover screw (not shown) to the top of the fixture 200 to seal the fixture 200.

The cover screw (not shown) prevents intrusion of bacteria and foreign substances present in the oral cavity into the fixture 200 while waiting for the fusion of the fixture 200. The duration of osseointegration differs somewhat depending on the patient's bone quality and implantation position, but generally, 3 to 6 months are avail- able.

Next, the gum 910 is opened through a secondary operation to expose the lid screw (not shown), the degree of fusion of the fixture 200 is checked, and the cover screw (not shown) is removed.

After the tooth model is manufactured and the artificial crown 800 is pierced, the abutment 300 is fastened on the fixture 200 and the artificial crown 800 is fixed on the abutment 300, .

The abutment 300 of the dental implant 100 capable of measuring blood glucose according to an embodiment of the present invention includes a fixture coupling unit 310 coupled to the fixture 200, And an upper extension 320 formed to extend upward from the upper portion 310 (see FIG. 2).

1 and 2, the fixture coupler 310 may be inserted into the fixture 200 and may be coupled to the fixture 200 in a variety of ways.

The upper extending portion 320 extends upward from the fixture coupling portion 310 and the upper extending portion 320 is formed with an inclined portion 321 whose diameter increases from the lower side toward the upper side .

1, the blood glucose sensor unit 400 measures a blood glucose level from a gingival fountain solution flowing out of the gingival fins 920. The blood glucose sensor unit 400 may be provided in the upper extension forming part 320, .

That is, when the blood glucose sensor unit 400 is installed along the outer circumference of the inclined portion 321 of the upper extension portion 320 (see FIG. 2), when the abutment 300 is coupled to the fixture 200 The blood glucose sensor unit 400 comes into contact with the gingival fins 920 in the oral cavity and the gingival fissure liquid flows out from the gingival fins 920. As a result, To measure blood sugar through the gingival crevicular fluid.

On the other hand, in order to drive the blood glucose sensor unit 400, the blood glucose sensor unit 400 must be supplied with power. To this end, referring to FIG. 3, a power supply unit 500 may be installed in the abutment 300.

That is, the power supply unit 500 is installed in the hollow 330 formed in the abutment 300 and supplies power to the blood glucose sensor unit 400 through wired or wireless communication.

The power supply unit 500 may be configured to be chargeable or replaceable. Here, the abutment 300 may be detachably attached to the fixture 200 for charging or replacing the power supply unit 500.

2 and 3, the abutment 300 may include a screw portion 340 which rotates the screw portion 340 to move the abutment 300 from the fixture 200 The power supply unit 500 is charged or replaced, and then the abutment 300 is coupled to the fixture 200 again.

Here, the abutment 300 does not necessarily include the screw portion 340, but a screw or bolt is inserted and tightened through the hollow 330 formed in the abutment 300 so that the abutment 300 And may be provided to be coupled to the fixture 200.

In this case, the end of the fixture coupling unit 310 may be provided in a hexagonal shape and may be coupled to the fixture 200.

The end of the fixture coupler 310 is not formed in a screw shape but a plurality of shape memory alloy blades (not shown) extending from an end of the fixture coupler 310 are provided to be coupled to the fixture 200 .

That is, the blades (not shown) of the shape memory alloy are gathered toward the end of the fixture coupling portion 310 at a predetermined temperature, and inserted into the fixture 200 in this state. When the predetermined temperature is reached, the wings (not shown) of the shape memory alloy are unfolded and contact the fixture 200 to press the fixture 200, whereby the abutment 300 is moved to the fixture 200 ). ≪ / RTI >

On the other hand, the data measured from the blood glucose sensor unit 400 can be transmitted to a data receiver unit 700 which can be recognized by a diabetic patient or a doctor, so that a diabetic patient, a doctor, or the like can easily grasp the blood sugar.

Here, the data receiver unit 700 may be a mobile communication terminal including a mobile phone, a smart phone, or various computers equipped with communication means.

That is, a diabetic patient, a doctor, or the like can continuously check the blood glucose level from the gingival fissure fluid discharged from the gingival fins 920 in the oral cavity through a mobile communication terminal, for example, a smart phone, The blood glucose is measured to reduce the pain of the diabetic patient, to prevent the risk of infection, and to improve the convenience of blood glucose measurement.

The control unit 600 controls the blood glucose sensor 400 to transmit the measured blood glucose data to the data receiver unit 700. To this end, the control unit 600 may be installed in the hollow 330 formed in the abutment 300, and may be connected to the blood glucose sensor unit 400 by wire or wireless.

Here, the control unit 600 may include a communication module (not shown) for transmitting data to the mobile communication terminal. That is, the blood glucose measurement data measured from the blood glucose sensor unit 400 may be provided to be transmitted to the data receiver unit 700 using RF communication or Bluetooth communication, wherein the control unit 600 performs the RF communication Or Bluetooth communication.

Hereinafter, in the dental implant 100 capable of measuring blood glucose according to an embodiment of the present invention, blood glucose can be continuously measured from the gingival fissure outflowed from the gingival fissure 920 in the oral cavity, The operation and effect will be described.

Referring to FIG. 1, a blood glucose sensor unit 400 capable of measuring blood glucose from a gingival perfusate in the oral cavity is installed in the abutment 300.

Here, when the abutment 300 is coupled to the fixture 200 placed in the alveolar bone 930, the blood glucose sensor unit 400 installed on the abutment 300 contacts the gingival fins 920, The sensor unit 400 measures blood glucose through the gingival fins 920 flowing out of the gingival fenestration.

The hollow 330 may be formed in the abutment 300. The hollow 330 may include a power supply unit 500 for supplying power to the blood glucose sensor unit 400, And a control unit 600 for transmitting the data to the receiver unit 700 may be provided. Here, the control unit 600 may include a communication module (not shown).

That is, when the blood glucose sensor unit 400 receives the power from the power supply unit 500 and measures blood glucose from the gingival crevice fluid, the control unit 600 transmits data measured from the blood glucose sensor unit 400 to a communication module The diabetes patient or the doctor or the like can check the blood glucose level through the data receiver unit 700. In addition,

As a result, blood glucose can be measured from the gingival crevicular fluid flowing from the gingival fissure 920 in the oral cavity without the process of blood collection from the diabetic patient, thereby reducing the pain of the diabetic patient, preventing the risk of infection, The convenience is improved.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: Dental implant capable of measuring blood glucose 200: Fixture
300: abutment 310: fixture coupling part
320: upper extension forming portion 321:
330: Hollow 340: Screw part
400: blood glucose sensor unit 500: power supply unit
600: control unit 700: data receiver unit
800: artificial crown 910: gums
920: Gingival fissure 930: Alveolar bone
940: Tooth

Claims (11)

A fixture placed in the alveolar bone;
An abutment coupled to the fixture and having an artificial crown for supporting the artificial crown; And
And a blood glucose sensor unit installed in the abutment and contacting the gingival fissure in the oral cavity to measure blood glucose from the gingival fissure discharged from the gingival fissure. The method according to claim 1,
The abutment may include:
A fixture coupler coupled to the fixture; And
And an upper extension portion extending upward from the fixture coupling portion. The dental implant according to claim 1, 3. The method of claim 2,
Wherein the upper extension forming portion is formed with an inclined portion whose diameter increases toward the upper side from the lower side. 3. The method of claim 2,
Wherein the blood glucose sensor unit is coupled to the upper extension portion. 5. The method of claim 4,
Wherein the blood glucose sensor unit is installed on an outer periphery of the upper extension portion. The method according to claim 1,
Wherein the abutment further includes a hollow and a power supply unit installed in the hollow to supply power to the blood glucose sensor unit. The method according to claim 6,
Wherein the abutment includes a screw portion detachably attached to the fixture for charging or replacing the power supply unit. The method according to claim 1,
And a data receiver unit for receiving the measured data from the blood glucose sensor unit. 9. The method of claim 8,
Further comprising a control unit installed in the abutment and connected to the blood glucose sensor unit and controlling the data measured from the blood glucose sensor unit to be transmitted to the data receiver unit Implant. 10. The method of claim 9,
Wherein the data receiver unit is provided as a mobile communication terminal. 11. The method of claim 10,
Wherein the control unit includes a communication module for transmitting the data to the mobile communication terminal.

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