KR20110090670A - Database and system for postmortem examination - Google Patents

Abstract

PURPOSE: A database and system for postmortem examination are provided to reduce the social costs for proving the cause of death. CONSTITUTION: A postmortem examination system(200) comprises a dead body image information input part(210) and a cause of death determining part(220). The dead body image input part receives an image of a dead body. The cause of death determining part is operated based on a postmortem examination database(110). An examiner determines the cause of death using the dead body image information of the postmortem examination database.

Description

Corpse Optometry Database and Corpse Optometry {DATABASE AND SYSTEM FOR POSTMORTEM EXAMINATION}

The present invention relates to a cadaveric optometry database and a cadaveric optometry system, and more specifically, the sign of a corpse without a necropsy or dissecting the current survivors have a sense of rejection and requires excessive cost and time or input of excessive medical personnel A carcass optometrist database and a carcass optometry system that make it possible to accurately determine

According to the statistics of the National Statistical Office in 2008, the domestic death toll and unidentified deaths in Korea are 246,113 deaths per year, 30,475 deaths in Korea are unknown, and 4,538 deaths are unidentified in Seoul. People. As such, there are 30,475 unidentified deaths per year, more likely to include unexplained deaths.

Meanwhile, referring to the Korea Consumer Protection Agency's judicial yearbook, the number of medical litigations per year was 1124 in 2004, and the number of applications for mediation of medical disputes per year was 1093 in 2005. This shows that there are more than 10,000 medical accident disputes, and more than 100,000 are expected annually if the number of unreported cases is expected.

As the cause of death is unclear, social costs such as increased social stress, surviving psychological shock, increased litigation costs, increased distrust of law enforcement, and increased distrust in medical institutions have been incurred. It is a situation.

For example, let's look at a case of a 36-week-old woman who was 23 years old who had complained of stomach pain and had been screened and administered by an obstetrician-gynecologist who was hospitalized because of no improvement. There was no abnormality in Round around 5 am, and Hb 11.3 PLT 30.4 in blood collection around 7:20, but the situation suddenly changed around 7:35, heart sounding at 7:50, and died after heart massage around 8:25 This confirmed situation happened.

In such a case, the survivors of the deceased usually suspend the medical accidents of the medical institutions, resulting in a lawsuit. Although it is necessary to clarify the cause of dissection, the identification of the cause of dissection is not disclosed to the survivor except information disclosed by the medical provider, the dissatisfaction of the dissection, the burden of dissection, the doctor's Due to the fact that it only depends on findings, it is not actually done much.

In order to solve this problem, a cadaveric optometry database or a cadaveric optometry system capable of identifying accurate signs without dissection is required.

The present invention was created in order to meet the above-mentioned needs, and it is now possible for the survivors to have a sense of rejection and to accurately grasp the cause of death without necropsy or dissection requiring excessive cost and time or excessive medical personnel input. The purpose of the present invention is to provide a cadaveric optometry database and a cadaveric optometry system.

On the other hand, the increased number of cases of unclear causes, such as increased social stress, surviving mental shock, increased litigation costs, increased judicial distrust, increased distrust in medical institutions, etc. And another object thereof is to provide a system for cadaveric optometry.

In addition, a variety of related organizations, such as medical institutions, research institutes, judicial authorities, survivors, insurance companies, etc., help to reduce the enormous cost, time, and effort that can be caused by the misreading of dead bodies. It is another object to provide a system.

The body optometry database according to the first embodiment of the present invention for achieving the above object matches and stores the body image information of the body and the sign of the body.

In addition, the carcass image information is preferably taken by any one or more of the X-Ray, MRI, CT and ultrasound imaging apparatus, converted to the DICOM standard and stored.

On the other hand, the carcass optometry system according to a second embodiment of the present invention, the carcass image information input unit for receiving the carcass image information photographed the body; And a body sign reading unit configured to read the sign of the body through the body image information stored in the body of the body optometry having a certain degree of similarity with the received body image information, based on the body of the body optometry database.

In addition, the carcass optometry system according to a third embodiment of the present invention, the carcass image information input unit for receiving the carcass image information photographed the body; On the basis of the cadaveric optometry database, information is sent to the terminal of the cadaveric optometry reading so that the signature of the catheter is read out through the cadaveric video information stored in the cadaveric optometry database having a predetermined similarity with the received cadaveric image information. It comprises a; providing a body of the optometrist reading to provide.

The apparatus may further include a body image information standard conversion unit for converting the body image information input to the body image information input unit into the DICOM standard or converting the body image information input to the body image information input unit into the DICOM standard. .

The apparatus may further include a body image information obtaining unit for photographing a body to obtain body image information.

The cadaveric optometry database may be an external cadaveric optometrist database server or exist inside the cadaveric optometry system.

The image information having a constant similarity is the body image information having the highest similarity or the body image information having the constant similarity or more.

The apparatus may further include an identity verification unit for determining the identity of the dead body by determining the similarity of the dental image.

As described above, the cadaveric optometry database and the catheter optometry system according to the present invention, through the cadaveric optometry database that matched the body image information and the sign of the catheter and the catheter optometry system using the same, have a sense of rejection of the survivors and excessive cost It is possible to accurately identify the cause of death without necropsy or dissection, which requires excessive time and excessive medical personnel.

Furthermore, the increase in cases where the cause of death is unclear has the effect of reducing social costs such as increased social stress, emotional shock of survivors, increased litigation costs, increased distrust of law enforcement agencies, and increased distrust of medical institutions. give.

In addition, through the establishment of a cadaveric optometry database and a cadaveric optometry system, various related organizations such as medical institutions, research institutes, judicial authorities, survivors, insurance companies, etc. utilize the database and system to save enormous cost, time and effort. It has the effect of saving.

In addition, when utilizing the system of the third embodiment, it is possible to support accurate reading of the cadaver optometry reading. Therefore, unnecessary waste can be reduced through erroneous cadaver readings. Currently, a licensed medical practitioner, doctor, dentist, and oriental medical doctor are all capable of cadaveric examination, but as a non-cardiologist can't do cardiac surgery, it is simply a doctor, dentist, or oriental medical doctor. Although the probability of many readings is varied, the use of the cadaver optometry system of the third embodiment brings the effect of enabling accurate reading of the cadaver optometry reading.

In addition, when utilizing the cadaver optometry system of the third embodiment, it is also possible to receive and synthesize a plurality of cadaver optometry readings. It has the effect of making it impossible to solve the problem of cost, time and input. In such a case, of course, the reliability of reading will rise.

In addition, the autopsy or dissection of the carcass can not be without the consent of the survivors, the carcass optometry database and carcass optometry system according to the present invention can be sufficiently implemented without the consent of the survivors.

1 is a schematic diagram showing a cadaver optometry database 100 according to a first embodiment of the present invention.
2 is a schematic diagram showing a cadaveric optometry system 200 according to a second embodiment of the present invention.
3 is a schematic diagram showing a cadaveric optometry system 300 according to a third embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention.

Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiments of the present invention and do not represent all of the technical idea of the present invention, various equivalents that may be substituted for them at the time of the present application It should be understood that there may be water and variations.

Hereinafter, a carcass optometry database and a carcass optometry system according to embodiments of the present invention will be described with reference to FIGS. 1 to 3.

(First embodiment)

First, FIG. 1 is a schematic diagram showing a cadaveric optometry database 100 according to a first embodiment of the present invention.

The cadaver optometry database 100 is stored by matching the corpse image information and the sine of the corpse, and may be stored in a table format on a database server or in a table format on a storage medium or the like.

The cadaver optometry database 100 may be a single database server or storage medium, but a combination of distributed database servers or storage media located in medical institutions such as a plurality of university hospitals, general hospitals, clinics, and national or domestic research institutes. Can be.

Here, the body means the body and the body of a dead person, and the body image information means the image data photographing the body. In general, a device for photographing a corpse is X-ray, CT, MRI, ultrasound imaging apparatus, etc., it should be understood that generically medical imaging equipment that will be used or used in hospitals or clinics in the present or future.

The carcass image information, as mentioned above, is preferably captured by the medical imaging equipment, converted to the DICOM standard and stored.

When photographing a body, it is preferable to photograph the whole body so that an image diagnosis or an image pathology can be diagnosed at the time of death, and the photographed body image information is usually a whole body image. It may be a partial image of a corpse.

The cause of death may be a specific cause, including natural or accidental death, such as a large hematoma that compresses the liver more specifically.

For example, in the case of a 36-week-old woman at age 23, mentioned in the background above, one usually suspects death due to negligence in obstetrics care. However, in this case, the analysis through the cadaveric image information showed that the death was caused by a huge hematoma that compresses the right liver area, and the dissected result was able to obtain the same result.

Through the cadaveric optometry database that matches the cadaveric image information with the autographs of the carcasses, the autographs of the carcasses are now carried out without the necessity of autopsies or dissections by the survivors who have a sense of rejection and require excessive cost and time or excessive medical personnel. It becomes possible to grasp exactly.

Furthermore, the increase in cases where the cause of death is unclear has the effect of reducing social costs such as increased social stress, emotional shock of survivors, increased litigation costs, increased distrust of law enforcement agencies, and increased distrust of medical institutions. give.

In addition, through the establishment of such a cadaver optometry database, various related organizations such as medical institutions, research institutes, judicial authorities, survivors, and insurance companies can use this database to reduce enormous costs, time and effort. give.

(Second embodiment)

2 is a schematic diagram showing a cadaveric optometry system 200 according to a second embodiment of the present invention.

The cadaver optometry system 200 includes a corpse image information input unit 210 and a corpse sign reading unit 220.

Here, the body image information input unit 210 receives the body image information of the body. The body image information standard converting unit converts the body image information input to the body image information input unit 210 into the DICOM standard or converts the body image information to the DICOM standard after being input to the body image information input unit 210. May further include).

Next, the carcass sign reading unit 220, based on the carcass optometry database 110, through the carcass image information stored in the carcass optometry database 110 having a predetermined similarity with the input carcass image information. Read the carcass of the carcass.

Here, the cadaveric optometry database 110 may be provided inside the cadaveric optometry system 200, or may be connected to an external cadaveric optometrist database 110 to download or transmit related information. In the case of an external cadaver optometrist database, the cadaver optometry database 110 may be a database server or a storage medium. It can be a combination of a distributed database server or a storage medium.

The body image may further include a body image information acquisition unit for photographing the body.

In addition, the image information having a predetermined similarity may be the body image information having the highest similarity or the body image information having the predetermined similarity or more. In other words, by comparing or contrasting the input carcass image information with the carcass image information stored in the carcass optometry database 110, the carcass sign reading unit 220 shows the carcass image information having the highest similarity and the carcass image. It is also possible to output the sine of the carcass for the information, or it is also possible to output a list of the carcass image information having similarity or more than a predetermined value and the sine of the carcass for the carcass image information.

In case of death due to physical accident or direct trauma, it is possible to easily identify the cause of death through visual discontinuity.If the cause of death is due to internal injury or disease, it can be used in Computer Aided Detection. Image processing methods such as edge detection, contrast detection, wavelet transform, or dual energy subtraction, such as head, neck, thorax, abdomen, spinal cord, bones and soft tissues. The similarity of carcass image information is judged by tissues to find the cause of the expected death.

On the other hand, the carcass optometry system 200 may further comprise an identity verification unit (not shown). The identity verification unit is configured to verify identity by determining similarity of the teeth image. First, the tooth image information portion is extracted from the carcass image information, and contrast enhancement and rotation correction are performed. It is necessary to correct the rotational error when comparing the dental image information of the carcass with the dental image information already stored to confirm the identity of the carcass. Through this correction, the similarity of the image information is determined to confirm the identity.

This system for cadaveric optometry enables the current family to automatically identify the cause of death without necropsy or dissection, which requires excessive cost and time or excessive medical personnel.

Furthermore, the increase in cases where the cause of death is unclear has the effect of reducing social costs such as increased social stress, emotional shock of survivors, increased litigation costs, increased distrust of law enforcement agencies, and increased distrust of medical institutions. give.

In addition, through the establishment of a cadaveric optometrist database and a cadaveric optometry system, various related organizations such as medical institutions, research institutes, judicial authorities, survivors, insurance companies, etc. can use this database to reduce enormous costs, time and effort. It has an effect.

(Third embodiment)

3 is a schematic diagram showing a cadaveric optometry system 300 according to a third embodiment of the present invention.

The cadaver optometry system 300 includes a corpse image information input unit 310 and a corpse optometry reading unit 320.

Here, the body image information input unit 310 receives the body image information of the body. The body image information standard converting unit converting the body image information input to the body image information input unit 310 into the DICOM standard or converting the body image information to the DICOM standard after being input to the body image information input unit 310 (not shown) May further include).

The body optometrist reading providing unit 320 stores the body through the body image information stored in the body of the body optometry database 120 having a predetermined similarity with the received body image information based on the body of the body optometry 120. Information is provided to the terminal 330 of the body optometry reading to read the signature of the body.

The third embodiment, unlike the second embodiment, is a system for assisting the body optometrist's reading, instead of automatically reading the signature of the body in the carcass optometry system itself. Since the cadaver optometrist may exist remotely, the terminal 330 of the cadaver optometrist may be remote, and may take the form of connecting the carcass optometry system 300 according to the third embodiment by wire or wirelessly. have. The wired / wireless connection method can be connected to the current wired / wireless connection method as well as technologies such as WCDMA and WiBro, which are expected to be standards for future 4G communication.

More specifically, the image information having the predetermined similarity may be the body image information having the highest similarity or the body image information having the predetermined similarity or more.

In other words, the input body image information and the body image information stored in the body of the body optometry 120 compare or contrast with each other, the body image information having the highest similarity to the terminal 330 of the body optometry reading and the corresponding body It is also possible to output or transmit the sign of the carcass for the image information, or to output or transmit a list of the carcass image information having similarity or more than a predetermined value and the carcass sign for the carcass image information.

Through this, the cadaver optometrist reads the corpse's signature on the basis of the information output or transmitted from the providing unit 320 of the cadaver optometry reading along with his or her own experience or knowledge.

The algorithm for determining the similarity of the carcass image information has already been described in the second embodiment, and thus description thereof will be omitted.

Here, the cadaveric optometry database 120 may be provided inside the cadaveric optometry system 300, or may be connected to an external cadaveric optometrist database 120 to download or transmit relevant information. In the case of an external cadaver optometrist database, the cadaver optometry database 120 may be a database server or a storage medium, but may be located in a plurality of university hospitals, general hospitals, medical institutions such as clinics, national medical investigation labs It can be a combination of a distributed database server or a storage medium.

The body image may further include a body image information acquisition unit for photographing the body.

On the other hand, the carcass optometry system 200 may further comprise an identity verification unit (not shown). The identity verification unit is configured to verify identity by determining similarity of the teeth image. First, the tooth image information portion is extracted from the carcass image information, and contrast enhancement and rotation correction are performed. It is necessary to correct the rotational error when comparing the dental image information of the carcass with the dental image information already stored to confirm the identity of the carcass. Through this correction, the similarity of the image information is determined to confirm the identity.

In addition, when utilizing the system of the third embodiment, it is possible to support accurate reading of the cadaver optometry reading. Therefore, unnecessary waste can be reduced through erroneous cadaver readings.

In other words, all currently licensed medical doctors, doctors, dentists, oriental doctors are all possible to cadaveric examination. However, just as non-cardiologists can't do cardiac surgery, they do cadaver checks simply because they are doctors, dentists, and oriental doctors, but this is likely to make error-prone readings. Utilization of the cadaver optometry system of the third embodiment has the effect of enabling accurate reading of the cadaver optometry reading.

In addition, when utilizing the cadaver optometry system of the third embodiment, it is also possible to receive and synthesize a plurality of cadaver optometry readings. It has the effect of making it impossible to solve the problem of cost, time and input. In such a case, of course, the reliability of reading will rise.

Furthermore, when the system of the third embodiment is utilized, the effects of the system of the second embodiment can be exhibited in the same way.

100, 110, 120 cadaver optometry database
200, 300 Corpse Optometry System
210, 310 body image input unit
220 Carcass autograph reader 320 Carcass optometrist reading provider
330 terminal of the cadaver optometry reading

Claims (10)

A database for cadaveric optometry, in which cadaveric image information of a cadaveric body is matched with a sine of the cadaveric. The method of claim 1,
The carcass image information is photographed by any one or more of the X-Ray, MRI, CT and ultrasound imaging apparatus, converted to the DICOM standard and stored, characterized in that the database. A body image information input unit configured to receive body image information of a body shot;
A corpse optometry system comprising: a corpse sign reading unit configured to read a sine of a corpse through the cadaver image information stored in the cadaver optometry database having a predetermined similarity with the received carcass image information based on the cadaver optometry database; . A body image information input unit configured to receive body image information of a body shot;
On the basis of the cadaveric optometry database, information is sent to the terminal of the cadaveric optometry reading so that the signature of the catheter is read out through the cadaveric video information stored in the cadaveric optometry database having a predetermined similarity with the received cadaveric image information. A cadaveric optometry system comprising; providing a cadaveric optometry reading unit. The method according to claim 3 or 4,
The body image optometry system further comprising; a body image information standard conversion unit for converting the body image information input to the body image information input unit to the DICOM standard or to convert the body image information input to the body image information input unit to the DICOM standard . The method according to claim 3 or 4,
A body for optometry, further comprising; a body image information acquisition unit for photographing a body to obtain body image information. The method according to claim 3 or 4,
The cadaveric optometry database is an external cadaveric optometrist database server or the cadaveric optometry system. The method according to claim 3 or 4,
The image information having a predetermined similarity is the body image information having the highest similarity or the body image information having a predetermined similarity or more. The method according to claim 3 or 4,
Identification body to determine the identity of the body by determining the similarity of the teeth image; body for optometry further comprising. The method of claim 8,
The similarity may be determined through an edge detection, contrast detection, wavelet transform, or dual energy subtraction to determine an expected cause of death, head, neck, thorax, abdomen, spinal cord, bone ( System for cadaveric optometry, characterized in that the degree of similarity of carcass image information determined by bones, soft tissues.

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