CN213606331U - ABI detection device and blood vessel detection system - Google Patents

Abstract

The utility model discloses an ABI detection device and a blood vessel detection system, wherein, the ABI detection device is provided with a brachial artery measuring unit which is worn on the upper limb of a detection object to obtain brachial artery pressure data, and an ankle artery measuring unit which is worn on the lower limb of the detection object to obtain ankle artery pressure data; the main control module receives the brachial artery pressure data and the ankle artery pressure data to further obtain an ABI value of the detection object, solves the technical problems that an ABI detection device in the prior art is complex in ABI value detection operation process and slow in ABI value detection result issuing, and provides the ABI detection device which is simple and rapid in detection process.

Description

ABI detection device and blood vessel detection system

Technical Field

The utility model belongs to the technical field of the medical equipment technique and specifically relates to an ABI detection device and blood vessel detection system are related to.

Background

At present, due to the accelerated pace of life, the body or the past medical history, the smoking and drinking history, the long-term irregular life habits and the like of people have vascular diseases of different degrees, wherein atherosclerosis is the most common, and other sudden diseases are easily caused by the abnormal conditions such as thickening and hardening of the arterial wall, stenosis and obstruction of the vascular cavity. If the patient can strengthen self-prevention and monitoring in daily life, the speed of disease development can be greatly delayed.

The ABI (ankle brachial index) index, also called ankle brachial index, is an important parameter for blood vessel detection, and is a precondition for rapidly and conveniently obtaining the ABI value of a detected object in order to detect the health state of blood vessels in time. In the prior art, when the ABI value of the ABI detection device is detected, the operation process is complicated, the detection result is slow to issue, and the user cannot obtain the ABI value in time, so that the use experience of the user is influenced, and the health state of the blood vessel of the detected object cannot be mastered in time, and further an accident occurs.

SUMMERY OF THE UTILITY MODEL

The utility model discloses aim at solving one of the technical problem that exists among the prior art at least. Therefore, the utility model provides a simple and convenient, quick ABI detection device of detection flow. In a first aspect, an embodiment of the present invention provides an ABI detection apparatus, which includes:

the brachial artery measuring unit is worn on the upper limb of the detection object and used for acquiring brachial artery pressure data;

the ankle artery measuring unit is worn on the lower limb of the detection object and used for acquiring ankle artery pressure data;

the main control unit is used for receiving the brachial artery pressure data and the ankle artery pressure data so as to obtain the ABI value of the detected object.

According to other embodiments of the ABI detection device of the present invention, the brachial artery measurement unit and the ankle artery measurement unit are both provided with a bluetooth communication unit;

the brachial artery measuring unit transmits brachial artery pressure data to the main control unit through the data connecting line, and the ankle artery measuring unit transmits the ankle artery pressure data to the main control unit through the Bluetooth communication unit.

According to other embodiments of the present invention, an ABI detection apparatus includes: a fixed cuff and a brachial artery pressure acquisition unit;

the brachial artery pressure acquisition unit is arranged in the fixed cuff;

the fixed cuff is used for fixing the brachial artery pressure acquisition unit to the upper limb of the detection object so as to acquire brachial artery pressure data.

According to other embodiments of the ABI detection apparatus of the present invention, the brachial artery pressure obtaining unit includes a first pressure sensor, a first sub inflation unit, and a first sub deflation unit;

the output end of the main control unit is respectively connected with the input end of the first sub-inflation unit and the input end of the first sub-deflation unit and is respectively used for controlling the working states of the first sub-inflation unit and the first sub-deflation unit;

the output end of the first pressure sensor is connected with the input end of the main control unit so as to transmit the brachial artery pressure data acquired by the first pressure sensor to the main control unit.

According to other embodiments of the ABI detection apparatus of the present invention, the brachial artery pressure obtaining unit further includes a second pressure sensor;

the output end of the second pressure sensor is connected with the input end of the main control unit, and the second pressure sensor is used for acquiring the pressure data of the fixed cuff and sending the pressure data of the fixed cuff to the main control unit.

According to other embodiments of the ABI detection device of the present invention, the ankle artery measurement unit includes an ankle fixing tether and an ankle artery pressure acquisition unit;

the ankle artery pressure acquisition unit is arranged in the ankle fixing lace;

the ankle fixing tether is used for fixing the ankle arterial pressure acquisition unit to the ankle of the detection subject to acquire ankle arterial pressure data.

According to other embodiments of the ABI detection apparatus of the present invention, the ankle arterial pressure obtaining unit includes a third pressure sensor, a second sub-inflation unit and a second sub-deflation unit;

the output end of the main control unit is respectively connected with the input end of the second sub-inflation unit and the input end of the second sub-deflation unit and is respectively used for controlling the working states of the second sub-inflation unit and the second sub-deflation unit;

the third pressure sensor is used for acquiring ankle artery pressure data and transmitting the ankle artery pressure data to the main control unit.

According to other embodiments of the ABI detection apparatus of the present invention, the ankle arterial pressure acquisition unit further includes a fourth pressure sensor;

the fourth pressure sensor is used for acquiring the pressure data of the ankle fixing strap and sending the pressure data of the ankle fixing strap to the main control unit.

According to other embodiments of the ABI detection device of the present invention, the ABI detection device further comprises a display unit;

the output end of the main control unit is connected with the input end of the display unit and used for displaying the ABI value.

In a second aspect, an embodiment of the present invention further provides a blood vessel detection system, which includes a data processing device and an ABI detection device;

the ABI detection device is connected with the data processing device to send the ABI value of the detection object to the data processing device;

the data processing device feeds back the blood vessel health status of the detected object according to the received ABI value, and displays the blood vessel health status on a display unit of the ABI detection device.

According to the blood vessel detection system of other embodiments of the present invention, the data processing apparatus includes a mobile terminal APP and a cloud server; mobile terminal APP receives the ABI value to with ABI value transmission to cloud ware, the blood vessel health status is fed back to mobile terminal APP to the cloud ware according to the ABI value, mobile terminal APP shows the blood vessel health status, and with blood vessel health status feedback to ABI detection device's display element show.

According to the blood vessel detection system in other embodiments of the present invention, data information of a plurality of detection objects is stored in the cloud server, the data information includes age, height, weight, past medical history, sleep duration and living habits, and the cloud server feeds back a blood vessel health state to the mobile terminal APP according to the ABI value and the data information and according to a preset matching rule.

According to the blood vessel detection system of other embodiments of the present invention, different blood vessel health states are displayed in different colors on the display unit of the ABI detection device.

The utility model discloses ABI detection device has following beneficial effect at least:

the ABI detection device provided by the utility model is provided with a brachial artery measuring unit which is worn on the upper limb of a detection object to obtain brachial artery pressure data, and an ankle artery measuring unit which is used for obtaining the lower limb of the detection object to obtain ankle artery pressure data; the main control module receives the brachial artery pressure data and the ankle artery pressure data to further obtain an ABI value of the detection object, solves the technical problems that an ABI detection device in the prior art is complex in ABI value detection operation process and slow in ABI value detection result issuing, and provides the ABI detection device which is simple and rapid in detection process.

Drawings

Fig. 1 is a schematic diagram of an ABI detection apparatus module according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of an ABI detection device module according to another embodiment of the present invention;

fig. 3 is a schematic block diagram of a blood vessel detection system according to an embodiment of the present invention;

fig. 4 is a schematic flow chart of a blood vessel detection system according to an embodiment of the present invention.

Detailed Description

The conception and the resulting technical effects of the present invention will be described clearly and completely with reference to the following embodiments, so that the objects, features and effects of the present invention can be fully understood. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention.

Referring to fig. 1, a schematic structural diagram of an ABI detection apparatus in an embodiment of the present invention is shown. The method specifically comprises the following steps:

a brachial artery measurement unit 100 worn on an upper limb of a detection subject for acquiring brachial artery pressure data;

an ankle artery measurement unit 300 worn on a lower limb of the detection subject for acquiring ankle artery pressure data;

the main control unit 200 is configured to receive brachial artery pressure data and ankle artery pressure data to obtain an ABI value of the detected object.

The embodiment of the utility model provides an in, brachial artery pressure data includes the highest systolic pressure of brachial artery, and ankle artery pressure data includes the highest systolic pressure of ankle artery, and host system is according to receiving the highest systolic pressure of brachial artery and the highest systolic pressure back of ankle artery, according to the computational method of ABI (ankle brachial index ): the ABI value is the highest systolic pressure of the ankle artery/the highest systolic pressure of the brachial artery, and the ABI value of the test subject is obtained. In this embodiment, two relatively independent measurement assemblies are provided: brachial artery measuring unit 100 and ankle artery measuring unit 300, convenience of customers can make things convenient for quick independent operation the utility model provides an ABI detection device's installation is used, rethread main control unit 200 acquires the highest systolic pressure of brachial artery that brachial artery measuring unit 100 detected and obtains and the highest systolic pressure of ankle artery that ankle artery measuring unit 300 detected and obtain respectively, and then reachs the ABI value of detection object fast, it is loaded down with trivial details to have solved among the prior art ABI detection device and has detected ABI value operation process, and the ABI value testing result issue slow technical problem, it is simple and convenient to provide a detection flow, quick ABI detection device.

In some embodiments, the brachial artery measurement unit 100 and the ankle artery measurement unit 300 are each provided with a bluetooth communication unit, and the two bluetooth communication units are in matching communication with each other. In this embodiment, the brachial artery measurement unit 100 transmits the brachial artery pressure data to the main control unit 200 through the data connection line, and the ankle artery measurement unit 300 transmits the ankle artery pressure data to the main control unit 200 through the bluetooth communication unit, that is, the main control unit 200 and the brachial artery measurement unit 100 are installed in the same housing, the ankle artery measurement unit 300 is independently installed in another housing, and the ankle artery measurement unit 300 obtains the ankle artery pressure data of the detection object and transmits the ankle artery pressure data to the main control unit 200 through the bluetooth communication unit. Realize that ankle artery measuring unit 300 and main control unit 200 carry out data communication with wireless transmission's mode through being provided with the bluetooth communication unit, not only can make the user wear the convenience when using, avoided moreover to carry out wired connection on two relatively independent equipment and leaded to the connecting wire fracture easily, lead to ABI detection device unable work.

Referring to fig. 2, in some embodiments, brachial artery measurement unit 100 includes: a fixed cuff and a brachial artery pressure acquisition unit; the brachial artery pressure acquisition unit is arranged in the fixed cuff, and the fixed cuff is used for fixing the brachial artery pressure acquisition unit at the artery of the detection object so as to acquire brachial artery pressure data. In some embodiments, the brachial artery pressure acquisition unit includes a first pressure sensor, a first sub inflation unit, and a first sub deflation unit;

the output end of the main control unit 200 is connected to the input end of the first sub-inflation unit and the input end of the first sub-deflation unit respectively, and is used for controlling the working states of the first sub-inflation unit and the first sub-deflation unit respectively; when obtaining the brachial artery pressure data of the detected object, the main control unit 200 outputs a control signal to control the first sub-inflation unit to inflate, and in the inflation process, the first pressure sensor transmits the obtained brachial artery pressure data to the main control unit 200, at this time, the brachial artery pressure data obtained in the inflation process is the pulse wave data of the detected object, and the heart rate value of the detected object can be obtained according to the pulse wave data. When the first pressure sensor is inflated to a certain degree, the first pressure sensor cannot acquire pulse wave data of the detected object (namely, the pulse wave data inflated to the brachial artery is blocked), at this time, the main control unit 200 outputs a control signal to control the first sub-deflation unit to deflate, the first pressure data signal obtained by the first pressure sensor after deflation is the highest systolic pressure of the brachial artery, and the obtained highest systolic pressure of the brachial artery is sent to the main control unit 200. In this embodiment, the first sub-inflation unit includes an inflation pump and an air bag, the first sub-deflation unit includes an air valve, the air pump receives control of the main control unit 200 to inflate the air bag, when the first sensor cannot detect brachial artery pressure data, the main control unit 200 controls the air valve to open to deflate the air bag, and when the first sensor deflates, the brachial artery pressure data acquired at the first time is the highest systolic pressure of the brachial artery.

Additionally, in some embodiments, the brachial artery pressure acquisition unit further comprises a second pressure sensor; the output end of the second pressure sensor is connected with the input end of the main control unit 200, and the second pressure sensor is used for acquiring the pressure data of the fixed cuff and sending the pressure data of the fixed cuff to the main control unit 200. In this embodiment, the second pressure sensor is configured to obtain pressure data applied to the detection object by the fixed cuff, and transmit the pressure data to the main control unit 200, a safe first preset pressure threshold is set in the main control unit 200, and when the pressure data obtained by the second pressure sensor is greater than the first preset pressure threshold, the main control unit 200 controls the first sub deflation unit to deflate, so as to prevent the fixed cuff from applying too much pressure to the detection object and injuring the detection object in the inflation process of the first sub inflation unit.

In some embodiments, the ankle artery measurement unit 300 includes an ankle fixing tether and an ankle artery pressure acquisition unit; the ankle arterial pressure acquisition unit is arranged in an ankle fixing tether for fixing the ankle arterial pressure acquisition unit to an ankle of a subject to acquire ankle arterial pressure data.

In some embodiments, the ankle artery pressure acquisition unit includes a third pressure sensor, a second sub-inflation unit, and a second sub-deflation unit; the output end of the main control unit 200 is connected to the input end of the second sub-inflation unit and the input end of the second sub-deflation unit, and is used for controlling the working states of the second sub-inflation unit and the second sub-deflation unit. When ankle artery pressure data of the detection object is obtained, the main control unit 200 outputs a control signal to control the second sub-inflation unit to inflate, when the second sub-inflation unit is inflated to a certain degree, the third pressure sensor cannot obtain the ankle artery pressure data of the detection object (namely, the third pressure sensor is inflated to block blood flow of the ankle artery), at the moment, the main control unit 200 outputs a control signal to control the second sub-deflation unit to deflate, the third pressure sensor obtains the first pressure data signal after deflation, namely, the ankle artery maximum systolic pressure is obtained, and the obtained ankle artery maximum systolic pressure is sent to the main control unit 200 through the Bluetooth communication unit. The main control unit 200 obtains the ABI value of the detected object according to the above-mentioned highest systolic pressure of brachial artery and highest systolic pressure of ankle artery. In this embodiment, the second sub-inflation unit also includes an inflation pump and an air bag, the second sub-deflation unit also includes an air valve, the air pump receives the control of the main control unit 200 to inflate the air bag, when the third sensor cannot detect the ankle artery pressure data, the main control unit 200 controls the air valve to open to deflate the air bag, and when the air is deflated, the brachial artery pressure data acquired by the third sensor at the first time is the highest systolic pressure of the brachial artery. In this embodiment, the ankle artery is the posterior tibial artery or the dorsum pedis artery.

In addition, in some embodiments, the ankle artery pressure acquisition unit further includes a fourth pressure sensor; the fourth pressure sensor is used to acquire pressure data of the ankle fixing strap and transmit the pressure data of the ankle fixing strap to the main control unit 200. In this embodiment, the fourth pressure sensor is configured to acquire pressure data applied to the detection object by the ankle fixing strap, and send the pressure data to the main control unit 200, a second safe preset pressure threshold is set in the main control unit 200, when the pressure data acquired by the fourth pressure sensor is greater than the second preset pressure threshold, the main control unit 200 controls the second sub-deflation unit to deflate, and the second self-inflation unit of the house is in an inflation process, and the ankle fixing strap exerts too much pressure on the detection object, thereby causing damage to the detection object.

In some embodiments, the ABI detection apparatus further comprises a display unit; the output end of the main control unit is connected with the input end of the display unit and used for displaying the ABI value. In this embodiment, the main control module obtains the ABI value of the detection object according to the received highest systolic pressure of the brachial artery and the received highest systolic pressure of the ankle artery, and the ABI value is displayed on the display unit to allow a user to directly observe and obtain the ABI value of the detection object. Further, the heart rate value of the detected object may be displayed on the display unit at the same time.

In some embodiments, the display unit is a touch display screen including touch screen keys, the touch display screen is not only used for displaying the heart rate value and the ABI value of the detected object, but also provided with a detection key and a stop key, the detection key is used for automatically initiating a process of detecting the ABI value by the ABI detection device, and the stop key is used for stopping detection during the process of detecting the ABI value. Obviously, in some embodiments, physical keys, such as a power-on key, a detection key, a stop key, and other conventional functional keys, may be further provided to connect with the main control unit 200. After the main control unit 200 acquires the control signal (including the power-on signal of the power-on button, the detection signal of the detection button, the stop signal of the stop button, etc.), the working state of the brachial artery measurement unit 100 is controlled in a wired connection manner (i.e., the main control unit 200 and the brachial artery measurement unit 100 are disposed in the same housing), and the control signal is transmitted to the ankle artery measurement unit 300 through the bluetooth communication unit, so as to control the working state of the ankle artery measurement unit 300, thereby realizing that the brachial artery measurement unit 100 and the ankle artery measurement unit 300 can simultaneously receive the control of the main control unit 200, and conveniently and rapidly detecting the ABI value of the detection object.

Referring to fig. 3, an embodiment of the present invention provides a blood vessel detection system, which includes: data processing means and ABI detection means; the ABI detection device is connected with the data processing device and sends an ABI value of a detection object to the data processing device; the data processing device feeds back the blood vessel health status of the detected object according to the received ABI value, and displays the blood vessel health status on a display unit of the ABI detection device.

The data processing device comprises a mobile terminal APP and a cloud server; the mobile terminal APP receives the ABI value and transmits the ABI value to the cloud server, the cloud server feeds the blood vessel health state back to the mobile terminal APP according to the ABI value, the mobile terminal APP displays the blood vessel health state, and the blood vessel health state is fed back to a display unit of the ABI detection device to be displayed; the cloud server stores data information of a plurality of detection objects, the data information comprises age, height, weight, past medical history, sleeping time and living habits, and the cloud server feeds the blood vessel health state back to the mobile terminal APP according to the ABI value and the data information and according to a preset matching rule. Different blood vessel health states are displayed in different colors on a display unit of the ABI detection device.

In some embodiments, the data processing device comprises an intelligent terminal app, and the data processing app is connected with a main control unit of the ABI detection device through a bluetooth module and performs data transmission.

In some embodiments, the cloud server of the intelligent terminal APP stores data information such as age, height, weight, past medical history, sleep duration and living habits of a detection object, the intelligent terminal APP uploads the data information to the cloud server after receiving the ABI value sent by the ABI detection device, the cloud server analyzes the blood vessel health condition of the detection object according to the ABI value of the received detection object and in combination with the data information such as the age, height, weight, past medical history, sleep duration and living habits of the detection object, and returns the blood vessel health condition of the detection object to the intelligent terminal APP, and the blood vessel health condition of the detection object is fed back to the ABI detection device by the intelligent terminal APP and displayed on the display unit.

In other embodiments, the cloud server uses the data information of the ABI value, age, height, weight, past medical history, sleeping duration, living habits and the like of the user counted in the actual case as the basic big database data for analyzing the health condition of the blood vessel, that is, the data of the actual case is firstly input into the big database as sample data, when data analysis is carried out, sample data in a large database is used as a total sample to carry out matching of different dimensions, for example, when a certain detection object is 50 years old, the system can match the proportion of a person with cardiovascular and cerebrovascular diseases in the total sample data of the person with 50 years old, and then, matching gender as one-dimensional matching, matching smoking + age as two-dimensional matching, matching smoking + drinking + age as three-dimensional matching until reaching multiple dimensions, wherein each matching parameter is carried out according to the information of the patient until finally analyzing the disease and the comprehensive severity of the disease of the detected object mainly caused by what reason in the total sample database. The larger the total sample value is, the more accurate the blood vessel health condition result obtained through the judgment of the cloud server is.

Referring to fig. 4, the embodiment of the present invention provides a detection process of a blood vessel detection system as follows:

s1: the method comprises the steps that an intelligent terminal APP receives an ABI value of an ABI detection device;

s2: the intelligent terminal APP uploads the ABI value to a cloud server, wherein the cloud server stores data information of the detected object such as age, height, weight, past medical history, sleeping time, living habits and the like;

s3: the cloud server performs data analysis to obtain the blood vessel health state of the detection object, returns the blood vessel health state of the detection object to the ABI detection device, displays the blood vessel health state on a display unit of the ABI detection device, and simultaneously broadcasts the blood vessel health state of the detection object in a voice mode through a voice unit arranged in the ABI detection device.

In addition, in this embodiment, the blood vessel health status of the detection object is distinguished by different colors indicated on the display of the ABI detection apparatus, and the user can know the blood vessel health status of the user.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art. Furthermore, the embodiments of the present invention and features of the embodiments may be combined with each other without conflict.

Claims (10)

1. An ABI detection device, comprising:

the brachial artery measuring unit is worn on the upper limb of the detection object and used for acquiring brachial artery pressure data;

the ankle artery measuring unit is worn on the lower limb of the detection object and used for acquiring ankle artery pressure data;

a main control unit for receiving the brachial artery pressure data and the ankle artery pressure data to obtain an ABI value of the detection object;

the brachial artery pressure data comprise highest systolic pressure of the brachial artery, the ankle artery pressure data comprise highest systolic pressure of the ankle artery, and the ABI value is the ratio of the highest systolic pressure of the ankle artery to the highest systolic pressure of the brachial artery.

2. The ABI detection apparatus according to claim 1, wherein the brachial artery measurement unit and the ankle artery measurement unit are each provided with a bluetooth communication unit;

the brachial artery measuring unit transmits the brachial artery pressure data to the main control unit through a data connecting line, and the ankle artery measuring unit transmits the ankle artery pressure data to the main control unit through the Bluetooth communication unit.

3. The ABI detection apparatus of claim 1, wherein the brachial artery measurement unit comprises: a fixed cuff and a brachial artery pressure acquisition unit;

the brachial artery pressure acquisition unit is arranged in the fixed cuff;

the fixed cuff is used for fixing the brachial artery pressure acquisition unit to the upper limb of the detection object so as to acquire the brachial artery pressure data.

4. The ABI detection apparatus of claim 3, wherein the brachial artery pressure acquisition unit comprises a first pressure sensor, a first sub inflation unit, and a first sub deflation unit;

the output end of the main control unit is respectively connected with the input end of the first sub-inflation unit and the input end of the first sub-deflation unit and is respectively used for controlling the working states of the first sub-inflation unit and the first sub-deflation unit;

the output end of the first pressure sensor is connected with the input end of the main control unit so as to transmit the brachial artery pressure data acquired by the first pressure sensor to the main control unit.

5. The ABI detection apparatus according to claim 3 or 4, wherein the brachial artery pressure acquisition unit further comprises a second pressure sensor;

the output end of the second pressure sensor is connected with the input end of the main control unit, and the second pressure sensor is used for acquiring the pressure data of the fixed cuff and sending the pressure data of the fixed cuff to the main control unit.

6. The ABI detection device according to claim 3 or 4, wherein the ankle artery measuring unit comprises an ankle fixing tether and an ankle artery pressure obtaining unit;

the ankle arterial pressure acquisition unit is arranged in the ankle fixing tether;

the ankle fixing tether is configured to fix the ankle arterial pressure acquisition unit to an ankle of the detection subject to acquire the ankle arterial pressure data.

7. The ABI detection apparatus of claim 6, wherein the ankle artery pressure acquisition unit comprises a third pressure sensor, a second sub inflation unit and a second sub deflation unit;

the output end of the main control unit is respectively connected with the input end of the second sub-inflation unit and the input end of the second sub-deflation unit and is respectively used for controlling the working states of the second sub-inflation unit and the second sub-deflation unit;

the third pressure sensor is used for acquiring the ankle artery pressure data and transmitting the ankle artery pressure data to the main control unit.

8. The ABI detection apparatus of claim 7, wherein the ankle artery pressure acquisition unit further comprises a fourth pressure sensor;

the fourth pressure sensor is used for acquiring pressure data of the ankle fixing lace and sending the pressure data of the ankle fixing lace to the main control unit.

9. The ABI detection apparatus according to claim 1 or 2, further comprising a display unit;

and the output end of the main control unit is connected with the input end of the display unit and is used for displaying the ABI value.

10. A blood vessel detection system comprising data processing means and an ABI detection means according to any one of claims 1 to 9;

the ABI detection device is connected with the data processing device to send the ABI value of the detection object to the data processing device;

the data processing device feeds back the blood vessel health status of the detected object according to the received ABI value, and displays the blood vessel health status on a display unit of the ABI detecting device.

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