RU2661724C1 - Device for automatic identification and correction of patients with diabetes mellitus - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to medical devices for the treatment of diabetes mellitus by external subcutaneous injection of insulin into the patient's body, and can be used for automatic identification and correction of patients with diabetes mellitus. Device contains a module for receiving messages from glucose sensors, a module for selecting reference addresses of glucose sensors in the database server and reference addresses for calling server procedures for processing messages from glucose sensors, memory module, the first, second and third modules for addressing messages of glucose sensors in the database server and addressing the call of server procedures for processing messages of glucose sensors, module for setting the total number of messages for glucose sensors and the total number of calls for server procedures for processing messages of glucose sensors, module for monitoring the number of messages received by glucose sensors and the number of calls for server procedures for processing glucose sensor messages and the module for integrating address signals.

EFFECT: invention allows to achieve a significant increase in the accuracy of the device.

1 cl, 5 dwg

Description

The device relates to medicine, in particular to medical devices for the treatment of diabetes mellitus by external subcutaneous injection of insulin into the patient's body.

Diabetes mellitus affects hundreds of millions of people in the world who need effective insulin-based diabetes treatments. Invasive treatments related to frequent patient sampling and calculation of insulin doses for manual syringe injections are still widespread.

Currently, there are more convenient devices for personal use in the form of glucometers, syringe pens, insulin pumps, and continuous glucose monitoring systems. Insulin pumps and continuous glucose monitoring systems are minimally invasive devices that are attached to the patient’s body for several days and do not require frequent puncture of subcutaneous tissue. But manual control and management of such systems is retained.

Manual insulin therapy devices are being replaced by automatic systems to stabilize the patient’s blood glucose level. Such systems are designed to completely release the patient from active participation in the processes of identification and correction of the current state of the patient. It is the processes of identification and correction of the current state of the patient that are the main objects of automation for automatic systems for stabilizing the level of glucose in the blood.

Identification is associated with the determination of the current blood glucose level using sensors and the analysis of deviations of the measured level from the norm that are hazardous to health. Correction is designed to generate signals to the insulin pump based on the results of identification of the patient's condition, ensuring the stabilization of glucose levels near normal.

Prior to the advent of automatic glycemic stabilization systems, the identification process and the state correction process were used separately. The sensor identification device continuously determined the current glucose level, and the calculation of doses and insulin injections was carried out manually.

Known technical solutions to the problem (1, 2).

The first known technical solution contains an independent unit for continuous subcutaneous monitoring of the glucose concentration in the patient’s blood with a glucose sensor, a sensor reading module and a calculator of required insulin doses, while the glucose sensor is fixed for several days on the patient’s body, and the calculator of required doses of insulin is constantly integrated into design of the sensor reading module (1). This device provides a minimally invasive treatment regimen, but only for the process of determining the current level of glucose in the blood with a period of 5 minutes. Injecting corrective doses of insulin with a syringe requires repeated piercing of the skin.

The disadvantage of this technical solution is its limited functionality, due to the lack of an insulin pump and a control device for supplying signals to the input of the insulin pump, which makes it impossible to organize automatic infusion of insulin according to the readings of the glucose sensor.

The device automatically performs only part of the process of identifying the patient’s condition associated with determining the current level of glucose in the blood, the rest of the identification and correction of the patient’s condition is performed manually. As a result, the accuracy of glycemic stabilization with such therapy is as low as with a completely manual method of treatment. In addition, this technical solution is applicable only to one patient, on whose body an independent unit for continuous subcutaneous monitoring of the glucose concentration in the patient’s blood is fixed.

Another technical solution is known that contains an external insulin infusion unit with a catheter, a needle, an insulin pump, an insulin reservoir, a sensor system for continuous subcutaneous monitoring of the glucose concentration in the patient’s blood, a control device for signaling the input of the insulin pump, fixed to the patient’s body for several days for automatically performing insulin injections according to the readings of glucose sensors without repeatedly piercing the patient's skin after a single piercing at the time fixing the block of external insulin infusion on the patient's body (2).

This technical solution is the closest to the proposed device.

Its disadvantage is its low accuracy, due to the fact that the device does not provide for the use of flexible or intelligent feedbacks.

The purpose of the invention is to eliminate this drawback, i.e. in increasing the accuracy of the device by using flexible feedback, forming the supply of control signals to the input of the insulin pump of both one patient and groups consisting of many patients.

This goal is achieved by the fact that in a device containing a module for receiving messages from glucose sensors, the information and synchronizing inputs of which are the first information and synchronizing inputs of the device, respectively, and the first information output of the module for receiving messages from glucose sensors is an information output of the device, intended for issuing messages to the information the input of the database server and the information input of the server for processing messages of glucose sensors, while the first The device’s first input is for receiving glucose sensor messages, the first synchronizing device input is for receiving synchronizing signals for gluing sensor messages into the glucose sensor message receiving module, the module for setting the total number of glucose sensor messages and the total number of server calls for processing glucose sensor messages, the first information and the first clock inputs of which are the second information and second clock inputs of the device, respectively, the second information and second synchronizing inputs of the module for setting the total number of messages of glucose sensors and the total number of calls to server procedures for processing messages of glucose sensors are the third information and third synchronizing inputs of the device, respectively, while the second information input of the device is designed to receive the total number of messages of glucose sensors, the third information the device input is designed to receive the total number of calls to server procedures for processing messages from sensors glitch Of course, the second synchronizing input of the device is designed to receive synchronizing signals for entering the total number of messages of glucose sensors into the module for setting the total number of messages of glucose sensors and the total number of calls to server procedures for processing messages of glucose sensors, the third synchronizing input of the device is for receiving synchronizing signals for entering the total number of messages of glucose sensors procedures for processing glucose sensor messages in the module for setting the total number of glucose sensor messages and the total number and calls to server procedures for processing messages of glucose sensors, the address signal integration module, the first address output of which is the first address output of the device, intended for issuing recording addresses of messages of glucose sensors to the database server, the second address output of the address signal integration module is the second address output of the device, intended for issuing call addresses of server procedures for processing glucose sensors messages, and the first synchronizing output of the address si integration module channel is the first synchronizing output of the device intended for issuing synchronizing signals to the input of the first interrupt channel of the database server, the second synchronizing output of the address signal integration module is the second synchronizing output of the device intended for issuing synchronizing signals to the input of the first interrupt channel of the glucose sensor message processing server, and a memory module, characterized in that a module for selecting reference addresses of glucose sensors in sulfur is introduced into the device faith of the database and reference addresses of the call of the server procedures for processing messages of glucose sensors, the first information input of which is connected to the second information output of the module for receiving messages of glucose sensors, the second information input of the module for selecting reference addresses of glucose sensors in the database server and reference addresses of the call of server processes of message processing glucose sensors is connected to the third information output of the glucose sensor messages receiving module, the first and second synchronizing inputs of the selection module reference addresses of glucose sensors and reference addresses of call server procedures for processing messages of glucose sensors are connected to the first synchronizing input of the device, and the signal outputs of the selection module for reference addresses of glucose sensors and reference addresses of call server procedures for processing messages of glucose sensors are connected to the corresponding signal inputs of the memory module glucose sensor messages in the database server and call addressing of server procedures for processing glucose sensor messages, information the operational inputs of which are connected to the corresponding information outputs of the memory module, the control inputs of the addressing modules for glucose sensor messages in the database server and the call addressing of server procedures for processing glucose sensor messages are connected to the corresponding control outputs of the selection module for reference addresses of glucose sensors and reference addresses for calling server messages glucose sensors, the first and second synchronizing outputs of which are connected to the corresponding synchronizing input the modules for addressing the messages of glucose sensors in the database server and addressing the call of server procedures for processing messages of glucose sensors, while the information outputs of the modules for addressing messages of glucose sensors in the database server and the addressing of calls for server processes for processing messages of glucose sensors are connected to the corresponding information inputs of the address integration module signals, and the signal outputs of the modules for addressing messages of glucose sensors in the database server and addressing the call of server procedures the processing of glucose sensor messages are the signal outputs of the device, and a module for monitoring the number of received glucose sensor messages and the number of server calls for processing glucose sensor messages, the first and second information inputs of which are connected to the corresponding first and second information outputs of the module for setting the total number of glucose sensors messages and the total the number of calls to server procedures for processing messages of glucose sensors, the first and second counting inputs of the module for monitoring the number of received messages th glucose sensors and the number of calls of server procedures for processing messages of glucose sensors are connected to the corresponding first and second synchronizing outputs of the address signal integration module, while the first and second clock outputs of the module for monitoring the number of received messages of glucose sensors and the number of calls to server processes of processing messages of glucose sensors are corresponding clock outputs of the device, intended for the issuance of signals for receiving messages from glucose sensors and server call signals procedures for processing glucose sensor messages, and the first and second control outputs of the module for monitoring the number of received messages of glucose sensors and the number of calls to server server procedures for processing messages of glucose sensors are the corresponding control outputs of the device designed to provide the corresponding signals for the end of the reception cycle of messages of glucose sensors and the end of the server call cycle glucose sensor message processing procedures.

The invention is illustrated by drawings, where in FIG. 1 is a structural diagram of a device; FIG. 2 is a block diagram of a selection module for reference addresses of glucose sensors in a database server and reference addresses for calling server procedures for processing glucose sensor messages; FIG. 3 is a structural diagram of the first, second, and third modules for addressing glucose sensor messages in a database server and for addressing a call to server procedures for processing glucose sensor messages; FIG. 4 is a block diagram of a module for monitoring the number of received messages of glucose sensors and the number of calls to server procedures for processing messages of glucose sensors, FIG. 5 is a block diagram of an address signal integration module.

The device (Fig. 1) contains a module 1 for receiving messages from glucose sensors, a module 2 for selecting reference addresses of glucose sensors in the database server and reference addresses for calling server procedures for processing messages of glucose sensors, a memory module 3, the first 4, the second 5, and the third 6 addressing modules glucose sensor messages in the database server and call addressing of server procedures for processing glucose sensor messages, module 7 for setting the total number of glucose sensor messages and the total number of calls for server procedures for processing sensor messages glucose control module 8 of received messages glucose sensors and the number of calls to the server message processing procedures of the glucose sensor, and a module 9 integrating address signals.

In FIG. 1 shows the first 12, second 16 and third 14 information inputs of the device, the first 11, second 15 and third 13 synchronizing inputs of the device, as well as the information 27 output of the device, the first 20 and second 21 address outputs of the device, the first 19 and second 23 synchronizing outputs of the device the first 18, second 22, third 24, fourth 17, fifth 25 and sixth 26 signal outputs of the device, the first 31 and second 28 clock outputs, the first 30 and second 29 control outputs of the device.

The glucose sensor messages receiving module 1 (Fig. 1) is made in the form of a register having information 33 and synchronizing 32 inputs, as well as first 36, second 34 and third 35 information outputs.

Module 2 selection of reference addresses of glucose sensors in the database server and reference addresses of the call server procedures for processing messages of glucose sensors (Fig. 2) contains the first 30 and second 130 decoders, elements 31-33 and 131-133 And, elements 34, 35, 134 and 135 delays. The drawing shows the first 38 and second 39 information inputs, the first 37 and second 40 clock inputs, a group of signal 41-43 and 44-46 outputs, a group of control 47-48, 53 and 50-51, 54 outputs, the first 49 and second 52 synchronizing output.

The memory module 3 (Fig. 1) is made in the form of a permanent storage device having read inputs 89-91 and 92-94, as well as the first 95 and second 96 information outputs.

Modules 4, 5 and 6 (Fig. 3) of the addressing of glucose sensor messages in the database server and the call addressing of server procedures for processing glucose sensor messages are identical and contain the first 50, second 51, third 150 and fourth 151 registers, adders 52 and 152, comparators 53 and 153, counters 54 and 154, groups 55 and 155 of AND elements, elements 56 and 156 AND, delay elements 57, 58, 157 and 158. The drawing shows the first 97 and second 100 information, the first 98 and second 101 control, the first 99 and second 102 clock inputs, as well as the first 116 and second 118 information, the first 117 and second 119 clock, the first 115 and second 120 signal outputs.

Module 7 for setting the total number of messages of glucose sensors and the total number of calls to server procedures for processing messages of glucose sensors (Fig. 1) is made in the form of a register having first 216 and second 218 information inputs, first 215 and second 217 synchronizing inputs, and first 219 and second 220 information outputs.

Module 8 for monitoring the number of glucose sensors messages received by the control device of the infusion system and the number of calls to server processes for processing glucose sensors messages (Fig. 4) contains counters 66 and 166, comparators 67 and 167, delay elements 68 and 168. The drawing shows the first 223 and second 224 information inputs, the first 221 and second 222 counting inputs, as well as the first 28 and second 30 clock outputs, and the first 29 and second 31 control outputs.

Module 9 integration of address signals (Fig. 5) contains a group of 73 and 173 elements OR, and elements 74 and 174 OR. The drawing shows the group of information inputs 187, 191, 195 and 189, 193, 197 and the group of clock inputs 188, 192, 196 and 190, 194, 198 as well as the first 20 and second 21 address outputs, the first 19 and second 23 clock outputs.

The device operates as follows.

In the process of patient insulin therapy, data on the blood glucose level of each patient belonging to a certain group of patients, using a glucose sensor mounted on the patient’s body, in accordance with the technology used for measuring glucose concentration, is received at the device input in the form of messages (codograms) having the following structure:

Glucose sensors are grouped in accordance with specific groups of patients having similar individual characteristics and similar insulin therapy procedures.

Messages from glucose sensors from the same group are recorded in the server database and processed by the same set of server procedures for this group of sensors, designed to form flexible feedback in a closed system for automatic glycemic stabilization.

Before the device starts to work, the code 7 is set for the specified number of messages to be received from the glucose sensors in each group of glucose sensors using the synchronization signal from the input 13, from the information input 14, and the code of the specified value is set from the information input 16 using the synchronization signal from input 15 the number of call processing procedures for messages from a particular glucose sensor from the processed group of glucose sensors.

In accordance with the technology used for measuring glucose concentration, each message of the glucose sensor is fed to the information input 33 of module 1 (Fig. 1), and the clock pulse from input 32 is entered in the register of module 1. The output 36 of module 1 is the information output 27 of the device, intended for issuing received messages to the information input of the database server and the information input of the server for processing messages from glucose sensors.

The glucose sensor identifier code from the output 34 of module 1 is fed to the information input 38 of the module 2 and then to the input 55 of the decoder 30, and the clock pulse from the input 11 through the input 37 of the device module 2 is delayed by the delay element 34 for the time the glucose sensor identifier code is entered into the module register 1 and the operation of the decoder 30, and then goes to the inputs 68, 70, 72 elements 31-33 I.

The decoder 30 decrypts the incoming code, opening one of the elements 31-32 And, and prepares the signal path from the output 62 of the delay element 34. For definiteness, we assume that a high potential is received at one input of element 31 I.

Considering that only one And 31 element will be open at one input, then passing this And element, the clock pulse from output 41 goes to the reading input 89 of the fixed memory cell of the permanent storage device 3.

The following data is stored in a fixed memory cell at input 89 of module 3:

The read data from the output 95 of module 3 is fed to the information inputs 97, 103, 109 of all addressing modules 4, 5, and 6, however, they will be accepted only by module 4, since the high potential from the output 47 of module 2 goes to the control input 98 of module 4 and opens one input group of elements 55 And, and element 56 I.

At the same time, the synchronizing pulse from the output 62 of the element 34 of the module 2 is delayed by the delay element 35 for the time of reading the fixed memory cell of the permanent storage device 3, and from the output 49 of the module 2 through the synchronizing input 99 of the module 4 passes through the element 56 AND to the synchronizing inputs 146 and 148 registers 50 and 51.

As a result of this, the code of the reference address of the recording of incoming messages from this glucose sensor is entered in register 50, and the number of messages that should come from this glucose sensor is entered in register 51 of module 4.

From the output 157 of register 50, the code of the reference address of the record goes to one input 171 of the adder 52, to the other input 172 of which the output 160 of the counter 54 is connected, and from the output 158 of register 51 the code of the number of messages to be received is received at one input 165 of the comparator 53, the other the input 167 of which is also connected to the output of the counter 54.

In parallel with this, the synchronizing pulse from the output 142 of the 56 element is delayed by the delay element 57 for the time the codes are entered into the registers 50, 51, and is fed to the synchronizing input 166 of the comparator 53. With this pulse, the comparator 53 compares the readings of the register 51 with the readings of the counter 54.

Considering that the counter 54 is currently in the initial state and its readings are equal to zero, the comparator 53 will give a signal at its first 175 output, from which the clock pulse firstly goes to the clock input 173 of the adder 52, which sums the reference address code from the output 157 of the register 50 with the counter zero code 54, and on its output 183 the code of the reference address of the database server will be fixed, which from the output 116 of the module 4 goes to the information input 187 of the module 9, and then through the elements 73 OR of the group is issued to the address first output 20 of the control device of the infusion system.

Secondly, the same synchronizing pulse arrives at the counting input 150 of the counter 54, bringing in the first unit, indicating that one message from this glucose sensor has already been received.

And, finally, thirdly, the same pulse is delayed by the delay element 58 for the response time of the adder 52 of the module 4, and from the output 117 of the module 4 is fed to the input 188 of the module 9, and then through the element 74 OR is issued to the synchronizing output 19 of the device, from where it is issued to the input of the first channel of the database server interrupt.

With the arrival of this impulse, the database server switches to the data recording routine of this glucose sensor from output 27 at the address set on address output 20.

In addition, the synchronizing pulse from the output 19 of the control device of the infusion system enters the counting input 221 of module 8 and then enters the counting input 229 of the counter 66, counting the number of messages received from glucose sensors, cumulatively. A fixed number of messages from counter 66 is issued to one input 235 of comparator 67, to the other 237 of which input from input 223 of module 8 receives a code for a given number of messages, which must be received from glucose sensors from the output of module 7. By a synchronizing pulse from input 69, delayed by an element delays 68 at the time of operation of the counter 66, the comparator 67 compares the readings of the counter with a given number of messages coming from the output 219 of module 7.

If the readings of counter 66 are less than the specified number of messages, then the comparator 67 of module 8 generates at its output 225 a clock pulse, which is supplied to the clock output 28 of the device as a control signal for receiving the next message.

If the readings of the counter 66 are equal to the specified number of messages to be received from module 7, then the comparator 67 of module 8 generates a pulse at the output 29 of the device, which is the signal for the end of the recording cycle of all messages of this group of glucose sensors.

A feature of the operation of the message addressing modules of glucose sensors is that each of them monitors the receipt of a given number of messages from a specific glucose sensor.

Indeed, the signal of receipt of all given messages at the signal output 115, 123, 129 of each of the message addressing modules 4, 5, 6 will be issued only if the counter 54 and the code for the specified number of messages to be received are the same.

The code of the identifier group of glucose sensors from the output 35 of module 1 is fed to the information input 39 of module 2 and then to the input 57 of the decoder 130, and the synchronizing pulse from input 11 through the input 40 of module 2 of the control device of the infusion system is delayed by the delay element 134 for the duration of entering the group identifier code glucose sensors in the register of module 1 and the operation of the decoder 130, and then goes to the inputs 74, 76, 78 elements 131-133 I.

The decoder 130 decrypts the incoming code, opening one of the elements 131-132 And, and prepares the signal path from the output of the delay element 134. For definiteness, we assume that a high potential is received at a single input of element 131 I.

Considering the fact that only AND element 131 will be open at one input, then passing through this AND element, the clock pulse from output 44 goes to the read input 92 of the fixed memory cell of the permanent storage device 3.

The following data is stored in a fixed memory cell at input 92 of module 3:

The read data from the output 96 of module 3 is fed to the information inputs 100, 106, 112 of all modules 4, 5 and 6, however, they will be accepted only by module 4, since the high potential from the output 50 of module 2 is supplied to the control input 101 of module 4 and opens by one input 138 group of elements 155 And, and element 156 I.

At the same time, the synchronizing pulse from the output 66 of the element 134 of the module 2 is delayed by the delay element 135 for the reading time of the fixed memory cell of the permanent storage device 3, and from the output 52 of the module 2 through the synchronizing input 102 of the module 4 passes through the element 156 And to the synchronizing inputs 152, 154 registers 150 and 151.

As a result of this, the code of the reference address of the call for processing procedures for incoming messages from this group of glucose sensors is entered into register 150, and the number of processing procedures that must be performed for this group of glucose sensors is entered into register 151 of module 4.

From the output 161 of register 150, the code of the reference address of the call to the processing procedures arrives at one input 177 of the adder 152, the output 174 of the counter 154 is connected to the other 178 input, and the output of 162 of the register 151 is the code for the number of processing procedures to be performed for this group of glucose sensors one 168 input of the comparator 153, the other 170 input of which is also connected to the output of the counter 154.

In parallel with this, the synchronizing pulse from the output 144 of the element 156 And is delayed by the delay element 157 for the time the codes are entered into the registers 150, 151, and arrives at the synchronizing input 169 of the comparator 153. With the arrival of this pulse, the comparator 153 compares the readings of the register 151 with the readings of the counter 154.

Given that by now the counter 154 is in the initial state and its readings are zero, the comparator 153 will give a signal at its first 181 output, from which the clock pulse, firstly, is fed to the clock input 179 of the adder 152, which sums the reference address code from the output 161 of the register 150 with the counter counter zero code 154, and at its output 118, the code of the reference address of the server procedure for processing glucose sensors messages will be fixed, which from the output 118 of the module 4 goes to the information input 189 of the module 9, and then through elements 173 OR groups issued to the address output 21 of the device.

Secondly, the same synchronizing pulse arrives at the counter 156 input of the counter 154, bringing the first unit into it, indicating that one call to process a message from this glucose sensor of the processed sensor group has already been accepted.

And finally, thirdly, the same pulse is delayed by the delay element 158 for the response time of the adder 152 of the module 4, and from the output 119 of the module 4 goes to the input 190 of the module 9, and then through the element 174 OR is issued to the synchronizing output 23 of the device, where it is issued to the input of the first channel of interruption of the glucose sensors message processing server.

With the arrival of this pulse, the glucose sensor message processing server switches to the data processing routine of this glucose sensor of the processed sensor group from output 27 at the address set on address output 21.

In addition, the synchronizing pulse from the output 23 of the device goes to the counting input 222 of module 8 and then goes to the counting input 231 of the counter 166, which counts the cumulative number of calls to the processing routines for a given glucose sensor of the processed sensor group.

A fixed number of calls to the counter routines 166 is issued to one input 238 of the comparator 167, to the other input 240 of which, from the input 224 of module 8, a code of a given number of processing procedures to be performed for this group of glucose sensors is received from the output of module 7.

According to the synchronizing pulse from input 222, delayed by delay element 168 for the response time of counter 166, comparator 167 compares the counter readings with a given number of message processing procedures received from output 220 of module 7.

If the readings of the counter 166 are less than the specified number of message processing procedures, the comparator 167 of module 8 generates a clock pulse at its output 227, which is supplied to the clock output 30 of the device as a control signal for receiving another call to the message processing procedure of the processed group of glucose sensors.

If the readings of the counter 166 are equal to the specified number of message processing procedures from module 7, then the comparator 167 of module 8 generates a pulse at the output 31 of the device, which is the signal for the end of the call cycle of all message processing procedures for this group of glucose sensors.

A feature of the operation of call addressing modules of glucose sensor message processing procedures is that each of them monitors the receipt of a given number of call processing procedures calls from a specific glucose sensor from the processed group of glucose sensors.

Indeed, the signal of receipt of all the given calls of the processing procedures at the signal output 120, 126, 132 of each of the message addressing modules 4, 5, 6 will be issued only if the counter 154 and the code of the specified number of calls to the message processing procedures from a particular glucose sensor from the treated group of glucose sensors will be the same.

Thus, thanks to the introduction of new modules and new constructive connections, a significant increase in the accuracy of the device was achieved by using flexible feedback that generates control signals to the input of the insulin pump of both one patient and groups consisting of many patients.

Information sources

1. US patent US 9014774, 04.21.2015

2. US patent US 9480796, 01/01/2016, (prototype)

Claims (1)

A device for automatically identifying and correcting the condition of patients with diabetes mellitus, comprising a module for receiving messages from glucose sensors, the information and synchronizing inputs of which are the first information and synchronizing inputs of the device, respectively, and the first information output of the module for receiving messages from glucose sensors is an information output of the device intended for issuing messages to the information input of the database server and the information input of the sensor message processing server a glucose ditch, while the first information input of the device is intended for receiving glucose sensor messages, the first synchronizing input of the device is for receiving synchronizing signals for entering glucose sensor messages into the glucose sensor message receiving module, the module for setting the total number of glucose sensor messages and the total number of server processing procedures calls glucose sensor messages, the first information and first synchronizing inputs of which are the second information and second synchronization respectively, the second information and second synchronizing inputs of the module for setting the total number of messages of glucose sensors and the total number of calls to server procedures for processing messages of glucose sensors are the third information and third synchronizing inputs of the device, respectively, while the second information input of the device is designed to receive the total number of messages glucose sensors, the third information input of the device is designed to receive the total number of server calls the procedure for processing messages of glucose sensors, the second synchronizing input of the device is designed to receive synchronizing signals for recording the total number of messages of glucose sensors in the module for setting the total number of messages of glucose sensors and the total number of calls to server procedures for processing messages of glucose sensors, the third synchronizing input of the device is for receiving synchronizing signals the total number of calls to server procedures for processing glucose sensors messages to the total number installation module and glucose sensor messages and the total number of calls to server procedures for processing glucose sensor messages, the address signal integration module, the first address output of which is the first address output of the device designed to provide the recording addresses of glucose sensor messages to the database server, the second address output of the address signal integration module is the second address output of the device, intended for issuing call addresses of server procedures for processing messages from glucose sensors, and the first synchronization the output output of the address signal integration module is the first synchronizing output of the device, intended for issuing synchronization signals to the input of the first channel server interrupt channel, the second synchronizing output of the address signal integration module is the second synchronizing output of the device, intended for issuing synchronization signals to the input of the first server interrupt channel processing glucose sensor messages, and a memory module, characterized in that the device has a module selected reference addresses of glucose sensors in the database server and reference addresses of call server procedures for processing glucose sensor messages, the first information input of which is connected to the second information output of the glucose sensor messages receiving module, the second information input of the selection module of reference glucose sensors addresses in the database server and reference call addresses of server procedures for processing glucose sensor messages is connected to the third information output of the glucose sensor messages receiving module, the first and one A swarm of synchronizing inputs of the module for selecting reference addresses of glucose sensors and reference addresses for calling server procedures for processing messages from glucose sensors is connected to the first synchronizing input of the device, while the signal outputs of the module for selecting reference addresses for glucose sensors and reference addresses for calling server procedures for processing messages from glucose sensors are connected to the corresponding signal inputs memory modules, addressing modules for glucose sensor messages in the database server and addressing of server procedure calls about processing glucose sensor messages, the information inputs of which are connected to the corresponding information outputs of the memory module, the control inputs of the modules for addressing glucose sensor messages in the database server and the call addressing of server procedures for processing glucose sensor messages are connected to the corresponding control outputs of the module for selecting reference addresses of glucose sensors and reference addresses call server procedures for processing glucose sensors messages, the first and second synchronizing outputs of which are connected with the corresponding synchronizing inputs of the modules for addressing messages of glucose sensors in the database server and addressing the call of server procedures for processing messages of glucose sensors, while the information outputs of the modules for addressing messages of glucose sensors in the database server and addressing calls for server procedures for processing messages of glucose sensors are connected to the corresponding information inputs the integration module of address signals, and the signal outputs of the addressing modules of messages of glucose sensors in the database server data and addressing the call of the server procedures for processing messages of glucose sensors are the signal outputs of the device, and a module for monitoring the number of received messages of glucose sensors and the number of calls of server procedures for processing messages of glucose sensors, the first and second information inputs of which are connected to the corresponding first and second information outputs of the common installation module the number of glucose sensor messages and the total number of server calls for processing glucose sensor messages, the first and second counted inputs The odes of the control module for the number of received messages of glucose sensors and the number of calls to server procedures for processing messages of glucose sensors are connected to the corresponding first and second synchronizing outputs of the address signal integration module, while the first and second clock outputs of the control module for the number of received messages of glucose sensors and the number of calls to server processing procedures messages of glucose sensors are the corresponding clock outputs of the device, intended for issuing signals receiving messages with glucose sensors and call signals of the server procedures for processing glucose sensor messages, and the first and second control outputs of the module for monitoring the number of received messages of glucose sensors and the number of calls of server procedures for processing messages of glucose sensors are the corresponding control outputs of the device for issuing the corresponding signals for the end of the cycle of receiving sensor messages glucose and end of the call cycle server procedures for processing glucose sensor messages.

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