RU2666588C1 - System for monitoring procedure parameters of correction of curvature of arches of lordosis of vertebral column - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to medicine, namely to vertebrology, in particular to a system for monitoring the parameters of procedures for correcting the curvature of arches of lordosis of the spine. In the method, the system contains the module for identifying the base address of the spine tomograms, the module for identifying the relative address of the spine tomograms, the module for selecting the address of the tomogram of the region of vertebral column of the requested patient, the module for recognizing the branch of processing of the tomograms of the region of vertebral column of patients, the patient data recording module, the module for monitoring the completion of the patient array analysis procedure, the module for identifying the base address of procedures for correcting the curvature of the lordosis arch of the region of vertebral column of the patient, the module for selecting the address of the parameters of the procedure for correcting the curvature of the lordosis arch of the region of vertebral column of the patient.EFFECT: invention provides an extension of the functional capability of the monitoring system for the parameters of procedures for correcting the curvature of arcs of lordosis of the spine by making a decision on each tomogram received for processing.1 cl, 9 dwg, 3 tbl

Description

The invention relates to medicine, namely to vertebrology, in particular, to a system for monitoring parameters of procedures for correcting curvature of the arches of lordosis of the spine, which implements the use of new information technologies for monitoring parameters of procedures for correcting curvature of arches of lordoses of the spine.

Vertebrology is the science of diseases and injuries of the spine. When translating this word into Russian, it sounds like a doctrine of the vertebra, since it comes from the Latin word “vertebra”, which means the vertebra, and the Greek word “logos” - the doctrine.

In terms of this teaching, spinal correction is a procedure for restoring the exact anatomical relationships of neighboring vertebrae, the axis of the spine as a whole, and mobility in the intervertebral joints.

The urgent need for the procedure for correction of the spine is confirmed by the data of [3], according to which 85% of the population of Russia suffer from diseases of the spine. Such depressing statistics requires the urgent organization of mass medical examination of the population with full automation of the processing of the obtained measuring materials.

To date, a fairly high level of comprehensive examination of the human body has been achieved through the use of modern high-tech diagnostic methods based on different functional capabilities, but yielding comparable reliability of the results. In such conditions, when choosing one or another diagnostic method, the informational component of the research is put forward in the first place.

One of the most informative methods is tomography, which gives much more information about each elementary component of the studied object than other known diagnostic methods.

Tomography (from the Greek. Tomos - chunk, layer and grapho - I write) is a method of non-destructive layer-by-layer investigation of the internal structure of an object by repeatedly scanning it in various intersecting directions, the so-called scanning transmission.

Currently, magnetic resonance imaging (MRI) and computed tomography (CT) are used in medical practice.

Magnetic resonance imaging (MRI) is a modern, reliable, painless and safe method for the accurate diagnosis of diseases of the central nervous system, muscular-articular apparatus and internal organs. The basis of MRI is a layered study of organs and tissues, which gives the doctor the opportunity to get a three-dimensional (3D) image of the studied area. The method is not associated with ionizing radiation or the introduction of any radioactive substances. The basis for MRI images is the measurement of the electromagnetic response of proton nuclei (hydrogen atoms) contained in the tissues of the body to their excitation by a certain combination of electromagnetic waves in a constant magnetic field of high tension, i.e. In this method, the waves that the human body emits are recorded.

The work of a computer tomograph (CT) is based on x-ray radiation, which has a negative effect on the human body, which limits the frequency of this procedure.

Considering the insecurity of the nature of x-ray radiation in computed tomography and especially the restrictions on the repeatability of the CT scan procedure, it is advisable to use only magnetic resonance imaging (MRI) as a tool for mass medical examination of the population.

In a typical case, magnetic resonance imaging data is a set of tomograms (slices) with a total number of up to several hundred, with each tomogram being a halftone image of 512 × 512 numbers corresponding to the relative densities of hydrogen atoms in the tissues of the human body in the scanning plane.

MRI allows you to study in detail and obtain a 3D image of not only bone structures, but also cartilage, and connective (fibrous) tissues, as well as blood vessels, nerves and spinal cord matter. With the help of MRI, the doctor has the opportunity to examine the condition of the nucleus and fibrous ring of the discs, the sizes and directions of prolapse, as well as the pinched nerve roots and spinal stenosis. This is especially important for degenerative pathologies of the spine, such as osteochondrosis, spondylosis and spondylarthrosis, as well as herniated discs.

In addition, during the scanning procedure, you can perform an MRI of the spine as a whole, and examine each of its departments: cervical, thoracic, lumbar and lumbosacral.

There are five divisions of the spine with Latin names: Pars Cervicalis-cervical region with vertebrae C1-C7; Pars Thoracalis - thoracic with vertebrae Th1-Th12 (or T1-T12, or D1-D12); Pars Lumbalis - Lumbar vertebrae L1-L5; Os Sacrum - the sacral region with the vertebrae S1-S5 (in an adult, they grow together in the sacral bone). Os Coccygis is the coccygeal section with the vertebrae Co1-Co5 (in an adult, they grow together in the coccygeal bone).

If you look at the structure of the human spine from the side, you can see that the vertebrae are not directly one above the other, but form the characteristic physiological curves of the spine: in the cervical region, the spine bends forward, forming the so-called cervical lordosis; in the thoracic spine bends back, forming the so-called thoracic kyphosis; in the lumbar spine has a forward bend, forming the so-called lumbar lordosis; in the sacral section, the spine bends back, forming the so-called sacral kyphosis.

Between the vertebrae of the cervical (except the first two), thoracic and lumbar spine there are intervertebral discs. Each disk consists of a pulpous (gelatinous) nucleus, a fibrous ring and locking plates of a thin layer of hyaline cartilage, covering the disk above and below and closely adjacent to the bodies above - and the lower vertebrae. The fibrous ring, in turn, also consists of thin fibrous layers (plates). The fiber of the ring is intertwined in different directions, which allows the disk to withstand multiple high loads when bending and twisting the spine. The elastic consistency of the disc allows it to change shape. The ability of the disk to take over and distribute pressure between the vertebrae allows it to play the role of a shock absorber and allows the spine to bend.

In [4], for the treatment of dystrophic diseases of the spine, a technique was developed for vertical underwater traction of the spine, using a swimming vest with a headrest in the form of a wide collar designed to support the patient’s head on the surface of the water as a floating device for maintaining the patient in warm water of a deep reservoir. , upper and lower chest straps designed to fix the patient’s chest to the swimming vest, removable inguinal strap designed for prevent the emergence of a vest without a patient.

The essence of the traction is that under the influence of gravity of the patient's musculoskeletal system acting on the spine, the spine begins to move from top to bottom, which is allowed by the mobility of the rib-vertebral joints of the thoracic region relative to the sternum of the chest, fixed on the swimming vest with the lower chest belt, and slowly opens the contacts of the edges of pathologically contacted or mating internal surfaces of the vertebrae of all adjacent vertebral pairs from the inside of the spine a, starting from the first upper pair of C1-C2 cervical spine to the last lower pair L4-L5 of the lumbar spine, forming a small lumen in the form of a dihedral angle, into the space of which, as it increases under the influence of constant gravity, the previously displaced fibrous ring returns intervertebral disc. In this case, the effectiveness of the traction depends both on the duration of the force of gravity applied to the spine and on the size of the load, additionally fixed to the lumbar spine using a belt covering the patient’s pelvic bone.

Before starting the procedure, the nurse puts the patient on a swimming vest, tightly wrapping his chest around the upper chest belt, fixes the lower chest belt under the sternum of the patient’s chest and fastens the load on the patient’s lower back around the patient’s pelvic bone. After that, the patient descends into the pool with a water temperature of 29-30 ° C.

A swimming vest, tightly wrapped around the chest of the patient, keeps him on the surface of the water. At the same time, the patient’s legs do not touch the bottom of the pool, the head is supported by a head restraint (pillow), the neck by a standing collar of the vest, and the patient himself is hanging by the chest on the lower waist belt. In this “hanging” position, the patient, being in zero gravity, can easily move around in the pool. The weight on the belt pulls the patient's pelvis down (to the bottom), dragging along the entire spinal column, which, being inside the chest fixed on the swimming vest, can move relative to it. At the same time, the rib-vertebral joints of the spine do not interfere with the movement of the spinal column relative to the “motionless” chest.

In addition, in the warm water of the pool, the patient’s muscles relax from the first minute the patient is immersed in water, and also do not interfere with the movement of the spinal column relative to the “immobile” chest. In this case, since the patient’s limbs are free, their passive movements in the “zero gravity” state create a side-sway effect, which stimulates a sequential, soft traction of the spinal segments from the lowest lumbosacral segment to the highest cervical segment, followed by soft mobilization of the joint blocks spine, setting simultaneously the form of lordosis in the lumbar and cervical spine.

The need to perform passive movements of the lower extremities during the traction procedure is explained by the fact that the human bone structure, including the structure of the spine, is constantly updated: cells of one type are engaged in the decomposition of bone tissue, cells of another type are engaged in its renewal. The mechanical forces, the loads that the vertebra undergoes, stimulate the formation of new cells. Increased effects on the vertebra provide accelerated formation of bone substance with a large number of bars and a denser bone substance, and vice versa, a decrease in the load causes its decay.

After 30 minutes of patient drift in the pool, the belt with the load is removed first, and then the swimming vest. The patient is in the water for another 30 minutes and swims. His limb movements are more active, which helps to strengthen the spinal traction effect obtained during the procedure. After the procedure is completed, the patient takes a shower and rests.

It should be noted that the parameters of the spinal traction procedure (the number of sessions, the duration of each session, the weight of the initial load, the weight of the maximum load, the duration of the voyage with each load, the procedure for increasing the load, etc.) are set for each patient according to the description obtained after preliminary decryption 3D image generated by a tomograph as a result of scanning his spine.

However, with large sample sizes of 3D images of the spine, a personalized approach for issuing parameters of the procedure for underwater spinal traction according to the description obtained after deciphering the presented 3D image of the patient’s vertebral section is unacceptable and it is necessary to automate it so that the parameters of the procedure for spinal traction are given to the patient by an automated system according to some a set of tomograms (slices) of the vertebral section.

When constructing an automated system, one should take into account the fact that the regimen of mass clinical examination allows one to limit the considered set of tomograms to only tomograms obtained by sections of the spine with one cutting plane and being the most informative.

In this regard, it should be noted that with magnetic resonance imaging (MRI) of the spine, especially valuable information is revealed on its sagittal sections. It is on the sagittal sections that the intravertebral neoplasms, the manifestations of hematomyelia, hydromyelia, as well as the structural manifestations of osteochondrosis and many other pathological processes are depicted.

Hence the task is to develop such an automated system that should receive, analyze, process and make decisions for each presented tomogram corresponding to a section of the spine with a sagittal secant plane.

Known systems that could be used to solve the problem [1, 2].

The first known system includes a module for receiving data of layer-by-layer slices of images of an object, a module for selecting reference addresses of records of reference layer-by-layer descriptions of slices of images of objects, a module for managing data samples of a knowledge base, a module for maintaining a database of reference layer-by-layer descriptions of slices of images of objects, a module for identifying data of layer-by-layer images of slices of objects , a module for receiving data of standard descriptions of layer-by-layer slices of images of objects, the first and second modules for modifying write and read addresses for data of the system server database, a module for integrating the signals of writing and reading data from the system database server [1].

Its disadvantage is the limited functionality of the system, due to the lack of decision on each tomogram from the resulting set of tomograms and their subsequent computer processing.

Another system is known that includes a module for selecting the reference address of the monitoring object in the server database, a module for determining the duration of time cycles for selecting layer-by-layer slices of object images, a module for generating addresses for reading layer-by-layer scan data from the server database, a module for receiving records of data for layer-by-layer scanning of object images from the database server data, a module for identifying the status of data of layer-by-layer scanning of images of objects, a module for generating a reference address for recording data layer scanning of images of objects in a server database, a module for generating current addresses of data records of layer-by-layer scanning of images of objects in a server database, a module for integrating data recording and reading signals [2].

The last of the above technical solutions is closest to the described.

Its disadvantage also lies in the limited functionality of the system, due to the lack of decision-making on each adopted and processed tomogram.

The purpose of the invention is the expansion of the functionality of the system by deciding on each tomogram received for processing.

This goal is achieved by the fact that in the system containing the identification module of the base address of the tomogram of the spine, the information input of which is the first information input of the system designed to receive the codogram of the request from the workstation of the user of the system, the synchronizing input of the identification module of the base address of the tomogram of the spine is the first synchronizing input a system designed to receive synchronization signals of entering the request codogram with automatic of the given workstation of the system user to the identification module of the base address of the tomograms of the spine, the identification module of the relative address of the tomograms of the vertebral section, the first and second information inputs of which are connected to the first and second information outputs of the identification module of the base address of the tomograms of the spine, respectively, one clock input of the identification module of the relative address of the tomograms the vertebral section is connected to the synchronizing output of the base address identification module tomograms of the spine, a module for selecting the address of tomograms of the vertebral section of the requested patient, the first information input of which is connected to the information output of the identification module of the relative address of tomograms of the vertebral department, the second information input of the module for selecting addresses of the tomograms of the vertebral section of the requested patient is connected to the third information output of the identification module of the base address of tomograms of the requested patient synchronizing input of the module of selection of the address of tomograms of the vertebral department and the requested patient is connected to the synchronizing output of the identification module of the relative address of the tomograms of the vertebral section, the information output of the selection module of the address of the tomograms of the vertebral section of the requested patient is the first address output of the system designed to provide addresses of the tomograms of the vertebral section of the requested patients to the address input of the database server synchronizing the output of the module selection of the address of the tomograms of the vertebral section of the requested patient is the first synchronization the system output intended for issuing control signals by reading the addresses of the tomograms of the vertebral section of the requested patients to the input of the first interrupt channel of the database server, the recognition module of the branch of processing tomograms of the vertebral section of the patients, the information input of which is the second information input of the system designed to receive tomograms of the vertebral section of patients read from the system server database, synchronizing the input of the recognition module of the tomogram processing branch m of the patient’s vertebral section is the second synchronizing input of the system designed to receive synchronization signals for storing tomograms of the vertebral section of patients, read from the system server database, into the recognition module of the branch processing of tomograms of the patient’s vertebral section, one synchronizing output of the module of recognition of the branch of processing of tomograms of the patient’s vertebral section the first signal output of the system intended for delivery to the user's workstation a signal system of compliance of the patient’s vertebral section with the norm, and the other synchronizing output of the recognition module of the branch processing of tomograms of the patient’s vertebral section is the second signal output of the system, designed to issue a signal to the automated workstation of the patient about the inconsistency of the patient’s vertebral section, the patient data registration module, information whose input is the third information input of the system, designed to receive patient data from the machine of the user workstation of the system, the synchronizing input of the patient data recording module is the third synchronizing input of the system designed to receive the synchronizing signals of entering patient data from the automated workstation of the system user into the patient data registration module, one information output of the patient data registration module is connected to the third information input module for identifying the relative address of the tomograms of the vertebral section, other information this output of the patient data recording module is connected to the third information input of the tomograms address module of the vertebral division of the requested patient, the synchronizing output of the patient data registration module is connected to another synchronizing input of the identification module of the relative tomograms of the vertebral department, the module for monitoring the completion of the analysis of the patient array, the information input of which connected to the fourth information output of the identification module of the base address of the tomograms pos one, the synchronizing input of the control module for completing the analysis of the patient array is connected to one synchronizing output of the recognition module for the branch processing of tomograms of the patient’s spine, one signal output of the control module for completing the analysis of the patient’s array is connected to one installation input of the module for selecting the address of the tomogram of the vertebral department of the requested patient, with one installation input of the recognition module of the branch of processing tomograms of the vertebral patients, with the second installation input of the patient data registration module, and at the same time it is the third signal output of the system, intended for issuing to the user’s automated workstation the signal of the next patient’s data input request signal, another signal output of the patient array analysis completion procedure control module is connected to another installation input of the selection module module addresses of tomograms of the vertebral section of the requested patient, with another installation input of the patient data registration module, with each m by the installation input of the recognition module for the branch processing of tomograms of the vertebral patients, with the installation input of the identification module of the base address of the tomograms of the spine and at the same time it is the fourth signal output of the system designed to issue a signal to the user of the system to complete the analysis of the patient array; the identification module of the base addresses of procedures for correction of curvature of the arch of lordosis of the vertebral patients, informational and synchronizing in the moves of which are connected to one information and another synchronizing outputs of the recognition module of the branch processing of tomograms of the vertebral patients, respectively, and a module for selecting the address of the parameters of the procedure for correcting the curvature of the arc of the lordosis of the patient’s vertebral department, one information input of which is connected to the information output of the identification module of the identification of the base address of the procedures for correcting the curvature of the arc lordosis of the vertebral patients, another information input of the selection module of the address of the process parameters the fools of curvature correction of the lordosis arch of the patient’s vertebral section is connected to another information output of the recognition module of the branch processing the tomograms of the vertebral patients, the synchronizing input of the address selection module of the curvature correction of the lordosis arc of the patient’s vertebral section is connected to the synchronizing output of the identification module of the identification of the base address of the base address of the curvature correction procedure of the lordosis of the vertebral arch Patient department, one and the other installation inputs of the selection module The curvature correction tools for the lordosis arch of the patient's vertebral section are connected to one and the other signal outputs of the control module for completing the analysis of the patient array, respectively, the information output of the module for selecting the address of the parameters for the correction of the curvature of the lordosis arc of the patient’s vertebral section is the second address output of the system designed to provide the addresses of the procedure parameters correction of the curvature of the arc of the lordosis of the vertebral patients to the address input of the database server, I synchronize the output of the selection module of the address of the parameters of the procedure for correcting the curvature of the lordosis arch of the patient’s vertebral section is connected to another synchronizing input of the control module for completing the analysis of the patient array, and this is the second synchronizing output of the system designed to provide control signals for reading the addresses of the parameters of the procedure for correcting the curvature of the arc of the lordosis of the vertebral department the patient at the entrance of the first channel interrupt the server database system.

The invention is illustrated by drawings, where in FIG. 1 is a structural diagram of a system; FIG. 2 shows an example of a specific constructive implementation of the identification module of the base address of the tomograms of the spine, in FIG. 3 is an example of a specific constructive implementation of the module for identifying the relative address of the tomograms of the vertebral section, FIG. 4 is an example of a specific constructive implementation of the module for selecting the address of the tomograms of the vertebral section of the requested patient, FIG. 5 is an example of a specific constructive implementation of a module for recognizing a branch of processing tomograms of the vertebral patients, FIG. 6 is an example of a specific constructive implementation of the base address identification module for the procedures for correcting the curvature of the arch of the lordosis of the vertebral patients, FIG. 7 is an example of a specific constructive implementation of the module for selecting the address of the parameters of the procedure for correcting the curvature of the arc of the lordosis of the patient’s vertebral section, FIG. 8 is an example of a specific constructive implementation of a patient data recording module; FIG. 9 is an example of a specific constructive implementation of a control module for completing an analysis of an array of patients.

The system (Fig. 1) contains a module 1 for identifying the base address of the tomograms of the spine, module 2 for identifying the relative address of the tomograms of the vertebral section, module 3 for selecting addresses of the tomograms of the vertebral section of the requested patient, module 4 for recognizing the branch of processing tomograms of the vertebral patients, module 5 for identifying the base address of the procedures correction of the curvature of the arc of the lordosis of the vertebral patients, module 6 selection address of the parameters of the procedure for the correction of the curvature of the arc of the lordosis of the vertebral patients coagulant, the data registration unit 7 patients completing the control unit 8 patients array analysis procedure.

In FIG. 1 shows the first 11, second 12 and third 13 information inputs of the system, the first 14, second 15 and third 16 synchronizing inputs of the system, as well as address 17-18, synchronizing 19-20 and signal 21-24 outputs of the system.

Module 1 identification of the base address of the tomogram of the spine (Fig. 2) contains a register 30, a decoder 31, a memory module 32, made in the form of read-only memory (ROM), elements 33-35 And, elements 36-37 delay. The drawing also shows information 38, synchronizing 39 and installation 40 inputs, information 45-48 and synchronizing 49 outputs.

The module 2 for identifying the relative address of the tomograms of the vertebral section (Fig. 3) contains a decoder 55, a memory module 56 made in the form of read-only memory (ROM), an adder 57, elements 58-60 AND, element 61 OR, group 62 elements OR, elements 63-64 delays. The drawing also shows information 65-67 and synchronizing 68-69 inputs, information 70 and synchronizing 71 outputs.

Module 3 selection of address tomograms of the vertebral section of the requested patient (Fig. 4) contains a register 75, a decoder 76, a memory module 77 made in the form of read-only memory (ROM), an adder 78, elements 79-81 AND, element 82 OR, group 83 OR elements and delay elements 84-86. The drawing also shows information 87-89, synchronizing 90 and installation 91-92 inputs, information 93 and synchronizing 94 outputs.

The recognition module 4 of the branch processing of tomograms of the vertebral patients (Fig. 5) contains a register 100, a comparator 101, an OR element 102, delay elements 103. The drawing also shows information 104, synchronizing 105 and installation 106-107 inputs, information 112-113 and synchronizing 114-115 outputs.

The base address identification module 5 of the procedures for correcting the curvature of the lordosis arc of the vertebral patients (Fig. 6) contains a decoder 120, a memory module 121, made in the form of read-only memory (ROM), elements 122-124 And, elements 125-126 delay. The drawing also shows information 127 and synchronizing 128 inputs, information 129 and synchronizing 130 outputs.

Module 6 of the selection of the address of the parameters of the procedure for correcting the curvature of the lordosis arch of the patient’s vertebral section (Fig. 7) contains a register 135, a decoder 136, a memory module 137 made in the form of read-only memory (ROM), an adder 138, elements 139-141 I, element 142 OR, delay elements 143-145. The drawing also shows information 146-147, synchronizing 148 and installation 149-150 inputs, information 151 and synchronizing 152 outputs.

The patient data recording module 7 (FIG. 8) comprises a register 160, an OR element 161, a delay element 162. The drawing also shows information 163, synchronizing 164 and installation inputs 165-166, information 167-168 and synchronizing 169 outputs.

Module 8 for monitoring the completion of the analysis procedure for the patient array (Fig. 9) contains a counter 170, a comparator 171, an OR element 172, a delay element 173. The drawing also shows information 174 and counting 175-176 inputs, signal 179-180 outputs.

All nodes and elements of the system are made on standard potential-impulse elements.

A remote workstation (AWP) of a system user consists of a terminal having a screen for displaying codograms of requests and system signals, and a personal computer keyboard. The presentation of readable tomograms of the vertebral patients is controlled from the server (not shown in the drawing).

The system operates as follows.

The spine and its departments have their own identification codes in the system, each of which is assigned a server database memory address, starting from which the server database information is stored in the form of a set of tomograms (digital representations) of the entire spine and its departments. At the same time, the memory address of the server database corresponding to the code of the spine is the base (initial) address relative to which the addresses of the tomograms of the vertebral sections, called relative, are shifted. The magnitude of the offset address of the tomograms of the vertebral section relative to the base address of the spine corresponds to the code of the vertebral section.

In turn, in the address space of the relative address of the vertebral section, the addresses of the tomograms of the vertebral section of the patients are distributed. The shift of the address of the patient’s vertebral section relative to the relative address of the vertebral section corresponds to the SNILS code of the patient.

This means that according to the SNILS code of the analyzed patient, the system determines the offset of the address of the tomograms of the vertebral section of this patient, which, combined with the relative address of the tomograms of the vertebral section, forms the address of the tomograms of the vertebral section of the patient, which is issued to the address input of the database server.

The server at the address at its address input reads from the memory of its database not only the tomogram of the patient’s vertebral section, but also the tomogram of the standard vertebral section, which are then forwarded by the server to the system’s information input for further analysis and processing.

The system maps the base address of the parameters of the correction procedures of the vertebral section to the tomogram of the standard vertebral section, and the tomogram of the vertebral section of the patient associates a certain address offset with respect to the base address of the parameters of the correction procedures of the vertebral section. After summing this bias with the base address of the parameters of the vertebral correction procedures, the memory address of the server database is set, in which all the parameters of the correction procedure of the patient’s vertebral section are painted.

The generated address of the parameters of the procedure for correcting the patient’s vertebral section is issued to the address input of the database server, by which the server reads the parameters of the procedure for correcting the patient’s vertebral section from its database and sends them to the user's workstation for further familiarization with the patient.

After that, the system first fixes the moment of analysis and processing of the parameters of the current patient, and then checks the completion of the analysis and processing of the patient array specified by the initial codogram of the processing request.

If the number of treated patients is less than the number of patients assigned to the system for processing, then the system asks to enter the parameters of the next patient. If the number of treated patients becomes equal to the number assigned to the system for processing, the system returns to its original state and ends its work.

To start the system, the user at his workplace generates a request codogram, which indicates the code of the spine, the code of the vertebral department, as well as the code of the insurance certificate of the first patient requested and the code of the number of requested patients to be processed (Table 1):

The generated codogram from the automated workstation of the user of the system is fed to the information input 11 of the system, fed to the information input 38 of the identification module 1 of the base address of the tomograms of the spine and entered into register 30 by a synchronizing pulse supplied to the synchronizing input 39 of module 1 from the synchronizing input 14 of the system.

The spine code from the output 41 of the register 30 is fed to the input of the decoder 31. The decoder 31 decrypts the code of the spine and generates at one of its outputs a high potential supplied to the corresponding inputs of elements 33-35 I. For definiteness, we assume that the high potential from the output of the decoder 31 will be open element 35 And one input.

In this case, the synchronizing pulse from the input 14 of the system, passing through the input 39 of the module 1, is delayed by the delay element 36 for the response time of the register 30 and the decoder 31 and enters through the open element 35 one by one input and to the read input of a fixed cell of a permanent storage device (ROM) 32.

In a fixed cell of ROM 32, the base address code of the tomograms of the spine is stored, starting from which tomograms of the vertebral departments of patients are stored in the memory of the server database. At the same time, for storing tomograms of each vertebral section in the memory of the server database, a separate memory area is allocated, the address of which is offset from the base address of the tomograms of the spine by a certain amount corresponding to the code of the vertebral section.

Therefore, the code of the vertebral section requested by the codogram from the output 46 of module 1 is sent to the information input 65 of the module 2 for identifying the relative address of the tomograms of the vertebral section, passes a group of 62 OR elements and is input to the decoder 55. The decoder 55 decodes the code of the vertebral section and generates one of its outputs a high potential arriving at the corresponding inputs of elements 58-60 I. For definiteness, let us assume that a high potential from the output of the decoder 55 will open an element 60 And one input.

In this case, the synchronizing pulse from the output of the delay element 36, delayed by the delay element 37 while reading the contents of the fixed cell of the ROM 32 of the module 1 and the operation of the decoder 55 of the module 2, is sent from the output 49 of the module 1 to the synchronizing input 68 of the module 2, the OR element 61 passes, and enters through element 60 And opened at one input and reads to a fixed cell location of a read-only memory device (ROM) 56. A fixed cell of ROM 56 stores the displacement code of the address of the tomograms of that vertebral section, whose code th has been submitted to the input of the decoder 55 with data input module 65 2.

The code for shifting the address of the tomograms of the vertebral section, read from the ROM 56, is supplied to one information input of the adder 57, to the other information input 67 of which the code of the base address of the tomograms of the spine is output from the output 45 of module 1.

According to the synchronizing pulse from the output of the OR element 61, delayed by the delay element 63 for the time of reading the fixed cell of the ROM 56, in the adder 57, the relative address of the tomograms of the vertebral section corresponding to the code of the vertebral section supplied to the decoder 55 from the information input 65 of module 2 is formed.

The code for the relative address of the tomograms of the vertebral section formed in adder 57 is, as it were, the “base” address for storing the addresses of tomograms of the vertebral section of patients who underwent an MRI examination of the vertebral section under consideration. Relative to this address, the addresses of the tomograms of the vertebral section of each patient are shifted. Moreover, the magnitude of the offset address of the tomograms of the patient’s vertebral section relative to the relative address of the tomograms of the vertebral section corresponds to the code of his insurance number of the individual personal account (SNILS).

To determine this bias, the SNILS - code of the first requested patient is supplied from the information output 47 of module 1 to the information input 87 of module 3, passes through the OR elements of group 83 and is fed to the input of the decoder 76. The decoder 76 decodes the SNILS - code of the first requested patient and generates one from its outputs a high potential arriving at the corresponding inputs of elements 79-81 I. For definiteness, let us assume that a high potential from the output of the decoder 76 will open the element 80 And one input.

In this case, the synchronizing pulse from the output of the delay element 63 of the module 2, delayed by the delay element 64 for the duration of the operation of the adder 57 of the module 2 and the decoder 76 of the module 3 and applied from the synchronizing output 71 of the module 2 to the synchronizing input 90 of the module 3, passes through the open one input element 80 And to the read input of a fixed cell of a read-only memory (ROM) 77. In a fixed cell of a ROM 77 is stored a code for shifting the address of the tomograms of the vertebral section of the patient whose SNILS is the code of which was applied to the input ifratora 76 from data input module 87 3.

The code for shifting the address of the tomograms of the patient’s vertebral section, read from the ROM 77, is fed to one information input of the adder 78, to the other information input 89 of which is the code of the relative address of the tomograms of the patient’s vertebral section from the information output 70 of module 2.

According to the synchronizing pulse from the synchronizing input 90 of module 3, delayed by the delay element 84 for the time of reading the fixed cell of the ROM 77, in the adder 78, the relative address of the tomograms of the patient’s vertebral section corresponding to its SNILS is generated, the code supplied to the input of the decoder 76 from the information input 87 of the module 3.

The address of the tomograms of the vertebral section of the requested first patient, formed in adder 78, is fed to the input of register 75, where it is entered by the synchronizing pulse from the output of delay element 84 after the delay by delay element 85 for the time of operation of adder 78.

The same pulse from the output of the delay element 85 is delayed by the delay element 86 for the time in which the tomogram address code of the vertebral section of the first requested patient is issued to the register 75, which is issued to the address output 17 of the system, and from the output 19 of the system is input to the first channel of the server interrupt.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 17 of the system, and issuing a tomogram of the vertebral section of the first requested patient to the information input 12 of the system.

The tomogram of the vertebral section of the first requested patient, read from the server database, is fed from the information input 12 of the system to the information input 104 of the register 100 of the module 4 for recognizing the branch of processing tomograms of the vertebral section of the patient, where it is entered by the synchronizing pulse of the server fed to the synchronizing input 105 of the register 100 from the synchronizing input 15 systems.

The tomogram of the vertebral section of the first requested patient, taken to the register 100, consists of two parts (Table 2):

A tomogram of the lumbar spine of the patient from the output 108 of the register 100 is fed to one information input of the comparator 101, to the other information input of which is a tomogram of a standard of the lumbar spine from the output 109 of the register 100.

Next, the tomogram of the standard of the lumbar spine from the information output 113 of the module 4 is fed to the information input 127 of the module 5 and is fed to the information input of the decoder 120. The decoder 120 decrypts the code of the tomogram of the standard of the lumbar spine and generates a high potential at one of its outputs that goes to the corresponding inputs elements 122-124 I. For definiteness, suppose that a high potential from the output of the decoder 120 will open at one input element 122 And, waiting on the other input signal permissions on the clock input 128 module 5.

In turn, the digital representation code (tomogram) of the patient’s lumbar spine from the information output 112 of module 4 is supplied to the information input 146 of module 6 and is fed to the information input of the decoder 136. The decoder 136 decrypts the digital representation code of the patient’s lumbar spine and generates on one of of its outputs, a high potential arriving at the corresponding inputs of the elements 139-141 I. For definiteness, suppose that a high potential from the output of the decoder 136 will open one input element 140 And, waiting on a different input permission signal on the clock input 148 of module 6.

According to the synchronizing pulse of the database server at the synchronizing input 105 of module 4, delayed by the delay element 103 for the response time of the register 100 and applied to the synchronizing input of the comparator 101, the comparator 101 compares the codes received at its information inputs.

If the codes of the digital representations of the standard of the lumbar spine and the lumbar spine of the patient are the same, then the output 111 of the comparator 101 produces a signal by which the signal “The vertebral spine of the patient’s spine does not require correction” is received from the signal output 24 of the system issued to the user's workstation.

In addition, the same signal from the synchronizing output 115 of module 4 is supplied to the synchronizing input 175 of module 8 to control the completion of the polling (analysis) procedure for the patient array, the OR element 172 passes and enters the counting input of the counter 170 and increments it, thereby fixing the moment of processing completion tomograms of the lumbar spine of the first patient.

Counter 170, in turn, counts the total number of patients received and processed on an accrual basis, each time outputting its contents to one information input of the comparator 171, to another information input 174 of which from the information output 48 of module 1 a code of the total number of all requested patients is submitted processing in the system.

Since the counter 170 currently recorded the completion of processing only the first patient, therefore, its contents supplied to one information input of the comparator 171 will be much less than the code of the total number of all requests for processing in the patient system, supplied to another information input 174 of the comparator 171 from the information output 48 modules 1.

In this case, a signal is generated at the output 177 of the comparator 171, which is output from the output 179 of the module 8:

- to the installation input 91 of module 3, the OR element 82 passes through and enters the installation input of the register 75, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 106 of module 4, the OR element 102 passes and enters the installation input of the register 100, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 149 of module 6, the OR element 142 passes and enters the installation input of the register 135, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 165 of module 7, the OR element 161 passes and enters the installation input of the register 160, resets its contents to zero and thereby prepares it for a new operation cycle.

By this signal, the request signal “Enter the parameters of the next patient” is removed from the synchronizing output 179 of module 8, which is issued from the signal output of the system 21 to the user workstation.

If the codes of digital representations of the standard of the lumbar spine and the lumbar spine of the patient do not match, then the output 110 of the comparator 101 produces a signal by which the signal "The vertebral spine of the patient's spine requires correction" is received from the signal output 23 of the system issued to the user's workstation.

In addition, the same signal from the synchronizing output 114 of module 4 is supplied to the synchronizing input 128 of module 5, is delayed by the delay element 125 for the response time of the decoder 120, and passes through the And 122 element, which is open at one input, and is fed to the read input of a fixed cell of a permanent storage device ( ROM) 121. In a fixed cell of ROM 121, the code of the base address of the procedures for the correction of lordosis of the vertebral department is stored, starting with which the information on the parameters of the correction procedures is stored in the memory of the server database and lordosis of the spinal card.

The base address code of the procedures for correction of lordosis of the vertebral section, read from ROM 125, is supplied from the information output 129 of module 5 to one information input 147 of adder 138 of module 6, the bias code read from the ROM 137 and corresponding to the digital representation code of the patient’s lumbar spine supplied to the input of the decoder 136 of the module 6 from the information output 112 of the module 4.

The synchronizing pulse from the output of the delay element 125, delayed by the delay element 126 for the time of reading the fixed cell ROM 121 of the module 5 and the operation of the decoder 136 of the module 6, coming from the synchronizing output 130 of the module 5 to the synchronizing input 148 of the module 6, passes through the element And open through one input 140 and is fed to the read input of a fixed cell ROM 137. In a fixed cell ROM 137 is stored a code for shifting the address of the parameters of the procedure for correcting the arc of lordosis of the vertebral section of the patient, fed to information th input of adder 138.

According to the synchronizing pulse at the synchronizing input 148 of module 6, delayed by the delay element 143 for the read time of the fixed cell ROM 137, the adder 138 generates the relative memory address of the server database in which the parameters of the procedure for correcting the arc of the lordosis of the vertebral spine of the patient are stored.

The relative memory address of the server database formed in adder 138, which stores the parameters of the procedure for correcting the lordosis arch of the patient’s spinal column, is fed to the information input of register 135, where it is entered by the synchronizing pulse from the output of the delay element 143 after the delay by the delay element 144 for the duration of the adder 138.

The same pulse from the output of the delay element 144 is delayed by the delay element 145 for the time of recording in the register 135 the code of the relative address of the parameters of the procedure for correction of the lordosis arch of the vertebral spine of the patient, issued to the address output 18 of the system, and from the output 20 of the system is fed to the input of the first server interrupt channel .

With the arrival of this impulse, the server switches to the subprogram for interrogating the contents of its database at the address generated on the address output of the system 18 and issuing the read code for the parameters of the procedure for correcting the arch of the lordosis of the vertebral spine of the patient’s spine to the user's workstation for direct familiarization with the patient himself.

The same pulse from the output 152 of module 6 is supplied to the counting input 176 of module 8, the OR element 172 passes and enters the counting input of the counter 170 and increments it, thereby fixing the next unit corresponding to the completion of processing of the parameters of the next patient.

The counter 170 counts on an accrual basis the number of patients received and processed, each time outputting its contents to one information input of the comparator 171, to the other information input 174 of which from the information output 48 of module 1, the code of the total number of all requested patients to be processed in the system is supplied.

If the contents of the counter 170 supplied to one information input of the comparator 171 will be much less than the code of the total number of all requested for processing in the patient system, supplied to another information input 174 of the comparator 171 from the information output 48 of module 1, a signal is generated at the output 177 of the comparator 171 which is output from the output 179 of module 8:

- to the installation input 91 of module 3, the OR element 82 passes through and enters the installation input of the register 75, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 106 of module 4, the OR element 102 passes and enters the installation input of the register 100, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 149 of module 6, the OR element 142 passes and enters the installation input of the register 135, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 165 of module 7, the OR element 161 passes and enters the installation input of the register 160, resets its contents to zero and thereby prepares it for a new operation cycle.

By this signal, the request signal “Enter the parameters of the next patient” is removed from the synchronizing output 179 of module 8, which is issued from the signal output of the system 21 to the user workstation.

With each request to enter the parameters of the next patient, the user of the system from his workplace sends the parameters of the next patient to the information input 13 of the system (Table 3):

The parameter code of the next patient from the information input 13 of the system enters the information input 163 of the register 160 of module 7, where it is entered by the synchronizing pulse supplied to the synchronizing input 164 of module 7 from the synchronizing input 16 of the system.

The received code of the vertebral section of the next patient from the information output 167 of module 7 is sent to the information input 66 of module 2, passes through the OR elements of group 62 and goes to the input of the decoder 55. The decoder 55 decodes the code of the vertebral section and generates a high potential at one of its outputs to the respective inputs of elements 58-60 I. For definiteness, suppose that high potential from the output of the decoder 55 will open element 59 And at one input. On another input, element 59 And will be open when a permission signal arrives at the synchronizing inputs 68-69 of module 2.

At the same time, the obtained SNILS - code for the next patient from the information output 168 of module 7 is sent to the information input 88 of module 3, passes through the OR elements of group 83 and goes to the input of the decoder 76. The decoder 76 decodes the SNILS - code of the next patient and generates on one of its high potential output coming to the corresponding inputs of elements 79-81 I. For definiteness, suppose that high potential from the output of the decoder 76 will open element 79 And one input. At a different input, element 79 And will be open when a permission signal arrives at the clock input 90 of module 3.

The pulse of starting a new cycle of processing the parameters of the next patient is a synchronizing pulse at the synchronizing input 164 of module 7, which is delayed by the delay element 162 for the response time of the register 160 of module 7 and from the synchronizing output 169 of module 7 is supplied to the synchronizing input 69 of module 2, the OR element 61 passes, and , passing through the element 59 And open at one input, it is fed to the read input of another fixed cell in the ROM 56.

This fixed cell of the ROM 56 stores the code for shifting the address of the tomograms of another vertebral section, the code of which was supplied to the input of the decoder 55 from the information input 66 of module 2.

The code for shifting the address of the tomograms of the other vertebral section, read from the ROM 56, is supplied to one information input of the adder 57, to the other information input 67 of which the code of the base address of the tomograms (digital representations) of the spine is output from the output 45 of module 1.

According to the synchronizing pulse from the output of the OR element 61, delayed by the delay element 63 for the time of reading the fixed cell of the ROM 56, in the adder 57, a new relative address of the tomograms of the vertebral section is formed corresponding to the code supplied to the input of the decoder 55 from the information input 66 of module 2.

The code of the relative address of the tomograms of the vertebral section formed in adder 57 from the information output 70 of module 2 is sent to one information input 89 of adder 78 of module 3. The address offset code corresponding to the SNILS code of the new patient and read from a fixed ROM cell is sent to the other information input of adder 78 77 by the pulse at the clock input 90 of the module 3, received from the clock output 71 of the module 2. This pulse from the clock input 90 of the module 3 passes through the element And 79 open at one input and, entering the read input of a fixed cell ROM 77, reads its contents, issued to another information input of the adder 78.

The address of the tomograms of the vertebral section of the other requested patient, formed in adder 78, is fed to the input of register 75, where it is entered by the synchronizing pulse from the output of delay element 84 after delay by delay element 85 for the time of operation of adder 78.

The same pulse from the output of the delay element 85 is delayed by the delay element 86 for the time in which the tomogram address code of the vertebral section of the other requested patient is entered into the register 75 and is sent to the address output 18 of the system, and from the output 20 of the system it enters the input of the first server interrupt channel.

With the arrival of this impulse, the server switches to a subprogram for interrogating the contents of its database at the address generated on the address output 18 of the system and issuing tomograms of the vertebral section of the other requested patient to the information input 12 of the system.

The described process of generating the addresses of tomograms of the vertebral section of patients using the SNILS code of each patient, followed by their selection from the memory of the server database in order to recognize the need for correction of the patient’s vertebral section and selecting parameters for the procedure for underwater spinal traction, will continue until the system processes the tomograms of the vertebral department of all patients defined by the initial request codogram. This will happen when the contents of the counter 170 of module 8, supplied to one information input of the comparator 171, will be equal to the code of the number of all patients requested for analysis and processing coming to the other input 174 of the comparator 171 from the information output 48 of module 1.

If the codes are equal at the information inputs of the comparator 171, a signal will be generated at its output 178, which, firstly, immediately arrives at the installation input of the counter 170, returning it to its original state.

Secondly, this signal from the output 180 of module 8 is supplied:

- to the installation input 92 of module 3, the OR element 82 passes through and enters the installation input of the register 75, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 107 of module 4, the OR element 102 passes and enters the installation input of the register 100, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 150 of module 6, the OR element 142 passes and enters the installation input of the register 135, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 166 of module 7, the OR element 161 passes and enters the installation input of the register 160, resets its contents to zero and thereby prepares it for a new operation cycle;

- to the installation input 40 of module 1 and enters the installation input of the register 30, resets its contents to zero and thereby prepares it for a new operation cycle.

Thirdly, according to this signal, the signal “Analysis and processing of tomograms of the vertebral sections of the patient is completed” is removed from the output 180 of module 8, which is output from the signal output 22 of the system to the user's workstation.

Thus, the introduction of new nodes and modules and new structural connections allowed us to significantly expand the functionality of the system by deciding on each tomogram received for processing.

Sources of information taken into account when drawing up the description of the application:

1. RF patent №125366 (05.06.2012).

2. RF patent No. 146670 (10.20.2014) - (prototype).

3. http://www.onclinic.ru.

4. Tretyakov S.S. An innovative method of underwater spinal traction as an alternative to surgical treatment of intervertebral hernias // Innovations and Investments. - 2014. - No. 2. - S. 34-38.

Claims (1)

A system for monitoring parameters of procedures for correcting the curvature of the arches of the lordosis of the spine, containing a module for identifying the base address of the tomograms of the spine in the database of the system server, the information input of which is the first information input of the system designed to receive the request codogram from the workstation of the system user, synchronizing the input of the base address identification module tomograms of the spine in the system server database is the first synchronizing system input, p designed to receive the synchronization signals of entering the request codogram from the workstation of the system user into the identification module of the base address of the tomogram of the spine in the database of the system server, the module of identification of the relative address of the tomogram of the spine in the database of the system server, the first and second information inputs of which are connected to the first and the second information outputs of the identification module of the base address of the tomograms of the spine in the database of the server system respectively Actually, one synchronizing input of the identification module of the relative address of the tomograms of the spinal column in the system server database is connected to the synchronizing output of the identification module of the base address of the tomograms of the spinal column in the system server database, the module for selecting the address of the tomograms of the spinal column of the requested patient in the system server database, the first information input which is connected to the information output of the identification module of the relative address of the tomograms of the spine in the database x the system server, the second information input of the module for selecting the address of the tomograms of the spine of the requested patient in the database of the system server is connected to the third information output of the module for identifying the base address of the tomograms of the spine in the database of the system server, synchronizing the input of the module for selecting the address of the tomograms of the spine of the requested patient in the database the server of the system is connected to the synchronizing output of the identification module of the relative address of the tomograms of the spine in the database e of the server’s data, the information output of the tomograms module of the address of the spine department of the requested patient in the database of the server system is the first address output of the system designed to provide the addresses of tomograms of the spine department of the requested patients to the address input of the database server, which synchronizes the output of the module of selection of the address of the tomograms of the spine department of the requested patient in the system server database is the first synchronizing system output intended for issuing a signal tomograms for reading the addresses of the tomograms of the spinal column of the requested patients from the system server database to the input of the first interrupt channel channel of the database server, the recognition module for the processing branch of tomograms of the patient spinal column, the information input of which is the second information input of the system for receiving tomograms of the spinal column of patients from the system server database, synchronizing the input of the recognition module of the branch of processing tomograms of the spine number of patients is the second synchronizing input of the system, intended for receiving synchronizing signals of entering tomograms of the patient’s spinal column, read from the database of the server of the system, into the recognition module of the processing branch of the tomograms of the patient’s spine, one synchronizing output of the recognition module of the processing of tomograms of the patient’s spinal column is the first signal output systems designed to issue a signal of conformity to the user's workstation the patient’s spine department is normal, and the other synchronizing output of the recognition module of the branch processing of tomograms of the patient’s spine department is the second signal output of the system, designed to issue a signal to the automated workstation of the user of the patient’s spinal column department, the patient data recording module, the information input of which is the third information input of the system, designed to receive patient data from an automated work There is a user of the system, the synchronizing input of the patient data recording module is the third synchronizing input of the system designed to receive the synchronizing signals of entering patient data from the workstation of the system user into the patient data registration module, one information output of the patient data recording module is connected to the third information input of the identification module the relative address of the tomograms of the spine in the system server database, another info the output of the patient data registration module is connected to the third information input of the tomogram address selection module of the spine department of the requested patient in the system server database, the synchronization output of the patient data registration module is connected to the other synchronization input of the identification module of the relative spine department tomograms in the system server database, module control of the completion of the analysis procedure for an array of patients whose information input is connected to the fourth information to the output of the identification module of the base address of the tomograms of the spine in the database of the system server, one synchronizing input of the control module for completing the analysis of the patient array is connected to one synchronizing output module for recognizing the branches of the processing of tomograms of the patient's spine, one signal output of the control module for completing the analysis of the patient array is connected to one installation input of the selection module of the address of the tomograms of the spine of the requested patient in the database system rver, with one installation input of the recognition module for the branch processing of tomograms of the patient's spine department, with one installation input of the patient data registration module, and at the same time it is the third signal output of the system designed to issue a data input request signal for the next patient to the automated workstation of the system, another the signal output of the control module for completing the analysis of the patient array is connected to another installation input of the tomogram address selection module of the spinal column of the requested patient in the system server database, with a different installation input of the patient data recording module, with another installation input of the recognition module of the tomogram processing branch of the patient spine department, with the installation input of the identification module of the base address of the spinal tomogram in the system server database and the fourth signal output of the system, intended for delivery to the automated workstation of the user of the system a signal of completion of the procedure anal from an array of patients, characterized in that the system contains a module for identifying the base address of the parameters of the procedure for correcting the curvature of the lordosis arch of the patient’s spine in the database of the system server, the information and synchronizing inputs of which are connected to one information and other synchronizing outputs of the recognition module of the tomogram processing branch of the patient’s spine accordingly, the module for selecting the address of the parameters of the procedures for correcting the curvature of the lordosis arch of the patient’s spine the database of the system server, one information input of which is connected to the information output of the identification module of the base address of the parameters of the procedure for correcting the curvature of the arch of the lordosis of the patient's spine in the database of the system server, the other information input of the module of the selection of the address of the parameters of the procedure of correcting the curvature of the arc of lordosis of the patient's spine in the database the server of the system is connected to another information output of the recognition module of the branch of processing tomograms of the patient spine, The synchronizing input of the address selection module for the parameters of the procedure for correcting the curvature of the arch of the lordosis of the spinal column of the patient in the system server database is connected to the synchronizing output of the identification module for the base address of the identification module for the identification of the base address of the parameters of the procedures for the correction of the curvature of the arc of lordosis of the patient's spine in the database of the system server. the parameters of the procedure for correcting the curvature of the lordosis arch of the patient’s spinal column in the system server database are connected to one and the other to the signal outputs of the control module for completing the analysis of the patient array, respectively, the information output of the selection module for the address of the procedure for correcting the curvature of the arch of the lordosis of the spinal column of the patient in the database of the server system is the second address output of the system designed to provide the addresses of the parameters of the procedure for correcting the curvature of the arc of the lordosis of the spinal column of patients to the address input of the database server that synchronizes the output of the selection module of the address of the parameters of the correction procedures to In the database of the server server, the arc of the lordosis arc of the patient’s spinal column is connected to another synchronizing input of the control module for completing the analysis of the patient’s array, and this is the second synchronizing output of the system designed to provide control signals by reading the addresses of the parameters of the procedures for correcting the curvature of the lordosis of the patient’s spinal column from the database system server data to the input of the first channel of the system database server interrupt.

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