RU2154985C1 - Method for determining chest deformity degree - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves applying computer tomography examination of anterior surface of the chest when setting the patient with his back to reference surface. Anatomically outstanding bone reference objects are detected and profiles of the surface under study are built in horizontal cross-section. Graphic presentation of the surface as axonometric projection is produced. The so obtained chest surface cross-section images are used for determining the sternocostal fossa depth. The value being equal to 175-160 deg, I stage chest deformity is to be diagnosed. The value being less than 160 deg, II-III stage chest deformity is to be the case. EFFECT: enhanced accuracy of diagnosis. 4 dwg, 1 tbl

Description

 The invention relates to medicine, namely to methods for visual diagnosis of biomechanical changes in the musculoskeletal system, and can be used in pediatric surgery, orthopedics and rehabilitation.

 One of the options for the pathology of cartilage and connective tissue is congenital deformation of the chest. Questions regarding its diagnosis and correction have a long history and sufficient experience.

 A known x-ray method for diagnosing chest deformity, which consists in the fact that a patient with chest deformity is performed x-ray of the chest in two projections. In a straight line, the position of the heart, the state of the pulmonary system are assessed, and a lateral projection is necessary to identify the degree of deformation of the chest (Gizycka I., 1962). The disadvantage of this method is significant radiation exposure does not allow for a detailed examination and dynamic observation.

 The closest way to the claimed is a method of computer optical topography of the body surface (Traumatology and Orthopedics, 1994, N 3, S. 43-51). This method is based on the use of optical projection of bands and spatial phase detection for computer processing of primary information, which allows determining the shape of the examined surface with high accuracy and spatial resolution.

The computer processing method is used for non-contact study of spinal deformity of various age groups. The software package is integrated to perform functions such as
- input of images of examined patients,
- the selection of reflective markers on the original image,
- spatial phase detection of the bands,
- restoration of the shape of the surface,
- interactive graphical analysis of the surface shape,
- construction of the output form of sagittal analysis,
- construction of the output form of profile analysis.

The disadvantage of the prototype is that a graphical analysis of only the posterior surface of the body is performed, and to study the topography of the anterior surface of the chest, it is necessary to introduce additional parameters, such as the allocation of new installation markers, comparing them with the anatomical bone landmarks; construction of a profile analysis based on horizontal sections at any level
The objective of the present invention is to improve the accuracy and completeness of information, as well as accelerate the diagnosis of deformation of the chest.

This object is achieved by performing a computer topography of the anterior surface of the chest when the patient is placed with his back to the reference surface, the size of the sterno-rib recess is determined from the images of horizontal profile sections of the surface of the chest, and conservative treatment is carried out with its value 175-160 ^o to stabilize the process, and when the angle is less than 160 ^o carry out surgical correction.

 The novelty of the method.

 1. We perform the study when installing the patient with his back to the reference surface, which ensures the determination of the relief of the front surface of the chest.

 2. The sternal-rib groove (GRU) - an osteo-cartilaginous formation of an arcuate shape, consisting of interconnected rib cartilages with grooves on the lateral edges of the sternum, form an angle consisting of lines drawn tangentially to the projection on profile sections with an apex in itself an approximate point to the reference surface (Fig. 1a, b; tablea).

 3. By the method of screening patients, the relative values of this angle are determined.

4. The value of 175-160 ^o is physiological for the sternum-rib recess. Patients of the correct physique. Visually, anatomical defects requiring surgical correction are not determined. There is no history of chronic diseases of the respiratory and cardiovascular systems, but this group of patients undergoes a course of physiotherapy to form the muscular skeleton of the upper shoulder girdle.

When the value is less than 160 ^o there is a deformation of the chest, which is determined not only visually, but also confirmed by the data of computer topography. Given the anatomical and cosmetic defect, as well as the presence of a history of chronic diseases, surgical treatment of chest deformity is indicated.

 5. The degree of chest deformity in terms of GRU has not been used previously in the diagnosis of chest deformity as a factor determining the further management tactics of the patient.

The image is illustrated by drawings where:
in FIG. 1a and 1b show the sternal-rib recess on a horizontal profile section and the formation of the angle S1CS2;
in FIG. 2a, 2b, 2c, 2d shows a series of images, including an axonometric and moire pattern, as well as a series of horizontal profile sections;
in FIG. 3a, 3b, 3c, 3d, deformation of the sternum is noted in the same graphic image of the anterior surface, but in a patient with a funnel-shaped deformation of the chest;
in FIG. 4 shows a diagram of the marking of the anterior surface of the chest.

 The essence of the method is as follows. Using the optical method of band projection and spatial phase detection for computer processing of primary information, it is possible to determine the shape of the examined surface with high accuracy and spatial resolution. To implement the method of projection of strips in the system, an optical scheme with a horizontal arrangement of a projector and a TV camera was used, i.e. their optical axes lie in one horizontal plane. The camera and the projector are mounted on the same rack, which has mechanisms for accurately aligning their orientation in space. Using slides, an image of vertically oriented light and dark stripes is projected onto the surface to be examined and the reference plane. The reference plane is represented by a vertically oriented opaque screen.

 The research procedure is as follows.

 Before examination, anatomically distinguished bone landmarks are determined on the anterior surface of the chest, onto which 3 x 3 mm markers are glued. A different degree of reflection of the skin and markers provides a contrast of their image in the picture.

The following scheme for marking the anterior surface of the chest has been applied (Fig. 4):
top point in the middle of the jugular notch (A);
the midpoint is in the projection of the xiphoid process (B);
the connection of these lines forms the line AB (linia stemalis).

Additional markers:
for each rib, starting from the 2nd rib, 6-7 ribs along the parasternal line on both sides, forming lines PSs and PSd (linia parasternalis sinistra, dextra).

Installation Markers:
the protruding part of the ilium on the right is SIASD,
the protruding part of the ilium on the left is SIASS.

A full description of the restored front surface of the chest is possible in three forms:
axonometric projection (Fig. 2A, 3A),
in the form of a moire pattern of the front surface of the chest (Fig. 2b, 3b) the preparation of the surface curvature in any plane of the slice at different levels (Fig. 2c, 2d, Fig. 3c, 3g).

 After the examination, profiles of the examined surface are built in horizontal section at any level. The construction of this profile provides the necessary information and is the main study of the chest.

 The construction of a complete graphical representation of the examined surface in the form of an axonometric projection is also being carried out. Moreover, the construction can be performed by choice from four directions: left, right, top, bottom. The image is shown in FIG. 2a and 3a. This presentation of the chest is not so informative and is in addition to a visual assessment of the shape of the chest. However, it is most readable by patients and their parents.

 One of the important points of this method is the possibility of dynamic monitoring of the patient. This will reveal the nature and rate of increase in chest deformity, make timely corrections to the treatment tactics and, if necessary, optimally plan the surgical intervention.

 Considering that changes during chest deformation are predominantly in the horizontal plane and they coincide with horizontal profile sections that accurately convey the shape of the chest, we stopped working on these sections as the most informative and containing the necessary information. Sections are set arbitrarily at different levels, and after graphic processing, the most deformed profile is selected, according to which a conclusion is made about the degree of deformation of the chest.

 Curve processing consists in searching for the most approximate central point (C) - FIG. 1a, 1b - on the curve with respect to the main plane and two points (S1, S2), as far as possible from the plane. Central is located on the sternum, and removed on both sides of it. A line (CD) is drawn through point C perpendicular to the main plane. Then we connect the points C and S1, C and S2, we get the angle S1-C-S2, hereinafter referred to as the sterno-rib groove. The perpendicular CD divides the GRU into two angles, characterizing the degree of symmetry of the chest. They are identical in magnitude with symmetrical deformation and different with asymmetric.

GRU values determine not only the presence of chest deformity, but also the degree, which allows a differentiated approach to treatment tactics. GRU values:
1st degree --- 175-160 ^o ,
2nd degree --- 160-150 ^o ,
3rd degree --- 150-140 ^o and less.

With a deformation of the chest of the 1st degree (175-160 ^o ), a conservative tactics of patient management may be sufficient, including a combination of physiotherapy, massage and hydrotherapy, and with the 2nd and 3rd degrees of deformation, surgical correction of the chest is indicated.

 Example 1. Plotnikova A.Yu., 9 years old.

 Was in the department of pediatric orthopedics with a diagnosis of contusion of the thoracic spine.

 With an objective examination, the chest shape is correct, there are no complaints from parents and the child about the shape of the chest.

 Optical topography of the back and chest was performed.

The patient is set with his back to the reference surface, the chest is taken. The study of axonometric projection reveals deformation not visible to the eye. Analysis of horizontal profile sections from the sternum handle to the xiphoid process shows not only the presence of deformation, but also its severity. GRU is equal to 170 ^o , which corresponds to the 1st degree of deformation, the difference in the angles forming the GRU, indicates the asymmetry of the chest.

 In FIG. 2a, 2b, 2c, 2d shows a series of images, including an axonometric and moiré picture, as well as a series of horizontal profile sections. The data obtained indicate the absence of deformation from the chest in the patient. Therefore, even slight changes in the shape of the chest that are not detected by visual inspection, due to the high resolution of the method of computer optical topography, can be determined. This degree of deformation does not require surgical correction. The data obtained allow dynamic monitoring of the patient, as well as a course of therapeutic exercises, hydrotherapy and tonic massage, aimed at strengthening the muscular frame of the upper shoulder girdle.

 Example 2. Burlev D.V., 9 years.

 Located in the department of pediatric orthopedics with a diagnosis of congenital funnel-shaped chest deformity, symmetrical 3rd degree.

 Complaints of chest deformity.

Optical topography of the back and chest was performed. The patient is installed with his back to the reference surface, reflective markers are fixed on the front chest cage according to the given scheme. GRU is 140 ^o , which corresponds to the 3rd degree of deformation of the chest. A lowered perpendicular through the top of the corner divided it into two angles of the same magnitude, which indicates a symmetrical deformation.

 Conclusion: congenital funnel chest deformity of the 3rd degree, symmetrical.

In FIG. 3a, 3b, 3c, 3d shows a funnel chest deformity with a GRU value of less than 160 ^o .

 In this case, the patient is shown surgical treatment to eliminate chest deformation.

 Thus, the method of optical topography allows you to examine the chest and presents an opportunity to compare with the pathology of the spine.

 The method is harmless to the patient, quickly executable, saves data for further dynamic observation.

Computer optical topography has a number of advantages over the X-ray examination method:
- complete harmlessness for the patient and staff,
- full automation of the process of inputting images of patients and their processing to obtain examination results,
- three-dimensional nature of the results obtained from one image of the patient in the frontal plane,
- high processing speed, providing results at the time of examination of patients,
- the ability to save the survey results in a database,
- the ability to create a fully automated data analysis and the ability to dynamically track it.

Claims (1)

A method for determining the degree of deformation of the chest, including computer optical topography of the body surface, characterized in that they perform topography of the front surface of the chest when the patient is placed with his back to the reference surface, anatomically distinguished bone landmarks are made, and then profiles of the examined surface are built in horizontal section and then a graphical representation of this surface in the form of an axonometric projection, determine the value of the sterno-rib angle from the curve Lenia and magnitude recesses 175 - 160 ^o determine 1st degree of deformation of the chest, and at a value less than 160 ^o - 2 and the third degree.

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