UA17539U - Method for generating imprints of individual orthopedic insoles - Google Patents

Abstract

The method for generating the imprints of the individual orthopedic insoles provides for the use of two chambers with elastic surface filled with the flowing medium and adapted to the load due to the weight of the patient. The method consists in previous heating of at least one elastic surface to the temperature of plastic deformation. Then the half-finished product is applied to the elastic surface of the chamber and kept under the load of the patient's weight until the loss of the plasticity in the imprint. The physiological position of the patient is provided by controlling the pressure of the flowing medium. The air used as the flowing medium. The pressure is controlled until the correct standing position of the patient where the imaginary line between the upper points of the wings of ilium is horizontal.

Description

Description of the invention

The useful model relates to the field of medicine, namely orthopedics or traumatology, and can be used 2 in the manufacture of individual orthopedic insoles for the correction and compensation of deformed feet, for example, clubfoot, flat feet, the presence of a diabetic foot, in the absence of a part of the foot, for any relief painful places of the foot, or to correct different length or width of the feet, or to correct the functional difference in the length of the lower limbs, etc. A useful model can be particularly useful in correcting foot pathologies in children caused by cerebral palsy. 70 Methods of forming individual orthopedic insoles based on the formed negative impression are known and still used (USSR copyright Mo316442, Russian patent Mo2085156, 1997, patent

RF 2094030, 1997, RF patent Mo2147850, 2000, RF patent Mo21811562, 2000, PCT application M/O Mo00/44251, 2000, Ukrainian patent Mo46116, 2000). During the production of a negative impression, the patient stood in a container with gypsum solution until the solution solidified. Filatova V.YI., L., 12 Medicine, 1978). Then plastered bandages were used instead of gypsum solution. This method is described in the author's certificate of the USSR Mo316442. Bandages are laid out on an elastic hydrocushion and loaded with the patient's foot. The obtained negative prints are dried, tried on, and positive ones are formed from the negative prints, which are then used to reproduce the insoles. This method is uneconomical due to double costs of material and time for time-consuming operations related to obtaining and drying the negative print, filling | drying the positive print, adjusting the insole and gluing compensators. In addition, the method is fundamentally imprecise and cannot ensure the formation of impressions of insoles for patients with different limb lengths.

With the emergence of new thermoplastic materials, in order not to keep patients in a plaster solution or on plastered bandages, which is often harmful to health, it was proposed to use thermoplastic materials for the manufacture of individual orthopedic insoles by hydrotechnical molding into blanks. To make impressions of orthopedic insoles heated to the temperature of plastic deformation, the workpiece is placed on the elastic surface of the hydrocushion and loaded directly by the patient's foot, as described, for example, in Ukrainian patents for the utility model Mo55316, 2003, and for the invention Mo25304, 1998.

The method for manufacturing individual orthopedic insoles is carried out using a device that contains a chamber or two chambers connected together as connected vessels and adapted to load them with the patient's weight. They are filled with water inside. The patient stands on the elastic surface with his feet, the load from his weight is evenly distributed over the entire plane of the foot, which causes an impression to be obtained, close to the anatomical structure of his foot. However, this method is not suitable for forming impressions of individual orthopedic insoles of patients with different lengths of lower limbs or curvature of the spine, as it does not ensure 3o obtaining impressions from which insoles would be obtained, the shape of which would provide compensation for this pathology. --

The reason is that the device does not take into account and does not equalize the different pressure of the feet on the workpieces, caused by the shift of the center of gravity due to the curvature of the spine or different lengths of the lower limbs. This leads to the formation of an inaccurate impression and the discrepancy of the formed insole with the actual requirements of the patient. The inaccuracy of the insole formation is also affected by the large modulus of volumetric elasticity of water, which C is practically incompressible and cannot respond to barely noticeable features of the foot, which is repeated by the elastic surface of the hydrocushion.

From" For correcting the patient's weight and muscle tone and the impact of the pillow material on the accuracy of the impression, in the patent

Мо55316 of Ukraine is proposed to raise the pressure in the pillow cavity even more, which not only does not increase the accuracy of the forming method, but additionally reduces it. The described method of forming impressions of orthopedic insoles is especially unsuitable for patients with different limbs, deviations in the proportions of the body, patients with scoliosis, etc., because there is no compensation for orthopedic pathologies. The method is also unsuitable for making insoles for diabetic patients, who usually have increased weight, insensitive skin on the soles, presence of angiopathy and pressure zones in the Charcot foot. i-th The closest to the claimed method of forming impressions of individual orthopedic insoles is the so 20 method described in Ukrainian patent Mo4320, 2005, in which an attempt is made to correct the patient's position.

The method is carried out on two chambers, each of which has an elastic surface filled with water and adapted to the load of the patient's weight, that is, the size of the elastic surface of the chambers is slightly larger than the area of the patient's foot, and these elastic surfaces can withstand his weight without destruction. The patient is placed with his feet on the indicated elastic surfaces, loading them with the weight of the patient's body. If the patient has a pathology, 29 for example, scoliosis or different limb lengths, different pressures arise in the chambers, caused by different loads on the left and right parts of the body due to the shift of the center of gravity. By equalizing the pressure in the cavities, they achieve a shift of the center of gravity to the axis of symmetry and thus achieve a state of equilibrium of the left and right parts of the body, that is, the physiological correct position of the patient who is standing. Next, preheated to the temperature of plastic deformation blanks of thermoplastic 60 material are applied to the elastic surfaces of the chambers, the patient is again placed with his feet on these surfaces and kept in this condition for the time required for the resulting impression to lose its plasticity.

The described method should be more accurate, as it involves the formation of impressions in the patient's condition, when the pressure in both chambers is the same. But, if the orthopedic pathology is large, for example, there is no part of the foot, just by equalizing the pressure in the chambers when the patient's body is loaded, it is not possible to achieve compensation for the orthopedic pathology. In addition, the rise of water pressure in the chambers reduces the sensitivity of the elastic surface due to the inability of water to compress, which causes the elastic surface to swell and reduce its covering capacity. Therefore, when forming individual orthopedic insoles for patients with diabetes, patients who have a lot of weight, children of low weight with scoliosis, etc., it is not always possible to achieve the desired accuracy of the obtained impression.

The basis of a useful model is the task of improving the method of forming impressions of individual orthopedic insoles, in which, by using air in elastic chambers as a fluid medium and more precisely determining the physiologically correct position of the patient, a greater correspondence of the obtained impressions to the needs of patients is achieved, regardless of existing pathologies, while ensuring a sense of comfort and the absence of unpleasant sensations in the process of forming prints. 70 The task is solved by the fact that, as in the known method of forming impressions of individual orthopedic insoles, it is carried out on two chambers, each of which has an elastic surface, filled with a fluid medium and adapted to the load of the patient's weight. The claimed method, as well as the known method, consists in placing on at least one specified elastic surface a workpiece made of thermoplastic material preheated to the temperature of plastic deformation, loading the specified /5 elastic surfaces with the patient's body weight, adjusting the pressure of the fluid in at least one chamber for placing the patient in the correct physiological position and holding the specified workpiece under load for the time required for the resulting impression to lose its plasticity. What is new in the claimed useful model is that air is fed into the chambers as a fluid medium, while the air pressure in the chambers is adjusted to occupy a standing patient, a position in which the conventional straight line, between the upper 2o points of the wings of the pelvic bones, has horizontal direction. Air has a much lower modulus of elasticity than water, so it compresses under force much more easily and covers the patient's feet more tightly. This is especially important for patients with "diabetic foot syndrome", who need a very careful selection of insoles and, at the same time, gentle treatment of the feet. If the patient has a functional difference in the length of the lower limbs, the pelvic bones on the side of the longer limb are shifted upwards. The displacement of the pelvic bones causes a curvature of the spine and a displacement of the center of gravity from the conventional center of symmetry of the patient, which leads to uneven pressure on the soles of the limbs, which, under the influence of the pressure difference, are deformed depending on the load difference. t

By adjusting the air pressure in the chambers, it is possible to very accurately expose the patient to the correct physiological position, which is controlled by the location of the upper points of the wings of the pelvic bones.

The advantage of the method is the sequence of its implementation, in which orthopedic pathologies are first detected Ge! and weight of the patient, then in the cavities of the specified chambers, the same air pressure is created, the value of which depends on the orthopedic pathology and the weight of the patient, before applying the blanks to the elastic surfaces and forming impressions. At the same time, pressure regulation in the chambers is carried out, preferably, before placing the workpieces on elastic surfaces. However, it is possible to implement a method in which the pressure in the chambers is adjusted after placing the blanks on the elastic surfaces during the formation of impressions. in.

The method can be successfully implemented not only in the preliminary determination of orthopedic pathologies, but also in the case when orthopedic pathologies are detected when elastic surfaces are loaded with the patient's body weight.

At the same time, it is possible to detect orthopedic pathologies and adjust the pressure before applying blanks and forming impressions, or after applying blanks in the process of forming impressions.

Regardless of the chosen sequence of actions, it is preferable to perform the method when the pressure adjustment is carried out taking into account the subjective feelings of the patient. If the patient has different lengths of the lower limbs, the difference in the length of the limbs is corrected by increasing the pressure in the chamber on which the shorter limb is located, or reducing the pressure in the chamber on which the longer limb is located. ;" In the presence of diabetic disease and/or low weight of the patient, choose blanks made of softened thermoplastic material, and set the minimum permissible pressure value in the chambers. If the patient's weight is small, blanks of reduced thickness are selected and installed in the chambers - the minimum permissible value of the pressure value.

The method of implementation of the claimed utility model is illustrated by drawings, where a general one is shown in Fig. 1

Ш- view of the device for forming impressions of individual orthopedic insoles; Figure 2 shows a schematic diagram of a device for forming impressions of individual orthopedic insoles; Fig. 3 - 5r illustrates the inclined direction of the conditional straight line connecting the upper points of the wings of the pelvic bones in the case of curvature of the spine with different lengths of the lower limbs.

The Drawings, as well as the below example of a specific implementation of the method, only explain the essence of the claimed useful model, without limiting the scope of rights defined by its formula.

To implement the method, a device for forming insoles is used, which contains two chambers 1 and 2, which are not connected to each other. Structurally, the chambers are made in the form of a single trough-like container with a bridge in the middle, which divides it into two cavities. Each cavity is hermetically closed with an elastic sheet 3, for example, made of rubber, the brand and thickness of which are selected so that the elastic sheets can withstand the load of the patient's weight, and has a shape that resembles a footprint. The area of the elastic surface is slightly larger than the maximum possible size of a human footprint. Each cavity has, respectively, 4 or 5 inlet and 6 or 7 outlet holes with fittings. Adjustable shut-off valves, respectively, 8 and 9 and manometers 10 and 11 are connected to the outlet fittings of the chambers. The device also contains a source of air pressure with two outlets, which is a compressor 12, or it can be, for example, a pneumatic pump from a car. The outputs of the pressure source are connected to check valves 15 and 16 through main air ducts 13 and 14, which allow air into the chambers and lock it there. A holder 17 is installed on the trough-shaped container for resting the patient's hands during impression formation. The method is mainly carried out as follows.

The patient's weight, as well as the length and width of his feet are preliminarily determined, visually detecting orthopedic pathologies of the feet and other diseases of the musculoskeletal system that affect orthopedic changes in the feet. Air is supplied to the cavities of chambers 1 and 2, creating the same air pressure in them, the value of which would approximately compensate for the effect on the elastic surface of the patient's weight, the patient is asked to stand on the surface of the elastic chambers and put him in a physiologically correct position. To do this, visually determine the direction of the conditional straight line that connects the upper points of the wings of the pelvic bones. If a conditional straight line can be drawn from the top of one specified bone to another, and it is horizontal, it is concluded that the patient's spine occupies a physiologically correct position. If the conventional straight line between the upper points of the wings of the pelvic bones has an inclination, for example, towards the left limb, it means that the left limb is shorter, and its shortening must be compensated by a greater thickness of the insole under the heel bone. The patient is placed in a physiologically correct position, visually controlling the location of the upper points of the wings of the patient's pelvic bones. The patient stands on air cushions in a physiologically correct position, and his right limb presses on the corresponding elastic surface with greater force than the left. The pressure difference in the chambers is displayed on manometers 10 and 11. The pressure in the chambers is equalized by venting the air in the right chamber 2 with an adjustable shut-off valve 9. At the same time, /5 | take into account the patient's subjective feelings. The method can be carried out without the readings of manometers, adjusting the pressure in the chambers visually based on the location of the upper points of the wings of the patient's pelvic bones and his subjective feeling. Check valves 15 and 16 close the chambers, and the pressure in the chambers remains constantly adjusted as necessary to compensate for the pathology.

Since the air is compressed under the influence of a person's weight, and the amount of excess pressure in chambers 1 | and 2 2o is regulated approximately within 20-100 mm Hg. depending on the weight, the foot under such pressure sinks into the chambers, is covered and accurately reproduced by an elastic surface. At the same time, the amount of pressure is usually enough to align the patient's position to the physiologically correct level.

After adjusting the device, the patient releases the elastic surfaces. Preheated to the temperature of plastic deformation, the workpieces made of thermoplastic material are placed on them and the patient is asked to stand on the specified workpieces. As a thermoplastic material, a material from the group of foamed polyethylenes or any other modern thermoplastic materials is used. The blanks, depending on the material and thickness, are kept under a load for 1-5 minutes until they lose their plasticity.

During the entire time of formation of the orthopedic insole, the patient feels comfortable and has no unpleasant sensations. The imprint exactly corresponds to the form, which is necessary for the establishment to acquire corrective properties from Ge! taking into account all pathologies without exception. The entire formation process takes into account the patient's feelings.

For patients - children and diabetics, a softer material is chosen for the workpiece and the pressure in the chambers is created in such a way that the elastic surface is soft, for children with cerebral palsy, the elastic surface must also be soft in order to get a more contoured impression, and to ensure more accurate manufacture of the required profile of the insole. For patients with a large body weight, a harder material is chosen for the insole, and the pressure in the chambers before the formation of ulcers is increased. The air inside the camera creates the possibility of such an individual approach and at the same time the high sensitivity of the device and the accuracy of the formation of prints are preserved.

Claims (11)

The formula of the invention «| | n | 1. The method of forming impressions of individual orthopedic insoles on two chambers, each of which has an elastic surface filled with a fluid medium and adapted to the load of the patient's weight, which consists in imposing on at least one of the specified elastic surfaces preheated to the temperature of plastic deformation workpieces made of thermoplastic material, loading the specified elastic surfaces with the weight of the patient's body, adjusting the pressure of the fluid in at least one chamber for - placing the patient in a physiologically correct position and maintaining the specified workpiece under load for the time required for the loss of plasticity obtained by the imprint, which is also distinguished by that air is supplied to the chambers as a fluid medium, and the air pressure is adjusted in the corresponding chamber until the standing patient occupies a position in which the conditional line between the upper points of the wings of the pelvic bones 5p has a horizontal direction. i95) 2. The method according to claim 1, which differs in that before applying the blanks to the elastic surfaces and Ge; orthopedic pathologies are preliminarily detected by the formation of impressions and the patient's weight is determined, the same air pressure is created in the cavities of the specified chambers, the value of which depends on the orthopedic pathology and the patient's weight. C. The method according to claim 2, which differs in that the pressure regulation in the chambers is carried out before the workpieces are placed on the elastic surfaces. with 4. The method according to claim 2, which differs in that pressure regulation in the chambers is carried out after placing the blanks on elastic surfaces during the formation of prints. 5. The method according to claim 1, which differs in that orthopedic pathologies are detected when elastic surfaces are loaded with the patient's body weight. 6. The method according to claim 5, which differs in that the application of blanks is carried out after detecting orthopedic pathologies and adjusting the pressure. 7. The method according to claim 5, which differs in that the application of blanks is carried out before detecting orthopedic pathologies and adjusting the pressure. 65 8. The method according to any of claims 1-7, which is characterized by the fact that the pressure adjustment is carried out taking into account the subjective feelings of the patient. 9. The method according to one of claims 1-8, which is characterized by the fact that, in the presence of orthopedic pathology of the lower limbs in the form of their different lengths, the difference in the length of the limbs is corrected by increasing the pressure in the chamber on which the shorter limb is located, or by reducing the pressure in the chamber , on which the longer limb is located. 10. The method according to any one of claims 1-9, which is characterized by the fact that, in the presence of a diabetic disease and/or low weight of the patient, blanks are selected from a softened thermoplastic material and the minimum permissible pressure value is set in the chambers. 11. The method according to any one of claims 1-10, which is characterized by the fact that, when the patient's weight is small, blanks of reduced thickness are selected and the minimum permissible pressure value is set in the chambers. z z (o) (ze) IF) in "- - and? - -and 1 (95) iChe) because b5