RU2316364C2 - Method and device for applying physiotherapeutic treatment - Google Patents

Abstract

FIELD: medicine; medical engineering.

SUBSTANCE: device has at least four permanent magnets, infrared radiator, electromagnets and at least four optical range radiators of different radiation frequency, enclosed in casing manufactured from non-magnetic material and having working surface. Each electromagnet has two inductance coils having their ends attached to U-shaped core ends. The electromagnet cores are set at an angle of to the working surface of the casing , electromagnets coils windings are joined in series-parallel or parallel opposite way and are connected to frequency converter via working mode switches of the electromagnets. The frequency converter shapes signals as positive or negative sinusoid half-period, or the complete sinusoid, or their permissible combinations having frequency selected from the bandwidth of (0.1-1500) Hz. The frequency converter inputs are connected to feeding voltage unit. Permanent magnets are mounted between electromagnet poles in alternating polarity order in perpendicular to the working surface. The working surface has openings for receiving radiators operating in optical and infrared bandwidth, one opening being available in the center with infrared radiator mounted beneath and connected to feeding voltage unit via a switch. Optical bandwidth radiators allowing variable tilt angle option are connected to feeding voltage unit via corresponding switches. The frequency converter has controllable oscillator producing signals of frequency selected from the bandwidth of (0.1-1500) Hz. Its first control input is connected to current frequency master output having frequency control unit, the second control input is connected to amplitude control output included into controllable oscillator feedback circuit. Frequency converter output signal shaper is connected with its input to controllable oscillator output and with its output to output signal parameter display. Method involves applying treatment combining five physical factors, to patient skin. The factors are permanent magnetic field of not higher than 50 mTesla units intensity combined with alternating magnetic field of frequency selectable from the bandwidth of (0.1-1500) Hz; infrared radiation directed to or focused upon treatment zone; optical bandwidth electromagnetic radiation having radiation power controllable in the range of 5-40 mW; and heat treatment applicable by means of physiotherapeutic treatment device.

EFFECT: enhanced effectiveness of treatment.

24 cl, 4 dwg

Description

The invention relates to medical equipment, namely to portable physiotherapy devices using, when carrying out procedures, the effects on the human body of compositions of several physical factors. The invention can be used to treat various diseases.

Currently, according to the results of the use of domestic and foreign medical devices and devices in medical practice, there is a lot of clinical material indicating that magnetic therapy devices that use low-frequency magnetic fields (pulsed, variable, constant, traveling and others), as well complex magnetotherapy devices (magneto-laser, magneto-infrared, magnetomodulating) have anesthetizing, hypotensive, and varying degrees of clinical effectiveness antispasmodic, sedative, hypocoagulating, desensitizing, anti-inflammatory and other types of effects that actively affect the metabolic processes of substances and the processes of reparative regeneration of injured tissues. The mechanisms for obtaining high biological and therapeutic effects of portable magnetic therapy devices and apparatuses when creating complex fields on their working surfaces depend on the following physical characteristics: the structure of the magnetic field and the form of the law of change in its frequency characteristics; type of field (constant, variable, pulsed, running, rotating, etc.); field magnetic induction values; AC field frequency values pulse shapes; magnitude of magnetic flux; the gradient direction of the magnetic induction vector and the mechanism of its effect on the internal organs and parts of the patient’s body; the duration of exposure and the location of the field on the patient’s body.

The analysis shows that in addition to magnetotherapy devices (MAG-30, Magniter, Biomag, Polyus-2D, ALMAG-01, etc.), combined magnetotherapy methods are widely used:

magneto-optical, magneto-laser, magneto-infrared, which are represented on the domestic medical equipment market by the ALMT-01, Vityaz, Milta, MIO-1 and other devices. The radiators of devices that implement the above methods do not have fundamental differences and represent specific constructions in which permanent magnets or electromagnets are stationary, as well as several laser diodes or LEDs with a total radiation power of 10-40 mW, powered by special control units.

These devices and the above portable devices of magnetotherapy and complex magnetotherapy, when used, have insufficient magnetic field exposure to biological objects, which is primarily due to the use of permanent magnets or only variable electromagnets, and there are a number of important physical characteristics shown above.

The closest analogue of the invention for physiotherapeutic effects is selected device for physiotherapeutic effects "MUM-50 EDMA" (see RU 2046609 C1, Maksimov EB and others, 10.27.1995), containing a housing with a working surface and a handle in which are placed accordingly, the magnetic system unit and the printed circuit board with operating mode switches and an indication element on the handle, four permanent magnets and four poles of two electromagnets, structurally made on two U-shaped cores made of transformer iron with four inductors installed on them, with permanent magnets installed between them, the cores of electromagnets are placed at an angle to the working surface of the housing, the coils of each electromagnet are connected in series through the operation mode switches to an alternating current source of voltage 220 V with a frequency of 50 Hz, to which display elements are also connected in series, a source of inf is installed under the working surface in the center akrasnogo radiation beam with a yield up through the aperture in the housing connected in series with a current source and displays.

When using the known device, a method of physiotherapeutic exposure is implemented by combining the composition with the following physical factors: either simultaneously with a constant magnetic field and variable electromagnetic field, with a frequency of 50 Hz, infrared radiation and heat, or a constant magnetic field and infrared radiation.

The known device has several disadvantages. Infrared radiation is constantly present, the heat generated on the cores cannot be regulated and depends on the duration of the procedure, the frequency of the alternating electromagnetic field (PeMP) is always 50 Hz for all modes, which reduces the clinical efficiency of the device, the input voltage of 220 V can damage the patient if the mains cable is damaged , due to the use of transformer iron inductor cores, the weight of the device 0.7 kg for elderly patients is critical, the physical factors used cannot be meneny separated from each other during procedures.

In the present invention, in contrast to the closest analogue, all factors can be applied both individually and simultaneously, or in any composition, which increases the synergistic capabilities of the device, making it clinically more effective compared to existing portable devices for magnetotherapy and complex magnetotherapy.

The present invention solves the problem of creating a high-tech, compact device for physiotherapeutic effects on biological objects with enhanced therapeutic efficacy.

The technical result consists in increasing the efficiency of physiotherapeutic procedures, due to the possibility of applying the composition of five physical impact factors in the present invention: magnetic field, variable electromagnetic field, optical radiation, infrared radiation and heat and optimizing their characteristics for various nosological forms of human diseases due to exposure on the lines of force of a constant magnetic field and on the electromagnetic field of optical emitters one band variable electromagnetic field with a frequency chosen in the range (0,1-1500) Hz, as well as by adjusting both the power of the electromagnetic radiation of optical range and the magnitude of heat.

In the proposed method, this is achieved by the fact that with the help of the proposed device, compositional effects on the skin of a patient are performed by five physical factors: a constant magnetic field in combination with an alternating electromagnetic field with a frequency selected in the range of 0.1-1500 Hz, infrared radiation, directed or focused with a given gradient; electromagnetic radiation of the optical range with a radiation power adjustable in the range from 5 mW to 40 mW; heat exposure.

In one of the embodiments of the claimed method, it is assumed the possibility of regulating the thermal effect in the temperature range from 20 ° to 40 ° C.

In this case, regulation is carried out with a gradual increase or decrease in temperature in the zone of influence.

A device for physiotherapeutic influence, with which the method is carried out, contains at least four permanent magnets, an infrared emitter, two electromagnets, each of which includes two inductors, the windings of which are placed inside a case made of non-magnetic material and provided with a working surface at the ends of the U-shaped core, and at least four emitters of the optical range with different radiation frequencies, while the cores of the electromagnets set angled to the working surface of the housing, the windings of the coils of electromagnets are connected in parallel in series or parallel to the counter and through the switches of the operating modes of the electromagnets are connected to a frequency converter configured to generate signals in the form of a positive or negative half-cycle of a sine wave, or a sinusoid, or their possible combinations with a frequency , selected in the range (0.1-1500) Hz, the inputs of which are connected to the block of supply voltage, between the poles of the electromagnets perpendicular Permanent magnets are installed with alternating polarity on the working surface, and the working surface is made with holes for emitters of the optical and infrared ranges, one of which is located in the center, an infrared emitter is installed under it, connected to the power supply unit via a switch, and other openings are installed with the possibility of changes in the angle of inclination to the working surface of the optical range emitters connected via appropriate switches to the power supply unit expressions.

Optical range emitters can be installed at the same distance from the center of the working surface or at different distances from the center of the working surface.

Moreover, red, orange, yellow, green, blue, blue or violet LEDs can be used as emitters.

The device may include an indicator of the operation of the optical range emitters.

The device can be equipped with adjustable thermocouples located on the inner side of the working surface of the housing and connected through a temperature controller to the power supply unit.

Thermocouples can be made in the form of a circle or rectangle.

The device can be equipped with a temperature indicator connected to the output of the temperature controller.

The cores of electromagnets can be made of ferrite.

The end part of the cores of the electromagnets can be beveled at an angle equal to the angle of inclination of the core to the working surface of the housing.

The device uses permanent magnets with a magnetic induction of no more than 50 mT, and electromagnets with the possibility of forming at the poles a magnetic induction of no more than 30 mT.

The housing can be made with a handle.

The mode switches of the electromagnets can be installed on the handle of the housing.

The frequency converter and the power supply unit can be installed in a separate case made of non-magnetic material.

In this case, the mode switches of the electromagnets can be installed on the outer surface of a separate housing.

An embodiment of the device is possible in which an indicator of the output signal of the current frequency converter, a temperature indicator, a temperature controller, switches of infrared and optical emitters, an indicator of the operation of optical emitters and switches of the operation modes of electromagnets are installed on the outer surface of a separate case.

The frequency converter of the electric current can be made in both analog and digital versions.

In the digital embodiment, the frequency converter contains a controlled generator, configured to generate a signal with a frequency selected in the range (0.1-1500) Hz, the first control input of which is connected to the output of the current frequency adjuster equipped with current frequency controllers, the second control input with the output of the amplitude regulator included in the feedback circuit of the controlled generator, the driver of the output signals, the input connected to the output of the controlled generator, and the output to the indicator of the parameters of the output of one signal, while the output signal shaper is configured to generate signals in the form of a positive or negative half-cycle of a sine wave or sine wave, or their possible combinations with a given current frequency, and its output is the output of a current frequency converter.

As shown by preliminary tests of prototypes, an increase in the clinical effect when using the invention is due to the possibility of forming an acting electromagnetic field in a wide frequency range. By adjusting the frequency of the alternating current supplied to the windings of the electromagnet coils in the range (0.1-1500) Hz, a local complex electromagnetic field with a selected frequency of oscillation of the lines of permanent magnets is formed on the working surface of the device. There is an effect of reverse magnetic therapy (Maximov effect). Doctors and patients can visually observe this effect on the working surface of the device using a special indicator of the structure of the magnetic field, which is included in the set of existing EDMA devices. Metal chips inside the indicator begin to move back and forth with a given frequency of oscillation of an alternating electromagnetic field.

When using the proposed device, they are exposed by combining a constant magnetic field with an alternating electromagnetic field with a frequency selected in the range (0.1-1500) Hz. In this case, a resulting field is formed, the intensity vector of which varies in magnitude and direction in a fixed local zone. Moreover, the magnitude of the intensity of their resulting field also varies depending on the distance between the crossing point of the fields and the working surface of the device.

This compositional combination of two fields (variable and constant) allows you to create an asymmetric spatio-temporal gradient of the resulting electromagnetic field, variable in time in the localized part of space.

Placing the cores of electromagnets at an acute angle relative to the working surface allows you to concentrate the maximum electromagnetic energy in the local area of biological tissue. In addition, when the polarity of the signal supplied to the coils is changed on the device’s working surface or perpendicular to it at a certain distance, a resulting field is formed with polarization of the field lines both clockwise (centripetal direction) and counterclockwise (centrifugal direction).

In the proposed device, the mode switches of the device are located on the outside of the case, which simplifies the process control modes.

The frequency converter of the electric current is configured to reduce or increase the frequency of the output current in the range of 0.1-1500 Hz with a sampling step of 0.5 Hz and the selection of accuracy at each step to 0.01 Hz or a smooth change in frequency. When a signal is supplied from the converter to the electromagnet windings, a resulting field is formed on the working surface of the housing, the intensity vector of which changes in magnitude and direction in a fixed local zone, creating a reversible oscillatory process of field lines.

The current frequency converter can be performed in both digital and analog versions. In analog performance, its cost is 3 times less.

The current frequency converter can be made in the form of a compact separate unit, combined with a block of supply voltages (adapter), or placed in the device’s body inside the handle.

The presence of optical radiation sources allows the impact of an additional physical factor - electromagnetic radiation of the optical range. In addition, when the combined exposure to electromagnetic radiation of the optical range and an alternating electromagnetic field formed by electromagnets, the radiation of the optical range begins to oscillate with a given frequency of an alternating electromagnetic field. The placement of optical radiation sources under the working surface of the housing with the possibility of changing the angle of inclination provides a change in the gradient of optical radiation. Connecting optical and infrared radiation sources to the power supply unit through the appropriate switches allows you to change the total radiation power and turn them off in cases provided for by medical methods.

The device uses optical radiation sources with different radiation frequencies (diodes of different colors), which makes it possible to optimize the characteristics of optical radiation for various nosological forms of human diseases. This increases the effectiveness of using the claimed device physiotherapeutic procedures.

The device uses permanent magnets with a magnetic induction value of not more than 50 mT and electromagnets with the possibility of forming at the poles a magnetic induction value of not more than 30 mT. As you know, such magnetic field parameters have the most biotropic properties when exposed to living organisms.

The device additionally includes adjustable thermocouples, which allows you to adjust the magnitude of the thermal effect. In this case, the temperature controller of the thermocouples can be placed, for example, on the mains voltage adapter, which simplifies the process of using the device.

To prevent overheating of the working device in case of exceeding the specified exposure, the device has an automatic switch of thermocouples.

The implementation of the cores of the electromagnets of the ferromagnetic material can reduce the supply voltage and the magnitude of the current passing through the inductors placed on the cores. This mode of supply of electromagnet coils does not lead to the formation of heat in the cores themselves, which makes it possible to most accurately control the thermal effect in a given mode from 20 to 40 ° C.

The device is illustrated by drawings in figures 1-4.

Figure 1 presents the structural diagram of one of the embodiments of the proposed device; figure 2 is a structural diagram of a current frequency Converter (PST); figure 3 presents a General view of the proposed device; figure 4 shows the options for the operating modes of the electromagnets and observed on the indicator structure of the generated field (figures 4.1, 4.2, 4.3, 4.4).

A device for physiotherapeutic exposure contains exposure elements: four permanent magnets 1, two electromagnets 2, infrared emitter 3, optical emitters 4 and thermocouples 5. The device also contains a control unit 6, including a current frequency converter 7 (PChT), switches 8 modes of operation of electromagnets, switch 9 of the infrared emitter 3, switches 10 of the optical emitters 4, temperature controller 11, indicators 12 and 13, respectively, of the temperature of the thermocouples and the operation of the optical emitters as well as a circuit breaker for 14 thermocouples. In addition, the device contains a block 15 of the supply voltage, which performs the functions of an adapter.

PChT 7 includes a controlled generator 16, the first control input of which is connected to the output of the current frequency controller 17, equipped with current frequency controllers 18 and 19, and the second control input - with the output of the amplitude controller 20 included in the feedback circuit of the generator 16. PChT 7 also includes a driver 21 output signals, the input connected to the output of the generator 16, and the output to the indicator 22 of the current frequency. The output of the shaper 21 is the output of the PCHT. The inputs of the supply voltage of the structural elements ПЧТ 7 are connected to the corresponding outputs of the block 15.

In PCT 7, the controlled generator 16 at its output generates an output signal with a frequency selected in the range of 0.1-1500 Hz. The choice of frequency is carried out using the frequency adjuster 17, equipped with regulators 18 and 19 for the possibility of selecting a frequency.

Shaper 21 of the output signals is configured to generate signals in the form of a positive or negative half-cycle of a sinusoid, or sinusoid, or their possible combinations with a given current frequency. In this case, the signal parameters are selected with the possibility of providing a given value of the magnetic induction of the electromagnets 2. The indicator 22 displays the current frequency of the output signal.

The housing of the device is made of non-magnetic material with a working surface 23 and a handle 24. The influence elements 1, 2, 3, 4 and 5 are installed in the housing. The switches 8 of the operation modes of the electromagnets are located on the handle 24 of the housing.

Each of the electromagnets 2 includes two inductors, the windings of which are located at the ends of the U-shaped core. The cores of the electromagnets 2 are installed at an angle to the working surface of the housing at the same distance from its center (not shown in the drawing). Permanent magnets 11 are mounted alternately between the poles of the electromagnets 2 perpendicular to the working surface 23 of the housing. Holes 25 and 26 are made on the working surface of the housing 23. The hole 25 is located in the center of the working surface 23 of the housing and is designed to accommodate an infrared emitter 3 connected to the block 15 supply voltages through switch 9. Holes 26 are made at the same distance from the center and are designed to accommodate optical emitters under them 4. Moreover, the dimensions of the holes ment 26 are such that allow exposure radiation of optical range fragile when changing tilt emitters 4 to the working surface of the housing.

Optical emitters 4 are made in the form of LEDs of red, orange, yellow, green, blue, blue and / or purple. The control unit 6 is equipped with switches 10 for connecting the emitters 4 to the block 15 of the supply voltage. The conclusions of the windings of the coils of each electromagnet 2 are connected to the PCT 7 through 8 switches of operation modes.

The cores of the electromagnets 2 are made of ferrite. Adjustable thermocouples 5 are located on the inner side of the working surface 23 of the housing and are connected to the power supply unit 15 through a temperature controller 11, to the output of which a temperature indicator 12 is connected.

PChT 7 and power supply unit 15 are located in a separate housing 27. On the external surface of housing 27 there are current frequency controllers 18.19, current frequency indicator 22, temperature indicator 12, temperature controller 11, switches 9 and 10, optical emitter switches 10, indicator 13 and 8 operation mode switches.

The device operates as follows. Choose the method of physiotherapy in accordance with the pathology of the patient. Set the working surface 23 of the device to the impact zone and, in accordance with the assigned parameters, using the block 17 select the frequency of the alternating current supplied to the windings of the electromagnets 2 and the operation mode of the electromagnets 2 using the switches 8. The following modes of operation of the electromagnets 2 are possible: 1 - sinusoidal current with a given frequency, 2 - pulsating current with a positive pulse with a given repetition rate, 3 - pulsating current with a negative pulse with a given repetition rate. The specified radiation intensity of the electromagnetic field of the optical range is also set using the switches 10 of the optical emitters 4, and also with the help of the regulator 11, the necessary temperature regime of the thermocouples 5. If necessary, turn on the infrared emitter 3. Then perform a physiotherapeutic effect on the selected area of the patient's body. The exposure time is chosen in accordance with well-known recommendations for physiotherapy procedures.

As shown by clinical trials, the practical application of the proposed device provides an increase in therapeutic efficacy.

Example 1. Patient U., 35 years old, complaints of pain in the right ankle joint during the last two months. To carry out physiotherapeutic effects, the proposed device was used. The impact on the joint was carried out by applying the device with the center of the working surface on the ankle contact for 10 minutes daily. The current frequency was set equal to 3 Hz. Mode 1. A total of 5 sessions were conducted. After the first session, the pain decreased, and after the fifth, they stopped completely. Previously, when carrying out procedures using the physiological therapeutic device “MUM-50 EDMA” with a similar pathology, a positive result occurred only after 10 sessions. Observation of the patient was carried out for 2 months, there were no complications.

Example 2. Patient T., 60 years old, complaints of pain in the right hip joint that occur periodically over the past two years. When walking uses a stick. For physiotherapy, the proposed device was used. The impact on the joint was carried out by applying the device with the center of the working surface to the center of the hip joint contact for 15 minutes daily. The current frequency was set equal to 2 Hz. Mode 1. In total, 10 sessions were conducted. After the second session, the pain significantly decreased and subsequently decreased after each session. After the entire cycle, there were minor pains that disappeared within two weeks. The patient began to walk without a stick. Previously, when carrying out procedures with a similar pathology using the MUM-50 EDMA device, a positive result occurred only after 20 sessions. Observation of the patient was carried out for 4 months, there were no complications.

Claims (24)

1. A device for physiotherapeutic treatment, comprising at least four permanent magnets, an infrared emitter, two electromagnets located inside a case made of non-magnetic material and provided with a working surface, each of which includes two inductors, the windings of which are located at the ends of П- shaped core, and at least four emitters of the optical range with different radiation frequencies, while the cores of the electromagnets are installed at an angle to the working surface These cases, the windings of the coils of electromagnets are connected in parallel in series or parallel to the counter and through the switches of the operating modes of the electromagnets are connected to a frequency converter configured to generate signals in the form of a positive or negative half-cycle of a sine wave or sine wave, or their possible combinations with a frequency selected in the range ( 0.1-1500) Hz, the inputs of which are connected to the block of supply voltages, between the poles of the electromagnets perpendicular to the working surface is installed with alternating polarity, permanent magnets, and the working surface is made with holes for optical and infrared emitters, one of which is located in the center, an infrared emitter is installed under it, connected to the power supply unit via a switch, under other holes are installed with the possibility of changing the angle of inclination to the working surface of the optical range emitters connected through the appropriate switches to the power supply unit. 2. The device according to claim 1, characterized in that the frequency converter is equipped with an indicator of the output signal parameters. 3. The device according to claim 1, characterized in that the optical range emitters are installed at the same distance from the center of the working surface. 4. The device according to claim 1, characterized in that the optical range emitters are installed at different distances from the center of the working surface. 5. The device according to any one of claims 1 to 4, characterized in that the emitters use LEDs of red, orange, yellow, green, blue, blue and / or purple. 6. The device according to claim 5, characterized in that the indicator of the optical range emitters is connected, connected to the outputs of the switches of the optical range emitters. 7. The device according to claim 1, characterized in that adjustable thermocouples are introduced, located on the inner side of the working surface of the housing and connected through a temperature controller to the power supply unit. 8. The device according to claim 7, characterized in that the core of the electromagnets is made of ferrite. 9. A device according to any one of claims 7 or 8, characterized in that a temperature indicator is connected to the output of the temperature controller. 10. The device according to claim 1, characterized in that the end part of the cores of the electromagnets is made with a bevel at an angle equal to the angle of inclination of the core to the working surface of the housing. 11. The device according to claim 1, characterized in that the magnitude of the magnetic induction of permanent magnets is not more than 50 mT, and the electromagnets are configured to form magnetic poles at the poles of not more than 30 mT. 12. The device according to any one of claims 1 to 4, 6-8, 10, 11, characterized in that the housing is made with a handle. 13. The device according to claim 5, characterized in that the housing is made with a handle. 14. The device according to claim 9, characterized in that the housing is made with a handle. 15. The device according to p. 12, characterized in that the mode switches of the electromagnets are mounted on the handle of the housing 16. The device according to any one of paragraphs.13 or 14, characterized in that the mode switches of the electromagnets are mounted on the handle of the housing. 17. The device according to claim 1, characterized in that the current frequency converter and the power supply unit are installed in a separate housing of non-magnetic material. 18. The device according to 17, characterized in that the mode switches of the electromagnets are mounted on the outer surface of a separate housing. 19. The device according to 17, characterized in that on the outer surface of the individual housing there is an indicator of the output signal of the current frequency converter, a temperature indicator, a temperature controller, switches of the infrared and optical emitters, an indicator of the operation of the optical emitters and a switch of operation modes of the electromagnets. 20. A frequency converter containing a controlled generator configured to generate a signal with a frequency selected in the range (0.1-1500) Hz, the first control input of which is connected to the output of the current frequency adjuster equipped with current frequency controllers, the second control input - with the output of the amplitude regulator included in the feedback circuit of the controlled generator, and the driver of the output signals, the input connected to the output of the controlled generator, and the output to the indicator of the parameters of the output signals, ormirovatel output signal is adapted to generate signals in the form of positive or negative half cycle of sine wave, or sine wave, or their possible combinations to a predetermined frequency of the current, and its output is the output current of the frequency converter. 21. The Converter according to claim 20, characterized in that the indicator of the parameters of the output signals is configured to indicate the frequency of the output signal. 22. The Converter according to claim 20, characterized in that the indicator of the parameters of the output signals is configured to indicate the frequency and amplitude of the output signal. 23. A method of physiotherapeutic exposure, including compositional exposure to the skin of the patient’s body with five physical factors: a constant magnetic field with an induction value of not more than 50 mT in combination with an alternating electromagnetic field with a frequency selected in the range (0.1-1500) Hz; directed or focused on the area of influence of infrared radiation; electromagnetic radiation of the optical range with a radiation power adjustable in the range from 5 mW to 40 mW, and thermal exposure using a physiotherapy device according to any one of claims 1 to 19. 24. The method according to item 23, wherein the thermal effect is controlled by gradually increasing or decreasing its value.

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