ITPR20100043A1 - MEDICAL DEVICE FOR MAGNETOTHERAPY. - Google Patents

Description

DESCRIPTION

Attached to a patent application for INDUSTRIAL INVENTION having the title

"MEDICAL DEVICE FOR MAGNETOTHERAPY"

The present invention relates to a medical device for magnetotherapy.

As is known, magnetotherapy is used in various fields of medicine, mainly in physiotherapy. It is a therapy practiced following a specialist indication of orthopedics, physiatry or geriatrics and consisting in the appropriate irradiation of a part of the human body with a generally localized magnetic field. Magnetotherapy has numerous fields and numerous methods of application, but it mainly works in regulating the electrochemical balance of the cell and restoring the correct permeability of the cell membrane. To this end, the areas affected by muscle, joint, bone and tissue pathologies are subjected to targeted irradiation.

Depending on the frequency of the electromagnetic field, it is possible to distinguish between high and low frequency magnetotherapy. High-frequency magnetotherapy is based on the emission of waves with carrier frequency greater than 15 MHz (preferably between 20 MHz and 30 MHz) and modulation frequency greater than 100 Hz (preferably between 100 Hz and 5000 Hz). Low-frequency magnetotherapy, on the other hand, consists in generating electromagnetic fields with a frequency of less than 100 Hz.

For several years now, devices for performing high and low frequency magnetotherapy have been on the market. However, the main disadvantage of the known solutions lies in the difficulty in updating the therapeutic program, with the need to open the device to reprogram the microprocessor contained therein.

In this context, the technical task underlying the present invention is to propose a medical device for magnetotherapy which overcomes the aforementioned drawbacks of the known art.

In particular, it is an object of the present invention to propose a medical device for magnetotherapy which is easy to reprogram and to control.

The specified technical task and the specified purposes are substantially achieved by a medical device for magnetotherapy, comprising the technical characteristics set out in one or more of the appended claims.

Further characteristics and advantages of the present invention will become clearer from the indicative, and therefore non-limiting, description of a preferred but not exclusive embodiment of a medical device for magnetotherapy, as illustrated in the accompanying drawings in which:

Figure 1 illustrates the block diagram of a medical device for magnetotherapy, according to the present invention;

Figure 2 illustrates a detail of the device of Figure 1, in a partially sectioned perspective view;

Figure 3 illustrates some signals (low frequency, carrier and modulating signal of the high frequency signal) generated by the device of Figure 1.

With reference to Figure 1, 1 indicates a medical device for magnetotherapy. Originally, this medical device 1 comprises at least a therapeutic section 2 dedicated to the generation of a therapeutic program and formed by a first circuit 3 suitable for generating a high frequency signal and a second circuit 4 suitable for generating a low frequency LF signal.

The high frequency signal is a modulated signal having P carrier with frequency greater than 15 MHz and modulating M with frequency between 100 Hz and 5000 Hz. Preferably, the P carrier has a frequency of 30 MHz. The frequencies of the modulating M are modifiable according to an increasing or decreasing trend according to the therapeutic program. The low frequency LF signal has a frequency between 6 Hz and 100 Hz.

Each pulse of the low-frequency signal LF alternates with a finite train T of pulses of the high-frequency signal, as shown in Figure 3. This alternation of signals is commonly known by the term "interpolation".

The medical device 1 has at least one applicator 5 formed by an antenna 6 and a solenoid 7. In particular, the antenna 6 is powered (directly or indirectly) by said first circuit 3. The solenoid 7, on the other hand, is powered ( directly or indirectly) by said second circuit 4. Preferably, the first circuit 3 and the second circuit 4 of the therapeutic section 2 are operated simultaneously in such a way as to generate the corresponding therapeutic program. Alternatively, the first circuit 3 and the second circuit 4 of the therapeutic section 2 are operated individually.

Advantageously, the device 1 comprises a wireless transmission module (from the English "wireless") which transmits data to a wireless receiving module housed in the applicator 5. The data thus received are used to polarize the solenoid 7 and to power antenna 6.

Preferably, the medical device 1 comprises a plurality of therapeutic sections 2 dedicated to the generation of as many therapeutic programs. In particular, each therapeutic section 2 is formed by a first circuit 3 and by a second circuit 4. Preferably, the medical device 1 has a plurality of applicators 5, each of which is fed by one of said therapeutic sections 2. In particular, each applicator 5 is formed by an antenna 6 and a solenoid 7. The antenna 6 of each applicator 5 is powered (directly or indirectly) by one of said first circuits 3. The solenoid 7 of each applicator 5 is powered (directly or indirectly) by one of said second circuits 4.

Advantageously, a control unit 11 is provided which is operatively active on the therapeutic sections 2 in such a way as to activate and manage them independently from each other.

Originally, a communication module 20 is provided which exchanges data (i.e. transmits or receives) with the control unit 11 in such a way as to load or update the therapeutic programs or to download historical operating data of the device 1.

For example, the communication module 20 has a USB interface to which a storage medium can be connected for uploading or downloading data.

Another possibility is to use a wireless communication module 20, capable of receiving data via radio.

Alternatively, it is possible to communicate via cable or serial.

The communication module 20 is located inside or outside the box-like body defining the device 1.

Each therapeutic section 2 is provided with a corresponding voltage and current regulation and control circuit 9 which is operatively active on the solenoids 7 and on the antennas 6 of the applicators 5 powered by said therapeutic section 2 to vary the relative magnetic fields. In fact, for each solenoid 7, it is possible to regulate the current flowing in its coils within a predetermined interval, so as to vary the value of the magnetic induction between 10 Gauss and 100 Gauss. Preferably, the voltage and current regulation and control circuit 9 includes a stage for reversing the direction of circulation of the current. In particular, the applicators 5 powered by the corresponding therapeutic section 2 (i.e. by the therapeutic section 2 to which the regulation circuit 9 belongs) are arranged in pairs in such a way that in the two solenoids 7 of each pair of applicators 5 the current flows in opposite directions so that the magnetic fields generated have opposite polarity. Preferably, the regulation and control circuit 9 carries out a feedback control of the current flowing in the corresponding solenoids 7.

In the embodiment illustrated in Figure 1, the medical device 1 has two therapeutic sections 2, each of which feeds four applicators 5 organized in two pairs. Therefore, it is possible to carry out two distinct therapeutic programs, each of which can be applied simultaneously to four patients or to four areas of the body of a single patient.

With reference to Figure 2, each applicator 5 comprises a shell 12 formed by a circular base 12a to which a spherical cap 12b is fixed. The antenna 6 is placed inside the shell 12 and fixed to the circular base 12a. Above the antenna 6 is the solenoid 7, whose longitudinal development axis is substantially perpendicular to the circular base 12a. As already said, at least one solenoid 7 is provided for applicator 5. For each applicator 5 there can be several solenoids 7 arranged in series, for example one next to the other, in order to simultaneously develop opposite polarity.

In alternative embodiments, the applicators 5 can be integrated in box-like bodies of different shapes or in bands for the body or in bed mats.

The control unit 11, preferably made by means of a microprocessor, communicates with a keyboard 14 and with a visualization screen 15 (or display). In particular, through the keyboard 14, the patients set the therapeutic programs, while through the display 15 they visualize information on the correct functioning of the medical device 1.

In an embodiment for blind patients, the device 1 is provided with a dedicated section 17 for blind patients, which is also managed by the control unit 11. In particular, the dedicated section 17 is formed by a first tactile plane 18 to allow the setting of the therapeutic programs and by a second tactile plane 19 to provide information in Braille language on the operation of the medical device 1 (see Figure 1). Preferably, the first tactile plane 18 consists of a tactile keyboard shaped so as to receive the fingertips of a hand of a blind patient. Preferably, the second tactile plane 19 consists of a needle bed. It is also possible that the first tactile plane 18 coincides with the keyboard 14.

Preferably, the explanations are provided by means of a voice dialer controlled by the control unit 11.

The medical device 1 can be powered either by means of an electrical network or by means of a battery. Preferably, the medical device 1 is powered by the battery, while the connection to the electrical network takes place to recharge the battery. The state of charge of the battery is monitored by means of the control unit 11 and, in the event that the residual charge is lower than a predetermined minimum level, the patient is notified by means of the display 15 or by means of an acoustic warning device 16. The interpolation is also managed by the control unit 11.

The communication between the therapeutic sections 2 and the applicators 5 is of the wireless type (from the English "wireless").

The operation of the medical device for magnetotherapy, according to the present invention, is substantially the following.

The patient applies one of the applicators 5 to the part of the body to be treated and selects the therapeutic program to be carried out using the keyboard 14. If the patient is blind, the selection of the therapeutic program is carried out by means of the first tactile plane 18 (which can coincide, as aforesaid, with said keyboard 14). For example, you can run a headache treatment program.

From the above description the characteristics of the magnetic therapy medical device according to the present invention are clear, just as the advantages are clear.

In particular, thanks to the fact that the control unit (i.e. the microprocessor) receives data via USB or wirelessly via the prepared communication module, the loading of new therapeutic programs is quick and easy and does not require opening the device. .

Furthermore, in the case of wireless communication, the downloading and uploading of data can also be done remotely from the device.

Furthermore, thanks to the fact that the applicators receive data from the device wirelessly, the device is very handy and can be easily used even by a patient who is in a position far from the relevant therapeutic section. Consider, for example, the case in which several patients use the same medical device to carry out the therapy at the same time: they can position themselves with their applicator in different treatment rooms, both for reasons of comfort and privacy.

Furthermore, thanks to the interpolation between the high-frequency signal and the low-frequency signal, the human body is able to assimilate more (ie more effectively) the therapeutic program set.

Moreover, thanks to the presence of several therapeutic sections dedicated to the generation of several therapeutic programs, it is possible to carry out these therapeutic programs simultaneously on several patients or on different areas of the body of a single patient.

Moreover, thanks to the timing carried out by the control unit, the therapeutic sections can be active at the same time or it is possible to select some of them and activate them, while the other sections remain inactive.

Moreover, thanks to the voltage and current regulation and control circuit, it is possible to vary the magnetic induction of each solenoid in such a way as to create the appropriate magnetic field for the chosen therapeutic program, achieving a double polarity. Furthermore, thanks to the use of the feedback, the current flow in each solenoid is controlled more efficiently than in prior art solutions.

Claims (9)

CLAIMS 1. Medical device (1) for magnetotherapy, comprising: at least one therapeutic section (2) dedicated to the generation of a therapeutic program, said therapeutic section (2) being formed by at least one circuit (3, 4) capable of generating at least one high-frequency signal or one low-frequency signal (LF) ; at least one applicatone (5) formed by an antenna (6) fed by said at least one circuit (3, 4); a control unit (11) of said at least one therapeutic section (2), characterized in that it comprises a communication module (20) which exchanges data with the control unit (11) in such a way as to be able to load or update said therapeutic program or to download historical operating data of the device (1). Device (1) according to claim 1, wherein said communication module (20) has a USB interface to which a storage medium for uploading or downloading data is connectable. Device (1) according to claim 1, wherein said communication module (20) is of the wireless type. Device (1) according to any one of the preceding claims, wherein said at least one therapeutic section (2) comprises a first circuit (3) adapted to generate a high frequency signal and a second circuit (4) adapted to generate a signal (LF) at low frequency, said high frequency signal being a modulated signal having carrier (P) with frequency greater than 15 MHz and modulating (M) with frequency between 100 Hz and 5000 Hz, each pulse of the signal (LF) a low frequency alternating with a finite train (T) of pulses of said high frequency signal. 5. Device (1) according to any one of the preceding claims, comprising a plurality of therapeutic sections (2) dedicated to the generation of as many therapeutic programs and a plurality of applicators (5), each of which being powered by one of said sections (2 ) therapeutic and being formed by an antenna (6) and a solenoid (7). Device (1) according to claim 5, wherein the communication between said therapeutic sections (2) and said applicators (5) is of the wireless type. Device (1) according to claim 4, wherein the first circuit (3) and the second circuit (4) of said at least one therapeutic section (2) are operated simultaneously in such a way as to generate the corresponding therapeutic program. Device (1) according to claim 5, wherein the value of the magnetic induction of said solenoid (7) is variable between 10 Gauss and 100 Gauss. Device (1) according to any one of the preceding claims, further comprising a section (17) dedicated for blind users, said section (17) being formed by a first tactile plane (18) to allow the setting of the therapeutic programs and a second tactile plane (19) for providing information in Braille language on the operation of said medical device (1).