EA026240B1 - Method for delivery of magnetocontrolled medicament - Google Patents

Abstract

The claimed method and device use magnetic field created by a system of electromagnets to treat blood, move, concentrate and activate a magnetocontrolled medicament in a chosen area, and also a device for dosed administration of a medicament into blood of a patient.

Description

The invention relates to medicine, in particular to methods for treating various diseases of a person and other living organisms by sharing magnetic fields and drugs and devices for its implementation.

One of the main problems of therapeutic treatment is the high toxicity of drugs. Patients are forced to take them during treatment, but their health problems are aggravated: the liver, kidneys, and heart are affected. Thanks to the use of magnetic nanoparticles in medicine, targeted drug delivery has become possible, which makes it possible to significantly reduce the toxic effect of drugs on other organs and systems of the body, the ability to direct and hold nanoparticles with a drug in a certain place using a magnetic field, visualize them, and carry out local heating with high-frequency magnetic a field for initiating the mechanism of desorption / decapsulation of drugs or magnetic hyperthermia.

A known method of treating tumors by conducting magnetothermochemotherapy. (KI 2348436, A61H 2/04, A61H 2/10). A solution of a magnetically controlled antitumor drug containing cytostatic agents is injected into the tumor, the drug is concentrated in the tumor by exposing it to an inhomogeneous constant magnetic field, followed by induction heating of the drug and tumor to 47-70 ° C with an alternating magnetic field, and necrotic tissues are removed with an antiseptic solution. Simultaneously with heating, the temperature of the tumor and the body of the animal are continuously measured.

The disadvantages of this method, as well as the hardware for its implementation, are the therapeutic effect of the drug is to provide heating of the local area of the body in which the drug is stored to a high temperature, and not the target chemical effect of the drug component;

a magnetic drug is introduced before the start of the magnetic field, which does not allow to control and increase the speed of its movement, the accuracy of localization and activation;

there is no instrumental control over the movement and accumulation of the desired dose of magnetically controlled drug in the selected area;

electromagnets do not have the ability to accurately orientate relative to the patient’s body, blood vessels transporting the drug, frequency and pulse control.

A device for magnetotherapy is known (RF patent No. 2071794 IPC Α61Ν 2/04, Α61Ν 2/10, published January 20, 1997) in which electromagnets with cores are used to create a high-frequency magnetic field, increasing the depth of penetration of the electromagnetic field into the body’s tissues, the generation system signal and control system.

The disadvantages of this device is there is no system for monitoring the effect of a magnetic field on the patient's body; lack of a drug delivery system for simultaneous chemotherapy;

low functionality, since magnets can only perform the function of influencing the patient’s body in order to create a directed movement of ions.

Closest to the claimed invention (prototype) is a method and device for hyperthermic treatment of a malignant tumor (US patent 5203782, IPC АВВ 17/36, Α61Ν 2/10, published on 04/20/1994, priority dated 03/26/1991).

The system according to the patent includes a device for moving ferromagnetic particles through the patient’s body between the injection point and the activation zone and includes a plurality of electromagnets 36 connected in series with the step switch. Each electromagnet 36 has a surface 37 adapted to the patient’s body, and the position of this surface is adjustable relative to the position of similar surfaces 37 of adjacent electromagnets 36. This device allows the magnetic path to ensure the transport of ferromagnetic particles along any surface of the human body, following the relief of the body.

The electromagnets 36 are pressed against the patient’s body by means of an electro-pneumatic manipulator.

The apparatus has a magnetic latch 11 of the type of an electromagnet connected to the power output 1 and attached to the body by means of a flexible holder 12.

According to the method, ferromagnetic particles are transferred through the patient’s body between the injection point and the activation zone. When the ferromagnetic particles reach the boundaries of the tumor, the tumor is locally exposed to a constant magnetic field of 6000 Oe to keep the particles within the boundaries of the tumor. At the same time, the tumor is exposed to an alternating electromagnetic field with a frequency of 13.65 MHz to create local hyperpyrexia (overheating) for a period of 120 minutes.

The disadvantages of this method and device are that the tumor is subjected to prolonged electromagnetic heating using ferromagnetic particles and, in fact, thermal decomposition of diseased cells with the release of toxins. Such treatment is not quite effective. In addition, the transport of ferromagnetic particles depends on the location and size of the vessels. Especially such transport is difficult in small vessels, since in such vessels the blood is denser and the passage of particles slows down and becomes difficult.

The aim of this invention is to increase the therapeutic effect and ensure the safety of the treatment of patients. This goal is achieved by the fact that the treatment method involves the parenteral dosage administration of a magnetically controlled drug depending on the speed and volume of its delivery to the selected area, its transportation in the blood stream with an adjustable magnetic field with simultaneous low-frequency pulsed magnetic treatment of the patient’s blood, which reduces its viscosity, stopping and activating the drug in the selected area to be treated, and the treatment of blood with low-frequency pulsed magnetic start with the field before the drug is administered, continue during the drug’s injection into the bloodstream and, at least, during the delivery time after the drug is stopped, and the drug is stopped and activated in the selected area as it arrives by appropriate modulation of the magnetic field in the selected area area.

A system for delivering a magnetically controlled drug to a selected area includes a magnetic carrier with a drug, a set of electromagnets and control system sensors configured to regulate their position along blood vessels, through which blood and a magnetic field transport the drug, a device for automatically dosing the drug, and electromagnets connected to the control system through channels for generating control signals, and the system further comprises a device forming anija baseband pulse signal to the modulation control signals of the electromagnets.

The prototype and the claimed invention has the following significant similar features:

1) a magnetically controlled therapeutic drug is regionally injected into the patient’s blood;

2) the magnets and the magnetic field are oriented so that they are close to the vessels transporting blood with a magnetically controlled drug, and the treatment area;

3) to activate a magnetically controlled drug in the treatment area, an alternating magnetic field is used;

4) during the procedure of drug administration and activation, the parameters of the patient’s body, in particular temperature, are measured;

5) in preliminary experiments determine the optimal parameters of magnetic fields during transportation, fixation and activation of a magnetically controlled drug;

6) at certain intervals, the treatment procedure is repeated depending on the physical condition of the patient.

In relation to the prototype of the proposed method has the following significant distinguishing features:

1) a magnetically controlled drug is injected into the patient’s blood after turning on the magnetic field;

2) treatment of the patient’s blood with a pulsed magnetic field is carried out for some time before, during and after the administration of the drug;

3) therapeutic treatment of the patient’s blood, transportation and activation of the drug in the selected area are carried out using the same magnets, changing the parameters of the pulses of the low-frequency modulated magnetic field using the control system unit;

4) the drug is introduced into the patient’s blood dosed, and its transportation using blood flow and magnetic field and activation is carried out as it enters the selected area;

5) the speed and volume of the injected magnetically controlled therapeutic drug is regulated using a dosing system depending on its movement through the patient’s body in a selected area, which is measured by sensors of the control and management system and visualized on the monitor in real time.

The aim of the invention is to increase the therapeutic effect and ensure the safety of treatment in humans and mammals. The objectives of the present invention are to develop a method that provides an increase in the therapeutic effect and reduce toxicity by using magnetically controlled drugs without surgical intervention;

increasing the accuracy and speed of delivery of the drug to the diseased organ; controlled by the administration of the drug into the blood of the patient;

creation of a software-controlled dynamic automatic system for controlling pulsed magnets;

creation of a magneto-therapeutic device for implementing this method.

The set of features characterizing the known methods of treatment using magnetically controlled drugs does not ensure the achievement of new properties, and the presence of the proposed distinctive features allows you to get new properties, a new technical result.

The prototype and analogues also used magnetic fields, but they do not provide high-quality and accurate delivery of drugs to the selected area and ensure safe treatment, which leads to an increase in the volume of drugs administered, requires additional therapeutic actions.

In the proposed method of treatment for targeted delivery to the selected area (to the diseased organ) of magnetically controlled drugs, it is proposed to use a magnetic field. The method of drug delivery using a magnetic field is already known in the art and in medicine, in this case the difference is

- 2,026,240 in the fact that the drug is injected into the patient’s blood in a dosed manner, depending on the speed and volume of its intake in the selected area. Moreover, the speed and volume of its receipt is controlled by magnetic sensors, and the control system automatically increases or decreases the second volume of the supplied medicine. This allows you to reduce the toxicity, getting the drug into the general bloodstream and into the patient’s liver, reduce the risks of overdose and incomplete supply of drugs to the selected area (new technical result).

In the proposed method, the controlled transportation of magnetically controlled drug particles, their stop and activation of the drug in the selected area is carried out by appropriate amplitude modulation of the magnetic field. This allows you to accurately deliver the drug to the selected area and perform its activation, which makes it possible to reduce the supply of drugs to the patient's body, their toxic effect and increase the safety of treatment (new technical result).

The drug supplied to the selected area with small doses of blood flow and a magnetic field is activated with an adjustable magnetic field as it arrives, so that it is more fully absorbed by the cells of the diseased organ and the effectiveness of its therapeutic effect increases (new technical result).

In the process of drug administration, a low-frequency pulsed magnetic treatment of the blood of the patient is additionally performed, which ensures a decrease in its viscosity, the blood treatment being started before the drug is administered, continued during drug administration into the blood and at least during the delivery time after drug administration is stopped. Less viscous blood provides faster and more complete delivery of the drug to the diseased organ and the removal of magnetic particles from the selected area after drug activation, which reduces the toxicity of the body and increases the safety of treatment (new technical result).

For the accurate delivery of a magnetically controlled drug to a selected area, electromagnets and a control system are used, which generates low-frequency pulsed modulated electromagnetic signals, including constant and variable components, and the same electromagnets, depending on the signals supplied to them, perform the function of magnetotherapy to reduce blood viscosity, transportation of a magnetically controlled drug in the patient’s body, its stopping and activation in the selected zone. This allows us to simplify the magnetotherapy device, increase its reliability and provide safe treatment for humans and mammals (new technical result).

The magnets and sensors of the control system are placed along the blood vessels through which blood and the magnetic field transport the medicine, and in the area selected for drug delivery, which allows more precise control and monitoring of the stop and activation of the magnetically controlled therapeutic drug, the use of a smaller amount of electromagnetic radiation and provides increased safety treating a patient (new technical result).

The introduction of a magnetically controlled drug into the patient’s blood is carried out using an automated dosing system controlled by a control and control unit, in accordance with the speed of movement and receipt of the drug in the selected area, which improves the accuracy of the dosage, transportation, stop and activation of drugs, improve the therapeutic effect and safety ( new technical result).

The above indicates that there is a causal relationship between the hallmarks and the technical result. According to the information available to the applicant, the proposed set of essential features characterizing the essence of the invention is not known from the prior art, therefore, the invention meets the criterion of novelty.

The essence of the claimed invention does not follow for a specialist explicitly from the prior art. The set of features characterizing the known methods of treatment and magnetotherapeutic devices does not ensure the achievement of new properties, and only the presence of distinctive features allows you to get new properties, a new technical result.

Therefore, the proposed device meets the criterion of inventive step. Brief Description of the Drawings

In FIG. 1 shows an embodiment of a method for treating a patient using a magnetically controlled drug and its delivery system to a selected area.

In FIG. 2 shows a variant of the technological scheme of the control and management system of the magnet system and the metering device.

The treatment method (Fig. 1) includes operations:

1) installation of the device frame with the electromagnets fixed on it or individual electromagnets on the patient’s body in a selected area along the projection of the blood vessel through which the drug is administered;

2) the selection and installation of the magnetic field parameters necessary in this particular case on the control and control unit and the inclusion of the device in operation;

3) pre-treatment of the patient’s blood with a low-frequency pulsed magnetic field,

- 3,026,240 providing a decrease in its viscosity;

4) installation of a magnetically controlled drug metering unit in the desired position and its connection with the circulatory system of the patient;

5) dosed introduction of a magnetically controlled drug into the patient’s blood and its movement by a blood stream together with a transporting magnetic field to a selected area;

6) treatment of the patient’s blood with a low-frequency pulsed magnetic field of electromagnets, which ensures a decrease in its viscosity during the movement of a magnetically controlled drug;

7) control of the speed and volume of the drug transported in the patient’s body by means of control sensors and automatic regulation of the supplied dose of the drug;

8) the magnetic field stops and activates a magnetically controlled drug in a selected area using a modulated control signal for the corresponding electromagnets;

9) treatment of the patient’s blood with a low-frequency pulsed magnetic field, which ensures a decrease in its viscosity after completion of the supply and activation of the entire dose of a magnetically controlled drug in order to better remove magnetic particles from the body.

A device for treating and delivering drugs to a diseased organ (Fig. 2) includes a control unit 1 of electromagnets 2 located along a blood vessel 3, through which magnetically controlled drugs 4 are transported, and sensors 5 for positioning magnetically controlled drugs 4. Electromagnets 2 and sensors 5 are located on the surface of the body 6 near and along the vessel 3. In accordance with the signals of the sensors 5 and the program of the computer 7, the control unit 1 generates the corresponding digital signals arriving at the set of digital ovyh converters (DAC) 8 and inverter 9, the active power amplifiers 10 the analog signal applied to the electromagnets 2 signal. A device that introduces and dispenses a magnetically controlled drug into the patient’s blood 11 generates a start signal for the control unit 1. When the device is in operation, the electromagnets 2 generate a directional magnetic field that affects the patient’s blood and magnetically controlled particles 4 with the drug moving through the vessels 3. In this case the program of the computer 7 sets the overlay on the transporting signals modulation of the therapeutic signal at the time intervals specified by the program in accordance with the method.

An example of the application of a treatment method and a device for delivering drugs to a diseased organ.

When conducting a treatment session on the patient’s body along the projection of the blood vessel through which the drug is administered and in the selected area, the device frame with the electromagnets attached to it or separate electromagnets 2 are installed. At the beginning of the session, the patient’s blood is treated with low-frequency for 10-15 minutes pulsed magnetic field, providing a decrease in its viscosity. At the injection site of the drug into the blood vessel 3, a dosage unit for magnetically controlled drug preparation 11 is mounted to the patient and connected to the circulatory system. An automatic system for supplying a magnetically controlled preparation to the blood of a patient 11 is turned on and its movement by a blood flow and a transporting magnetic field of electromagnets to a selected area is monitored using sensors 5, without stopping the treatment of the patient’s blood with a low-frequency pulsed magnetic field. During the session, the computer 7 controls the speed and volume of the drug moved in the patient’s body by means of control sensors 5 and automatically adjusts the dose of the drug using the control unit 1 and computer 7. The magnetically controlled drug is stopped and activated in the selected area as the drug arrives automatically using the control system 1 generated by the DAC 8 and inverters 9 and amplified by power amplifiers 10 a modulated magnetic field signal for uyuschih electromagnets 2. The treatment of the patient blood low frequency pulsed magnetic field, providing a reduction of its viscosity was continued for 1015 minutes after the completion of supply and activating the entire dose solenoid medicament to better excretion of the magnetic particles.

Practical applicability

The proposed method of treatment and device may find application in oncology, the treatment of strokes and other diseases. A device for delivering a magnetically controlled drug to a diseased organ has a relatively simple device and software and can be used in the practice of treating patients. Due to the programmed automatic control of the dosage of the drug and constant monitoring of its movement in the patient’s body in real time, errors related to the human factor are eliminated, the device increases the safety of treatment and therapeutic effect.

Claims (5)

CLAIM 1. A method of delivering a magnetically controlled drug to a selected area, including regional administration of a magnetically controlled drug, transporting it in a blood stream with a magnetic field, stopping the drug, and activating it in a selected area to be treated, characterized in that the drug is introduced into the blood the patient is dosed depending on the speed and volume of its receipt to the selected area, the drug is transported to the selected area as it is received iruemym magnetic field, and further comprising a low frequency magnetic pulse treatment of the patient's blood, which provides reduction of its viscosity. 2. The method according to claim 1, characterized in that the processing of blood with a low-frequency pulsed magnetic field is carried out by amplitude modulation of the transporting magnetic field. 3. The method according to claim 1, characterized in that the blood treatment with a low-frequency pulsed magnetic field is started before the drug is administered, continued during drug administration into the bloodstream, and at least during the delivery time after drug administration is stopped. 4. The method according to claims 1, 2, characterized in that the drug is stopped and activated in a selected area by appropriate modulation of the magnetic field in the area of the selected area. 5. The method according to claims 1, 2, characterized in that the rate of administration and the amount of magnetically controlled drug introduced into the patient’s blood, the speed of its movement to the selected area is monitored and controlled in real time.