JP2019024688A - How to support hyperthermia - Google Patents

Abstract

A method for supporting hyperthermia and an apparatus for hyperthermia are provided. An electromagnetic wave generating means for outputting an electromagnetic wave in the ISM frequency band, a means for improving the directivity of the electromagnetic wave generated by the electromagnetic wave generating means, and the relationship between the electromagnetic wave irradiation amount and the tumor cell survival rate are approximated. Calculated by an irradiation amount determining means for calculating an electromagnetic wave irradiation amount suitable for inducing apoptosis of tumor cells formed on the body surface based on a function to perform, and a command from the irradiation amount determining means or an irradiation amount determining means A hyperthermia having means for adjusting the amount of electromagnetic wave output by the electromagnetic wave generating means according to an instruction by an operator based on the amount of electromagnetic radiation irradiated, and means for arranging the body so that the electromagnetic waves penetrate into tumor cells formed on the body surface Equipment. [Selection] Figure 4

Description

  The present invention relates to a method for supporting hyperthermia and an apparatus for hyperthermia. More specifically, the present invention relates to a method for supporting hyperthermia and a device for hyperthermia that can effectively induce apoptosis of tumor cells while preventing damage to normal cells.

  Hyperthermia is a method of treating a disease such as a tumor by warming a part of the body to about 39 to 43 ° C. An electromagnetic wave such as an RF wave or a microwave is used to warm a part of the body.

  The principle of hyperthermia by electromagnetic wave irradiation is as follows. By irradiation with electromagnetic waves, the electrons of the cells vibrate, and both normal cells and cancer cells generate heat due to frictional heat of the molecules. Normal cells are quickly cooled to normal temperature by blood flow through normal blood vessels. On the other hand, cancer cells tend to be hot and difficult to cool because they have a lot of moisture, blood vessels are fragile, and blood flow is low. As a result, only cancer cells are damaged by heat. In addition, since normal cells are warmed, immunity is improved and blood flow is improved, so that the function of internal organs is activated. However, if the amount of electromagnetic wave irradiation is excessive, normal cells may also be damaged by heat.

Various devices intended to perform hyperthermia while preventing excessive electromagnetic wave irradiation have been proposed.
For example, Patent Document 1 is a thermotherapy apparatus system for malignant tumors, and uses a static magnetic field strength of 0.5 to 9 T to detect an increase in temperature with an MR temperature image, and thermotherapy at 42 to 43 ° C. The power switch is turned on and off repeatedly to control the target area to the target level of temperature by irradiating the microwave with a 0.4-3GHz microwave generator Disclosed is a thermotherapy apparatus system for malignant tumors that has a function to select.

  Patent Document 2 corresponds to the output of the electromagnetic wave generating means in a hyperthermia heating device including an electromagnetic wave generating means for outputting an electromagnetic wave and an applicator for irradiating the living body with the electromagnetic wave output from the electromagnetic wave generating means. An output drop for controlling the output level of the electromagnetic wave generating means to be lowered when the temperature measuring means detects a living body temperature that is equal to or higher than a preset temperature. A hyperthermia heating device is disclosed, which is equipped with a control means.

  Patent document 3 is an apparatus for treating skin tissue with microwave radiation, a treatment surface for positioning on an area of skin to be treated, a plurality of radiating elements on the treatment surface, and microwave energy. And is arranged to emit the transmitted microwave energy outward as an electromagnetic field on the treatment surface, the power supply structure arranged to deliver the radiation to the radiating element, and As a result, during treatment, the emitted electromagnetic field has a uniform electromagnetic field distribution arranged to penetrate the area of the skin to be treated to a predetermined depth, and the skin tissue to be treated for the impedance of the radiating element. The dynamic impedance arranged to control the power supplied to the power amplifier based on the information detected by the monitoring unit. Further comprising a dance matching unit, discloses an apparatus.

JP 2008-86525 A JP 61-33668 A Special table 2010-511459 gazette

  An object of the present invention is to provide a hyperthermia support method and a hyperthermia device capable of effectively inducing apoptosis of tumor cells while preventing damage to normal cells.

  As a result of repeated studies to achieve the above object, the present invention including the following aspects has been completed.

[1] Irradiate an electromagnetic wave in the ISM frequency band to a culture medium in which tumor cells are transplanted, and measure the relationship between the electromagnetic wave irradiation amount and the tumor cell viability,
Determine a function that approximates the relationship between the measured electromagnetic radiation dose and tumor cell viability,
A method for supporting hyperthermia, comprising calculating an electromagnetic radiation dose suitable for inducing apoptosis of tumor cells formed on a body surface from a determined function.

[2] The method according to [1], wherein the function is based on a multi-target 1-hit model or a linear quadratic curve model.
[3] The method according to [1] or [2], wherein the irradiated electromagnetic wave is an electromagnetic wave in a frequency band having a center frequency of 2450 MHz.
[4] The relationship that the function approximates is the relationship between the size of the medium in which the tumor cells are transplanted and the size of the tumor cells formed on the body surface, the relationship between the tumor cell viability and the size of the medium in which the tumor cells are transplanted And / or the method according to any one of [1] to [3], further comprising a relationship between tumor cell viability and the size of tumor cells formed on the body surface.
[5] The relationship that the function approximates further includes the relationship between the electromagnetic wave irradiation amount and the medium temperature and / or the relationship between the tumor cell viability and the medium temperature, according to any one of [1] to [4] the method of.

[6] An electromagnetic wave generating means for outputting an electromagnetic wave in the ISM frequency band, a means for improving the directivity of the electromagnetic wave generated by the electromagnetic wave generating means, and the relationship between the electromagnetic wave irradiation amount and the tumor cell survival rate are approximated. Calculated by the dose determining means for calculating the electromagnetic radiation dose suitable for inducing apoptosis of tumor cells formed on the body surface based on the function and the command from the dose determiner or the dose determining means For hyperthermia, comprising means for adjusting the amount of electromagnetic wave output by the electromagnetic wave generating means according to an instruction by an operator based on the amount of electromagnetic wave irradiation, and means for arranging the body so that the electromagnetic waves penetrate into tumor cells formed on the body surface apparatus.

  According to the method or apparatus of the present invention, apoptosis of tumor cells can be effectively induced while preventing damage to normal cells.

It is a figure which shows the relationship between electromagnetic wave irradiation amount (cycle number) and tumor cell survival rate. It is a figure which shows the relationship between electromagnetic wave irradiation amount (cycle number) and temperature. It is a figure which shows the effect which electromagnetic wave irradiation has on the tumor cell growth rate. It is a figure which shows an example of the apparatus for hyperthermia of this invention.

  Next, examples of the present invention will be shown to explain the present invention in more detail. However, the present invention is not limited to the examples.

  The method for supporting hyperthermia of the present invention irradiates a medium in which tumor cells are transplanted with electromagnetic waves in the ISM frequency band, measures the relationship between the electromagnetic wave irradiation amount and the tumor cell viability, and the measured electromagnetic wave irradiation amount. A function that approximates the relationship with the tumor cell survival rate is determined, and an electromagnetic radiation dose suitable for inducing apoptosis of tumor cells formed on the body surface is calculated from the determined function. Furthermore, the method for supporting hyperthermia according to the present invention includes calculating various treatment conditions such as irradiation time and irradiation dose that can enhance the effect of cancer treatment with hyperthermia.

  An electromagnetic wave in the ISM frequency band is an electromagnetic wave having a frequency assigned by the ITU (International Telecommunication Union) for industrial, scientific and medical purposes. Specifically, the center frequency is an electromagnetic wave having a wavelength band of 433.920 MHz, 915.000 MHz, 2450 MHz, 5800 MHz, 24125 MHz, 61250 MHz, 122500 MHz, or 245000 MHz. Among these, the 2450 MHz band is preferable because a small and light permanent magnet built-in magnetron which is an electromagnetic wave generating means is available at low cost. Since electromagnetic waves in the ISM frequency band are said to penetrate from the body surface to a depth of several centimeters to several tens of centimeters, they are suitable for the treatment of superficial tumors.

  Although the tumor cell used for this invention is not specifically limited, The malignant melanoma (melanoma) cell etc. which generate | occur | produce on a body surface are preferable. Melanoma occurs in skin, intraorbital tissues, oral mucosal epithelium, and the like. The medium is not particularly limited as long as it is generally used in cell culture. The number of tumor cell colonies seeded is preferably about 100. The medium volume can be 2 ml and 4 ml, but is not limited thereto.

  Irradiation of electromagnetic waves may be intermittent irradiation or continuous irradiation, but intermittent irradiation is preferable because of easy temperature control. Intermittent irradiation performs multiple cycles with one cycle of irradiation and stopping. The irradiation time and stop time in one cycle can be set as appropriate. For example, it can be performed in a plurality of cycles, with 7 seconds of irradiation for 3 seconds stopped as one cycle. The output of electromagnetic waves is preferably 200 W to 10 kW, more preferably 300 W to 1 kW, and even more preferably 400 W to 800 W. While irradiating electromagnetic waves, noise can easily enter into electrical signals, etc., which can affect instruments. Therefore, it is preferable to create a program so that the temperature and the like are measured by instruments while the electromagnetic wave is stopped. In addition, temperature measurement using MRI (see Futagawa “Non-invasive temperature distribution measurement and dielectric heating using MRI”, Kokushikan University, Faculty of Science and Engineering Bulletin No. 7 (2014)), Temperature measurement using optical fiber thermometer (Higo) Et al., “Classification of Temperature Characteristics by Microwave Heating (Part 2) Heating Rate of Various Foods” (Japanese Journal of Home Economics Vol. 41 No. 8 733-743 (1990)) is hardly affected by electromagnetic waves. This is preferable.

  The tumor cells transplanted in the medium are irradiated with electromagnetic waves in a predetermined amount, for example, by performing intermittent irradiation for 7 seconds and stopping for 3 seconds for 1 to 10 cycles. The electromagnetic wave irradiation device 1 is preferably arranged so as to be able to irradiate electromagnetic waves from two directions facing the culture medium. Thereafter, when a predetermined time, for example, 12 hours elapses, the number of surviving colonies is counted. By this measurement, for example, the relationship between the electromagnetic wave irradiation amount and the tumor cell survival rate as shown in FIG. 1 can be obtained.

Next, a function that approximates the relationship between the measured electromagnetic radiation dose and the tumor cell survival rate is determined. As a function, for example, one target one hit type model (SF = exp (a × Dose)), multiple target one hit type model (SF = 1− (1−exp (−a × Dose)) ^b ), exponential function Type model (SF = a × b ^Dose ), linear-quadratic curve model (SF = exp (− (a × Dose + b × Dose ² ))), LQ evolution type model (SF = exp (− (a × Dose + b × Dose) ² + c × Dose ³ ))) and RCR type model (SF = exp (−a × Dose) + b × Dose × exp (−c × Dose)). Of these, a multi-target 1-hit model and a linear-quadratic curve model are preferable, and a multi-target 1-hit model is more preferable. Table 1 and Table 2 show the coefficients of a model that approximates the relationship shown in FIG. df is the degree of freedom, and AIC is the Akaike information criterion. The smaller the AIC, the better the model fit.

Next, an electromagnetic wave irradiation amount suitable for inducing apoptosis of tumor cells formed on the body surface is calculated from the determined function. For example, the dose Dose for realizing the survival rate SF in the multi-target 1-hit model can be calculated by Dose = log (1−exp (log (1−SF) / b)) / − a. . The dose Dose for realizing the survival rate SF in the linear-quadratic curve model is given by Dose = ((a ² -4 × b × log (SF)) ^1/2 −a) / (2 × b) Can be calculated.
The irradiation amount of the 2450 MHz band electromagnetic wave for realizing the 50% survival rate based on the multi-target 1-hit type model shown in Table 1 (medium 2 ml) was calculated to be about 1.5 cycles. Therefore, it can be estimated that the survival rate of the tumor cells can be reduced to less than 50% by setting the irradiation amount of the 2450 MHz band electromagnetic wave to 2 cycles in 2 ml of the medium. The irradiation amount of the 2450 MHz band electromagnetic wave for realizing the 50% survival rate based on the multi-target 1-hit type model shown in Table 2 (medium 4 ml) was calculated to be about 4.5 cycles. Therefore, it can be estimated that the survival rate of tumor cells can be reduced to less than 50% by setting the irradiation amount of the 2450 MHz band electromagnetic wave to 5 cycles in 4 ml of the medium. Furthermore, it can be estimated that the survival rate of tumor cells can be reduced to several percent by setting the irradiation amount of the 2450 MHz band electromagnetic wave to 9 cycles in 4 ml of the medium. The amount (size) of the medium is considered to correlate with the size of the tumor. The present invention relates to the relationship that the function approximates, the relationship between the size of the tumor cell-implanted medium and the size of the tumor cell formed on the body surface, the tumor cell viability and the size of the tumor cell-implanted medium. It is preferable to further include the relationship and / or the relationship between tumor cell viability and the size of tumor cells formed on the body surface. The size of the tumor formed on the body surface is measured, and the electromagnetic radiation dose suitable for inducing apoptosis of tumor cells is determined by a function that approximates the relationship between the electromagnetic radiation dose and the tumor cell viability, and the tumor cell The relationship between the size of the transplanted medium and the size of the tumor cells on the body surface, the relationship between the tumor cell viability and the size of the medium on which the tumor cells were transplanted, and / or the tumor cell survival rate and the body surface It is preferable to calculate from a function that approximates the relationship with tumor cell size.

Table 3 shows changes in the temperature of the medium when intermittent irradiation is performed with 4 ml of medium and 7 seconds of irradiation stopped for 3 seconds. The temperature of the medium at 5 cycles of irradiation was 33.8 ° C., and the temperature of the medium at 9 cycles of irradiation was 43.3 ° C. In the present invention, it is preferable that the relationship that the function approximates further includes the relationship between the electromagnetic wave irradiation amount and the medium temperature and / or the relationship between the tumor cell viability and the medium temperature. Excessive heating (for example, heating such that the cell temperature exceeds 60 ° C.) may cause cell necrosis due to acute burns. Therefore, in order to prevent acute burns, a function that approximates the relationship between the electromagnetic wave irradiation amount and the tumor cell viability, the relationship between the electromagnetic wave irradiation amount and the medium temperature, and / or the relationship between the tumor cell viability and the medium temperature. Approximate function and, if necessary, the relationship between the size of the tumor cell transplanted medium and the size of the tumor cells on the body surface, the relationship between the tumor cell viability and the size of the tumor cell transplanted medium and It is preferable to calculate an appropriate irradiation dose from a function that approximates the relationship between the survival rate of tumor cells and the size of tumor cells formed on the body surface.
Adjustment to the calculated irradiation amount can be performed, for example, by changing the electromagnetic wave output, changing the irradiation time and stop time in one cycle, or changing the number of cycles.

10 ⁶ malignant melanoma cells (3 μl) were transplanted into the left hind limb of the mouse and allowed to grow for 12 days. On the 12th day, 2 cycles of 2450 MHz band electromagnetic waves (500 W, 100 V) were irradiated for 7 seconds, and 9 cycles of intermittent irradiation with a pause of 3 seconds were performed. Thereafter, the proliferation rate of malignant melanoma cells was measured. As a control, the proliferation rate of unirradiated malignant melanoma cells was measured. This nine-cycle intermittent irradiation is an irradiation condition estimated to be a survival rate of several percent based on a function based on the multi-target 1-hit type model shown in Table 2 (medium 4 ml). The results are shown in FIG. Tumor cell growth could be delayed by 1-2 days with 9 cycles of irradiation. Since the cell cycle of malignant melanoma cells is about 18 to 24 hours, the possibility of complete necrosis of the tumor is suggested by performing daily doses of 9 cycles. In addition, the electromagnetic wave irradiation apparatus 1 was arrange | positioned so that electromagnetic waves could be irradiated from two directions facing a mouse | mouth.

  The hyperthermia device of the present invention includes an electromagnetic wave generating means for outputting an electromagnetic wave in the ISM frequency band, a means for improving the directivity of the electromagnetic wave generated by the electromagnetic wave generating means, the electromagnetic wave irradiation amount and the tumor cell survival rate. A dose determining means for calculating an electromagnetic radiation dose suitable for inducing apoptosis of tumor cells formed on the body surface based on a function approximating the relationship between the dose and a command or a dose decision from the dose determiner Means for adjusting the amount of electromagnetic wave to be output by the electromagnetic wave generating means according to an instruction input by an operator based on the electromagnetic wave irradiation amount calculated by the means, and means for arranging the body so that the electromagnetic waves penetrate into tumor cells formed on the body surface Have

As means for improving the directivity of electromagnetic waves, a directional antenna such as a parabolic antenna or a dipole antenna can be used.
As a means for determining the amount of irradiation, a program for calculating the amount of irradiation of electromagnetic waves suitable for inducing apoptosis of tumor cells formed on the body surface based on a function that approximates the relationship between the amount of irradiation of electromagnetic waves and the survival rate of tumor cells. A digital device such as a personal computer in which is installed can be used. The function is as described above. Digital equipment such as a computer is preferably shielded against electromagnetic waves in order to prevent interference of electromagnetic waves output by the electromagnetic wave generating means.
The electromagnetic wave amount adjusting means is not particularly limited as long as it can adjust the amount of current flowing to the electromagnetic wave generating means. For example, a device equipped with a known electric element or electronic element such as a switch, an electric resistor, or a thyristor is mounted. Can be used.

As the means for arranging the body so that the electromagnetic waves penetrate into the tumor cells formed on the body surface, an appropriate one can be selected depending on the part of the body where the tumor cells are formed.
For example, when an animal 3 such as a dog or a cat is targeted, the animal 3 is placed on the operating table 2 and the retainer 4 holds the animal 3. In order to prevent the retainer 4 from being unnecessarily irradiated with electromagnetic waves, it is preferable to wear gloves made of electromagnetic shielding material, surgical clothes, and the like. It is preferable that the animal 3 is also made to wear a garment made of an electromagnetic wave shielding material, a muzzle or the like so that electromagnetic waves are not irradiated as much as possible to the parts other than the tumor cells. In thermotherapy with radio waves (several MHz to several tens of MHz), irradiation for 60 to 90 minutes is required before the effect is exerted. On the other hand, in the electromagnetic wave irradiation in the ISM frequency band in the present invention, the time required for reducing the desired tumor cell survival rate is extremely short, from several tens of seconds to several hundreds of seconds. There is no need for anesthesia.

1: Electromagnetic radiation device 2: Operating table 3: Animal 4: Retainer

Claims (6)

Irradiate the medium in which tumor cells are transplanted with electromagnetic waves in the ISM frequency band, and measure the relationship between the amount of electromagnetic radiation and the survival rate of the tumor cells.
Determine a function that approximates the relationship between the measured electromagnetic radiation dose and tumor cell viability,
A method for supporting hyperthermia, comprising calculating an electromagnetic radiation dose suitable for inducing apoptosis of tumor cells formed on a body surface from a determined function.   The method of claim 1, wherein the function is based on a multi-target 1-hit model or a linear quadratic model.   The method according to claim 1 or 2, wherein the irradiated electromagnetic wave is an electromagnetic wave in a frequency band having a center frequency of 2450 MHz.   A function that approximates the relationship between the size of the medium in which the tumor cells are implanted and the size of the tumor cells formed on the body surface, the relationship between the tumor cell viability and the size of the medium in which the tumor cells are implanted, and / or The method according to any one of claims 1 to 3, further comprising a relationship between tumor cell viability and the size of tumor cells formed on the body surface.   The method according to any one of claims 1 to 4, further comprising a relationship between the electromagnetic wave irradiation amount and the culture medium temperature and / or a relationship between the tumor cell viability and the culture medium temperature in the relationship in which the function approximates.   Based on an electromagnetic wave generating means for outputting an electromagnetic wave in the ISM frequency band, a means for improving the directivity of the electromagnetic wave generated by the electromagnetic wave generating means, and a function approximating the relationship between the electromagnetic wave irradiation amount and the tumor cell viability Irradiation amount determining means for calculating an electromagnetic wave irradiation amount suitable for inducing apoptosis of tumor cells formed on the body surface, and an electromagnetic wave irradiation amount calculated by a command from the irradiation amount determining means or the irradiation amount determining means An apparatus for hyperthermia, comprising: means for adjusting the amount of electromagnetic wave output by the electromagnetic wave generating means according to an instruction input by an operator based on the above; and means for positioning the body so that the electromagnetic waves penetrate into tumor cells formed on the body surface.

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