DE2423399A1 - Irradiation of body tissue with electromagnetic waves - prevents damage to normal cells by frequency selection - Google Patents

Abstract

Apparatus for irradiating human body tissues with electromagnetic waves uses a transmitter frequency which is adjusted in accordance with a spectral line from the emission or absorption spectrum of the cells, either by comparison of frequency and/or phase with the respective spectral line for synchronisation of the transmitter oscillator, or by receiving a spectral line and re-transmitting it after a delay. The spectral line is pref. received by the tissue to be irradiated and the transmitter and receiver are switched on and off alternately one after the other and connected to a common aerial by decoupling members, e.g. directional couplers, circulators, etc.

Description

Arrangement for extremely frequency-selective irradiation of clay on human tissue with electromagnetic waves The arrangement according to the invention relates to the Entereuchungen and treatment of body tissue with the help of electro-saanetic waves The starting point for this arrangement according to the invention is US Pat. No. 3,789,832. which for the first time an early detection of cancer with the help of the reception of microwaves due to the characteristic frequencies of the radiation emitted by the cancer cell allows the effect of the irradiation with the transmitter according to the invention on one or several such characteristic frequencies has a certain parallel in newer methods for the targeted excitation of chemical reactions by laser light, e.g. in uranium enrichment The method according to the invention applies this for the first time targeted influencing of a chemical process with the help of extremely frequency selective Radiation on biochemical processes in body tissue The biggest problem in the Realization is that the frequency of the transmitter is extremely precise with the one for a chemical process, e.g. change of the molecular binding energy, corresponds to the characteristic frequency of the vibration emitted by the cell, after the range of effects is extremely small.

The frequency accuracy that can be achieved with conventional crystal oscillators and - stability is here by a few orders of magnitude too low According to the procedure According to the invention, the frequency standard emitted by the cell to be irradiated is used Frequency itself used in accordance with the ii technical measures described below of the invention for obtaining such a synchronous transmitter horn 6 exist t a) either ii sequence and phase comparison of a crystal oscillator with the received one Vibration b) or in the delayed re-radiation of the previously received Vibration of cells Care should be taken to avoid feedback effects The transmitter and receiver are preferably on the same frequency on the antenna side work, according to the invention an antenna-side, periodic keying of the antenna where appropriate, sender and receiver including sufficient breaks provided The arrangement according to the invention provides a spectrum analyzer on the receiving side is used to investigate the emission or absorption spectrum of cells, in particular of cancer cells in the body tissue, e.g. using characteristic spectral lines Cancer cells are detected in a reciprocal rhythm with the reception Microwave transmitter switched on, its frequency using the inventive Measures exactly the same as the reception frequency of the cell is the transmission energy is emitted via the antenna onto the body tissue and can stimulate the growth of the Cancer cells irradiated here with selective frequency influence influence other cells (e.g. healthy cells) are due to their different spectrum from this transmitter radiation not affected as there is no response.

This is a decisive advantage over the previously known Hyperthermia, the broad spectrum of which cannot have a frequency-selective effect.

In a further development of the invention, a Common antenna (Siiultanantenne) uses ile further components of the invention the simuitan antenna in the 1st focal point of an ellipsoidal mirror is accordingly Patent application P 24 17 263. 2 arranged, in the 2nd focal point of the to be irradiated Area of body tissue should be brought up to avoid reflections at boundary layers and to achieve optimal bonding, both the concave mirror including antenna as auoh der Rann wisohen concave mirror and body with one e.g. liquid medium (e.g. water) with the same dielectric constant as be filled in the body tissue Though the primary goal of the ingeniously unmatched method is the irradiation of human tissue, this basic arrangement can be used to the irradiation of any organic and inorganic substances as well to be used in the case of substances that do not emit self-radiating properties as a reference standard a spectral line of the absorption spectrum can be used by external energy input First to win is the subject of the invention described here is an arrangement for irradiating organic substances, preferably human tissue, with electromagnetic Waves, characterized in that the transmitter frequency by one of the following technical measures with a spectral line from the emission or absorption spectrum This substance is brought into harmony by cells a) Frequency and / or phase comparison with the relevant spectral line for synchronization of the transmitter oscillator b) Reception of a spectral line and retransmission after delay has taken place In FIG 1 is the block diagram for an arrangement according to the invention with a synchronized one Quartz oscillator specified The cell area (i) of the body (2) is located in the 2. Focal point B2 of the ellipsoidal concave mirror (3), in whose 1st focal point F1 the Antenna (4) is arranged This antenna is connected to the distributor via a line (5) (6) (e.g.

Zirkilator analogous to the Hadar technique) on the one hand with the input circuit (7) of the receiver and on the other hand with the output circuit (19) of the transmitter in this way connected that the receiver and the transmitter are decoupled from each other the cell (1) via the antenna (4) received signal is via the input circuit (7) of the mixer (8) fed from the Niso oscillator (9) via an isolation amplifier (io) on the other hand is fed.

The intermediate frequency i filter (11) produced in this mixer stage (8) is preferably passed on to the IF amplifier (12) will from the exit this. Amplifier 1r) passed the intermediate frequency via the isolating amplifier (13) to the frequency discriminator (14) l whose output difference - rectified direct voltage controls the retuning device (15), which in turn readjusts the mixer oscillator (9) automatically in such a way that the intermediate frequency frequency filter (11) In the middle pass band of the intermediate -In the quartz oscillator (16) an uninterrupted oscillating and as constant frequency as possible oscillator oscillation is generated, which is multiplied n-fold in the frequency multiplier (17) ) for radiation via the output circuit (19) and on the other hand to the mixer stage (20) In the mixer stage (20) this quartz harmonics and from the oscillation of the mixer oscillator (9) fed via the isolating amplifier (21) the intermediate frequency is preferentially created to the 2nd intermediate The phase comparison required for synchronizing the crystal oscillator (16) to the receive frequency (or its nth part) takes place in the phase discriminator (24) 1st intermediate frequency from the received oscillation of the 2nd intermediate frequency originating via the isolating amplifier (25) and on the other hand the quartz harmonics Isolation amplifier (26) fed to the phase discriminator (24).

The differential directional voltage of the phase discriminator (24) controls the retuning device (27) of the crystal oscillator (16) in the sense of an indirect Synchronization and enforces frequency equality of transmit and receive frequency, if the quartz frequency is so close before the start of the synchronization station its nominal value was located, so that the crystal frequency is in the capture range of the synchronization has found.

In the event that the oscillator frequency of the crystal oscillator (t6) is not yet within the joint range, an additional signal is obtained in an additional frequency comparison circuit of the frequency comparator (28), the frequency multiplier (29) and the frequency multiplier t30) The size and polarity of the frequency deviation of the quartz harmonics is proportional to the receiving frequency 2. 2 intermediate frequency n. 2) is multiplied.

to their n-fold value (e.g.

At these two different multiples of the two intermediate frequencies, a third intermediate frequency arises in the Msch stage (31) as a differential frequency the vol filter (32) is preferably led to the amplifier (33) and from there to the frequency discriminator (28). 21) or the niche levels (8) or (20) switches on and off alternately.

2 shows the block diagram of a further arrangement according to the invention, which uses a delay line instead of a synchronized oscillator ) and fed via the line (5) to the circulator (6). From there, the receiving signal arrives via the input circuit (7) to the milk stage (8), which is fed by the isolating amplifier (9) with the n - th harmonic of the quartz oscillator (11) The intermediate frequency of the received oscillation produced in the mixer stage (8) passes through the filter (12) preferably to the IF amplifier (13) and from there to the mixer stage (14) Double super principle, the 2nd mix with the oscillator oscillation of the 2nd quartz oscillator8 (15).

The 2nd intermediate frequency resulting from this 2nd mixture reaches the 2nd IF amplifier (17) via the IF filter (16) and is fed there to the ultrasonic delay line (18) - Auxiliary carrier (443 NEz) is selected, one or more commercially available ultrasonic delay lines with z. B. 64 1 sec delay time per line can be used From the output of the delay line (13) the delayed signal passes through the amplifier (19) and the filter (20) to the mixer (21) t which this delayed signal with the help of the 2nd oscillator oscillation in the 1st IF range is back-transformed This delayed signal, whose frequency is exactly the same as the first intermediate frequency, preferably arrives via the ritter (22) amplifier (23) and from there to the mixer (24), which as an oscillator vibration via the amplifier (25) generates the n - th harmonic of the 1st crystal oscillator (11).

The differential frequency is created by mixing in the mixer (24) its frequency is exactly the same as that of the cell's microwave received by the antenna agrees if the nth harmonic is selected above the receive frequency This differential frequency is transmitted via the transmitter stage (26) and the output circuit (27) preferably for A radiation via the circulator (6) and the antenna (4).

The sum frequency occurring at the same time at the output of the mixer (24) is suppressed in the output circuit (27).

The double super principle was used for the optimal "mirror selection" Highest possible first intermediate frequency selected The clock generator (28) switches, with the interposition of sufficient breaks, the receiver and the transmitter reciprocally on and off The sum of the on-time and a break should be about the running time the delay line (18) correspond as a result of the one after the other The transmitter frequency can change between reception and transmission due to frequency fluctuations of the oscillator gates within the switchover pause from reception to transmission and during the sending time deviate somewhat from the setpoint. According to the invention, the operating voltages and control voltages for the oscillators with high-capacity storage capacitors sieved and the Umachaltzeiten chosen sufficiently short, so that such Yrequensanderungen be reduced to a minimum There is a further increase according to the invention in that at least one oscillator with a different from the switching frequency, z.fl. lower, modulation frequency fm is frequency-modulated with the frequency deviation should be in the order of magnitude of the frequency fluctuations mentioned above, so that at least for a long time after the turning point, the transmitter frequency is certain is in the resonance range of the spectral line.

In the event that either at the same time or one after the other on several Spectral lines to be received or sent can either according to the invention several receivers and transmitters connected in parallel for the respective spectral lines can be switched on or off at the same time or with only one receiver and transmitter the oscillators switched in successive switching cycles and thus the respective spectral lines are received and sent one after the other The Wobbel principle is used for recording the emission or absorption spectrum "the local oscillator of the receiver periodically frequency-modulated sufficiently slowly The IF signal is given preference over an extremely selective filter to an AN demodulator From the output of the AM demodulator, the signal can either be srektrum an oscilloscope screen for display and diagnosis or an automatic spectrum analyzer, which is programmed for certain spectra are forwarded to Tn continuation The inventive measures can be used for very high frequencies (e.g. in the range of Light rays of visible light and above) the frequency measurement at the receiving end both the received emission or absorption spectral lines with the for physical measuring methods (diffraction grating etc. ) be performed

Claims (17)

Claims arrangement for the irradiation of organic slab dances , preferably human tissue with electromagnetic waves, marked thereby -net, that the transmitter frequency with one of the following technical measures a spectral line from the emission or absorption spectrum of cells of this Substance is reconciled with: a) Frequency and / or phase comparison with the relevant spectral line for synchronization of the transmitter oscillator; b) Receipt of a spectral line and retransmission after the delay has taken place 2. Arrangement according to claim 1, characterized in that the spectral line from the to be irradiated Tissue area itself is received 3. Arrangement according to claim 2, characterized in that that the receiver and the transmitter alternately on and off one after the other - are switched 4. Arrangement according to claim 32, characterized in that the transmitter and receiver are connected to a common antenna via decoupling elements such as directional couplers, circulators, Circuits with switching diodes etc. are connected 5. Arrangement according to claim 4, characterized characterized in that the information received is about the frequency of the spectral line from the receiver for at least the duration of the pause between receiving and sending and the transmission time is saved 6. Arrangement Moh claim 5 characterized that the storage in frequency and phase envergl ei chs arrangements for synchronization of the transmitter oscillator. 7. Arrangement according to Ansplauh 52 dadurc} gekes, indicating that the storage is done in delay lines 6. Arrangement according to claim 1, characterized characterized in that the spectral line is to be irradiated from a tissue region outside of the -the area is received 9. Arrangement according to claim 1, characterized that the spectral line is received by a frequency standard provided in the device 10. Arrangement according to claims 8 and 9, characterized in that the transmitter continuously or amplitude-modulated during the entire duration of irradiation or touched shines 11. Arrangement according to claims 1 to 10, characterized that the antenna is arranged in the first focal point of an ellipsoidal concave mirror and the tissue area to be irradiated is brought into the 2nd focal point of this concave mirror will 12. Arrangement according to claims 1 to 6 and 11, characterized in that the waveform of the receiver and transmitter corresponding to that shown in FIG Sequence of technical measures expires. 13. Arrangement according to claims 1 to 5, 7 and 11, characterized gekeunzeich -net that the waveform of the receiver and transmitter corresponds to that shown in FIG Sequence of technical measures expires. 14. Arrangement according to claims 1 to 13, characterized that the operating voltages and the control voltages for the oscillators with storage capacitors high capacity can be sieved 15. Arrangement according to claims 1 to 14, characterized characterized n that the oscillators are housed in thermostats 16. Arrangement according to Claims 1 to 15, characterized in that the transmitter frequency is frequency modulated with an additional modulation frequency, the frequency deviation in the order of magnitude of the remaining frequency fluctuation to be expected in the transmitter frequency is chosen 17. Arrangement according to claims 1 to 16, characterized that the receiver and transmitter are operated in the microwave range Blank page