DE102017118333A1 - Device for light treatment of diseased internal organs - Google Patents

Abstract

The invention relates to a device for light treatment of diseased internal organs, which has a source of yellow light, optical fiber cable and a sensor mini-nanomicroscope, wherein as a source of yellow light in front of the entrance of a connecting head, a halogen lamp with a power of 150 watts with a light glass filter 19 and the sensor mini-nanomicroscope is made in the form of two glass plates placed one above the other with an offset of up to 5 mm and with the formation of a gap between them of up to 7 μm, further comprising the sensor mini-microscope. Nanoscopic microscope and the light guide cable are mounted on opposite ends of an electrically insulating tube and the distance between the end-side emitting end of the optical fiber cable and the sensor mini-nanomicroscope is 25 - 30 mm.

Description

The present invention relates to the medical field, namely a means for light treatment of diseased internal organs through the skin surface of living beings in diagnostic zones and in the head zakharjin zones.

The current task of today's medicine is to improve safe and highly efficient early treatment at the supramolecular level, which is available to everyone.

In this context, there is a need to broaden the selection of technical medical devices for highly efficient supramolecular treatment. At present, there is no such development work.

For a long time it has been known that the skin is one of the most important building blocks that make up the health of the body as a whole. All skin segments are connected to all internal organs of our body. Diagnostic zones and head zakharjin zones are specific areas of the skin in which internal organs often suffer from pain in transmission and pain and temperature hyperesthesia.

The occurrence of diagnostic zones and head zakharjin zones is associated with the irradiation of irritations emanating from the affected internal organ, which are conducted from the nerve fibers passing through the organ to specific centers where these fibers terminate.

It is known that the skin forms a tissue system of three components. These consist of epidermis, dermis and hypodermis, which form a morphofunctional unit and consist of a variety of functional and structural elements.

The Japanese scientist Suti has proved through experiments that the outer layer of the epidermis is very dry and that only under the second layer are many cavities with intercellular fluid leading to a substantial reduction in resistance.

Based on the results obtained, Suti has concluded that the point at which the substantial reduction in resistance occurs is in the outer layer of Stratumergerminativum and that the epidermis divides into a dry outer layer and a very moist inner layer. Also, Suti has found that increasing the filtration of fluid from the dilated skin vessels under the influence of human heat does not result in any changes in the level of fluid in the skin. This confirms the autonomy of the system of intangible perspiration (skin respiration).

In the total amount of imperceptible perspiration, even the maximum perspiration through the sweat pores obviously does not take up any significant place, since the total area of the sweat pores is very small and is about 90 cm ² , while the total area of the body is 1.8 m ² .

It is known that one can observe an excretion of water on a corpse. Although in this case less water is excreted than in the case of imperceptible perspiration in living people, this fact proves the penetration of the epidermis through the water.

Even in the days of Hippocrates was known that water vapor can escape from the body through the skin.

Galen has argued that perspiration, though imperfect, occurs constantly and evenly over the entire surface of the body (Jas Kuna, 1961).

In this connection, it is pointed out that only the blood itself from all internal organs and systems of the living being has a direct and back connection with the outside world through the system of intangible perspiration. Consequently, there are reasons to suggest that any affect on the skin of the animal is immediately transferred to the "blood system" through the constant contact "blood - imperceptible vapor - external agent". Therefore, light treatment of the skin surface of diagnostic zones and head zakharjin zones immediately reaches any pathological cell.

In this context, an experiment was carried out: infrared spectrobiopsy of the blood from the non-irradiated skin of the hand. With the essential difference of the data of the spectrobiopsy of the blood on both sides of the surface of the non-irradiated hand (palm and back of the hand) it is shown that each diagnostic zone and head zakharjin zone of the projection of the internal organs on the skin surface an individual and unique spectrobiopsy of the Have blood. This is very important and perspective for the development of a bank of spectrobiopsy of the inconspicuous blood.

In this context, a special sensor mini-nanomicroscope has been developed, through which a direct and backward connection with all cells of the living being is carried out.

Due to the device, the light transport of yellow light for medical purpose in the internal organs of the living being is performed by the epidermis. Immediately after light treatment, it is possible to perform the spectrobiopsy of the blood, which at the given moment presents a full picture of the interaction of the light with the animal at the supramolecular level. The proposed device for light treatment of diseased internal organs has the source of yellow light, a light pipe, and a sensor mini-nanomicroscope. In this case, a halogen lamp with 150 watts with a glass filter No. 19 is arranged as the source of the yellow light in front of the entrance of a connecting head of the optical fiber cable. The sensor mini-nanomicroscope is designed in the form of two glass plates, which lie one above the other with an offset of up to 5 mm and with a gap between them up to 7 μm. In addition, the sensor mini-nanomicroscope and the light guide cable are mounted on the opposite ends of an electrically insulating tube. The distance between the end-face emitting end of the fiber optic cable and the sensor mini-nanomicroscope is 25-30 mm. The glass plates are equipped with the contacts with a double output for connection to a Fourier Spectroscope "Vector 22". An electrically insulating tube is made of corrugated flexible material. The invention provides a "direct and reverse linkage" to the internal organs of the animal at the supramolecular level.

The displacement of the plates up to 5 mm is due to the fact that the space created between the skin and the upper glass plate and between the glass plates is sufficiently large for the direct contact of the imperceptible vapor emanating from the blood together with the yellow light. Increasing the offset leads to a reduction in the area of mutual contact of the glass plates, resulting in the exclusion of the tunneling effect, which is a very perspective way of penetrating the yellow light into the internal organs of the body at the supramolecular level.

The gap between the plates up to 7 μm is necessary for the tunneling effect in the course of the light treatment, i. that is, the sensor acquires the function of a tunneling scanning microscope to fully detect all cells of the whole body at the supramolecular level.

The optimum distance between the end-side emitting end of the optical fiber cable and the sensor mini-nanomicroscope is 25-30 mm. As this distance decreases, the undesirable heating effect during light treatment with the yellow light having a wavelength of 480-3400 nm increases. As it is enlarged, the illumination diminishes; that is, the distance of 25 - 30 mm is best suited to the formation of a uniform illumination of the attack surface.

• 1 eine infrarote Spektrobiopsie des Bluts aus der nicht bestrahlten Oberfläche der Haut der Hand;

  -

  Innenhandfläche

  -

  Rückhandfläche

• 2 eine Fotoaufnahme des Sensor-Mini-Nanomikroskops mit:

  1

  obere Glasplatte

  2

  untere Glasplatte

  3

  Silberkontakt der oberen Glasplatte

  4

  Silberkontakt der unteren Glasplatte

  5

  Ausführungen der Glasplattenkontakte

• 3 ein Sensor-Mini-Nanomikroskop mit dem Lichtleitkabel

  Ansicht 1

  seitliche Darstellung der größeren Seite des Sensor-Mini-Nanomikroskops

  Ansicht 2

  Darstellung des Sensor-Mini-Nanomikroskops von oben

  Ansicht 3

  seitliche Darstellung der kleineren Seite des Sensor-Mini-Nanomikroskops

  Ansicht 4

  Darstellung des Sensor-Mini-Nanomikroskops von oben mit

  1

  Sensor-Mini-Nanomikroskop

  2

  oberer Glasplatte

  3

  unterer Glasplatte

  4

  Kontakt der oberen Glasplatte

  5

  Kontakt der unteren Glasplatte

  6

  Ausführungen der Kontakte der Glasplatten

  7

  nichtmetallischem Flexrohr

  8

  Raum zwischen der Oberfläche der Haut des Lebewesens und der oberen Glasplatte mit Übergang in den Raum zwischen zwei Glasplatten (7 µm), der den unmittelbaren Kontakt des Bluts durch das Perspirationssystem (Absonderung der Flüssigkeit aus dem Blut in die Umgebung in Form des unfühlbaren Dampfes) durch die Epidermis gewährleistet

  9

  Lichtleitkabel

• 4 ein Schema des Zusammenwirkens der Einrichtung zur Lichtbehandlung mit dem Lebewesen

  Ansicht 1

  Einrichtung in der Bereitschaft zur Lichtbehandlung

  Ansicht 2

  Stelle der Wirkung des gelben Lichts auf der Oberfläche der Haut des Lebewesens

  1

  Lichtquelle, Halogenlampe 150 Watt mit einem gelben Lichtglasfilter Nr. 9, Ø 72 mm, der in eine Metallkiste eingebaut ist

  2

  Verbindungskopf, der in die Öffnung der Metallkiste (1) hineingesteckt ist und die Lichtquelle mit dem Lichtleitkabel verbindet

  3

  Lichtleitkabel

  4

  pyroelektrischer Empfänger DTGS

  5

  Spektrometer Bruker „Vector 22“

  6

  Spiegellinsen-Apparat für die Verbindung der Einrichtung zur Lichtbehandlung mit dem Fourier-Spektrometer „Vector 22“

  7

  Computer

  8

  Bürstenauswahlschalter

  9

  Kontaktanschluss aus der losen Faser AgCIBr

  10

  Oberfläche der Haut des Lebewesens

  11

  Sensor-Mini-Nanomikroskop

• 5 eine infrarote Spektrobiopsie des Bluts aus der Rückhandfläche der Haut der rechten Hand nach der Bestrahlung mit dem gelben Licht während 10 Minuten und aus der nicht bestrahlten Haut.

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  Rückhandfläche der bestrahlten Hand

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  Rückhandfläche der nicht bestrahlten Hand

In order to understand the spirit of the invention, it has been illustrated in drawings and floor plans. Show it:

• 1 an infrared spectrobiopsy of the blood from the non-irradiated surface of the skin of the hand;

  -

  Palm of the hand

  -

  Backhand area

• 2 a photo of the sensor mini-nanomicroscope with:

  1

  upper glass plate

  2

  lower glass plate

  3

  Silver contact of the upper glass plate

  4

  Silver contact of the lower glass plate

  5

  Versions of the glass plate contacts

• 3 a sensor mini-nanomicroscope with the light guide cable

  View 1

  Side view of the larger side of the sensor mini-nanomicroscope

  View 2

  Representation of the sensor mini-nanomicroscope from above

  View 3

  Side view of the smaller side of the sensor mini-nanomicroscope

  View 4

  Representation of the sensor mini-nanomicroscope from above with

  1

  Sensor Mini Nano microscope

  2

  upper glass plate

  3

  lower glass plate

  4

  Contact of the upper glass plate

  5

  Contact of the lower glass plate

  6

  Versions of the contacts of the glass plates

  7

  non-metallic flex tube

  8th

  Space between the surface of the skin of the living being and the upper glass plate with transition into the space between two glass plates (7 microns), the direct contact of the blood by the Perspirationssystem (secretion of the liquid from the blood into the environment in the form of imperceptible vapor) through the epidermis

  9

  optical cable

• 4 a scheme of interaction of the device for light treatment with the living being

  View 1

  Device in readiness for light treatment

  View 2

  Place the effect of yellow light on the surface of the skin of the animal

  1

  Light source, halogen lamp 150 watts with a yellow light glass filter No. 9, Ø 72 mm, which is built into a metal box

  2

  Connecting head, which is inserted into the opening of the metal box (1) and connects the light source with the light guide cable

  3

  optical cable

  4

  pyroelectric receiver DTGS

  5

  Spectrometer Bruker "Vector 22"

  6

  Mirror lens apparatus for the connection of the light treatment device with the Fourier spectrometer "Vector 22"

  7

  computer

  8th

  Brush selector switch

  9

  Contact connection made of loose fiber AgCIBr

  10

  Surface of the skin of the living being

  11

  Sensor Mini Nano microscope

• 5 an infrared spectrobiopsy of the blood from the back of the skin of the right hand after irradiation with the yellow light for 10 minutes and from unirradiated skin.

  -

  Backhand area of the irradiated hand

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  Backhand area of unirradiated hand

It is known that the light at the boundary of the distribution glass-air at a very large angle to the outside does not go out and reflects inside the glass, that is, there is a full internal reflection. But if a similar glass is brought closer from the other side, forming an air gap of about one micron, then the light can overcome this insurmountable barrier and jump over to the second glass. This is called full internal reflection, d. H. Tunnel effect.

At the beginning of 1908, Gerd Binnik and Henrich Rorer, employees of the Swiss department IBM, developed a device with which it is possible to observe individual atoms of a substance. In this device, a quantum phenomenon of the tunnel effect was applied, and this was called a "raster tunnel microscope".

The idea is that a very fine needle probe with an atomic tip is guided at a distance of 1 nm over the surface of an object. According to the law of quantum mechanics, the tunneling effect arises in this way: electrons overcome the vacuum barrier between the object and the needle in the "pattern-needle" chain; the stream starts to flow.

In this connection, the present invention corresponds to the above-mentioned scanning tunneling microscope. This was used by us for light treatment, d. h., with the sensor mini-nanomicroscope, the light (electromagnetic waves) reaches each cell of the entire body in curative intent.

Yellow light with a wavelength of 480 - 3400 nm of the light source in 4 (1) falls through the light guide of the 3 (9) . 4 (3) on the surface of the glass plate of the sensor mini-nanomicroscope the 2 (1) , Then the light penetrates through the lower glass plate of the 2 (2) that interfere with the surface of the skin 4 (10) contacted by the Perspirationssystem (excretion of the fluid from the blood in the form of imperceptible vapor through the epidermis) and is after 3 (8) with the blood immediately brought to all cells of the living thing.

1. 1. Silberkontakt der unteren Glasplatte nach 2 (4);
2. 2. Perspirationsdampf, der aus dem Blut durch die Epidermis herausgeht und den Raum zwischen der Oberfläche der Haut und der oberen Glasplatte nach 3 (8) besetzt;
3. 3. Tunneleffekt: Komplexe aus dem Perspirationsdampf im Raum zwischen der Haut und der oberen Glasplatte, zwischen zwei Glasplatten, 7 µm dick, zusammen mit der Haut und zwei Glasplatten, funktionieren als „Raster-Tunnel-Mikroskop“.

In connection with this, the present device contacts the skin simultaneously in three ways:

1. 1. Silver contact of the lower glass plate after 2 (4) ;
2. 2. Perspiration vapor emerging from the blood through the epidermis and following the space between the surface of the skin and the upper glass plate 3 (8) occupied;
3. 3. Tunnel effect: Complexes of perspiration vapor in the space between the skin and the upper glass plate, between two glass plates, 7 μm thick, together with the skin and two glass plates, function as a "Scanning Tunnel Microscope".

Therefore, with this invention, at any time, without removing the sensor mini-nanomicroscope from the surface of the skin, the reliability of the above can be checked, the device from the source of yellow light with its further connection by the switch button after 4 (8) to the spectrometer Bruker "Vector 22" off. This is a spectroscopy of the blood, a spectrobiopsy of the blood, with the efficiency and importance of the currently performed light treatment at the supramolecular level are shown and detected. This is the unique feature of the present invention; a "direct and back connection" with the internal organs.

Claims (3)

Device for light treatment of diseased internal organs, which has a source of yellow light, light guide cable and a sensor mini-nanomicroscope, wherein mounted as a source of yellow light in front of the entrance of a connecting head, a halogen lamp with a power of 150 watts with a light glass filter no and the sensor mini-nanomicroscope is designed in the form of two glass plates that are placed one above the other with an offset of up to 5 mm and with the formation of a gap between them up to 7 μm, further comprising the sensor mini-nanomicroscope and the fiber optic cable are mounted on opposite ends of an electrically insulating tube and the distance between the end-side emitting end of the optical fiber cable and the sensor mini-nanomicroscope is 25-30 mm. Setup after Claim 1 , characterized in that the two glass plates are equipped with silver contacts in double design for the connection of a Fourier spectroscope "Vector 22". Setup after Claim 1 , characterized in that the electrically insulating tube is made of a corrugated flexible material.

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