GB2248552A - Adhesive plaster for treatment at acupuncture points using ceramic semiconductor - Google Patents

Abstract

A kind of fine ceramics semiconductor 1, which is mainly made of transition metal oxides such as managanese, cobalt, iron, and nickel, is attached on the base 4 of plaster 2 by a layer of glue 3. First, while the devices are applied on the traditional acupuncture vital points of body skin, they absorb thermal energy of the body and irradiate far ultra-red rays. Secondly, the fine ceramics semiconductors 1 can be ionized by acting with electrolytes (such as perspiration) excreted from minute pits of skin. These two effects work together and provide as a good remedy as the traditional acupuncture for human illness. <IMAGE>

Description

FINE CERAMICS SEMICONDUCTOR NEEDLELESS ACUPUNCTURE PLASTER SPECIFICATION At present few people can be skillful with traditional acupuncture technique although it is a good medical remedy.

Nonprofessionals can not manipulate it. therefore it is impossible for the public to get benefits conveniently from it. Moreover, patients suffer from the electrical treatment of stimulating body cells with electrical current.

This device transcends the traditional acupuncture on these defects. It has significant effects. induces no pain and can be used without limit of experience. Thus it has high value of medical application.

This invention is a kind of fine ceramics semiconductor needleless acupuncture plaster and the device is a kind of fine ceramics semiconductor made of sintered compounds of transition metal oxides. When the devices are attached on acupuncture vital points of body skin with proper numbers.

they can be ionized by acting with skin electrolytes (such as perspiration) thus induce electric impulses. On the other hand, the emitting far ultrared rays can resonate with body and raise the momenta of structural atoms. These two effects can activate cellular functions and cure patients of their illness.

For your judging commitee to realize more details of the structure, special feature, purpose etc. of this invention, herewith illustrated with figures and some samples as follows: Figure 1 is a sectional lateral view of the present invention; and Figure 2 is a perspective view perspective view of the present invention Original samples: OMOU TSUBO OMOU TSUBO OMOU TSUBO The present invention comprises: Manganese bioxide (Mn 02) 25% + - 5 Iron glance (Fe2 03) 25% + - 5 Cobaltic oxide (Co3 04) 25% + - 5 Nickelic oxide (Ni2 03) 25% + - 5 The present invention is made by the following procedures: A: Mixing and churning the materials above; B: Put the materials in slurry mixer to make scurry; C: After dehydration make the slurry materials into thin sheets which then cut with mould cutter; D:Bake the thin sheets with over 1240 degrees C high temperature heater; E: Put the baked sheets in ball mill to round off the R angle; F: After final performance test. the fine ceramics semiconductor 1 is stuck on plaster 2.

The present invention is obtained and possesses the specification as follows: A: Structure: (see Figure 1 and Figure 2) The prepared fine ceramics semiconductor 1 squares are attached on the base 4 of plaster 2. The are connected by glues 3.

B: Size of the fine ceramics 1: 3mm x 3mm x 0.3mm C: Hardness of the fine ceramics L: 650 | + - 150 HV (tested under 200 g force, 10 seconds duration ) D: Surface roughness of fine ceramics 1 : 10# m + -3S m E: Wavelength of emitting far ultra-red rays: Ay m to 308 m ( micron) F: Ion concentration: 200 ppb/g to 500ppb/g as contacting with electrolytes (100 ml pure water 36 degrees C. after 24 hrs: analyzed by Atomic Absorption Spect rophotomet er) The devices are used by attaching on relevant acupuncture vital points of traditional Chinese acupuncture.

They have the same clinical effects that of the traditional Chinese acupuncture.

When the devices are applied onto body skin, the transition metal oxide in the ceramics devices are ionized b acting with electrolytes ( such as perspiration ) excreted from minute pits of skin. The ion concentration is abort 200 ppb/g to o00ppb/g at 36 degrees C after 24 hours.

The small amount of electrons induced by ionization will diffuse into epidermis (including stratum corneum.

stratum lucidum, stratum granulosum, stratum spinosum and stratum basal), further into dermis through conduction of electrolytes (such as perspiration) excreted from skin.

The electrons further diffuse into extracellular fluid of muscle cells and nerve cells, reducing the resting potential of these cells. and causing slow depolarization of cell membranes. As the membrane potential approaches the threshold potential, an action potential (AP) is produced.

The AP propagates on axon to mal-functional target tissue and fasten its recovery. The resting membrane of nerve or muscle cells has very efficient sodium pumps that active-i transport sodium ions out of the cell against a concentration gradient and transport potassium ions into the cell. It results in the presence of a slight excess of negative ions inside the cell membrane and a slight excess of positive ions outside. The resting cell is said to be electrically "polarized". and the potential difference across the membrane is about -70 mv. (called "resting potential"). An electrical, chemical or mechanical stimulus may alter the resting potential, by increasing the permeability of the plasma membrane to sodium ions to the self-propagating electric impulse called "action potential".

which is about ones to tens of mv. In a resting excitable cells (such as nerve cells or muscle cells), the outer surface of the cell membrane is positively charged compared with the inside surface because large numbers of negatively charged proteins and organic phosphates within cells are too big to diffuse out. When the electrons released from the ionized fine ceramics semiconductor 1 diffuse into extracellular fluid of the the cells, the membrane potential lowers down, that is. the membrane depolarizes.

As the extent of depolarization reaches above the threshold level. an AP is produced. The cell membrane quickly reaches zero potential and overshoots to tens of mv so that there is a momentary reversal in polarit. By the time the AP moves a few millimeter along. the axon. the membrane over which it has just passed begins to repolarize The succeeding electric impulses within an axon are transmitted from one cell body to another neurons or ganglion, and then to brain cortex ( the same passway as in traditional acupuncture ), finally arrive at mal-functional target tissue.

By attaching the fine ceramics semiconductors on specific acupuncture points, the electrical impulses will activate the acupuncture points and promote the blood circulation of the mal-functional target tissue thus fasten its recovery. Comparison between "traditional acupuncture" and "fine ceramics semiconductor. needleless acupuncture plaster on their effects and mechanisms:

Traditional Acupuncture : FCS Needleless Acupuncture I case (Lumbago) ' case (Lumbago) I I I I Treatment: : Treatment: Push the needles on acu- : Attach the devices on acu | | | puncture vital points (B23,' puncture vital ponts (B23, | , B2s, B31, Yes points) : B25, B31, Yes points) I | | | Passways: : Passways: : | 1. Mechanical stimuli pro- : 1. The electrons released | | duced by spearing the : from the ionized transi specific acupuncture : tion metal oxides diffuse | | points induce electric : into dermis through epi | | | impulses on cell mem- : dermis. I | | brane of excitable : 2. The diffusing electrons f

cells : induce cells and the | 2. 2. The impulses travel to ', action potentials are I | | ganglia : produced | | 3. Then to sensory nerves : 3. The action potentials arel I I 4. 4. To brain cortex - ', transmitted on axons to | | 5. 5. To motor nerves ', nerve cells and ganglia 6. And I 6. And reach target tissue. : 4. The impulses travel on | | | sensory nerves | | | 5. and reach brain cortex I I 6. ', 6. then through motor nerves | | | 7. , 7. to mal-functional target | tissue.

Fine ceramics semiconductor 1 is made of transition metal oxide compounds sintered above 1000 degrees C. It is called "fine" ceramics for it can only be observed on electron microscope (Magnified 50,000 times). When the devices is attached on human skin above 36 degree C it can irradiate FUR (Far ultra-red rays) of 4 micron to 30 micron long.

Resonance effect of the fine ceramics semiconductor 1 to FUR emitting from human body: Human body is a natural irradiating source of ultra-red rays. About 45% of the energy emitting from human skin is 3 micron to 50 micron length of ultra-red rays. 46% of energy radiating from a whole body is FUR of 8 micron to 14 micron.

Only 1% of it drops on 3.2 micron to 4.8 micron range.

Atoms which construct materials are expanded and contracted their distance among one another to keep themselves from turning, and they have their own specific frequencies.

As one places a compound and simultaneously irradiates it with the same frequency of electromagnetic energy as of the vibration of its certain kind of constructive atoms, the atoms may absorb the energy through a process known as "magnetic resonance , which can raise the momenta of the atoms and the atoms then emit the radiation in various part of an electromagnetic spectrum ( or heat ). The fine ceramics semiconductor 1 attached on body skin can irradiate 4 micron to 30 micron length of FUR. Through the process of "magnetic resonance" to the 8 micron to 14 micron FUR emitting naturally from human body, the device can promote the momenta of atoms of human body and produce heat.

Effects of the fine ceramics semiconductor FUR to human body: A. It can raise the temperature of deep tissues of living body and activate the malfunctional cells.

B. It can promote the blood circulation by dilating blood capillaries.

C. It can activate the metabolism of circulatory system and other tissues.

D. It can strengthen the regenerative and analgesic ability of tissues.

E. It can inhibit the abnormal excitability of sensory nerves.

F. It can regulate the functions of automatic nerves.

G. It functions as satisfactorily as traditional acupuncture when it is attached on acupuncture vital points.

H. It can influence deep tissues of body and remains no trace.

For a better understanding of the clinical effects of the present invention, please refer to the accompanying Clinical Report of the fine ceramics semiconductor needleless acupuncture plaster by the China Medical College Hospital Acupuncture Department, September 15, 1990.

(Appendix 1)

Claims (3)

1. A kind of fine ceramics semiconductor which made of transition metal oxides such as manganese, cobalt, iron and nickel mixed, shaped at a proper ratio and sintered at high temperature, then finished after cutting and surface sanding.

2. A semiconductor as defined in claim 1 which is attached on plaster.

3. A semiconductor substantially as hereinbefore described with reference to and as shown in the accompanying drawings.