KR20110090508A - Multiple-frequency exposure unit for in vitro experiment - Google Patents

Abstract

PURPOSE: A multiple-frequency exposure apparatus for an in vitro experiment is provided to effectively performing cell experiment under the similar condition with real situation. CONSTITUTION: A multiple-frequency exposure apparatus for an in vitro experiment comprises: a multiple-frequency source(10) which provides by synthesizing CDMA frequency signal and WCDMA frequency signal; an RF radiation chamber(20) having a plurality of petri dishes containing cells; a cooling device(40) for maintaining the temperature of RF radiation chamber inside; and an carbon dioxide tank(50) and an incubator.

Description

Multiple-Frequency Exposure Unit for In Vitro Experiment

The present invention relates to a multi-frequency exposure apparatus for in vitro experiments, and more specifically, a cell for studying the effects of electromagnetic waves on the human body by scanning a variety of CDA (CDMA) and WUDMA (WCDMA) signals The present invention relates to a multi-frequency exposure apparatus for in vitro experiments that can effectively conduct experimental research.

With the recent increase in the use of electronic devices, many questions have been raised about the adverse effects of electromagnetic waves emitted from these radio facilities and devices on the human body, and consumer anxiety is also increasing.

Misunderstanding and anxiety about the vague electromagnetic waves are increasing the possibility of social disruption and economic loss.

In addition, with the development and dissemination of personal mobile communication devices, the probability of exposure of the human body to electromagnetic waves is increasing. In addition, there is a movement to establish regulations on human exposure of electromagnetic waves at home and abroad, and research for preparing the basis is actively being conducted.

The quantitative evaluation of the current electromagnetic wave is made by measuring the Specific Absorption Rate (SAR).

In addition, the study of the effect of electromagnetic field on the human body can be largely divided into cell experiment study (in vitro test study), animal experiment study, epidemiological study, and volunteer study in humans. Of these, in vitro laboratory studies may provide important insights into the basic mechanisms of biological effects due to electromagnetic field exposure, while biological experiments may be more convincing about the detrimental health effects, whether for animals or humans. There is an advantage in providing evidence that can be used, and epidemiological studies can provide the most direct information about the effects on the human body.

However, in order to ensure objectivity and scientific validity of the research results, the World Health Organization (WHO) provides accurate assessment of the exposure dose, strength of electromagnetic steel or absorption rate (SAR), exposure signal and environment similar to the actual situation, sufficient sample number and reproducibility. Emphasis is placed on experiments. Therefore, in cell and animal experimental studies, the establishment and confirmation of the correct dosage is very important. In addition, the World Health Organization (WHO) requires that the accuracy of the exposures be at least 30% in order to obtain internationally recognized results in biological experiments on exposure to electromagnetic waves. In addition, in the long-term exposure experiment, it is necessary to monitor the exposure environment periodically and perform the experiment by the user.

Various electromagnetic wave exposure apparatuses have been manufactured and provided for biological experiment research including cell experiments and animal experiments satisfying the above conditions.

Conventional electromagnetic wave exposure apparatus is manufactured to be exposed to only one frequency by using the resonance characteristics, it is mainly used for the study of cell exposure experiments for a single frequency.

However, when the actual human body is exposed to electromagnetic fields, simultaneous exposure to various frequencies is made, and thus, it is impossible to perform a cell experiment close to the actual situation by the conventional electromagnetic wave exposure apparatus.

The present invention has been made in view of the above points, and the frequency of electromagnetic waves can be simultaneously exposed to various choices such as CDA (CDMA) and WUDMA (WCDMA) signals, so that the effect of electromagnetic waves on the human body is more. It is an object of the present invention to provide a multi-frequency exposure apparatus for in vitro experiments, which can effectively conduct cell experiment studies under conditions close to the actual situation.

An embodiment of a multi-frequency exposure apparatus for an in vitro experiment according to the present invention comprises a multi-frequency generator for synthesizing and providing a CDMA frequency signal and a WCDMA frequency signal, and transmitting from the multi-frequency generator An RF radiation chamber in which an antenna radiating the synthesized frequency signal and a plurality of Petri dishes containing cells for an electromagnetic wave exposure experiment are installed therein, and a cooling apparatus for maintaining a temperature inside the RF radiation chamber; And a carbon dioxide tank and an incubator to supply carbon dioxide to keep the pH of the culture medium neutral during prolonged cell exposure experiments.

A control device is connected to the multi-frequency generating source so as to generate a CD frequency signal and a WPC frequency signal in a predetermined pattern.

The multi-frequency generator includes a first frequency oscillator for generating and transmitting a CD-A frequency signal, a second frequency oscillator for generating and transmitting a double-USE DM-A frequency signal, and a first frequency oscillator and a second frequency oscillator, respectively. An amplifier combined with a power amplifier for amplifying the signal, and an amplified signal through an amplifier connected to the first frequency oscillator and the second frequency oscillator, and transmitting the synthesized signal to an antenna of the RF radiation chamber. (RF combiner).

The RF radiation chamber is provided with a conical antenna at an inner center thereof, and a plurality of Petri dishes are radially disposed at a predetermined distance (radius) from the antenna.

The inner surface of the RF radiation chamber is covered with an RF absorber to prevent the frequency signal emitted from the antenna from being reflected and disturbing the experiment.

According to the embodiment of the multi-frequency exposure apparatus for in vitro experiments according to the present invention, since it is possible to simultaneously expose the CDA frequency signal and WPCDAM signal to the cell, the effect of the electromagnetic wave on the human body in a more real situation It is possible to carry out cell experiment studies and the like effectively under the conditions close to.

And according to an embodiment of the multi-frequency exposure apparatus for the test tube experiment according to the present invention, since the carbon dioxide and cooling water is supplied to the RF radiation chamber, it is possible to precisely control the temperature and the internal environment to enable long-term cell exposure experiments Do.

1 is a block diagram showing an embodiment of a multi-frequency exposure apparatus for in vitro experiments in accordance with the present invention.
Figure 2 is a cross-sectional view showing an RF radiation chamber in one embodiment of a multi-frequency exposure apparatus for in vitro experiments in accordance with the present invention.
Figure 3 is a partially enlarged cross-sectional view showing an antenna in one embodiment of a multi-frequency exposure apparatus for in vitro experiments in accordance with the present invention.

Next, a preferred embodiment of a multi-frequency exposure apparatus for in vitro experiments according to the present invention will be described in detail with reference to the drawings.

First, an embodiment of a multi-frequency exposure apparatus for an in vitro experiment according to the present invention includes a multi-frequency generator 10 and an RF radiation chamber 20, as shown in Figs.

The multi-frequency generator 10 is configured to synthesize and provide a CDMA frequency signal and a WCDMA frequency signal.

The multi-frequency generator 10 includes a first frequency oscillator 12 for generating and transmitting a CD-A frequency signal, a second frequency oscillator 14 for generating and transmitting a double-USED-MAC signal, and the first frequency generator. An amplifier 16 connected to the frequency oscillator 12 and the second frequency oscillator 14 to amplify a signal, and an amplifier connected to the first frequency oscillator 12 and the second frequency oscillator 14 ( And an RF combiner 18 for synthesizing the signal amplified through the 16 and transmitting the synthesized signal to the RF radiation chamber 20.

The multi-frequency generating source 10 is connected to the control device 30 to generate a CD pattern and a DC signal frequency signal in a predetermined pattern set.

The control device 30 is connected to the first frequency oscillator 12 and the second frequency oscillator 14 to control the output and exposure time of the frequency in a set range.

The control device 30 can be implemented using a computer system, it is possible to mount and use a program suitable for frequency control, if necessary.

The first frequency oscillator 12 and the second frequency oscillator 14 are each in the mobile communication frequency band CDM (CDMA) with the largest number of users and the new 3G mobile communication frequency WCDMA band (WCDMA) band Configure to oscillate multiple frequency signals.

However, if necessary, the first frequency oscillator 12 and the second frequency oscillator 14 may be configured to oscillate a signal in a frequency band other than the CDM and WPC.

The control device 30 controls the first frequency oscillator 12 and the second frequency oscillator 14 to oscillate and transmit various frequencies in the CD frequency band and the double-use DC frequency band. Configure.

The signals generated by the first frequency oscillator 12 and the second frequency oscillator 14 are amplified by the amplifier 16 and then synthesized by the RF combiner 18 in the RF radiation chamber. 20 is transmitted inside.

That is, the antenna 22 radiating the composite frequency signal transmitted from the RF combiner 18 of the multi-frequency generator 10 is installed at the inner center of the RF radiation chamber 20.

The antenna 22 is composed of a conical antenna, which is a broadband antenna having an omni radiation pattern.

The RF combiner 18 and the input of the antenna 22 are connected via a coaxial cable, and the antenna 22 has a structure of a conical antenna having a coaxial feed located at the center of the parallel plate. 3)

And the inner surface of the RF radiation chamber 20 is covered with an RF (RF) absorber is configured to prevent the frequency signal emitted from the antenna 22 is reflected to disturb the experiment.

By positioning the conical antenna 22 in the center of the parallel plate as described above, it is possible to excite only the basic TEM (Transverse Electromagnetic wave), and to install the RF absorber on the inner surface of the RF radiation chamber 20 as described above. As a result, standing waves in the TEM mode are removed by the RWG (radial waveguide) being terminated by the absorber.

The RF radiation chamber 20 is configured of a radial transmission line (RTL) structure. In other words, the RF radiation chamber 20 has a structure in which two circular metal plates are formed in parallel to form a top plate and a bottom plate, and a structure in which a conical antenna 22 is disposed at an inner center thereof.

In this configuration, the TEM wave is reflected and scattered while hitting the opening end of the antenna 22, but as the operating frequency is increased, reflection and scattering are reduced, and the antenna 22 exhibits the same characteristics as the infinite transmission line.

As described above, when the antenna 22 of the RF radiation chamber 20 is configured to have an RTL feeding structure, excellent uniformity is exhibited over a wide bandwidth.

In addition, a plurality of petri dishes 24 containing cells for electromagnetic wave exposure experiments are radially disposed at a predetermined distance (radius) from the antenna 22 in the RF radiation chamber 20.

The petri dish 24 has a thickness of about 1 mm and is made of a synthetic resin material such as polyethylene.

When the inner diameter of the petri dish 24 is 100mm, it is possible to arrange at least six radially at the same time, and when the inner diameter is 60mm, it is possible to simultaneously test at least 10 radially.

And the RF radiation chamber 20 is connected to the cooling device 40 for maintaining the temperature inside.

The cooling device 40 is configured to precisely control the internal temperature of the RF radiation chamber 20 to 37 ± 0.2 ℃ by circulating the cooling water.

When the temperature of the culture solution contained in the petri dish 24 rises rapidly, it is impossible to accurately determine the effect of the cells due to the exposure of the electromagnetic waves, so it is very important to precisely control the internal temperature of the RF radiation chamber 20. Do.

In addition, the RF radiation chamber 20 is installed with a carbon dioxide tank 50 and an incubator 60 for supplying carbon dioxide to maintain the pH of the culture medium in a long-term cell exposure experiment.

The incubator 60 is connected to the RF radiation chamber 20 to maintain the carbon dioxide concentration and humidity therein, and the incubator 60 and the carbon dioxide tank 50 are continuously connected to the RF radiation chamber 20. It is configured to supply carbon dioxide.

When the culture solution of the petri dish 24 is contaminated and changed to acidic or alkaline, it is impossible to accurately determine the effect of the cells due to the exposure of the electromagnetic wave, so that the inside of the RF radiation chamber 20 is kept neutral. need.

In addition, although not shown in the drawing, the RF radiation chamber 20 is configured to precisely control the operation of the cooling device 40 and the incubator 60 by installing a temperature sensor and a carbon dioxide sensor.

In the above, a preferred embodiment of a multi-frequency exposure apparatus for in vitro experiments according to the present invention has been described, but the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the specification and the accompanying drawings. This also belongs to the scope of the present invention.

10-multi-frequency generator, 12-first frequency oscillator, 14-second frequency oscillator
16-amplifier, 18-RF combiner, 20-RF radiation chamber
22-Antenna, 24-Petri Dish, 30-Control, 40-Chiller
50-carbon dioxide tank, 60-incubator

Claims (3)

A multi-frequency generator that synthesizes and provides a CDA frequency signal and a WCDMA frequency signal,
An RF radiation chamber in which an antenna radiating a composite frequency signal transmitted from the multi-frequency generator and a plurality of petri dishes containing cells for an electromagnetic wave exposure experiment are installed therein;
A cooling device for maintaining a temperature inside the RF radiation chamber;
A multi-frequency exposure apparatus for in vitro experiments comprising a carbon dioxide tank and an incubator to supply carbon dioxide to maintain the pH of the culture medium in a long-term cell exposure experiment. The method according to claim 1,
The multi-frequency generator includes a first frequency oscillator for generating and transmitting a CD-A frequency signal, a second frequency oscillator for generating and transmitting a double-USE DM-A frequency signal, and a first frequency oscillator and a second frequency oscillator, respectively. An amplifier connected and installed to amplify the signal, and an RF combiner for synthesizing the amplified signal through an amplifier connected to the first frequency oscillator and the second frequency oscillator, and transmitting the synthesized signal to the antenna of the RF radiation chamber,
And a control device connected to the multi-frequency generator so as to generate a CD-A frequency signal and a WU-DM signal in a predetermined pattern. The method according to claim 1 or 2,
The RF radiation chamber is provided with a conical antenna in the center of the center, a multi-frequency exposure apparatus for a test tube experiments are arranged with a plurality of petri dishes radially arranged at a distance from the antenna.

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