USE OF FLUOROQUINOLONE ANTIBIOTICS
Provided are a method and an apparatus for coordinating inter-cell interference. A user equipment receives from a serving cell information on a downlink timing offset between an interfering cell and an interfered cell and a limited resource measurement, and applies the downlink timing offset to perform measurement using a radio resource indicated for the limited resource measurement, thereby allowing the user equipment to be provided services through the radio resource which substantially mitigates interference, and enhancing connectivity with a network.
This application claims the benefit of priority of Korean Patent Application No. 10-2015-0070682 filed on May 20, 2015, all of which are incorporated by reference in their entirety herein.
BACKGROUND OF THE INVENTIONField of the Invention
The present invention relates to a use of fluoroquinolone antibiotics.
Description of the Related Art
Labeling, fluorescence imaging, and measurement methods using fluorescent materials which are frequently used in biological researches are methods of fluorescently expressing only a predetermined area of interest in body organs of organisms except for humans and have an advantage of photographing with a high contrast ratio. However, currently, as a fluorescent label material targeted to a human body, only ICG and fluorescein are used for vascular labeling, but there are no materials used for labeling cells or microorganisms.
Fluoroquinolone antibiotics generally have single-photon fluorescence generating one fluorescent photon by one high-energy incident photon. However, since excited light expressing the fluoroquinolone antibiotics is in an ultraviolet-ray area in which moxifloxacin is 280 nm and gatifloxacin is 292 nm, the fluorescent characteristic is not used to determine bacteria causing diseases in cells in the human body and the like.
The material having the single-photon fluorescence may also have a multi-photon fluorescent characteristic which generates one fluorescent photon through cooperation of two or three low-energy incident photons such as two-photon fluorescence and three-photon fluorescence which are non-linear fluorescence. However, the multi-photon fluorescent characteristic may not be known until being actually experimentally verified, and fluorescence efficiency may be verified only by measuring.
Accordingly, currently, there are no fluorescent label materials used for the cells of the human body and the like, and in order to determine the bacterial, a method of diagnosing infectious bacteria is used.
The method of diagnosing the infectious bacteria is a method of verifying inflammation due to infection through a slit lamp, extracting a tissue at an inflammation portion by rubbing a cotton swab, and observing the extracted tissue through labeling or observing the extracted tissue after culture for several days. In the method, there is a disadvantage in that it takes a lot of time and thus a treatment time is delayed.
SUMMARY OF THE INVENTIONTherefore, an object of the present invention is to provide a use and a method of labeling cells in at least one of a biological tissue, bacteria, and fungi with fluoroquinolone antibiotics, a use of applying labeled cells in the body tissue to a method of diagnosing infectious bacteria by labeling the cells in the body tissue, and information on diagnosis of infectious bacteria and fungi.
An object of the present invention is achieved by labeling cells in at least one of a biological tissue, bacteria, and fungi in a use of fluoroquinolone antibiotics.
The tissue may include at least one of a cornea, a skin, and a bladder.
The labeling may use multi-photon fluorescence expression.
The fluoroquinolone antibiotics may include moxifloxacin.
The fluoroquinolone antibiotics may include gatifloxacin.
Another object of the present invention is achieved by labeling cells in a biological tissue to be used for a diagnosis method of at least of infectious bacteria and fungi in a use of fluoroquinolone antibiotics.
The tissue may include at least one of a cornea, a skin, and a bladder.
The infectious bacteria may include at least one of pseudomonas, staphylococcus, and the infectious fungi include at least one of the aspergillus and candida.
The labeling may use multi-photon fluorescence expression.
The fluoroquinolone antibiotics may include at least one of moxifloxacin and gatifloxacin.
Yet another object of the present invention is achieved by including preparing a tissue to be fluorescent-labeled by cell unit and administering the fluoroquinolone antibiotics to the tissue, in a labeling method of fluoroquinolone antibiotics.
The tissue may include at least one of a cornea, a skin, and a bladder.
The labeling may use multi-photon fluorescence expression.
The fluoroquinolone antibiotics may include at least one of moxifloxacin and gatifloxacin.
Still another object of the present invention is achieved by a method of providing information on at least one of infectious bacteria and fungi including: preparing a tissue to be fluorescent-labeled by cell unit; adding the fluoroquinolone antibiotics into the tissue and labeling the tissue; and providing information on infectious bacteria by inspecting the tissue through a multi-photon fluorescence-based optical image.
At least one of the infectious bacteria may include at least one of cornea, skin, and bladder bacteria.
The infectious bacteria may include at least one of pseudomonas, staphylococcus, and the infection fungi include at least one of aspergillus and candida.
The fluoroquinolone antibiotics may include at least one of moxifloxacin and gatifloxacin.
According to the present invention, it is possible to provide an object of the present invention is to provide a use and a method of labeling cells in at least one of a biological tissue, bacteria, and fungi with fluoroquinolone antibiotics, a use of applying labeled cells in at least one of the bacteria and fungi to a method of diagnosing infectious bacteria and fungi by labeling the cells in the biological tissue, and information on diagnosis of infectious bacteria and fungi.
The present invention provides a use of fluoroquinolone antibiotics labeling cells in a at least one of a biological tissue, bacteria, and fungi. and using the labeled cell in a diagnosis method of infectious bacteria and fungi.
In the present invention, the labeling method of cells in the at least one of a biological tissue, bacteria, and fungi. using the fluoroquinolone antibiotics includes (a) preparing a at least one of a biological tissue, bacteria, and fungi to be fluorescent-labeled by cell unit, and (b) adding fluoroquinolone antibiotics to at least one of the biological tissue, bacteria, and fungi.
Further, the present invention provides information on diagnosis of at least one of infectious bacteria and fungi. including (a) preparing a tissue to be fluorescent-labeled by cell unit, (b) adding and labeling fluoroquinolone antibiotics to the tissue, and (c) providing information on at least one of infectious bacteria and fungi by inspecting the tissue through a multi-photon fluorescent-based optical image.
A moving appearance of molecules, cells, and tissues of the organism may be observed through a fluorescence microscope when being treated by a fluorescent probe (FP). While electrons in the FP become in the excited state by the incident photon and return to the original site again, fluorescent photons having special colors are emitted.
When the fluorescent photons are emitted in the visible light area, it may be used to determine the bacteria causing the diseases in cells in the human body and the like. In the present invention, it was found that the fluoroquinolone antibiotics may be fluorescent-expressed in the visible light area as well as the ultraviolet light area. Further, it was found that the fluoroquinolone antibiotics may label the cells in the human body and it was verified that the fluoroquinolone antibiotics may label the bacteria and fungi. Accordingly, the present invention may provide the method of labeling the cells of the tissue in the human body and information on diagnosis of the infectious bacteria and fungi, by using the fluoroquinolone antibiotics.
As the fluoroquinolone antibiotics, there are moxifloxacin, gatifloxacin, pefloxacin, difloxacin, nofloxacin, ciprofloxacin, ofloxacin, enrofloxacin, and the like, but preferably, fluoroquinolone antibiotics in which auto-fluorescence is expressed in the visible light area or multi-photon fluorescence including the visible light area may be expressed are suitable. Hereinafter, in Experimental Example, the experiment was performed by using gatifloxacin and hydrochloride moxifloxacin substituted with hydrochloride which are frequently used as ocular antibiotics among the fluoroquinolone antibiotics.
In the following Experimental Example, it was verified that the hydrochloride moxifloxacin and the gatifloxacin may express fluorescent signals even in a light source having a near-infrared wavelength in a range of 700 nm to 800 nm. Further, it was verified through the following Experimental Examples that fluorescence efficiency of the body tissue administered with the antibiotics is 10 to 100 times larger than the auto-fluorescence and images of antibiotics-based cells in the tissue may be photographed without removing the tissue.
The present invention may be applied to various at least one of the following: a biological tissue, bacteria, and fungi, and preferably, may be applied to cells in the tissue, for example, eye (cornea), skin, small intestine, stomach, cecum, colon, rectum, liver, lung, etc. In Experimental Example of the present invention, the fluorescence expression was measured by administering hydrochloride moxifloxacin and gatifloxacin to corneal cells, skin cells, and bladder cells.
In order to use the fluoroquinolone antibiotics in the method of diagnosing at least one of the infectious bacteria and fungi, only when causative bacteria or fungi existing in each cell as well as the cells in the tissue are labeled, whether infection exists or not may be determined. The method of the present invention may be applied to various at least one of bacteria and fungi, and preferably, may be applied to at least one of bacteria and fungi, and preferably which may be infected in the cells in the biological tissue. Further, the method of the present invention may be applied even to fungus consisting of eukaryotes such as a human.
In Experimental Example of the present invention, pseudomonas and staphylococcus were cultured, fluoroquinolone antibiotics were administered, and it was verified through the multi-photon microscope that the fluorescence was expressed.
First, moxifloxacin and gatifloxacin which are used in the experiment and areas and intensities of the fluorescence expression of the antibiotics will be described with reference to
The moxifloxacin as 0.5% of vigamox eye drops being sold in the market (Alcon Korea Co., Ltd.) is hydrochloride moxifloxacin (moxifloxacin HCl, 5.45 mg of hydrochloride moxifloxacin) synthesized with hydrochloride like a structural formula illustrated in
The gatifloxacin is gatiflo eye drops (Handok pharmaceuticals Co., Ltd., 3 mg of gatifloxacin) having a structural formula illustrated in
Hereinafter, the present invention will be described in more detail through Experimental Examples. Experimental Examples are just to describe the present invention in more detail, and the scope of the present invention is not limited by Experimental Examples according to the gist of the present invention. In the following experiment, as cells of a tissue, a cornea, a skin (ears), and a bladder are targeted, but the present invention is not limited thereto, and may be applied to cells of various tissues in the body such as a prostate and a colon.
The bacteria target pseudomonas and staphylococcus, but the present invention may be applied to various bacteria which may be infected in cells of the tissue in the body, and is not limited to the following Experimental Examples. And the present invention may be applied to various fungi such as aspergillus and candida, and is not limited to the following
Further, the present invention may be applied even to a fungus which is a eukaryote such as a human and is not limited even to a kind of fungus.
EXPERIMENTAL EXAMPLE 1 Measurement of Multi-Photon Fluorescence of Corneal Cells of Fluoroquinolone Antibiotics (Hydrochloride Moxifloxacin and Gatifloxacin)1) Preparation of Materials and Samples
Blab/c female mice after five or six weeks, gatifloxacin, hydrochloride moxifloxacin, and a multi-photon microscope including a biaxial scanner (a galvano scanner of x axis and a galvano scanner of y axis) to be used by a point scanning method were prepared.
In this Experimental Example, a two-photon microscope using a femtosecond laser as a light source was used and the multi-photon fluorescence was equally measured under the following condition throughout an experimental process.
Excitation wavelength: 780 nm for vigamox (moxifloxacin)
Filter set: Ch01: [430 nm, Ch02:]430 nm
Manufacturer/Product name of Microscope: Leica/TCS SP5II MP SMD FLIM
Filter: 500/25 bandpass filter, chroma
Light source: chameleon vision II, coherent
Camera: photon multiplier tube (PMT) 6357, Hamamatsu Photonics
Objective lens: 25×0.95 NA objective lens, leica
2)Measurement of Multi-Photon Fluorescence of Corneal Cells of Fluoroquinolone Antibiotics (Hydrochloride Moxifloxacin and Gatifloxacin)
In order to compare fluorescence expression of hydrochloride moxifloxacin with auto-fluorescence expression of the corneal cells of the mouse, the corneal cells of the mouse which are not applied with hydrochloride moxifloxacin were first photographed.
The Blab/c mouse to be used in the experiment was anesthetized and then fixed to an eye holder for photographing the eye, and photographed by the two-photon microscope. Laser power was set as 30.8 mW, and in this case, the intensity of auto-fluorescence of the photographed mouse cornea was recorded.
In order to measure the fluorescence expression degree of the mouse cornea by vigamox (hydrochloride moxifloxacin), hydrochloride moxifloxacin of 10 μl was dropped in a left eye of the mouse and an eyelid was closed for 30 seconds. About 20 minutes waited so that hydrochloride moxifloxacin may penetrate into cells inside the mouse cornea.
An incubation time when the antibiotic penetrates varies according to a tissue, but was verified by photographing with for example, a time lapse such as after 5 minutes and after 10 minutes. In the cornea, the incubation time was within about several tens of minutes. The fluorescence image of the cornea was photographed by the point scanning method through the two-photon microscope. (In this case, an excitation wavelength of the spectrum was set as 790 nm, the laser power of the hydrochloride moxifloxacin was about 14.8 mW, and the laser power of the gatifloxacin was set as 30.8 mW which was the same as the laser power before administering the antibiotic.
In the photographs illustrated in
In a concentration difference of fluorescent colors illustrated in
When comparing
Further, when comparing graphs of
Hereinafter, in Experimental Examples, an experiment was performed by using only hydrochloride moxifloxacin of which fluorescence expression is better than that of gatifloxacin.
EXPERIMENTAL EXAMPLE 2 Measurement of Multi-Photon Fluorescence in Skin Cells of Hydrochloride Moxifloxacin1) Preparation of Materials and Samples
Blab/c female mice after five or six weeks, hydrochloride moxifloxacin, and a two-photon microscope including a biaxial scanner (a galvano scanner of x axis and a galvano scanner of y axis) to be photographed by a point scanning method, a scotch tape, a PBS were prepared.
In this Experimental Example, a two-photon microscope using a femtosecond laser as a light source was used and the multi-photon fluorescence was equally measured under the following condition throughout an experimental process.
Excitation wavelength: 780 nm for vigamox (moxifloxacin)
Filter set: Ch01: [490 nm, Ch02: ]490 nm
Light source: Chameleon Ultra II, Coherent
Camera: photomultiplier tube (PMT) H7421-40P, Hamamatsu Photonics
Objective lens: 20×1.0 NA objective lens, XLUMPlanFL, Olympus
Photographing area: 300 μm ×300 μm (512×512 pixels)
2) Measurement of Multi-Photon Fluorescence in Skin Cells of Hydrochloride Moxifloxacin
In order to compare fluorescence expression of hydrochloride moxifloxacin with auto-fluorescence expression of the skin cells of the mouse, the skin cells of the mouse which are not applied with hydrochloride moxifloxacin were first photographed by the two-photon microscope. While the mouse was alive through inhalation anesthesia, a skin (ear) tissue was photographed.
In order to photograph the fluorescence expression of the hydrochloride moxifloxacin in the skin tissue of the mouse, a general scotch tape was repeatedly attached to and detached from the ear tissue of the mouse about 15 times to remove a horny layer and vigamox was applied.
After the vigamox penetrated for about 20 minutes, the vigamox was washed by using the PBS, and while the mouse was alive through inhalation anesthesia like the pre-photographing of the vigamox, the image of the skin (ear) tissue was photographed by the point scanning method through the multi-photon microscope.
When describing the fluorescence expression degrees of
Further, when comparing
1) Preparation of Materials and Samples
Hydrochloride moxifloxacin, a rat (normal), a vigamox eye drop (hydrochloride moxifloxacin), an anesthetics, a warmer, a slide glass, a forcep, a PBS, and a two-photon microscope including a biaxial scanner (a galvano scanner of x axis and a galvano scanner of y axis) to be used by a point scanning method for measuring the multi-photon fluorescence expression degree were prepared.
In this Experimental Example, the used vigamox and the two-photon microscope using a femtosecond laser as a light source were measured under the following specification condition throughout an experimental process.
Excitation wavelength: 780 nm for vigamox (moxifloxacin)
Filter set: Ch01: [490 nm, Ch02: ]490 nm
Light source: Chameleon Ultra II, Coherent
Camera: photomultiplier tube (PMT) H7421-40P, Hamamatsu Photonics
Objective lens: 20×1.0 NA objective lens, XLUMPlanFL, Olympus
Photographing area: 300 μm×300 μm (512×512 pixels)-
150 μm×150 μm (512×512 pixels)-
2) Measurement of Multi-Photon Fluorescence in Bladder Cells of Hydrochloride Moxifloxacin
In order to compare fluorescence expression of hydrochloride moxifloxacin with auto-fluorescence expression of the bladder cells of the mouse, the rat (normal) which was not applied with hydrochloride moxifloxacin was prepared and the bladder cells of the rat (normal) were first photographed by the two-photon microscope.
The rat (normal) was sacrificed and the bladder tissue was extracted. After the extracted bladder tissue was washed in a PBS solution about five times, the washed bladder tissue was cut with scissors for surgery and unfolded so that photographed portions (the lumen and the serosa) may be exposed outside. After the unfolded bladder tissue was placed on the slide glass so that the photographed portions (the lumen and the serosa) faced upward, covered with a coverslip, and fixed well (using a tape), the auto-fluorescence intensity was measured.
In Experimental Example, the auto-fluorescence intensity was measured while the objective lens descended by 2 μm so as to verify an appearance of cells photographed for each depth of the lumen and serosa tissues of the bladder tissue. Particularly, the lumen tissue was photographed so that the umbrella cell, the intermediate cell, and the laminar propria were verified, respectively.
Even like this Experimental Example, the incubation time when the antibiotic penetrated was photographed and verified with a time lapse. The fluorescence image of the bladder was photographed by the point scanning method through the two-photon microscope. In this experiment, in the lumen of the bladder tissue, the laser power of 300 mW or more was used, and in the serosa, the laser power of 200 mW or more was used.
Hereinafter, an experimental process of the multi-photon fluorescence measurement of the bladder cells administered with hydrochloride moxifloxacin will be described with reference to
The rat normal was sacrificed, the bladder tissue was extracted, and the extracted tissue was immersed in vigamox (hydrochloride moxifloxacin) for 20 minutes and incubated. Thereafter, the bladder tissue was held with the forceps and gently washed while being shaken about 2 to 3 times in the PBS.
Thereafter, a tissue sample was prepared on the slide glass so that the lumen tissue which is the inside of the cell and the serasa tissue which is the outside of the cell are exposed during photographing and TPM-photographed within 30 minutes after the vigamox was treated so as to complete the photographing when the cells are activated.
Even like this Experimental Example, the incubation time when the antibiotic penetrated was photographed and verified with a time lapse. The fluorescence image of the bladder was photographed by the point scanning method through the two-photon microscope. In the lumen tissue of the bladder tissue treated with the hydrochloride moxifloxacin, the laser power of 15 mW was used, and in the serosa tissue, the laser power of 10 mW was used.
In the lumen of the bladder tissue of
Even in the serosa of the bladder tissue of
More effectively, in order to observe expression of the hydrochloride moxifloxacin in the cells of the bladder tissue, it will be described in detail with reference to
That is,
When comparing the respective cells, even though the laser power is strong, it was difficult to verify the structure of the cells in the photograph of auto-fluorescence expression before administering the hydrochloride moxifloxacin. Particularly, in the case of the laminar propria, it is difficult to observe the laminar propria because blood vessels are mainly distributed, and after administering the hydrochloride moxifloxacin, even though the intensity of the laser power is decreased to 1/20, the structure of the laminar propria may also be efficiently observed together with peripheral blood vessels.
Referring to
Referring to
1) Preparation of Materials and Samples
Bacteria (pseudomonas and staphylococcus) used in the experiment, hydrochloride moxifloxacin, and a biaxial scanner (a galvano scanner of x axis and a galvano scanner of y axis) to be used by a point scanning method were prepared.
In this Experimental Example, a two-photon microscope using a femtosecond laser as a light source was used, and the multi-photon fluorescence was equally measured under the following condition throughout an experimental process.
Excitation wavelength: 780 nm for vigamox(moxifloxacin)
Filter set: Ch01:[430 nm, Ch02:]430 nm
Manufacturer/Product name of Microscope: Leica/TCS SP5II MP SMD FLIM
Filter: 500/25 bandpass filter, chroma
Light source: chameleon vision II, coherent
Camera: photon multiplier tube (PMT) 6357, Hamamatsu Photonics
Objective lens: 250.95 NA objective lens, leica
2) Measurement of Multi-Photon Fluorescence in Bacteria of Hydrochloride Moxifloxacin
The bacteria were incubated under the following condition.
A. Used medium
pseudomonas-nutrient broth (nutrient medium)
staphylococcus-lysogeny broth (LB medium)
B. Incubation process
1. A bacteria stock was put in a medium of 3 mL and cultured after overnight incubation (37° C. and 200 rpm).
2. Here, 0.03 mL of the cultured bacteria stock was taken and put in a fresh medium of 3 mL, and then cultured (37° C. and 200 rpm) up to OD600=1.5.
3. The cultured bacteria stock was put in two high-pressure/sterilized e-tubes by 1.0 mL, supernatants thereof were removed by using a centrifugation (6,000× g, 20 min, 4° C.), and then the bacteria stock was resuspended with sterile PBS.
4. In this case, a colony forming unit (CFU) was resuspended by PBS of 0.1 mL and then serial diluted, and the bacteria stock was smeared on an agar plate.
5. Then, the concentration was shown and a PBS volume to be 107 CFU/5 μL may be calculated by the concentration.
C. Experiments of auto-fluorescence expression of bacteria (pseudomonas and staphylococcus) and fluorescence expression of hydrochloride moxifloxacin
In order to compare fluorescence expression of hydrochloride moxifloxacin with auto-fluorescence expression of bacteria, fluorescence expression of bacteria (pseudomonas and staphylococcus) which are not applied with hydrochloride moxifloxacin was first photographed and intensity of the auto-fluorescence expression was recorded. Subsequently, the hydrochloride moxifloxacin was administered to the medium and then the intensity of the fluorescence expression after the incubation time was measured.
First, through
Further, when comparing
Values for the accurate fluorescence expression may be verified through a grape illustrated in
1) Preparation of Materials and Samples
Aspergillus and candida albican to be used in the experiment, hydrochloride moxifloxacin, a petri dish, and a biaxial scanner (a galvano scanner of x axis and a galvano scanner of y axis) to be used by a point scanning method were prepared.
In this Experimental Example, a two-photon microscope using a femtosecond laser as a light source was used, and the multi-photon fluorescence was equally measured under the following condition throughout an experimental process.
Excitation wavelength: 790 nm for moxifloxacin
Filter set: Ch01: [490 nm, Ch02: ]490 nm
Light source: Chameleon Ultra II, Coherent
Camera: photomultiplier tube (PMT) H7421-40P, Hamamatsu Photonics
Objective lens: 20×1.0 NA objective lens, XLUMPlanFL, Olympus
Photographing area: 150 μm×150 μm (512×512 pixels)
2) Measurement of Multi-Photon Fluorescence in Fungi (Aspergillus and Candida Albican) of Hydrochloride Moxifloxacin
The aspergillus and the candida albican as the fungi were cultured on the petri dish.
A. Used medium
aspergillus-nigger agar
candida-LB agar
B. Incubation process
1. First, a nutrient agar was slowly dissolved while being boiled in 1 L of distilled water.
2. An autoclave was performed at 121° C. for about 15 minutes.
3. An agar medium of about 25 to 30 ml was spilled on a plate to prepare a nutrient agar plate.
4. The fungi (aspergillus and candida) were smeared on the prepared agar plate and incubated at 30° C.
5. A single fungus colony was found after about 24 hours.
C. Sample preparing process
1. An appropriate amount of fungi formed on the agar plate with the colony scooped up with a thing such as a toothpick.
2. The toothpick coated with the fungi was put into the e-tube containing distilled water of about 500 ml to be centrifuged (10 min, 4000× g, 4° C.).
3. After the centrifuge, the toothpick was removed and distilled water was mixed with the fungi sunken in the e-tube by using a pipet. About 50 μl of the fungi and the distilled water in the e-tube was extracted and placed on a well-slide glass to prepare a control sample.
4. About 20 μl of a moxifloxacin solution (a vigamox solution) was dropped into the fungi and the distilled water remaining in the e-tube and then centrifuged (10 min, 4000× g, and 4° C.).
5. Thereafter, the remaining solution except for the fungi sunken in the e-tube was removed by using the pipet, distilled water of about 500 ml was added, and then mixed by using the pipet.
6. About 50 μl of a mixed solution of the fungi and the distilled water in the e-tube was extracted to be placed on the well-slide glass to prepare a moxifloxacin (vigamox) labelled fungus sample.
D. Experiment of auto-fluorescence expression of fungi (aspergillus and candida albican) and fluorescence expression of hydrochloride moxifloxacin
In order to compare auto-fluorescence expression of fungi (aspergillus and candida albican) and fluorescence expression of hydrochloride moxifloxacin, first, fluorescence expression of fungi (aspergillus and candida albican ) which are not applied with the hydrochloride moxifloxacin was photographed and then intensity of the fluorescence expression was recorded.
Subsequently, after the hydrochloride moxifloxacin was administered to the petri dish and sufficiently smeared for 10 minutes, the fungi (aspergillus and candida albican) were collected by using a centrifuge and the intensity of the fluorescence expression was measured.
An experimental result will be described in detail with reference to
First, referring to
Further, in the aspergillus of
That is, the fluoroquinolone antibiotics may label the bacteria and the fungi, and in this case, the intensity of the fluorescence expression is 10 times stronger than the auto-fluorescence. As illustrated in Experimental Examples 1 to 3, since the cell tissue in the body tissue may be labeled, it can be seen that whether the bacteria exist in the body may be easily determined only by administration of the antibiotic.
The fluoroquinolone antibiotics may be easily obtained as antibiotics which are sold to be clinically used and have an advantage of observing the cells while minimizing the damage. In this case, the tissue to be observed may be high-speed imaged in vivo without extraction of the tissue or incubation of the cell.
Further, even in addition to the cornea, the skin and bladder cells may be labeled, and as a result, the fluoroquinolone antibiotics may be used as an inspection method of cell fluorescent chromosomes and cells of various biological tissues.
Since the fluoroquinolone antibiotics may express the fluorescent signal of a minimum of 10 times more than the auto-fluorescent signal in the cells, even though the laser power having a small value is used, the cells in the body tissue may be observed. Particularly, in addition to labeling of the vascular endothelia cells and fluorescent labeling of the bacteria, the fungi consisting of a eukaryote such as a human may be labeled, and as a result, the fluoroquinolone antibiotics may be used for inspection of the infectious bacteria of various tissues and cells.
Particularly, a time may be more shortened than the existing diagnosis method of the infectious bacteria in which cells are extracted and cultured for several days, and as a result, there is an advantage of advancing a treatment time.
The above Experimental Examples are just examples for describing the present invention, and the present invention is not limited thereto. Since those skilled in the art can implement the present invention through various modifications therefrom, the technical protection scope should be determined by the appended claims.
Claims
1.-5. (canceled)
6. A method for diagnosing at least one of an infectious bacteria or fungi, the method comprising labeling cells in a biological tissue using fluoroquinolone antibiotics.
7. The method of claim 6, wherein the tissue includes tissue from at least one of a cornea, a skin, and a bladder.
8. The method of claim 6, wherein the infectious bacteria include at least one of pseudomonas, staphylococcus, and the infectious fungi include at least one of the aspergillus and candida.
9. The method of claim 6, wherein the labeling uses multi-photon fluorescence expression.
10. The method of claim 6, wherein the fluoroquinolone antibiotics includes at least one of moxifloxacin and gatifloxacin.
11. The method of claim 6, comprising:
- preparing a tissue to be fluorescent-labeled by cell unit; and
- administering the fluoroquinolone antibiotics to the tissue.
12.-14. (canceled)
15. The method of claim 11, further comprising:
- providing information on infectious bacteria and fungi by inspecting the tissue through a multi-photon fluorescence-based optical image.
16.-18. (canceled)
Type: Application
Filed: Feb 3, 2017
Publication Date: May 25, 2017
Inventors: Ki Hean Kim (Gyeongsangbuk-do), Myoung Joon Kim (Seoul), Jun Ho Lee (Seoul), Seong Hun Lee (Daegu), Jin Hyoung Park (Gangwon-do), Bum Ju Kim (Gyeongsangbuk-do), Tae Jun Wang (Busan)
Application Number: 15/423,901