Dr.T.V.Rao MD
Dr.T.V.Rao MD
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Sir George G. Stokes
The phenomenon of fluorescence was known by the middle of the nineteenth century. British scientist Sir George G. Stokes first made the observation that the mineral fluorspar exhibits fluorescence when illuminated with ultraviolet light, and he coined the word "fluorescence"
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Discovery of Fluorescence Microbiology
The fluorescence microscope was devised in the early part of the twentieth century by August Köhler, Carl Reichert, and Heinrich Lehmann, among others. However, the potential of this instrument was not realized for several decades, and fluorescence microscopy is now an important (and perhaps indispensable) tool in cellular biology.
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Differences between Conventional and Fluorescent Microscope
The Conventional microscope uses visible light (400-700 nanometers) to illuminate and produce a magnified image of a sample.
A fluorescence microscope,
uses a much higher intensity light source which excites a fluorescent species in a sample of interest. This fluorescent species in turn emits a lower energy light of a longer wavelength that produces the magnified image instead of the original light source.
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What is Fluorescence?
Fluorescence is light
produced by a substance when it is stimulated by another light. Fluorescence is called "cold light" because it does not come from a hot source like an incandescent light bulb.
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What is Fluorescence Microscopy?
Fluorescence microscopy is a unique way of using a
microscope to discover facts about specimens that often are not shown by standard bright field microscopy. In bright field microscopy, specimens are illuminated from outside, below or above, and dark objects are seen against a light background. In fluorescence microscopy, specimens are self-illuminated by internal light, so bright objects are seen in vivid color against a dark background. Bright objects against dark backgrounds are more easily seen. This characteristic of fluorescence microscopy makes it very sensitive and specific.
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Principle of Fluorescent Microscopy
Most cellular components are colorless and cannot be clearly distinguished under a microscope. The basic premise of fluorescence microscopy is to stain the components with dyes. Fluorescent dyes, also known as fluorophores of fluorochromes, are molecules that absorb excitation light at a given wavelength (generally UV), and after a short delay emit light at a longer wavelength. The delay between absorption and emission is negligible, generally on the order of nanoseconds. The emission light can then be filtered from the excitation light to reveal the location of the fluorophores.
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Principle of Fluorescent Microscopy
Fluorescence microscopy uses a much higher intensity light to illuminate the sample. This light excites fluorescence species in the sample, which then emit light of a longer wavelength. The image produced is based on the second light source or the emission wavelength of the fluorescent species -- rather than from the light originally used to illuminate, and excite, the sample.
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Works on Faster Transmission of Light
Fluorescence, describes light emission that continues only during the absorption of the excitation light. The time
interval between absorption of excitation light and emission of re-radiated light in fluorescence is of extraordinarily short duration, usually less than a millionth of a second.
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Works on Principles of Light Pathways
Specifically, a dichroic mirror is used to separate the excitation and emission light paths. Within the objective, the excitation/emission share the same optics. In a fluorescence microscope, the dichroic mirror separates the light paths.
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Advantages of Fluorescent Microscopy
Fluorescence microscopy is the most popular method for studying the dynamic behavior exhibited in live cell imaging. This stems from its ability to isolate individual proteins with a high degree of specificity amidst non-fluorescing material.
The sensitivity is high enough to detect as few as 50 molecules per cubic micrometer.
Different molecules can now be stained with different colors, allowing multiple types of molecule to be tracked simultaneously. These factors combine to give fluorescence microscopy a clear advantage over other optical imaging techniques, for both in vitro and in vivo imaging.
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Fluorescence Microscope
Fluorescence microscopy by
epi-illumination is
the most commonly used method today because it is simple to do, needs relatively simple equipment, and is efficient.
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Epifluorescence Microscopy
Epifluorescence microscopy is a method of fluorescence microscopy that is widely used in life sciences The excitatory light is passed from above (or, for inverted microscopes, from below), through the objective lens and then onto the specimen instead of passing it first through the specimen. The fluorescence in the specimen gives rise to emitted light which is focused to the detector by the same objective that is used for the excitation
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The Specimens to be Stained
Most specimens for fluorescence microscopy must be stained. Fluorescent stains are called "fluorochromes." Acridine orange, auramine O, and fluorescent antibody (FA) are the fluorochromes used most.
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Fluorescence Microscopy applied in Many Braches of Science and Medicine uses of fluorescence
microscopy are many and varied. They are in medicine, public health, biological research, and environment monitoring. The most common application is medical
laboratory diagnosis.
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How to Use a Fluorescence Microscope
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How to Use a Fluorescence Microscope
The object to be studied is marked with a molecule called a fluorophore (a dye). When the florescent light is activated, the light used for illumination is separated from the florescent molecule (the fluorophore), which is much weaker. This is done
through an emission filter.
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Step 1
Locate the light switch on the side of the microscope that turns on the light. Turn the microscope on. Write down the exact time you turn on the light. The florescent light is mercury-based, and a time log must be kept for exposure and use of the light.
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Step 2
Locate the toggle switch on the right side of the microscope between the oculars and objectives. This switch controls the shutter for the mercury light to the objective lens.
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Step 3
Select the appropriate dye for your object (this will depend entirely on what you are going to be studying). The most common dyes include I3 (for use with CTC, DTAF and fluorescein), A (for use with DAPI and f420), N21 (for use with Rhoda mine) and L3 (for use Dr.T.V.Rao MD with fluorescein).
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Step 4
Put the filter (dye) into the tray operated by the silver sliding knob. To remove the tray, simply pull the silver knob out.
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Step 5
Select the lens you would like to use. The 63x objective lens will have the highest numerical aperture. The 100x objective lens will have the highest magnitude that can be used with the mercury-based florescent light source.
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Step 6
Turn the light off when finished, and mark the time. Wait 30 minutes before turning the light back on, or the lamp could explode. It is a good idea to keep track of how many hours the lamp is in use and replace it according to the manufacture's guidelines.
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Step 7
Clean off the microscope lens with lens paper, or if really dirty, use a cotton swap and glass cleaner.
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Direct Immunofluorescence
A specific antibody is labeled by chemically attaching a fluorophore to form what is known as a conjugate, which is then spread on a microscope slide containing the suspected presence of a particular antigen known to stimulate production of the antibody. If the antigen is present, the labeled antibody conjugate binds to the antigen and remains bound to the specimen after it is washed. The presence of the chemically attached fluorescent conjugate and antigen is demonstrated when the fluorophore is excited at its excitation peak, and the subsequent emission intensities at various wavelengths can then be observed visually or captured by a detector system (digital or traditional camera).
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Indirect Immunofluorescence
Indirect immunofluorescence here serum possibly containing unlabeled antibody and its related, but known, antigen are incubated together. A fluorochrome conjugated to an anti-human antibody (if the specimen being tested is human) is then placed on the slide containing the unlabeled antibody-antigen. If indeed, there has been an antigen-antibody reaction, the fluorochrome-labeled anti-human antibody attaches itself to the complex formed by the antigen and antibody. Subsequently, the labeled grouping of antigen, antibody, and fluorochrome labeled anti-human antibody is excited at the peak wavelength intensity for that fluorochrome and any resulting emission is observed. The indirect immunofluorescence technique reduces the necessity of keeping in stock large numbers of labeled antibodies, and also usually results in greater fluorescence intensity. fluorescence,
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Fluorescence Microbiology Modernises the Diagnostic Laboratories Advantages of fluorescence microscopy are due to its sensitivity, specificity, rapid testing, and easy use. It is easy to set up and do, provides rapid diagnostic tests, and can be very specific. Modern technology allows conversion of most compound microscopes easily and economically into effective fluorescence microscopes.
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Fluorescent Staining in Tuberculosis
The Auramine-rhodamine process uses a yellow fluorescent dye to visualize Mycobacterium tuberculosis under a fluorescence microscope. Potassium permanganate or acridine orange can be used as a counterstain. Under the lens, the bacterial cells will appear green.
The Auramine-rhodamine stain is more sensitive than the Zhiel-Neelson and more cost effective.
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Auramine-phenol solution
Reagents for staining
Auramine O 25 g Ethanol 3000 ml Phenol 250 g Distilled water 5300 ml
Suspend 25 g auramine-O in 3000 ml of ethanol in a 5-litre conical flask. Add a magnet and place on a magnetic stirrer until solution is complete. Dissolve 250 g phenol in 5300 ml of distilled water. Mix the phenol solution with alcoholic auramine solution. Store in an amber colored bottle at room temp. for up to 3 mths. Filter before use.
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Reagents for staining
Acid-alcohol for decolorization
Sodium chloride 20 g Hydrochloric acid, A.R. 20 ml Distilled water 500 ml Ethanol 1500 ml
Dissolve sodium chloride in distilled water Add conc. hydrochloric acid, mix thoroughly. Add alcohol Can be stored at room temperature for 3 months.
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Reagents for staining
Counter stain
Potassium permanganate Distilled water 1 gm 1000 ml
Dissolve and store in an amber colored bottle Stays at room temperature for up to 3 months.
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Fuchsin-stained smears require Use of 1000x magnification Use of oil immersion Examination of 300 microscopic fields About 15 minutes to examine one negative smear Examination by an experienced microscopist
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Staining procedure
Place the slides on a staining rack, with the smeared side facing up, the slides not touching each other Flood the slides with freshly filtered auraminephenol. Let stand for 7-10 min. Wash well with running water Decolorize with acid-alcohol for 1-2 min. Wash as before with water and slope the slides to air dry Counter stain with 0.1% KMNO4 for 30 seconds
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Staining procedure - Precautions
Avoid under-decolorization. AFBs are difficult to over-decolorize since the decolorization procedure with acid-alcohol is relatively milder than the 25% H2SO4 used in Z-N. Thick smears: Interfere with decolorization, and counter stain. Mask the presence of AFB and tendency to flake, resulting in loss of smear material and possible transfer of material to other slides Strong counter stain: May mask the presence of AFB Re Staining : Smears examined by FM may be restained by Z-N to confirm findings. However, Z-N stained smears cannot be used for FM Fading: Stained smears may fade on exposure to light. To be stored wrapped in brown or black paper and kept away from light
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EXAMINATION PROCEDURE
The mercury vapor lamp : It takes about 10 min. to reach full intensity Examination: Using the low power objective (100150x) first examine a known pos. slide to ensure that the microscope is correctly set up Appearance: Bacilli appear as slender bright yellow fluorescent rods, standing out clearly against a dark background Positive: Minimum of 4 AFB in the entire smear. Negative: Less than 4 bacilli ( No.of bacilli to be recorded)
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Screen the Smear in Defined Pattern
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Identify the Acid Fast Bacilli with Caution
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EXAMINATION PROCEDURE
The mercury vapor lamp : It takes about 10 min. to reach full intensity Examination: Using the low power objective (100-150x) first examine a known pos. slide to ensure that the microscope is correctly set up Appearance: Bacilli appear as slender bright yellow fluorescent rods, standing out clearly against a dark background Positive: Minimum of 4 AFB in the entire smear. Negative: Less than 4 bacilli ( No.of bacilli to be recorded)
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Grading is Essential to Determine Prognosis
Morphological Confirmation: With a high power objective (400-600x) - To be done with all doubtful smears as well as scanty positives. Examination: At least three horizontal sweeps on the entire smear. Gradation: Grade positive smears into three degrees of positivity using the high power objective
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QUANTIFICATION OF FLUOROCHROME SMEAR RESULTS
FM Magnification ZN
1000x 0 1-9/100FIELD 10-99/FIELD 1-10/FIELD >10/FIELD NO.AFB
REPORT
250x 0
450x 0 DIVIDE
630x 0
EXACT NO 1+ 2+ 3+
by 10
by 4
by 2
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Examining and Reporting Acid-fast Smears
Number of AFB Observed
Report
No AFB seen Doubtful: repeat 1+ 2+ 3+ 4+
200x,250x
0 1-2/30F* 1-9/10F 1-9/F 10-90/F >90/F
400x,450x
0 1-2/70F 2-18/50F 4-36/10F 4-36/F >36/F
* number of acid-fast bacilli observed per microscopic field
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FM Grading
No. of bacilli per HPF
Less than 6 per field
Grade
1+
6-100 bacilli per field
2+
More than 100 per field or large clumps
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3+
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Fluorescence Microscopy Advantages in Acid Fast Bacilli Identification
More than 50 smears examined/day Continuous availability of power More sensitive. where small No. of bacilli are present Majority of FM +ve samples are also +ve by culture Does not yield more false positive than ZN Doubtful smears to be re examined by ZN Dr.T.V.Rao MD
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How to get better Photomicrograph for Documentation
The quality of a photomicrograph, either digital or recorded on film, is dependent upon the quality of the microscopy. Film is a stern judge of how good the microscopy has been prior to capturing the image. It is essential that the microscope be configured using Köhler illumination, and that the field and condenser diaphragms are adjusted correctly and the condenser height is optimized. When properly adjusted, the microscope will yield images that have even illumination over the entire field of view and display the best compromise of contrast and resolution.
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QBC Malaria Test Uses the Principles of fluorescence
The QBC Malaria Test is a fluorescence microscopy-based malaria diagnostic test that speeds and simplifies malaria detection
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Quantitative Buffy Coat (QBC) Test
The method is centrifugation and thereby concentration of the red blood cells in a predictable area of the QBC tube, making detection easy and fast. Red cells containing Plasmodia are less dense than normal ones and concentrate just below the leukocytes, at the top of the erythrocyte column. The float forces all the surrounding red cells into the 40 micron space between its outside circumference and the inside of the tube. Since the parasites contain DNA which takes up the acridine orange stain, they appear as bright specks of light among the non-fluorescing red cells. Virtually all of the parasites found in the 60 microliter of blood can be visualized by rotating the tube under the microscope. A negative test can be reported within one minute and positive result within minutes.
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EXAMINATION OF SPECIMENS for Fungal Diseases
MICROSCOPIC EXAMINATION 0.1% Calcofluor White (W/V) Solution (a) Use commercially available solution cellufluor 17352 (Polysciences, Washington, PA), fluorescent brightener 28.F6259 (Sigma, St. Louis, MO), 1 gm (b) distilled water, 100 ml (c) Gently heat if precipitate develops. Filter if precipitate persists. Store at 25 C in the dark. (3) Commercially prepared kits are
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Need Specific Protocols
Microscope filter system: An epifluorescent microscope equipped with a mercury vapor lamp and either an ultraviolet (UV) or blueviolet (BV) excitation filters to achieve radiation on the slide below 412 nm should be used since the maximum absorbance of CFW is 347 nm.
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Fluorescent stains for demonstrating Cryptosporidium spp. oocysts include Auramine- rhodamine, Auramine Carbol Fuschin and Acridine orange . Confirmatory staining of suspected oocyst by another method may be required
Casemore 1984
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Fluorescent stains Cryptosporidium spp.
Fluorescent stains for demonstrating Cryptosporidium spp. oocysts include Auraminerhodamine, Auramine Carbol Fuschin and Acridine orange . Confirmatory staining of suspected oocyst by another method may be required
Casemore 1984
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Immunofluorescent antibody (IFA) procedure employing
cryptosporidium- specific polyclonal or monoclonal antibodies has been developed
•Polyclonal AB, raised against 18 and 20 kDa C. parvum coproantigen, were used to react with C. parvum sporozoites in an immunofluorescence assay. •Monoclonal antibody reagents offer increased sensitivity and an excellent alternative to conventional staining methods. •These reagents are helpful when screening large numbers of patients or those with minimal symptoms. •Elimination of the problems of false-positive and falsenegative results with routine staining methods.
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Giardia and Cryptosporidium
The sensitivity and specificity of the Merifluor DFA test, have been reported to be 96 to 100% and 99.8 to 100%, respectively, for both Giardia and Cryptosporidium
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Enumerable Possibilities with Florescent Methods
Several Immuno Diagnostic Methods are available Using the Fluorescent Techniques, which needs specific testing material and to follow specific protocols. The Technologists should be familiar with literature available with the Kits
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Created by Dr.T.V.Rao MD for ‘ e ‘ learning resources for Microbiologists in the Developing world
Email
[email protected]
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