microscopy
TRANSCRIPT
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MICROSCOPY
PRESENTED BYDR.MONALISA MOHANTY
1st Yr P.G Dept. of MICROBIOLOGY
SCB MCH,CUTTACK.
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LAYOUT OF PRESENTATION
• Introduction• Historical Background• Variables Used In Microscopy• Parts of microscope• Micrometry• Types of Microscope & Uses• Care Of Microscope
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INTRODUCTION
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- A microscope (Greek: mikron = small and scopeos = to look).
- MICROSCOPE: Is an instrument for viewing objects that are too small to be seen by the naked or unaided eye.
- MICROSCOPY: The science of investigating small objects using such an instrument is called microscopy.
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HISTORICAL BACKGROUND
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• 1590 - Hans Janssen and his son Zacharias Janssen, developed first microscope.
• 1609 - Galileo Galilei - occhiolino or compound microscope.
• 1620 - Christian Huygens, another Dutchman, developed a simple 2-lens ocular system that was chromatically corrected.
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Anton van Leeuwenhoek (1632-1723)
Robert Hooke (1635-1703)
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VARIABLES USED IN MICROSCOPY
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1.MAGNIFICATION• Degree of enlargement.• No of times the length, breadth or
diameter, of an object is multiplied.
• It depends upon – Optical tube length Focal length of objective Magnifying power of eye piece
• TOTAL MAGNIFICATION: magnification of the eyepiece x magnification of the objective.
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2.RESOLUTION
• Ability to reveal closely adjacent structural details as separate and distinct.
• LIMIT OF RESOLUTION (LR): The minimum distance between two visible bodies at which they can be seen as separate and not in contact with each other.
• LR = 0.61 x W W = Wavelength NA NA = Numerical
aperature
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3.NUMERICAL APERTURE(NA)
- Ratio of diameter of lens to its focal length- NA = n Sin θ/2
n = refractive index,θ = angle of aperture (CAD)
θ/2
A
B DC
4.DEFINITIONCapacity of an objective to render outline of the image of an object clear and distinct.
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5. ABERRATION
SPHERICAL CHROMATIC
Focus of marginal rays
Focus of axial rays
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- Chromatic aberration
Blue focusRed focus
Incident light
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6.WORKING DISTANCEDistance between the front surface of lens and surface of cover glass or specimen.
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7.CONTRAST• Differences in intensity between two objects,
or between an object and background.
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PARTS OF A MICROSCOPE
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COMPOUND LIGHT MICROSCOPE
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MICROMETRY
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• Helps in measurement of the size of microscopic objects.
• Achieved by the use of- 1.STAGE MICRO METER 2.MICOMETER EYE PIECE
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CALIBRATION OF THE OCULAR MICROMETER
Stage micrometer (objective micrometer) has calibration lines or graduations that are separated 0.01 mm (10 µm) apart.
Calibration achieved by superimposing the two scales and determining how many ocular graduation coincide with graduations on stage micrometer.
Ocular micrometer with retaining ring inserted into the eyepiece’s base
Stage micrometer positioning by centering the small glass disk over the light source
After completed calibration, specimen’s slide is positioned for measurement
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TYPES OF MICROSCOPE&
USES
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LIGHT MICROSCOPE : use sunlight or artificial light.A. Bright field microscope.B. Dark field microscope.C. Phase contrast microscope.D. Fluorescence microscope.
ELECTRON MICROSCOPE : use of electron.1. Transmission electron microscope.2. Scanning electron microscope.
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A. BRIGHT-FIELD MICROSCOPE
Produces a dark image against a brighter background.
Has several objective lenses.
2 types: Simple Compound
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SIMPLE
• Contain a single magnifying lens.
COMPOUND
• Series of lenses for magnification.
• Light passes through specimen into objective lens • Oil immersion lens increases resolution.
• Have one or two ocular lenses.
• Resolution=200nm
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THE EFFECTS OF IMMERSION OIL ON RESOLUTION
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OPTICS OF COMPOUND MICROSCOPE
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ADVANTAGES
• Used to view live or stained cells.
• Simple setup with very little preparation required.
DISADVANTAGES• Biological specimen are often of low contrast
and need to be stained.
• Staining may destroy or introduce artifacts.
• Resolution is limited to 200nm.
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IMAGE FORMED BY BRIGHT FIELD MICROSCOPY
(unstained)
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B.DARK FIELD MICROSCOPE
• Produces a bright image of the object against a dark back ground.
• Optical system to enhance the contrast of unstained bodies.
• Specimen appears gleaming bright against dark background.
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REQUISITES FOR DARK FIELD MICROSCOPY
- Dark ground condenser
- High intensity
lamp
- Funnel stop
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OPTICS OF DARK FIELD MICROSCOPY
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USES OF DARK GROUND MICROSCOPY
Treponema pallidum
Useful in demonstrating
-Treponema pallidum
- Leptospira
- Campylobacter jejuni
- Endospore
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ADVANTAGES• Simple setup
• Provides contrast to unstained tissue,so living cells can be viewed.
DISADVANTAGES• Specimen needs to be strongly
illuminated which can damage delicate samples.
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PHASE CONTRAST MICROSCOPE
• First described in 1934 by Dutch physicist Frits Zernike
• Produces high-contrast images of transparent specimens.
• Advantage - Living cells can be examined in their natural state.
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PRINCIPLE OF PHASE CONTRAST MICROSCOPY
• It is an optical illumination technique in which small phase shifts in the light passing through a transparent specimen are converted into contrast changes in the image.
• Light rays in phase produce brighter image.
• Light rays out of phase form darker image.
• Contrast is due to out of phase rays.
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REQUISITE FOR PHASE CONTRAST MICROSCOPY
• Annular Diaphragm
• Phase Plate
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CONDENSER ANNULUS
• The condenser annulus or annular diaphragm is opaque flat-black (light absorbing) plate with a transparent annular ring.
• Produces hollow cone of light.
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PHASE PLATE
- Placed in back focal plane of objective.
- Function:1. Enhances phase difference by retarding
diffracted wave front by one quarter of wavelength .2. Reduces intensity of direct rays and equalizes it with diffracted rays intensity.
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OPTICS OF PHASE CONTRAST MICROSCOPE
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IMAGES OF PHASE CONTRAST MICROSCOPY
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ADVANTAGES
• Phase contrast enables visualization of internal cellular components.
• Diagnosis of tumor cells .
• Examination of growth, dynamics, and behavior of a wide variety of living cells in cell culture.
• Ideal for studying & interupting thin
specimen.
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DISADVANTAGES
• Annuli or ring limits the apperature to some extents which causes decrease in resolution.
• Not ideal for thick specimen.
• Shade off and Halo effect may occur.
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THE FLUORESCENCE MICROSCOPE
• Exposes specimen to ultraviolet, violet, or blue light.
• Specimens usually stained with fluorochromes.
• Shows a bright image of the object resulting from the fluorescent light emitted by the specimen.
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PRINCIPLE OF FLUORESCENCE MICROSCOPY
• Certain dyes,called as fluorochrome after absorbing UV rays raised to a higher energy level.
• When the dye molecules return to their normal state,they release excess energy in the form of visible light(fluoroscence).
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OPTICS OF FLUOROSCENT MICROSCOPE
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USE OF FLUORESCENCE MICROSCOPY
- Auramine Rhodamine – Yellow fluorescence Tubercle bacilli
- Acridine Orange R - gives orange red fluorescence with RNA and yellow green fluorescence with DNA
- QBC- IMMUNOFLUORESCENCE
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IMMUNOFLUORESCENCE
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ELECTRON MICROSCOPE
Co-invented by Max knoll and Ernst Ruska in 1931.
Electron Microscopes uses a beam of highly energetic electrons to examine objects on a very fine scale.
Magnification can upto 2million times while best light microscope can magnify up to 2000 times.
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TRANSMISSION ELECTRON MICROSCOPE (TEM)
Stream of electrons is formed.
Accelerated using a positive electrical potential.
Focused by metallic aperture and Electro magnets.
Interactions occur inside the irradiated sample
which are detected and transformed into an image.
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-Projector Lens forms image on Fluorescent viewing screen
- 2D Image
- Magnification 10,000 X to 100,000
X
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OPTICS OF TEM
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- Scan a gold-plated specimen to give a 3-D view of the surface of an object which is black and white.
- Used to study surface features of cells and viruses.
- Scanning Electron microscope has resolution 1000 times better than Light microscope.
SCANNING ELECTRON MICROSCOPE
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OPTICS OF SEM
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SEM IMAGES
Vibrio cholerae with polar flagellaTreponema pallidum
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COMPARING SEM AND TEM
TEM SEM
ImagingElectrons must pass through and be transmitted by the
specimen
Information needed is collected near the surface
of the specimen
Electron Beam Broad, static beamsBeam focused to fine point;
sample is scanned line by line
Voltages Needed TEM voltage ranges from
60-300,000 volts
Accelerating voltage much lower; not necessary to penetrate the
specimen
Image RenderingTransmitted electrons are collectively focused by the
objective lens and magnified to create a real image
Beam is scanned along the surface of the sample to
build up the image
Interaction of thebeam electrons
Specimen must be very thinWide range of specimens
allowed; simplifies sample preparation
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OTHER MICROSCOPES AND USES
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Uses a laser beam to illuminate a specimen whose image is then digitally enhanced for viewing on a computer monitor.
Laser beam scans single plane of 1µm thickness.
CONFOCAL LASER SCANNING MICROSCOPE
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OPTICS OF CONFOCAL MICROSCOPY
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USES OF CONFOCAL MICROSCOPE
- Observing cellular morphology in multilayered specimen.
- Eg. used in diagnosing Ca cervix
- Evaluation and diagnosis of basal cell carcinoma of skin.
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ADVANTAGE OF USING A CONFOCAL MICROSCOPE
- By having a confocal pinhole, the microscope is really efficient at rejecting out of focus fluorescent light so that very thin section of a sample can be analyzed.
- By scanning many thin sections through a sample, one can build up a very clean three-dimensional image .
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INVERTED MICROSCOPE• Used in metallurgy
• Examination of cultures in flat bottom dishes
• Micro dissection
• Examination of parasites
• Observation of agglutination in serology
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STEREO MICROSCOPE• Double Microscope• Produces 3D images
POLARIZING MICROSCOPE
• Uses two Polariser
• Gives information about Birefringence of a body
• Used in Crystallography, Urine examination
• Apple Green Birefringerence in AMYLODOSIS
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SCANNING PROBE MICROSCOPE - Class of Microscope that measures surface
features by moving a sharp probe over object surface. Used to visualize atoms and molecules
• scanning tunneling microscope (stm)
• atomic force microscope (afm)
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SCANNING TUNNELING MICROSCOPE
Steady current (tunneling current) maintained between microscope probe and specimen.
The arrangement of atoms on the specimen is determined by moving probe tip back and froth over specimen keeping a constant height.
ATOMIC FORCE MICROSCOPE
Sharp probe moves over surface of specimen at constant distance.
Up and down movement of probe as it maintains constant distance is detected and used to create image.
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SCANNING PROBE MICROSCOPES
Scanning probe microscopes “feel” changes in surfaces of the sample. They use ultra-sharp tips to measure changes in electric currents, electrostatic forces, or magnetic forces coming from the surface.
The tips of the microscopes have to be incredibly sharp to allow them to collect information about individual atoms or molecules.
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CARING OF MICROSCOPE
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• PROPER STORAGE
• HANDLING
• CARE OF LENSES
• CARE OF OIL EMERSION OBJECTIVE
• CARE OF LAMP
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