Microscopes PDF

Summary

This document is an overview of different types of microscopes, including their optical principles, parts, and applications. It features descriptions of optical microscopy, bright-field, and dark field microscopy.

Full Transcript

❑ Microscope
⮚ Optical Principals of Microscope
⮚Optical Resolution
⮚Numerical Aperture(N.A.) -Resolution(R)
⮚Bright Field Microscopy
⮚Dark Field Microscopy
⮚ Phase Contrast Microscopy A 17th century Compound Microscope

⮚Fluorescence Microscope
⮚Confocal Microscope
⮚Electron Microscope
⮚Scanning Electron Microscope
❑ Microscope
⮚ A microscope is an instrument for viewing objects that
are too small to be seen by the naked or unaided eye.
⮚ The name microscope was coined by Johannes Faber
(1574-1629) who in 1628 borrowed from the Greek to
combined micro-, small with skopein, to view.
⮚ The science of investigating small objects using such an
instrument is called microscopy, and the term microscopic
means minute or very small, not easily visible with the
unaided eye. In other words, requiring a microscope to
examine. A 17th century Compound Microscope

⮚ The most common type of microscope is the optical microscope. This is
an optical instrument containing one or more lenses that produce an enlarged
image of an object placed in the focal plane of the lenses.

⮚ There are two kinds of Optical Microscopes:
1- Simple Optical Microscope
2- Compound Optical Microscope
❑ Optical Principals of Microscope
Basic optical principles of a microscope is quite simple:
⮚ The objective lens is a very high powered magnifying glass with a very
short focal length. This is brought very close to the specimen being examined
so that the light from the specimen comes to a focus about 160 mm inside the
microscope tube. This creates a virtual and enlarged image of the subject.
This image is inverted and can be seen by removing the eyepiece and placing
a piece of tracing paper over the end of the tube. By careful focusing a rather
dim image of the specimen, much enlarged can be seen. It is this virtual
image that is viewed by the eyepiece lens that provides further
enlargement.
⮚ Usually, the eyepiece is a compound lens, which is made of two lenses
one near the front and one near the back of the eyepiece tube forming an air
separated couplet. So, the virtual image comes to a focus between the two
lenses of the eyepiece, the first lens bringing the virtual image to a focus and
the second lens enabling the eye to focus on the image.
⮚ In all microscopes the image is viewed with the eyes focused at infinity.
Headaches and tired eyes after using a microscope are usually signs that the
eye is being forced to focus at a close distance rather than at infinity
❑ Optical Resolution
A lens magnifies by bending light. Optical microscopes are restricted in their
ability to resolve features by a phenomenon called diffraction. It is based on
the numerical aperture (NA or AN) of the optical system and the wavelengths
of light used (λ), sets a definite limit to the optical resolution (Rlim).
Assuming that optical aberrations are negligible, the resolution (R) is given by:

λ of 550 nm is assumed. With air as
medium, the highest practical NA is 0.95,
Rlim~
N.A. and with oil, up to 1.5.
Due to diffraction, even the best optical
microscope is limited to a resolution of 0.2
micrometers.

Rlim~ Rlim~ They are all approximations
nsinθ D
 ❑ Parts of a Microscope

⮚ Compound optical microscopes can magnify an image up to
1000× ( or rarely 2000x) and are used to study thin specimens
as they have a very limited depth of field. Typically they are
used to examine a smear or a thinly sectioned slice of some
material. With a few exceptions, they utilize light passing
through the sample from below and special techniques are
usually necessary to increase the contrast in the image to
useful levels. On a standard compound optical microscope,
there are three objective lenses: a scanning lens (4×), low
power lens (10×), and high power lens (40×).

⮚ Advanced microscopes often have a fourth objective lens,
called an oil immersion lens. To use this lens, a drop of oil is
placed on top of the cover slip, and the lens moved into place
where it is immersed in the oil. They usually has a power of
100×. The actual power or magnification is the product of the
powers of the eyepiece, usually about 10×, and the objective
lens being used. To study the thin structure of metals and 1- Ocular(eyepiece); 2- Nosepiece
3- Objective Lenses 4- Coarse Adjustement Knob
minerals, another type of microscope is used, where the light is 5- Fine Adjustement Knob 6- Object Holder(Stage
7- Mirror 8-Diaphragm(Condenser)
reflected from the examined surface.
The actual power (magnification)=power of the eye piece. (times) power of the lens
 ❑ Stereo Microscope
⮚ The stereo or dissecting microscope is designed
differently from the diagrams above, and serves a different
purpose. It uses two separate optical paths with two objectives
and two eypieces to provide slightly different viewing angles to
the left and right eyes. In this way it produces a three-
dimensional(3-D) visualisation of the sample being examined.
⮚ The stereo microscope is often used to study the surfaces of
solid specimens or to carry out close work such as sorting,
dissection, microsurgery, watch-making, small circuit board
manufacture or inspection, and the like.

⮚ Great working distance and depth of field are important qualities for this type of
microscope. Both qualities are inversely correlated with numerical angle (NA): the higher the NA,
the smaller the depth of field and working distance. NA depth of field working distance

⮚ The stereo-microscope should not be confused with ordinary compound microscopes equipped
with a binocular eyepieces. In these microscopes both eyes can see the image but the
binocular head provides greater viewing comfort and slightly better appearance of resolution.
However the image in such microscopes remains monocular.
❑ Other Medical Devices
❑ Otoscope
⮚ An Otoscope is a medical device which is used to look into
the ears. Health care providers use otoscopes to screen for
illness and investigate when a symptom involves the ears. With
an otoscope, it is possible to visualize the outer and middle ear.
⮚ Otoscopes consist of a handle and a head. The head
contains an electric light source and a low power magnifying
lens. The front end of the otoscope has an attachment for
disposable plastic ear speculums. After inserting the ear Image of an Otoscope and accessories

speculum side of the otoscope into the external ear, the
examiner looks through a lens on the rear of the instrument to
see inside the ear canal.
⮚ Many models have a detachable sliding rear window which
allows the examiner to insert instruments through the otoscope
into the ear canal, such as for removing earwax (cerumen).
Most models also have an insertion point for a bulb capable of
pushing air through the speculum. This puff of air allows an
examiner to test the mobility of the tympanic membrane.
 ❑Bright Field Microscopy
⮚ Some specimens are considered amplitude objects because they absorb
light partially or completely, and can thus be readily observed using
conventional bright field microscopy
⮚Simple set up with basic equipment
⮚The technique can only image dark or strongly refracting objects
effectively.
⮚Low optical resolution. Diffraction limits resolution to approximately 0.2
micron. Diffraction limited
⮚Out of focus light from points outside the focal plane reduces image
clarity.
⮚ reducing or inreasing amount of ligth source
How to make enhancement?
⮚Use of oil immersion objective
⮚Use of staining methods http://zeiss-
⮚Use of filters on the light source campus.magnet.fsu.edu/articles/basics/res
olution.html
 ❑Bright Field Microscopy
Low optical resolution. Diffraction limits resolution to approximately
0.2 micrometers in the best conditions
Use of filters on the light source

Resolution of an optical device (eye or microscope) is its ability to
distinguish between two very closely placed objects as separate
objects.

The resolution limit (resolving power) of a microscope depends on
wavelength of light
numerical aperture (NA) of the lens system used.
Abbe Equation

Resolution (Limit) ~ λ/NA ~ λ/2n Sinθ ~ λ/n Sinθ
Resolution The ability to distinguish two very small and closely spaced objects as separate entities

Best when the distance separating is small
❑Bright Field Microscopy N.A. ~ nsin(θ)
Rlimit ~ λ/N.A.
λ = wavelength of light used; 450-750 nm for visible light used in
a compound microscope; Blue light has the shortest wavelength
(λ =450nm) gives maximum resolution. Therefore, blue filter
blue light is commonly used in microscopy.

NA – n Sin θ; where n is the refractive index of the medium
(usually air or oil) between the specimen and objective lens. For
air n = 1.0 and for immersion oil, n = 1.5.

θ or a- half angle of the cone of light entering the objective lens
from the specimen.
If oil and blue light used, then resolution power is 0.2
micrometers
 Sin (θ)
θ

θ

θ

θ

θ

θ

Higher NA collects more light NA More light Resolution limit Rlimit ~ λ/N.A.

Higher NA, Resolution limit is smaller, improved
resolution (better resolution)
❑ Working Distance
light microscope can never resolve two closer particles less than about 0.2 µm apart, no
matter how many times the image is magnified. The resolution of electron microscope is
about 0.0001 µm (0.1 nm) whereas the human eye is about l00 µm.
Bright-field microscopy is a standard light microscopy technique, and
therefore magnificationis a standard light microscopy technique, and
therefore magnification is limited by the resolving poweris a standard light microscopy
technique, and therefore magnification is limited by the resolving power possible with
❑Dark Field Microscopy
⮚ Dark field microscopy produces an image with a dark background
⮚In dark-field microscopy, the non-diffracted rays are removed altogether so that the
image is composed solely of diffracted wave components.
⮚Live and unstained samples, increase the contrast
⮚Sample must be strongly illuminated which can damage the sample
 http://www.nobelprize.org/educational/physics/microscopes/phas
❑Phase Contrast Microscopy
phase shifts in light passing through a
transparent specimen to brightness changes
in the image.
the human eye is only sensitive to amplitude
The same cells imaged with traditional bright
variations. Phase changes are invisible.
field microscopy (left) and with phase contras
phase contrast microscopy makes phase microscopy (right).

changes visible.
⮚No need staining

the change in phase can be increased to half a wavelength by
a transparent phase-plate in the microscope and thereby
causing a difference in brightness. This makes the transparent
object shine out in contrast to its surroundings
Comparison of transillumination techniques used to generate contrast in a
sample of tissue paper. 1.559 μm/pixel.

Bright field Dark field illumination, Phase contrast
illumination, sample sample contrast illumination, sample
contrast comes comes from contrast comes from
from absorbance of light scattered by the interference of different
light in the sample. sample. path lengths of light
through the sample.
 ❑Fluorescence Microscopy
⮚ A fluorescence microscope is an optical
microscope that uses fluorescence and
phosphorescence
⮚Fluorescence is the emission of light by a substance
that has absorbed light or other electromagnetic
⮚Fluorescent dyes, also known as fluorophores or fluorochromes,
radiation
are molecules that absorb excitation light at a given wavelength
(generally UV), and after a short delay emit light at a longer
wavelength.

Excitation Emission
Spectrum Spectrum
Live Cells
Fixed Cells
Localize/measure enzyme
activity
 Fluorescence
Photoluminescence, light
energy, or photons, stimulate the
emission of a photon.

Fluorescence, specifically, is a
type of photoluminescence where
light raises an electron to an
excited state. The excited state
undergoes rapid thermal
energy loss to the environment
through vibrations, and then a
photon is emitted from the lowest- Jablonski
lying singlet excited state. diagram
 Confocal Microscopy
⮚Light can certainly penetrate through tissue
⮚The confocal microscope is designed to accept light only from a
thin slice within the tissue and to reject light reflected and
scattered from other regions.
⮚parallel beam of light for illumination of the object (Laser source)
 Confocal Microscopy
Laser Scanning Confocal Microscope
Laser beam used to illuminate spots
on specimen
we must scan the region point by
point
a very thin section within the tissue
A photomultiplier
computer compiles images created
from each point to generate a 3-
dimensional image
Live Cells
Fixed Cells
Localize/measure
enzyme activity
TGs in atherosclerotic remodeling

18.75 μm

FXIIIA colocalizes with CD68+ cells as shown by
immunofluorescent doublestaining;
nuclei stained with DAPI
Thrombin induces stress fiber formation
and TG2 re-distribution in HUVECs

50 μm
Rendering SMC in 3D
Confocal Microscopy
 Electron Microscope
Transmission Electron Microscope (TEM)
magnify up to 250,000x
TEM is electron illuminated.
This gives a 2-D view.

The samples must be dry, thin,
and in some cases coated.

Thin slices of specimen are
obtained. The electron beams
pass through this.

It has high magnification and
high resolution.
 Electron Microscope
Transmission Electron Microscope

mitochondrion
 Scanning Electron Microscope (SEM)
magnify up to 100,000x
SEM use electron illumination.

The image is seen in 3-D.

It has high magnification and high resolution.

The specimen is coated in gold and the electrons
bounce off to give you and exterior view of the
specimen.
The pictures are in black and white.
scanning probe
microscopy (SEM)
have extremely
high resolution
can be used to
observe individual
atoms
pigeon blood