Microscopy basics for medical undergraduate students:
Source of light: Brightfield microscope uses visible light for illumination; specimen appears against a bright background. In brightfield microscope, the source of light is sunlight or indoor bulbs, or inbuilt lamps. The inbuilt lamps are made up of low voltage tungsten filament lamp or more recently LED lamp.
Microorganisms are so called
because they are so small that they can not be ordinarily seen using unaided
eye. The optical instrument that magnifies the image of these organisms that
enables us to view their morphological features is a microscope.
Antony van Leeuwenhoek is often
considered as the father of microscopy, although compound microscopes were
actually invented much before. A compound microscope contains several sets of
lenses that magnify the image at different levels. Typically, the image is magnified
initially by the objective lens and then again by the eye piece before it
reaches the eye.
Most bacteria measure in the
range of 0.5 to 4 µm (micrometer NOT microns). Mycoplasma and Coxiella are the
shortest among bacteria and Spirochetes the longest. Viruses are
ultramicroscopic structures; they can’t be seen by compound microscopes. They
can be visualized by electron microscopes and their measurements are in nm
(nanometer). The Å (Armstrong units) is the unit of measurement for still
smaller particles.
1 mm = 1000 µm
1 µm = 1000 nm
1 nm = 10 Å
Various types of microscopes are:
- Simple (dissection) microscope
- Compound microscope
- Darkground microscope
- Phase contrast microscope
- Fluorescent microscope
- Polarisation microscope
- Interference microscope
- Atomic force microscope
- Electron microscope
Principles of microscopy and
concepts:
Magnification: This represents
the number of times the image of a specimen is amplified. 10x means the size of
the image is increased by ten times. The magnifying power of the lens is
limited. After a certain point the magnification results in a blurred image and
is termed empty magnification. Even with the best optics, 1400x is the highest
useful magnification achieved. Magnifying power of an objective is determined
by the dividing the optical tube length by the focal length of the lens. Optical
tube length is the length of the microscope body tube between the nosepiece
opening, where the objective is mounted, and the top edge of the observation
tubes where the eyepieces are inserted. In most microscopes, it is fixed at 160mm.
Low power dry objective 160/16 = 10x
High power dry objective 160/4 = 40x
Oil immersion objective 160/1.7 = 94x or approximately 100x
Numerical Aperture of the lens is
an important consideration in optics as it dictates the angle at which the light
enters it. The light-gathering ability of a microscope objective is
quantitatively expressed in terms of the numerical aperture. Higher values of
numerical aperture allow increasingly oblique rays to enter the objective front
lens, producing a more highly resolved image.
It is defined by the following
formula: Numerical Aperture (NA) = n × sin(θ)
Where n is the refractive index
of the medium between the object and the objective
θ is one-half the angular
aperture (angle of aperture is the angle formed by the two most divergent rays
of light which enter the objective, starting from the center of the object )
Refractive index of oil is 1.5
and that of air is 1.0.
NA of dry objective: 1 x sin 90o
= 1, but practically the highest practical numerical aperture of a dry lens is
0.95.
NA of oil immersion objective:
1.5 x sin 90o = 1.5, however in practice only 1.4 is achieved for
apochromatic objective and 1.3 for achromatic objective.
Limit of resolution or resolving
power: In simple words, it is the ability to see two closely placed dots as two
separate dots. If the distance between the two points is lessened, it would
appear as a single point. It is expressed quantitatively as limit of
resolution. The resolution of human unaided eye is 200 µm. This means that human
eye can not see objects small than 200 µm. The resolving power of compound
microscope is 0.2 µm and that of electron microscope is 1-10 nm. The limit of
resolution depends on the wavelength of the light used. Resolution increases
with the decreasing wavelength of light. Violet colour light offers more
resolution that red coloured light. Electron beams, which have very low
wavelength offers maximum resolution. It is calculated by using formula:
LR
= 0.61 x wavelength of
light
Numerical aperture
For example, if green light of
wavelength 0.55 µm is used and oil immersion objective with NA 1.4 is used, the
maximum resolution obtained is 0.24 µm
0.61 x 0.55 = 0.24 µm
1.4
Definition: This is the capacity
of the objective to render the outline of the image clear and distinct.
Definition of an image is disturbed by spherical or chromatic aberrations. The
central part of the image is usually well focused but the edges may suffer some
aberration, which are of two types; spherical or chromatic. In spherical
aberration, the periphery of the image appears out of focus. This happens
because all the light passing through the lens doesn’t condense at the same
point. In chromatic aberration, the light is split into different colours at
the peripheral part of the image since the edges of the lens act like a prism.
The aberrations can be corrected by using achromatic or apochromatic lenses.
Parts and functions of compound microscope:
Source of light: Brightfield microscope uses visible light for illumination; specimen appears against a bright background. In brightfield microscope, the source of light is sunlight or indoor bulbs, or inbuilt lamps. The inbuilt lamps are made up of low voltage tungsten filament lamp or more recently LED lamp.
Condenser: The parallel beam of light from
natural or artificial source is condensed into a cone of light that illuminates
the specimen or the object (smear on slide) by the sub-stage condenser. If the
source of light is sunlight or indoor bulbs, the light is diverted to the
condenser using the mirror. Concave mirror is used when low or high power
objective lenses are used, whereas plane mirror is used when oil immersion
objective lens is used. Mirrors are absent when in-built lamps are used. The
condenser consists of series of lenses, which focuses the light to the object
placed on the stage. Kohler illumination ensures that the diffuse light of
uniform brightness is available without the view of the source of light. Various
types of condenser in use are Abbe, Paraboloid and Cardoid condensers. The Abbe
condenser (which is named after its inventor Ernst Karl Abbe) is the simplest
of condensers that contains two lenses. The condenser can be lowered or raised
according to the requirements. The condenser is lowered while using low power
dry objectives, and raised while using oil immersion objectives.
Iris diaphragm: The amount of light passing on to
the specimen from the condenser is regulated by using iris diaphragm. Light is
reduced by closing the diaphragm partially for use with dry objectives. Oil
immersion objectives require maximum light and this is achieved by keeping the
iris diaphragm fully open.
Objectives: The light passing through the
object (specimen) enters the objective lens. Typically, most microscopes have
four objective lenses mounted on a revolving nose piece. The dry objectives
include scanner (5x), lower power (10x) and high power (40 or 45 x). The oil
immersion objective (100x) offers maximum magnification.
Eyepiece: Depending on the type of
microscope, the magnified image may travel straight or can be reflected or
divided using prism towards the eye piece. Monocular microscopes have single
eyepiece where binocular microscopes have two. The magnified image is again
magnified in the eyepiece lens and an inverted image is formed on the retina of
the viewer’s eye. Older Huyghenian eye pieces were used with achromatic
objective lenses but the newer apochromatic objectives require compensating eye
pieces. These eye pieces correct the lateral colour errors of their objectives.
In a compound microscope, the image is magnified twice; first by the objective
lens and then by the eye piece. The eye piece consists of two planoconvex
lenses with a circular diaphragm between them. Their magnification can vary
form 5x to 10x.
The magnifications of the image
in a compound microscope are as follows:
|
Objective lens
|
Eye piece
|
Total magnification
|
|
5x
|
10x
|
50x
|
|
10x
|
10x
|
100x
|
|
40x
|
10x
|
400x
|
|
100x
|
10x
|
1000x
|
The image of a specimen is
magnified approximately 1000 times using a compound microscope. With an
inclined body, the magnification of the microscope may be improved by another 1.5
times. With the highest practically achievable NA of about 1.4, 1400x is the
highest useful magnification that can be achieved.
Role of oil: Since the condenser is fully
raised for use with oil immersion objectives, light focused on to the specimen
are at acute angles. For this reason the objective lens must be as low as
possible. Despite this, the light can pass away without entering the objective
lens due to diffraction suffered by light when moving from one medium to
another (glass to air). Hence, the place between the glass slide and oil
immersion objective is filled with immersion oil having same refractive index
as that of glass. The light rays leaving the glass do not deviate and enter
straight into the objective lens.
Even though the magnification of
1000x is achieved using 100x objective of 1.4 NA and 10x eyepiece, it does not
provide image as sharp as that obtained with magnification of 400x using 40x
objective of 0.65 NA and 10x eyepiece.
Adjustments for dry objectives
(5x, 10x, 40x):
Mirror: concave, condenser:
partially lowered, iris diaphragm: partially closed
Adjustments for oil immersion
objective (100x):
Mirror: plane, condenser: fully
raised, iris diaphragm: fully open
Focusing the slide:
Before viewing the slide under
microscope, it is important to obtain a bright background. For oil immersion
objective usage, follow these steps:
Ensure that iris diaphragm is
fully open and condenser fully risen. With 10x objective in place, look through
the eyepiece and adjust the plane mirror such a way that you obtain perfectly
bright and uniformly lit white background.
Place a drop of oil on the
stained smear and place it on the stage and center it such a way that the smear
is above the source of light and below the objective lens.
Shift to 100x objective and raise
the stage till the oil on the slide touches the objective. This must be done
looking sideways and not while looking through the eyepiece or else the slide
will break and damage the objective lens.
Using fine adjustment, try to
focus the image. Move the slide accordingly to obtain a good field.
After viewing and noting down the
observations, lower the stage and remove the slide.
Proper usage and handling the
microscope:
Microscope is a delicate
instrument that must be handled with care. All kinds of mechanical shocks must
be avoided. The microscope must be lifted by holding its arm in one hard and
supporting the base of the microscope with the palm of the other hand. The
microscope must be kept in dust free environment. The oil must be wiped clean
using a soft tissue paper. After usage the slide must be removed and cleaned
before returning to its original place.
