Light Microscopy - Summary - PDF

Summary

This document is a summary of light microscopy. It covers various techniques for microscopic observation, including bright-field, dark-field, phase-contrast, and fluorescence microscopy.

Full Transcript

 The Light Microscope

many types
– bright-field microscope
– dark-field microscope
– phase-contrast microscope
– fluorescence microscopes
are compound microscopes
– image formed by action of 2
lenses
 Lenses and the Bending of Light

Light is refracted (bent) when passing
from one medium to another
Refractive index
– a measure of how greatly a substance
slows the velocity of light
Direction and magnitude of bending is
determined by the refractive indexes of
the two media forming the interface
 Lenses

Focus light rays at a specific place
called the focal point
Distance between center of lens
and focal point is the focal length
strength of lens related to focal
length
– short focal length more
magnification
The Bright-Field Microscope

Produces a dark image against a
brighter background
Parfocal microscopes remain in
focus when objectives are
changed
Parcentral ?:
Total magnification
– product of the magnifications of
the ocular lens and the objective
lens
Field of View
 Bright-Field

Common multipurpose microscope
for live and preserved stained
specimens, specimen is dark and
field is white/bright

Magnification: 2000X
Resolution: 0.2um (200nm)
 Microscope Resolution

Ability of a lens to separate or
distinguish small objects that
are close together
Wavelength of light used is
major factor in resolution
shorter wavelength  greater
resolution

200nm
 Working Distance
Distance between the front surface of
lens and surface of cover glass or
specimen
What is happening to working distance and field of
view as you increase the magnification?
 The Dark-Field Microscope

Produces a bright image of the
object against a dark
background
Used to observe living,
unstained preparations
Magnification: 2000X
Resolution: 0.2um
The Phase-Contrast Microscope

Enhances the contrast between
intracellular structures having
slight differences in refractive
index
Excellent way to observe living
cells
Magnification: 2000X
Resolution: 0.2um
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
DNA stained blue
with DAPI.
Microtubules and
centromeres
stained with
fluorescently
tagged antibodies
Immunofluorescence
 The Differential Interference
Contrast Microscope

Creates image by detecting
differences in refractive indices
and thickness of different parts
of specimen

Excellent way to observe living
cells
 Preparation and Staining of
Specimens

Increases visibility of specimen

Accentuates specific
morphological features

Preserves specimens
 Dyes and Simple Staining

Dyes
– make internal and external
structures of cell more visible by
increasing contrast with background
– have two common features
chromophore groups
–Chemical groups give dye its
color
ability to bind cells by ionic,
covalent, or hydrophobic bonding
 Two Types of Ionizable Dyes

Basic Dyes: Methylene blue,
basic fuchin, crystal violoet, safranin,
malachite green-positively charged
(Positive Staining)
Acid Dyes: Eosin, rose
Bengal,Nigrosin and acid fuchin-
possess, India Ink, negatively
charged group
(Negative Staining)
*Bacterial Cell Surface has net
negative charge
 Smear

A thin, uniform film of
bacterial growth on a glass
slide in order to proceed with
further staining for
microscopic examination.
 Fixation

Process by which internal and external
structures are preserved and fixed in
position
Process by which organism is killed and
firmly attached to microscope slide
– heat fixing
preserves overall morphology but not
internal structures
– chemical fixing
protects fine cellular substructure and
morphology of larger, more delicate
organisms
 Dyes and Simple Staining

Simple staining
–a single staining agent is
used
–basic dyes are frequently
used
dyes with positive charges
e.g., crystal violet
 Differential Staining

Divides microorganisms into
groups based on their staining
properties
–e.g., Gram stain
–e.g., Acid-fast stain
 Gram Staining

Most widely used differential
staining procedure

Divides Bacteria into two
groups based on differences in
cell wall structure
 Gram Staining
1. The smear is heat fixed and then first
stained with crystal violet, which stains all
cells purple

2. Iodine is used as a mordant to increase
interaction between the cells and the dye

3. Ethanol or acetone is used to decolorize

4. Safranin is then added as a counterstain
to turn the gram-negative bacteria pink
while leaving the gram-positive bacteria
purple
 Acid-fast staining

Particularly useful for staining members of
the genus Mycobacterium
e.g., Mycobacterium tuberculosis –
causes tuberculosis
e.g., Mycobacterium leprae – causes
leprosy
– high lipid content in cell walls is
responsible for their staining
characteristics
ACID FAST STAINING
 Staining Specific Structures

Negative staining: Widely used to
visualize diffuse capsules
surrounding the bacteria; those
capsules are unstained by the
procedure and appear colorless
against a stained background

*Acid dyes are used, such as
Nigrosin or India Ink
 NEGATIVE STAINING

Morphology Bacterial Capsule
 Spore Staining:

Double staining technique by which
bacterial endospores are left one color
and the vegetative cell a different color

Flagella Staining:

Mordants are applied to increase the
thickness of flagella to make them easier
to see after staining
 Electron Microscopy

Beams of electrons are used to
produce images

Wavelength of electron beam is
much shorter than light,
resulting in much higher
resolution
 Specimen Preparation

Analogous to procedures used
for light microscopy
For transmission electron
microscopy, specimens must be
cut very thin
Specimens are chemically fixed
and stained with electron dense
material
 Other Preparation Methods

Shadowing
– coating specimen with a thin film
of a heavy metal
Freeze-etching
– freeze specimen then fracture
along lines of greatest weakness
(e.g., membranes)
 The Transmission Electron
Microscope

Electrons scatter when they pass
through thin sections of a
specimen
Transmitted electrons (those that
do not scatter) are used to
produce image
Magnification: 1000000X
Resolution: 0.5nm
The Scanning Electron Microscope

Uses electrons reflected from the
surface of a specimen to create
image
produces a 3-dimensional image of
specimen’s surface features
Magnification: 100000X
Resolution: 10nm
 Newer Techniques in Microscopy

confocal
microscopy and
scanning probe
microscopy
have extremely
high resolution
can be used to
observe
individual
atoms
Figure 2.20