1. Tools

2. How are microorganisms cultured?
Inoculation
Incubation
Isolation
Inspection
Identification

3. How is media inoculated?
Inoculation
Introduce a sample of a microorganism into growth media.
Samples obtained from:
CSF
Blood
Urine
Sputum
Feces
Dead tissue

4. How are microorganisms grown?
Incubation
Allow microoragnism to grow at appropriate temperature for a period of time
37 C in humans

5. How are microorganisms separated in a mixed culture?
Isolation
Separate multiple microorganisms in a mixed culture
Make a pure culture
Differential media
Provide different media with specific nutritive requirements
Only certain microorganisms will grow
Mannitol-Salt agar used to distinguish S. aureus from other Staphylococcus sp.

6. Isolation Methods
Streak plating
Loop dilution
Spread plate
Pour plate

7. How are microorganisms inspected?
Inspection
Observed
Media
Staining
Gram stain
Acid fast stain
Microscopy

8. How are bacteria identified?
Identification
Determine the type of microbe
Based on results of differential & selective tests

9. How are microorganisms visualized?
Stain
Wet mount
Negative vs positive
Simple vs differential
Microscopy
Bright field
Dark field
Phase contrast
Differential interference contrast
Fluorescent
Confocal
Transmission electron
Scanning electron

10. How are live microbes observed?
Wet mount

11. Positive vs Negative Stains
Positive Stains
Heat fix the specimen
Dye sticks to specimen
Examples:
Negative Stains
Dye does NOT stick to specimen
Forms a silhouette around specimen
Pros:
Prevents distortion and shrinkage of cells
Heat fixing not used
Capsule s
Gram stain
Endospore stain
Acid fast stain
Nigrosin stain

12. Simple Stains vs Differential Stains
Single dye used
Dye sticks to specimen
Examples:
Differential Stains
Two dyes used
Primary dye
Counterstain
Distinguishes cell types or parts
Gram stain
Endospore stain
Acid fast stain

13. Anatomy of the Compound Light Microscope
Eyepiece
Tube
Arm
Coarse adjustment knob
Nosepiece
Objective lenses
Stage clip
Fine adjustment knob
Stage
Coaxial stage
controls
Light source
Base

14. Anatomy of the Compound Light Microscope
Condenser
Iris diaphragm

15. Anatomy of the Compound Light Microscope

16. How is Total Magnification Calculated?
Total Magnification = (Ocular magnification) x (Objective magnification)
Type
Ocular Magnification
Objective Magnification
Total Magnification
Scanning 10 4 40
Low
High
Oil Immersion
100

17. What is the field of view?
The diameter of the field of view is measured in millimeters, micrometers, and nanometers.

18. What happens to the field of view as the total magnification increases?
The diameter of the field of view decreases.

19. What happens to the field of view as magnification increases?
Field of view – the diameter of the field at different magnifications.
Total Magnification
Field of View (mm)
Field
40 X
7 mm
100 X
3 mm
400 X
1 mm

20. What is “depth of field”?
Distance between the nearest and farthest objects in a scene that appear sharp in an image.
A lens can precisely focus at only one distance at a time.

21. How does the depth of field affect microscopy?
Cells are 3D.
You must be aware of the plane in which the focus lies.

22. Why do we use oil for the 100X objective?
The refractive index is a measure of the light-bending ability of a medium
The light may bend in air so much that it misses the small high-magnification lens
Immersion oil is used to keep light from bending

23. Resolution Limits Human eye Compound microscope ~ 0.2 mm 10 m 1 m
Human height
1 m
Length of some nerve and muscle cells
0.1 m
Unaided eye
Chicken egg
Human eye
~ 0.2 mm
Compound microscope
1 cm
Frog egg
1 mm
100 µm
Most plant and animal cells
Light microscope
10 µm
Nucleus
Most bacteria
1 µm
Mitochondrion
Smallest bacteria
Electron microscope
100 nm
Viruses
Ribosomes
10 nm
Proteins
Lipids
1 nm
Small molecules
0.1 nm
Atoms

24. Visible Light Microscopy
Bright field microscopy
Visible light transmitted through specimen
Use compound light microscope
Multipurpose use
Dark field microscopy
Visible light reflected of sides of specimen
Use compound light microscope with “stop” on the condenser
View shape, movement of cells

25. Visible Light Microscopy
Differential interference contrast microscopy
Two beams of light
Two prisms
Add contrasting colors
Colored 3D
Phase-contrast microscopy
Light patterns moving through denser regions of cell transformed into a density map
Used to visualize:
Internal structures
Endospores
Granules
Organelles
External structure
Cilia

26. Ultraviolet Microscopy
Fluorescence microscopy
Fluorescent dyes attached to specific cell structures
DAPI
Fluorescein
Texas-red
View internal/external structures of cells & viruses
View interactions of cell biomolecules in 2D
Confocal microscopy
Fluorescent dyes attached to specific cell structures
View internal/external structures of cells/viruses
View interactions of cell biomolecules in 2D or 3D
Plant embryo
Cytoskeleton Proteins

27. Electron Microscopy Transmission electron microscopy
Transmits electrons through specimen
View internal structures of cells & viruses
Resolution = 0.5 nm
Scanning electron microscopy
Surface of specimen coated with metal
Electrons bounce off metal
Produces 3D image of surface
Resolution = 10 nm