🦠Microbiology Unit 2 – How We See the Invisible World
Microscopy revolutionized our understanding of the microbial world by allowing us to see organisms invisible to the naked eye. From simple magnifying glasses to advanced electron microscopes, these tools have unveiled the intricate structures of cells, bacteria, and viruses.
This unit explores the principles of microscopy, including resolution, magnification, and contrast. It covers various types of microscopes, sample preparation techniques, and their applications in microbiology. The limitations and future developments in microscopy are also discussed, highlighting ongoing advancements in the field.
Microscopy involves using microscopes to view objects that are too small to be seen with the naked eye
Resolution measures the ability to distinguish two separate points as distinct and is limited by the wavelength of light used
Magnification increases the apparent size of an object but does not necessarily increase resolution
Contrast enhances the difference between the object and the background, making it easier to observe details
Numerical aperture (NA) is a measure of a microscope's ability to gather light and resolve fine details, calculated using the formula: NA=nsinθ
n represents the refractive index of the medium between the objective lens and the specimen
θ represents the half-angle of the maximum cone of light that can enter the objective lens
Working distance is the distance between the objective lens and the specimen when the specimen is in focus
Depth of field refers to the range of distances over which the specimen remains in acceptable focus
History of Microscopy
The first microscopes were simple magnifying glasses developed in the late 16th century by Dutch spectacle makers Hans and Zacharias Janssen
Robert Hooke coined the term "cell" in 1665 after observing plant cells using a compound microscope
Antonie van Leeuwenhoek advanced microscopy in the late 17th century by creating high-quality single-lens microscopes capable of magnifying up to 300 times
Ernst Abbe and Carl Zeiss collaborated in the 19th century to develop improved lenses and illumination systems, leading to the creation of the first modern compound microscopes
August Köhler introduced Köhler illumination in 1893, a method that provides even illumination of the specimen and is still used in modern microscopes
The development of electron microscopy in the 1930s allowed for the visualization of structures smaller than the wavelength of visible light
The invention of the scanning tunneling microscope in 1981 and the atomic force microscope in 1986 enabled the imaging of individual atoms and molecules
Types of Microscopes
Light microscopes use visible light to magnify specimens and include:
Bright-field microscopes, which produce dark objects on a bright background
Dark-field microscopes, which produce bright objects on a dark background
Phase-contrast microscopes, which convert phase shifts in light passing through a specimen into brightness differences
Differential interference contrast (DIC) microscopes, which use polarized light to enhance contrast
Electron microscopes use electron beams to magnify specimens and achieve higher resolution than light microscopes
Transmission electron microscopes (TEM) pass electrons through thin sections of specimens to create images
Scanning electron microscopes (SEM) scan the surface of specimens with electron beams to generate detailed 3D images
Scanning probe microscopes use physical probes to scan and interact with the surface of a specimen, providing information about its topography and properties
Scanning tunneling microscopes (STM) use an electrically conductive tip to measure the electron density of a conductive surface
Atomic force microscopes (AFM) use a fine tip attached to a cantilever to scan the surface of a specimen and measure its topography
Principles of Light and Optics
Light behaves as both a wave and a particle (photons), a concept known as wave-particle duality
Refraction occurs when light passes through materials of different densities, causing it to bend and change velocity
Lenses use refraction to focus light and form images
Convex lenses converge light rays to a focal point
Concave lenses diverge light rays
Aberrations are imperfections in the image formed by a lens system, such as:
Spherical aberration, caused by the difference in refraction between the center and edges of a lens
Chromatic aberration, caused by the different refractive indices of various wavelengths of light
Numerical aperture (NA) determines the light-gathering ability and resolution of a microscope objective
Köhler illumination provides optimal contrast and even illumination by focusing the light source onto the specimen and the condenser aperture diaphragm onto the objective back focal plane
Sample Preparation Techniques
Fixation preserves the structure of specimens by cross-linking proteins and stabilizing membranes (formaldehyde, glutaraldehyde)
Dehydration removes water from specimens using a series of increasing concentrations of ethanol or acetone
Embedding infiltrates specimens with a supportive medium (paraffin wax, epoxy resin) to allow for thin sectioning
Sectioning cuts specimens into thin slices using a microtome or ultramicrotome
Paraffin-embedded samples are typically cut into 5-10 μm thick sections
Resin-embedded samples for electron microscopy are cut into 50-100 nm thick sections
Staining enhances contrast and highlights specific structures or molecules
Hematoxylin and eosin (H&E) staining is commonly used for tissue sections, staining nuclei blue and cytoplasm pink
Immunohistochemistry uses antibodies conjugated to enzymes or fluorophores to label specific proteins
Mounting places the stained specimen on a microscope slide and covers it with a coverslip and mounting medium for optimal viewing
Microscopy in Action: Observing Microorganisms
Brightfield microscopy is the most common technique for observing bacteria, fungi, and parasites in clinical samples
Gram staining differentiates bacteria based on cell wall composition, with Gram-positive bacteria appearing purple and Gram-negative bacteria appearing pink
Acid-fast staining identifies Mycobacterium species, which retain the carbol fuchsin stain after an acid-alcohol decolorization step
Wet mounts allow for the observation of live microorganisms in a drop of water or saline solution
Darkfield microscopy enhances the contrast of unstained, transparent specimens like spirochetes (Treponema pallidum)
Fluorescence microscopy uses fluorescent dyes to label specific structures or molecules, such as the auramine-rhodamine stain for Mycobacterium tuberculosis
Electron microscopy provides high-resolution images of viruses, bacteria, and cellular ultrastructure
Negative staining with heavy metal salts (uranyl acetate) enhances contrast in TEM images
SEM reveals the surface morphology of microorganisms and biofilms
Limitations and Challenges
Resolution is limited by the wavelength of light used, with visible light microscopes having a maximum resolution of approximately 200 nm
Sample preparation can introduce artifacts or alter the native structure of specimens
Fixation and dehydration can cause shrinkage or distortion of tissues
Sectioning can result in incomplete or damaged samples
Staining can be nonspecific or variable, leading to misinterpretation of results
Live cell imaging is challenging due to the need to maintain appropriate environmental conditions (temperature, pH, osmolarity) and minimize phototoxicity
Electron microscopy requires extensive sample preparation and can only image dead, fixed specimens
Three-dimensional reconstruction from 2D images can be computationally intensive and may not fully capture the complexity of biological structures
Future Developments in Microscopy
Super-resolution microscopy techniques (STED, PALM, STORM) overcome the diffraction limit of light, achieving resolutions of 20-100 nm
Stimulated emission depletion (STED) microscopy uses a depletion laser to selectively turn off fluorophores around a focal point
Photoactivated localization microscopy (PALM) and stochastic optical reconstruction microscopy (STORM) use photoswitchable fluorophores to localize individual molecules
Cryo-electron microscopy (cryo-EM) enables the high-resolution imaging of macromolecular complexes and viruses in their native state
Specimens are rapidly frozen in liquid ethane to preserve their structure
Single-particle analysis averages multiple 2D projections to reconstruct a 3D model
Correlative light and electron microscopy (CLEM) combines the advantages of fluorescence microscopy and electron microscopy to study the same specimen
Expansion microscopy physically expands specimens using a swellable polymer, allowing for super-resolution imaging with conventional microscopes
Advances in computational methods, such as deep learning and artificial intelligence, will improve image analysis, segmentation, and interpretation