The
optical microscope, often referred to as the "
light microscope", is a type of
microscope which uses
visible light and a system of
lenses to magnify images of small samples. Optical microscopes are the oldest design of microscope and were designed around 1600. Basic optical microscopes can be very simple, although there are many complex designs which aim to improve
resolution and sample
contrast. Historically optical microscopes were easy to develop and are popular because they use visible light so the sample can be directly observed by
eye.
The image from an optical microscope can be captured by normal light-sensitive cameras to generate a micrograph. Originally images were captured by photographic film but modern developments in CMOS and charge-coupled device (CCD) cameras allow the capture of digital images. Purely digital microscopes are now available which just use a CCD camera to examine a sample, and the image is shown directly on a computer screen without the need for eyepieces.
Alternatives to optical microscopy which do not use visible light include scanning electron microscopy and transmission electron microscopy.
Optical configurations
There are two basic configurations of the conventional optical microscope, the simple (one lens) and compound (many lenses). The vast majority of modern
research microscopes are compound microscopes while some cheaper commercial
digital microscopes are simple single lens microscopes. A
magnifying glass is, in essence, a basic single lens microscope. In general microscope optics are static; to focus at different focal depths the lens to sample distance is adjusted and to get a wider or narrower field of view a different magnification objective lens must be used. Most modern research microscopes also have a separate set of optics for illuminating the sample.
Single lens (simple) microscope
A
simple microscope is a microscope that uses only one lens for magnification, and is the original design of light microscope.
Van Leeuwenhoek's microscopes consisted of a small, single
converging lens mounted on a brass plate, with a screw mechanism to hold the sample or specimen to be examined.
Demonstrations by British microscopist have images from such basic instruments.
Though now considered primitive, the use of a single, convex lens for viewing is still found in simple magnification devices, such as the
magnifying glass, and the
loupe.
Compound microscope
A
compound microscope is a microscope which uses multiple lenses to collect light from the sample and then a separate set of lenses to focus the light into the eye or camera. Compound microscopes are heavier, larger and more expensive than simple microscopes due to the increased number of lenses used in construction. The main advantages of multiple lenses are improved numerical aperture (see resolution limit below), reduced chromatic aberration and exchangeable objective lenses to adjust the magnification. A compound microscope also makes more advanced illumination setups, such as
phase contrast.
History
Invention
It is difficult to say who invented the compound microscope.
Dutch spectacle-makers Hans Janssen and his son
Zacharias Janssen are often said to have invented the first compound microscope in 1590, but this was a declaration made by Zacharias Janssen himself during the mid 17th century. The date is unlikely, as it has been shown that Zacharias Janssen actually was born around 1590. Another favorite for the title of 'inventor of the microscope' was
Galileo Galilei. He developed an ''occhiolino'' or compound microscope with a convex and a concave lens in 1609. Galileo's microscope was celebrated in the
Accademia dei Lincei in 1624 and was the first such device to be given the name "microscope" a year later by fellow Lincean
Giovanni Faber. Faber coined the name from the
Greek words ''μικρόν'' (micron) meaning "small", and ''σκοπεῖν'' (skopein) meaning "to look at", a name meant to be analogous with "
telescope", another word coined by the Linceans.
Christiaan Huygens, another Dutchman, developed a simple 2-lens ocular system in the late 17th century that was achromatically corrected, and therefore a huge step forward in microscope development. The Huygens ocular is still being produced to this day, but suffers from a small field size, and other minor problems.
Popularisation
Anton van Leeuwenhoek (1632–1723) is credited with bringing the microscope to the attention of biologists, even though simple magnifying lenses were already being produced in the 16th century. Van Leeuwenhoek's home-made microscopes were very small simple instruments, with a single, yet strong lens. They were awkward in use, but enabled van Leeuwenhoek to see detailed images. It took about 150 years of optical development before the compound microscope was able to provide the same quality image as van Leeuwenhoek's simple microscopes, due to difficulties in configuring multiple lenses. Still, despite widespread claims, van Leeuwenhoek is not the inventor of the microscope.
Lighting techniques
While basic microscope technology and optics have been available for over 400 years it is much more recently that techniques in sample illumination were developed to generate the high quality images seen today.
In August 1893 August Köhler developed Köhler illumination. This method of sample illumination gives rise to extremely even lighting and overcomes many limitations of older techniques of sample illumination. Before development of Köhler illumination the image of the light source, for example a lightbulb filament, was always visible in the image of the sample.
The Nobel Prize in physics was awarded to Fritz Zernike in 1953 for his development of phase contrast illumination which allows imaging of transparent samples. By using interference rather than absorption of light, extremely transparent samples, such as live mammalian cells, can be imaged without having to use staining techniques. Just two years later, in 1955, George Nomarski published the theory for differential interference contrast microscopy, another interference-based technique for imaging transparent samples.
Fluorescence microscopy
Modern biological microscopy depends heavily on the development of
fluorescent probes for specific structures within a cell. In contrast to normal transilluminated light microscopy in
fluorescence microscopy the sample is illuminated through the objective lens with a narrow set of wavelengths of light. This light interacts with fluorophores in the sample which then emit light of a longer
wavelength. It is this emitted light which makes up the image.
Since the mid 20th century chemical fluorescent stains, such as DAPI which binds to DNA, have been used to label specific structures within the cell. More recent developments include immunofluorescence, which uses fluorescently labelled antibodies to recognise specific proteins within a sample, and fluorescent proteins like GFP which a live cell can express making it fluorescent.
Components
All modern optical microscopes designed for viewing samples by transmitted light share the same basic components of the light path, listed here in the order the light travels through them:
In addition the vast majority of microscopes have the same 'structural' components:
Ocular lens (eyepiece) (1)
Objective turret or Revolver (to hold multiple objective lenses) (2)
''Objective'' (3)
Focus wheel to move the stage (4 – coarse adjustment, 5 – fine adjustment)
Frame (6)
Light source, a light or a mirror (7)
Diaphragm and condenser lens (8)
Stage (to hold the sample) (9)
These entries are numbered according to the image on the right.
Eyepiece (ocular)
The
eyepiece, or ocular, is a cylinder containing two or more lenses; its function is to bring the image into focus for the eye. The eyepiece is inserted into the top end of the body tube. Eyepieces are interchangeable and many different eyepieces can be inserted with different degrees of magnification. Typical magnification values for eyepieces include 2×, 5× and 10×. In some high performance microscopes, the optical configuration of the objective lens and eyepiece are matched to give the best possible optical performance. This occurs most commonly with
apochromatic objectives.
Objective turret or Revolver
Objective turret or Revolver is the part that holds the set of objective lenses, it allows to change them.
Objective
At the lower end of a typical compound optical microscope there are one or more
objective lenses that collect light from the sample. The objective is usually in a cylinder housing containing a glass single or multi-element compound lens. Typically there will be around three objective lenses screwed into a circular nose piece which may be rotated to select the required objective lens. These arrangements are designed to be
parfocal, which means that when one changes from one lens to another on a microscope, the sample stays in
focus. Microscope objectives are characterized by two parameters, namely,
magnification and
numerical aperture. The former typically ranges from 5× to 100× while the latter ranges from 0.14 to 0.7, corresponding to
focal lengths of about 40 to 2 mm, respectively. Objective lenses with higher magnifications normally have a higher numerical aperture and a shorter
depth of field in the resulting image. Some high performance objective lenses may require matched eyepieces to deliver the best optical performance.
Oil immersion objective
Some microscopes make use of
oil-immersion objectives or water-immersion objectives for greater resolution at high magnification. These are used with
index-matching material such as
immersion oil or water and a matched cover slip between the objective lens and the sample. The refractive index of the index-matching material is higher than air allowing the objective lens to have a larger numerical aperture (greater than 1) so that the light is transmitted from the specimen to the outer face of the objective lens with minimal refraction. Numerical apertures as high as 1.6 can be achieved. The larger numerical aperture allows collection of more light making detailed observation of smaller details possible. An oil immersion lens usually has a magnification of 40 to 100×.
Focus wheels
Adjustment wheels move the stage up and down with separate adjustment for coarse and fine focussing. The same controls enable the microscope to adjust to specimens of different thickness. In older designs of microscopes, the focus adjustment wheels move the microscope tube up or down relative to the stand and had a fixed stage.
Frame
The whole of the optical assembly is traditionally attached to a rigid arm which in turn is attached to a robust U shaped foot to provide the necessary rigidity. The arm angle may be adjustable to allow the viewing angle to be adjusted.
The frame provides a mounting point for various microscope controls. Normally this will include controls for focusing, typically a large knurled wheel to adjust coarse focus, together with a smaller knurled wheel to control fine focus. Other features may be lamp controls and/or controls for adjusting the condenser.
Light source
Many sources of light can be used. At its simplest, daylight is directed via a
mirror. Most microscopes, however, have their own adjustable and controllable light source – often a
halogen lamp, although illumination using
LEDs and
lasers are becoming a more common provision.
Condenser
The
condenser is a lens designed to focus light from the illumination source onto the sample. The condenser may also include other features, such as a
diaphragm and/or filters, to manage the quality and intensity of the illumination. For illumination techniques like
dark field,
phase contrast and
differential interference contrast microscopy additional optical components must be precisely aligned in the light path.
Stage
The stage is a platform below the objective which supports the specimen being viewed. In the center of the stage is a hole through which light passes to illuminate the specimen. The stage usually has arms to hold
slides (rectangular glass plates with typical dimensions of 25×75 mm, on which the specimen is mounted).
At magnifications higher than 100x moving a slide by hand is not practical. A mechanical stage, typical of medium and higher priced microscopes, allows tiny movements of the slide via control knobs that reposition the sample/slide as desired. If a microscope did not originally have a mechanical stage it may be possible to add one.
All stages move up and down for focus. With a mechanical stage slides move on two horizontal axes for positioning the specimen to examine specimen details.
Focusing starts at lower magnification in order to center the specimen by the user on the stage. Moving to a higher magnification requires the stage to be moved higher vertically for re-focus at the higher magnification and may also require slight horizontal specimen position adjustment. Horizontal specimen position adjustments are the reason for having a mechanical stage.
Due to the difficulty in preparing specimens and mounting them on slides, for children it's best to begin with prepared slides that are centered and focus easily regardless of the focus level used.
Magnification
The actual power or
magnification of a compound optical microscope is the product of the powers of the ocular (
eyepiece) and the objective lens. The maximum normal magnifications of the ocular and objective are 10× and 100× respectively giving a final magnification of 1000×.
Magnification and micrographs
When using a camera to capture a
micrograph the effective magnification of the image must take into account the size of the image. This is independent of whether it is on a print from a film negative or displayed digitally on a
computer screen.
In the case of photographic film cameras the calculation is simple; the final magnification is the product of: the objective lens magnification, the camera optics magnification and the enlargement factor of the film print relative to the negative. A typical value of the enlargement factor is around 5× (for the case of 35mm film and a 15x10 cm (6×4 inch) print).
In the case of digital cameras the size of the pixels in the CMOS or CCD detector and the size of the pixels on the screen have to be known. The enlargement factor from the detector to the pixels on screen can then be calculated. As with a film camera the final magnification is the product of: the objective lens magnification, the camera optics magnification and the enlargement factor.
Operation
The optical components of a modern microscope are very complex and for a microscope to work well, the whole optical path has to be very accurately set up and controlled. Despite this, the basic operating principles of a microscope are quite simple.
The objective lens is, at its simplest, a very high powered magnifying glass ''i.e.'' a lens 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 an 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 carefully focusing a brightly lit specimen, a highly enlarged image can be seen. It is this real image that is viewed by the eyepiece lens that provides further enlargement.
In most microscopes, the eyepiece is a compound lens, with one component lens near the front and one near the back of the eyepiece tube. This forms an air-separated couplet.
In many designs, the virtual image comes to a focus between the two lenses of the eyepiece, the first lens bringing the real image to a focus and the second lens enabling the eye to focus on the virtual image.
In all microscopes the image is intended to be viewed with the eyes focused at infinity (mind that the position of the eye in the above figure is determined by the eye's focus). 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.
The essential principle of the microscope is that an objective lens with very short focal length (often a few mm) is used to form a highly magnified real image of the object. Here, the quantity of interest is linear magnification, and this number is generally inscribed on the objective lens casing. In practice, today, this magnification is carried out by means
of two lenses: the objective lens which creates an image at infinity, and a second weak tube lens which then forms a real image in its focal plane.
Illumination techniques
Many techniques are available which modify the light path to generate an improved
contrast image from a sample. Major techniques for generating increased contrast from the sample include
cross-polarized light,
dark field,
phase contrast and
differential interference contrast illumination. A recent technique (
Sarfus) combines
cross-polarized light and specific contrast-enhanced slides for the visualization of nanometric samples.
Other techniques
Modern microscopes allow more than just observation of transmitted light image of a sample; there are many techniques which can be used to extract other kinds of data. Most of these require additional equipment in addition to a basic compound microscope.
Reflected light, or incident, illumination (for analysis of surface structures)
Fluorescence microscopy, both:
:*
Epifluorescence microscopy
:*
Confocal microscopy
Microspectroscopy (where a UV-visible spectrophotometer is integrated with an optical microscope)
Ultraviolet microscopy
Near-Infrared microscopy
Multiple Transmission Microscopy for contrast enhancement and aberration reduction.
Automation (for automatic scanning of a large sample or image capture)
Applications
Optical microscopy is used extensively in microelectronics, nanophysics, biotechnology, pharmaceutic research, mineralogy and microbiology.
Optical microscopy is used for medical diagnosis, the field being termed histopathology when dealing with tissues, or in smear tests on free cells or tissue fragments.
In industrial use, binocular microscopes are common. Aside from applications needing true depth perception, the use of dual eyepieces reduces eye strain associated with long workdays at a microscopy station
. In certain applications, long-working-distance or long-focus microscopes are beneficial. An item may need to be examined behind a window, or industrial subjects may be a hazard to the objective. Such optics resemble telescopes with close-focus capabilities.
Optical microscope variants
There are many variants of the basic compound optical microscope design for specialized purposes. Some of these are physical design differences allowing specialization for certain purposes:
Stereo microscope, a low powered microscope which provides a stereoscopic view of the sample, commonly used for dissection.
Comparison microscope, which has two separate light paths allowing direct comparison of two samples via one image in each eye.
Inverted microscope, for studying samples from below; useful for cell cultures in liquid.
Student microscope, designed for low cost, durability, and ease of use.
Fiber optic connector inspection microscope, designed for connector end-face inspection
Other microscope variants are designed for different illumination techniques:
Petrographic microscope, whose design usually includes a polarizing filter, rotating stage and gypsum plate to facilitate the study of minerals or other crystalline materials whose optical properties can vary with orientation.
Polarizing microscope, similar to the petrographic microscope.
Phase contrast microscope, which applies the phase contrast illumination method.
Epifluorescence microscope, designed for analysis of samples which include fluorophores.
Confocal microscope, a widely used variant of epifluorescent illumination which uses a scanning laser to illuminate a sample for fluorescence.
Digital microscope
A
digital microscope is a microscope equipped with a
digital camera allowing observation of a sample via a
computer. Microscopes can also be partly or wholly computer-controlled with various levels of automation. Digital microscopy allows greater analysis of a microscope image, for example measurements of distances and areas and quantitaton of a fluorescent or
histological stain.
Low-powered digital microscopes,
USB microscopes, are also commercially available. These are essentially
webcams with a high-powered
macro lens and generally do not use
transillumination. The camera attached directly to the
USB port of a computer, so that the images are shown directly on the monitor. They offer modest magnifications (up to about 200×) without the need to use eyepieces, and at very low cost. The lack of illumination optics limits their use in a similar manner to
stereo microscopes.
Limitations
At very high magnifications with transmitted light, point objects are seen as fuzzy discs surrounded by
diffraction rings. These are called
Airy disks. The ''resolving power'' of a microscope is taken as the ability to distinguish between two closely spaced Airy disks (or, in other words the ability of the microscope to reveal adjacent structural detail as distinct and separate). It is these impacts of diffraction that limit the ability to resolve fine details. The extent and magnitude of the diffraction patterns are affected by both the
wavelength of
light (λ), the refractive materials used to manufacture the objective lens and the
numerical aperture (NA) of the objective lens. There is therefore a finite limit beyond which it is impossible to resolve separate points in the objective field, known as the
diffraction limit. Assuming that optical aberrations in the whole optical set-up are negligible, the resolution ''d'', can be stated as:
:
Usually a wavelength of 550 nm is assumed, which corresponds to green light. With air as the external medium, the highest practical ''NA'' is 0.95, and with oil, up to 1.5. In practice the lowest value of ''d'' obtainable with conventional lenses is about 200 nm. A new type of lens using multiple scattering of light allowed to improve the resolution to below 100 nm.
Surpassing the resolution limit
Multiple techniques are available for reaching resolutions higher than the transmitted light limit described above. Techniques for surpassing the resolution limit for bright field microscopy include ultraviolet microscopes, which use shorter wavelengths of light so the diffraction limit is lower. Holographic techniques, as described by Courjon and Bulabois in 1979, are also capable of breaking this resolution limit, although resolution was restricted in their experimental analysis.
Using fluorescent samples more techniques are available. Examples include Vertico SMI, near field scanning optical microscopy which uses evanescent waves, and stimulated emission depletion. In 2005, a microscope capable of detecting a single molecule was described as a teaching tool.
While most techniques focus on increases in lateral resolution there are also some techniques which aim to allow analysis of extremely thin samples. For example sarfus methods place the thin sample on a contrast-enhancing surface and thereby allows to directly visualize films as thin as 0.3 nanometers.
Structured Illumination SMI
SMI (spatially modulated illumination microscopy) is a light optical process of the so-called
point spread function (PSF) engineering. These are processes which modify the PSF of a
microscope in a suitable manner to either increase the optical resolution, to maximize the precision of
distance measurements of fluorescent objects that are small relative to the
wavelength of the illuminating light, or to extract other structural parameters in the nanometer range.
Localization Microscopy SPDMphymod
SPDM (spectral precision distance microscopy), the basic localization microscopy technology is a light optical process of
fluorescence microscopy which allows position, distance and angle measurements on "optically isolated" particles (e.g. molecules) well below the theoretical
limit of resolution for light microscopy. "Optically isolated" means that at a given point in time, only a single particle/molecule within a region of a size determined by conventional optical resolution (typically approx. 200–250 nm
diameter) is being registered. This is possible when
molecules within such a region all carry different spectral markers (e.g. different colors or other usable differences in the
light emission of different particles).
Many standard fluorescent dyes like
GFP, Alexa dyes, Atto dyes, Cy2/Cy3 and fluorescein molecules can be used for localization microscopy, provided certain photo-physical conditions are present. Using this so-called SPDMphymod (physically modifiable fluorophores) technology a single laser wavelength of suitable intensity is sufficient for nanoimaging.
3D super resolution microscopy
3D super resolution microscopy with standard fluorescent dyes can be achieved by combination of localization microscopy for standard fluorescent dyes SPDMphymod and structured illumination SMI.
STED
Stimulated emission depletion is a simple example of how higher resolution surpassing the diffraction limit is possible, but it has major limitations. STED is a fluorescence microscopy technique which uses a combination of light pulses to induce fluorescence in a small sub-population of fluorescent molecules in a sample. Each molecule produces a diffraction-limited spot of light in the image, and the centre of each of these spots corresponds to the location of the molecule. As the number of fluorescing molecules is low the spots of light are unlikely to overlap and therefore can be placed accurately. This process is then repeated many times to generate the image.
Stefan Hell of the Max Planck Institute for Biophysical Chemistry was awarded the 10th German Future Prize in 2006 for his development of the STED microscope.
Alternatives
In order to overcome the limitations set by the diffraction limit of visible light other microscopes have been designed which use other waves.
Atomic force microscope (AFM)
Scanning electron microscope (SEM)
Scanning ion-conductance microscopy (SICM)
Scanning tunneling microscope (STM)
Transmission electron microscopy (TEM)
Ultraviolet microscope
X-ray microscope
The use of electrons and x-rays in place of light allows much higher resolution – the wavelength of the radiation is shorter so the diffraction limit is lower. To make the
short-wavelength probe non-destructive, the atomic beam imaging system (atomic nanoscope) has been proposed and widely discussed in the literature, but it is not yet competitive with conventional imaging systems.
STM and AFM are scanning probe techniques using a small probe which is scanned over the sample surface. Resolution in these cases is limited by the size of the probe; micromachining techniques can produce probes with tip radii of 5–10 nm.
Additionally, methods such as electron or X-ray microscopy use a vacuum or partial vacuum, which limits their use for live and biological samples (with the exception of an environmental scanning electron microscope). The specimen chambers needed for all such instruments also limits sample size, and sample manipulation is more difficult. Color cannot be seen in images made by these methods, so some information is lost. They are however, essential when investigating molecular or atomic effects, such as age hardening in aluminium alloys, or the microstructure of polymers.
See also
Digital microscope
Köhler illumination
Microscope slide
References
Further reading
"Metallographic and Materialographic Specimen Preparation, Light Microscopy, Image Analysis and Hardness Testing", Kay Geels in collaboration with Struers A/S, ASTM International 2006.
External links
Antique Microscopes.com A collection of early microscopes
Historical microscopes, an illustrated collection with more than 3000 photos of scientific microscopes by European makers
The Golub Collection, A collection of 17th through 19th Century microscopes, including extensive descriptions
''Molecular Expressions'', concepts in optical microscopy
Online tutorial of practical optical microscopy
OpenWetWare
Cell Centered Database
Antonie van Leeuwenhoek: Father of Microscopy and Microbiology
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