specialised applications, for example using total internal reflection microscopy
(TIRF) (Section 4.3.5).
Applications of the microscope in biomedical research may be relatively simple and
routine; for example, a quick check of the status of a preparation or of the health of
cells growing in a plastic dish in tissue culture. Here, a simple bench-top light
microscope is perfectly adequate. On the other hand, the application may be more
involved, for example, measuring the concentration of calcium in a living embryoElectron
gunProjector
lensSpecimen
(EM grid)Light
sourceEyepieceSlide
Specimen
CoverslipCondenser
lensObjective
lensLight microscope electron microscopeTransmissionEye or digital camera Viewing screen ordigital camera
(Resolution limit 0.2 m)
Live and dead cells(Resolution limit 1 nm)
Dead cells onlyFig. 4.1Light and electron microscopy. Schematic that compares the path of light through a compound light
microscope (LM) with the path of electrons through a transmission electron microscope (TEM). Light from a
lamp (LM) or a beam of electrons from an electron gun (TEM) is focussed at the specimen by a glass condenser
lens (LM) or electromagnetic lenses (TEM). For the LM the specimen is mounted on a glass slide with a coverslip
placed on top, and for the TEM the specimen is placed on a copper or gold electron microscope grid. The image
is magnified with an objective lens, glass in the LM and electromagnetic lens in the TEM, and projected onto
a detector with the eyepiece lens in the LM or the projector lens in the TEM. The detector can be the eye or
a digital camera in the LM or a phosphorescent viewing screen or digital camera in the TEM. (Light and EM
images courtesy of Tatyana Svitkina, University of Pennsylvania, USA.)101 4.1 Introduction