(a) (b) (c)
Fig. 4.9Fluorescence microscopy. Comparison of epifluorescence and confocal fluorescence imaging of a
mitotic spindle labelled using indirect immunofluorescence labelling with anti-tubulin (primary antibody) and
a fluorescently labelled secondary antibody. The specimen was imaged using (a) conventional epifluorescence
light microscopy or (b) and (c) using laser scanning confocal microscopy. Note the improved resolution of
microtubules in the two confocal images (b) and (c) as compared with the conventional image (a). (b) and
(c) represent two different resolution settings of the confocal microscope. Image (b) was collected with the
pinhole set to a wider aperture than (c). (Images kindly provided by Brad Amos, University of Cambridge, UK.)CCD arrayEmission filterLensLight sourceExcitation filterObjective lensDichromatic
mirrorImmersion mediumObjective lensCoverslip
Specimen
SlideFig. 4.10Epifluorescence microscopy. Light from a xenon or mercury arc lamp (Light source) passes through a
lens and the excitation filter and reflects off the dichromatic mirror into the objective lens. The objective lens
focusses the light at the specimen via the immersion medium (usually immersion oil) and the glass coverslip
(see insert). Any light resulting from the fluorescence excitation in the specimen passes back through the
objective lens, and since it is of longer wavelength than the excitation light, it passes through the dichromatic
mirror. The emission filter only allows light of the specific emission wavelength of the fluorochrome of interest
to pass through to the CCD array, where an image is formed.113 4.2 The light microscope