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Phase Contrast Optics Theory & Appl. Light Microscopy Abbé Theory • Designed optics for amplitude objects • Absorb light without change in phase of light waves • Based on assumption of no difference in index of refraction between specimen and background Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Criterion for Resolution • Lens must capture undiffracted light plus at least first order of diffracted rays • Combine these in image plane by interference • But — most biological specimens (esp. living) are not amplitude objects • Phase Objects Theory & Appl. Light Microscopy Phase Objects • Do not absorb light • Difference in index of refraction between specimen and background Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Example: Cell • Object 1.25 m thick, i.r. = 1.35; i.r. water = 1.30 (0.05 difference) • Difference in path length for light = 1.25 (0.05) = 0.0625 m • 62.5/500 nm = 1/8 wavelength • /8 = /4 radians = 45° • This is difference in phase of wave passing through cell against wave passing next to cell Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Phase Differences • Our eyes cannot see this • Eyes set for amplitude differences, so cell is essentially transparent • But — information is present in light beams from specimen and in image • How do we see this? Theory & Appl. Light Microscopy Frits Zernike (1888–1966) • Dutch physicist • Developed vector notation for theory of light propagation through phase objects • Invented phase contrast optics in 1930; not manufactured until 1941 by Zeiss Theory & Appl. Light Microscopy Zernike Phase Vector Diagram For propagation of light through phase object S S = incindent wave P P = particle wave P = phase shift of ray through specimen (S = U, undiffracted (0order) ray Length of P = amplitude specimen/amplitude medium = transmission ratio Theory & Appl. Light Microscopy Calculate P by vector addition D U+D=P By the law of sines U P D = of all diffracted orders of light from specimen U = undiffracted light P = resulting specimen light, produced by interference between U and D in image formation Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Brightfield Optics • Shifts all vectors in phase equally, and may change all amplitudes equally: U+D=P U=P • No amplitude image • Information in P is present in , not in amplitude — eye cannot see this Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Phase Contrast Imaging • Basic principle: – Shift phases (s) and/or amplitudes of U and D differentially – This can produce a change in amplitude of P (length of vector) Theory & Appl. Light Microscopy In microscope In specimen At image plane D' D' D D P' U U' U' P U=P U' P' Amplitude! Phase Contrast Optics • Physically separates U and D light and subjects one or the other to phase shift and/or amplitude shift • In theory, any shift of U and D are possible • In practice, a shift of 90° (/4) is appropriate for most biological specimens Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Optical Arrangements • Several possible, but major design challenge to keep U and D rays separate and handled differently • In practice, use a hollow cone of light to illuminate specimen – Phase Annulus below condenser – Phase plate at back focal plane of objective • Only 0 order rays from annulus pass through plate Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Phase Plate • Rings in phase plate can include – Attenuating layer (absorption but no phase shift), or – Phase-shifting layer (no absorption, phase shift only), or – Any combination of the two Theory & Appl. Light Microscopy Positive/Negative Phase • Positive Phase Specimen dark against light background (usual now) • Negative Phase Specimen bright against dark background (looks like darkfield optics) Theory & Appl. Light Microscopy Positive Phase D D' U' U P U=P P' U' > P' Retard D relative to U (move D vector clockwise) Negative Phase D' D P' U U' P U=P U' < P' Advance D relative to U (move D vector counterclockwise) Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Example Systems • Anoptral Phase Contrast Change amplitude of U (soot on ring), no phase shifts for either U or D rays. Bright image — negative phase Popular among algae workers in Great Britain in 50s–60s Theory & Appl. Light Microscopy Anoptral Phase D No phase shifts on ring U D' P U' P' U=P U' < P' Produces delicate image against brown background Theory & Appl. Light Microscopy Example Systems • Zernike Phase Contrast Differential changes in amplitude and phase of U and D rays. • All combinations possible: – Amplitude absorption with no phase shift (metal coating) – Phase shift wavefront with no absorption (silica coating) Theory & Appl. Light Microscopy From: Rose & Pomerat (1960) J. Biophys. Biochem. Cytol. 8:423. Use/Limitation of Phaseco • Use for qualitative, not quantitative evaluation of specimens • Reasons: – Intensity differences in image not uniquely related to index of refraction differences of specimen – Phase halo — optical artifact Cannot completely separate U and D rays in optics Theory & Appl. Light Microscopy Intensity Differences • Two points may have same image intensity, but have different values (different i.r.s) • I.e., if IP/IU of at 240° identical to ratio at 320°, then how distinguish different i.r.? Theory & Appl. Light Microscopy Phase Halo • Serious artifact, most prominent at boundaries of sharp differences in i.r. • Exceeds ability of optics to produce an accurate image • So identification of exact boundary of specimen from image is very difficult Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Reducing Phase Halo • Modification of design of phase plate • Apodized Phase Contrast Addition of neutral density filters to phase plate to suppress halo • Optical Process Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Reducing Phase Halo • Modification of specimen and medium • Worst halo comes from abrupt i.r. difference between specimen (cell) and medium it is in • Match i.r. of medium to i.r. of specimen to reduce halo • Barer & Joseph (1957) Symp. Soc. Exp. Biol. 10:160–184. • Use of non-osmotic solutes to increase medium index of refraction Theory & Appl. Light Microscopy Interference Microscopy • Like phaseco in that imaging produces amplitude differences from phase differences in specimen • Quantitative Techniques • Qualitative Techniques Theory & Appl. Light Microscopy Optical Path Difference • Specimen vs. medium • ' = (s - m)t ' = optical path length t = physical thickness Can measure ', then calculate s = ('/t) + m Theory & Appl. Light Microscopy Dry Mass Calculations • Derived from ' • Need to determine , the refractive increment (difficult) (For most biological specimens, = 1.8 x 10-3 i.r./gm solute/100 ml) Theory & Appl. Light Microscopy • C (dry weight concentration) = (specimen - water)/ = (s – 1.33)/1.8 x 10-3 = gm/100 ml = gm solids x 100/(area x thickness) • ' = C t • Mass of solids per cell = (' x area)/100 = (' x area)/0.18 Theory & Appl. Light Microscopy Double Beam Interference • Phaseco — image formed from interference between 0 order and diffracted orders from specimen • Double Beam Interference — image arises from interference between light from specimen and from a reference beam that does not pass through specimen • (No phase halos from incomplete separation of U and D rays) Theory & Appl. Light Microscopy Vector Diagrams R = reference beam = U = P = A0 R R U P U' U' = 2 A0 1.4 A0 P' Interference between P and R produces P' 1.8 A0 • Image – Specimen bright against background – Ratio of intensities (1.8/1.4)2 1.6 • Can vary amplitude and phase of R vector to produce negative contrast as well Theory & Appl. Light Microscopy Coherent Optics • For this to work, the specimen and reference beams must be coherent to one another • (Not needed for phaseco: U and D emerge from same point in specimen and are automatically coherent) • Light from source must be split into 2 beams and reunite these in image Theory & Appl. Light Microscopy Mach-Zender Double Microscope • • • • • Classical form Difficult to construct Difficult to set up optics Difficult to interpret images Beam splitter system must have twin matched objectives and condensers (and add appropriate compensators) Theory & Appl. Light Microscopy • Image contains interference fringes in a gradient across field: /2, 3/2, 5/2, 7/2, etc. • Displacement of fringe is related to difference in optical path through the specimen: ' • Measure physical thickness of specimen and calculate C and dry weight Theory & Appl. Light Microscopy Not Commonly Used • Mach-Zender expensive and specialized • More commonly used systems: split beam interference optics • Single condenser and objective used • Reference and Specimen beams present in same system • Double Beam Interference Optics Theory & Appl. Light Microscopy Jamin-Lebedeff Microscope • Special attachments applied to condenser and objective, as well as polarizer and analyzer system • About 2/3 of field has useable image (rest has ghost image) • Rotation of analyzer allows quantification of image information • Angle information produces ' • Then measure vertical thickness of specimen to calculate dry weight Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Problems with Designs • Image deteriorates with higher magnification objectives (40x max) • Optical path differences in different scopes • Contrast is lost with open aperture • Condenser and Objective must be specially modified and are not useable for other optics Theory & Appl. Light Microscopy Common Biological Use • Nomarski Differential Interference Contrast (DIC) • Qualitative, not quantitative use • Nomarski 1952 patent • (Allen, et al. (1969) Zeit. fur Wiss. Mikros. 69:193) • DIC sensitive to d/ds, so shows refractive gradients or interfaces Theory & Appl. Light Microscopy Georges (Jerzy) Nomarski (1919–1997) • Polish-born, lived in France after World War II • Physicist, many inventions • Developed modification of interference microscopes now known as differential interference contrast (DIC) optics Theory & Appl. Light Microscopy Robert Day Allen (1927–1986) • Pioneered practical applications of Nomarski’s system Theory & Appl. Light Microscopy DIC • Complicated optical arrangement involving polarizer, analyzer, double wollaston prisms. • Polarizer produces light; lower wollaston prism separates that into 2 component beams polarized at right angles to one another Theory & Appl. Light Microscopy • Lower wollaston also modified to separate two beams in space • Each beam is R for the other • Displacement of beams is set for each objective’s resolution: – 100x, NA 1.25 — 0.2 m – 40x, NA 0.65 — 0.55 m – 16x, NA 0.32 — 1.32 m • Upper wollaston recombines 2 beams into same path, but is adjustable • Usually displace from precise recombination Theory & Appl. Light Microscopy Nomarski Image • Result is extinction (shadow) on one side of specimen and reinforcement (bright) on the other • Shear of image • False relief 3D image • Consider wavefront diagrams Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Shear in Image • Degree of shear is set by wollaston combination • Bias of shear adjustable by shifting upper wollaston position to retard one beam more or less relative to other • Cannot be used for quantitative measurements of dry mass • But extremely useful for observing living cells Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Comparison of Nomarski and Phase Contrast Optics Phase Contrast Cheaper Easier to set up Uses less than full aperture of objective Phase Halo — surrounds specimen and other changes in i.r. Nomarski More expensive Fussy alignment Uses full aperture — closet to theoretical limit Shadow Effect — contrast greatest at shear direction maximum Phase Contrast Insensitive to birefringence in specimen or slides Extremely large depth of field — sensitive to artifacts far out of plane of specimen Doesn’t work well with stained specimens Nomarski Optics disrupted by birefriengence Extremely shallow depth of field — useful for optical sectioning of specimen Works well with stained specimens; optics can be adjusted to enhance contrast Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy Theory & Appl. Light Microscopy