Differential Interference Contrast Microscopy (DIC)

“…In this section, a brief review of our previously published works about the quantitative orientation-independent differential interference contrast (OI-DIC) microscopy [6][7][8][21][22][23] with updates is presented for completeness. The optical scheme of the OI-DIC assembly, which allows changing the shear direction, is shown in Fig.…”

“…Earlier, Shribak described two simple methods for determining the shear angle by measuring the retardance variation of a single DIC prism in the transmitted or in the reflected light and tabulating the shear distance produced by standard Olympus DIC prisms with various objective lenses. 6,7 The shear distance is a product of the focal distance of the objective lens and the shear angle of the DIC prism.…”

“…The DIC image is produced by interference of the light field coming from the object with a laterally displaced copy of itself. [1][2][3][4][5][6] The DIC microscope can employ a high numerical aperture (NA) objective and condenser lenses and, therefore, provides good lateral resolution as well as good axial discrimination. The shear distance is usually smaller than the Airy disk radius, 7 and it does not affect the lateral resolution substantially.…”

“…18 This is double the shear of a standard high-resolution Olympus Nomarski DIC prism U-DICTH. 6 In addition, the microscope suffers from light energy loss. It only uses the first diffraction orders.…”

Mapping optical path length and image enhancement using quantitative orientation-independent differential interference contrast microscopy

“…In this section, a brief review of our previously published works about the quantitative orientation-independent differential interference contrast (OI-DIC) microscopy [6][7][8][21][22][23] with updates is presented for completeness. The optical scheme of the OI-DIC assembly, which allows changing the shear direction, is shown in Fig.…”

“…Earlier, Shribak described two simple methods for determining the shear angle by measuring the retardance variation of a single DIC prism in the transmitted or in the reflected light and tabulating the shear distance produced by standard Olympus DIC prisms with various objective lenses. 6,7 The shear distance is a product of the focal distance of the objective lens and the shear angle of the DIC prism.…”

“…The DIC image is produced by interference of the light field coming from the object with a laterally displaced copy of itself. [1][2][3][4][5][6] The DIC microscope can employ a high numerical aperture (NA) objective and condenser lenses and, therefore, provides good lateral resolution as well as good axial discrimination. The shear distance is usually smaller than the Airy disk radius, 7 and it does not affect the lateral resolution substantially.…”

“…18 This is double the shear of a standard high-resolution Olympus Nomarski DIC prism U-DICTH. 6 In addition, the microscope suffers from light energy loss. It only uses the first diffraction orders.…”

Mapping optical path length and image enhancement using quantitative orientation-independent differential interference contrast microscopy

“…The differential interference contrast (DIC) microscope is the most suitable instrument for imaging transparent animals (Shribak, 2012). However the contrast in conventional DIC imaging depends on the specimen orientation.…”

An orientation‐independent DIC microscope allows high resolution imaging of epithelial cell migration and wound healing in a cnidarian model

Differential interference contrast microscopy with adjustable plastic Sanderson prisms