High-definition quadriwave lateral shearing interferometry.

We present an evolution of quadriwave lateral shearing interferometry that improves the definition of quantitative phase images. It is now possible to produce images with as many pixels as the camera that records the interferogram. This is done by moving a diffraction grating in front of the camera and linearly combining at least nine acquisitions.

Quantitative phase imaging of adherent mammalian cells: a comparative study.

The Quantitative phase imaging methods have several advantages when it comes to monitoring cultures of adherent mammalian cells. Because of low photo-toxicity and no need for staining, we can follow cells in a minimally invasive way over a long period of time. The ability to measure the optical path difference in a quantitative manner allows the measurement of the cell dry mass, an important metric for studying the growth kinetics of mammalian cells.

Wavefront sensing applied to determine the temperature dependence of the refractive index of liquids.

A method based on wavefront sensing is described to determine the temperature dependence of the refractive index of liquids. The technique only implies measuring the wavefront of a light beam passing through a micro-vessel containing the liquid. Here, this vessel is a crater made by CO laser processing in a fused silica plate.

Microscale Temperature Shaping Using Spatial Light Modulation on Gold Nanoparticles.

Heating on the microscale using focused lasers gave rise to recent applications, e.g., in biomedicine, biology and microfluidics, especially using gold nanoparticles as efficient nanoabsorbers of light.

Large field-of-view phase and fluorescence mesoscope with microscopic resolution.

Phase and fluorescence are complementary contrasts that are commonly used in biology. However, the coupling of these two modalities is traditionally limited to high magnification and complex imaging systems. For statistical studies of biological populations, a large field-of-view is required.