A cellular-level study of the pathophysiology is crucial for understanding the mechanisms
behind human diseases. Recent advances in quantitative phase imaging (QPI) techniques …

In this paper, we review spatial light interference microscopy (SLIM), a common-path, phase-
shifting interferometer, built onto a phase-contrast microscope, with white-light illumination …

Quantitative phase imaging (QPI) is an emerging label-free modality that attracts significant
interest in biomedicine in general and neuroscience in particular. Based on the principle of …

The risk of biochemical recurrence of prostate cancer among individuals who undergo
radical prostatectomy for treatment is around 25%. Current clinical methods often fail at …

Optical imaging is arguably the most effective tool to visualize living cells with high
spatiotemporal resolution and in a nearly noninvasive manner. Driven by this capability …

We demonstrate a real-time blood testing system that can provide remote diagnosis with
minimal human intervention in economically challenged areas. Our instrument combines …

We here develop a method to measure and image the full optical scattering properties by
inverse spectroscopic optical coherence tomography (ISOCT). Tissue is modelled as a …

Quantitative phase imaging (QPI), a method that precisely recovers the wavefront of an
electromagnetic field scattered by a transparent, weakly scattering object, is a rapidly …

We present a wide-field quantitative label-free imaging of mouse brain tissue slices with sub-
micrometre resolution, employing holographic microscopy and an automated scanning …

Quantitative phase imaging (QPI) has been proven to be a powerful tool for label-free
characterization of biological specimens. However, the imaging speed, largely limited by the …