Quantitative phase imaging, integrated with artificial intelligence, allows for the rapid and
label-free investigation of the physiology and pathology of biological systems. This review …

Artificial intelligence (AI) has dramatically changed the landscape of science, industry,
defence, and medicine in the last several years. Supported by considerably enhanced …

Two-photon microscopy has enabled high-resolution imaging of neuroactivity at depth within
scattering brain tissue. However, its various realizations have not overcome the tradeoffs …

The need for imaging and ranging in robotics has brought LiDAR (light detection and
ranging) to the forefront of consumer technology. Among various approaches, time-of-flight …

Understanding information processing in the brain requires monitoring neuronal activity at
high spatiotemporal resolution. Using an ultrafast two-photon fluorescence microscope …

Single-shot ultrafast optical imaging can capture two-dimensional transient scenes in the
optical spectral range at≥ 100 million frames per second. This rapidly evolving field …

Understanding the structure and function of vasculature in the brain requires us to monitor
distributed hemodynamics at high spatial and temporal resolution in three-dimensional (3D) …

Characterizing blood flow dynamics in vivo is critical to understanding the function of the
vascular network under physiological and pathological conditions. Existing methods for …

After over 30 years of advances, multiphoton microscopy (MPM) is now instrumental in a
wide range of in vivo biological imaging applications. However, it has, until recently …

The ability to rapidly assay morphological and intracellular molecular variations within large
heterogeneous populations of cells is essential for understanding and exploiting cellular …