High‐speed microscopy for in vivo monitoring of lymph dynamics

The lymphatic system contributes to body homeostasis by clearing fluid, lipids, plasma proteins and immune cells from the interstitial space. Many studies have been performed to understand lymphatic function under normal conditions and during disease. Nevertheless, a further improvement in quantification of lymphatic behavior is needed. Here, we present advanced bright‐field microscopy for in vivo imaging of lymph vessels (LVs) and automated quantification of lymphatic function at a temporal resolution of 2 milliseconds. Full frame videos were compressed and recorded continuously at up to 540 frames per second. A new edge detection algorithm was used to monitor vessel diameter changes across multiple cross sections, while individual cells in the LVs were tracked to estimate flow velocity. The system performance initially was verified in vitro using 6‐ and 10‐μm microspheres as cell phantoms on slides and in 90‐μm diameter tubes at flow velocities up to 4 cm/second. Using an in vivo rat model, we explored the mechanisms of lymphedema after surgical lymphadenectomy of the mesentery. The system revealed reductions of mesenteric LV contraction and flow rate. Thus, the described imaging system may be applicable to the study of lymphatic behavior during therapeutic and surgical interventions, and potentially during lymphatic system diseases. An imaging system for in vivo continuous monitoring of lymph vessels (LVs) and quantification of lymphatic function was developed. High frame rate bright‐field videos of LVs were processed to automatically detect vessel diameter and flow velocity. System performance was tested on in vitro test samples and on a rat model of intestinal lymphadenectomy. Reduced LV contraction and flow rate were detected after surgical lymphadenectomy of the rat mesentery.