Abstract
Oxygen tension is a key regulator of early human neurogenesis; however, quantifying intra-tissue O(2) in 3D models for an extended period remains difficult. Existing approaches, such as needle-type fiber microsensors and intensity-based oxygen probes or time-domain lifetime imaging, either perturb the organoids or require high excitation doses that limit the measurement period. Here, we present a step-by-step protocol to measure intra-organoid oxygen in human cerebral organoids (hCOs) using embedded ruthenium-based CPOx microbeads and widefield frequency-domain fluorescence lifetime imaging microscopy (FD-FLIM). The workflow covers dorsal/ventral cerebral organoid patterning, organoid fusion at day 12 with co-embedded CPOx beads, standardized FD-FLIM acquisition (470-nm external modulation, 16 phases at 50 kHz, dual-tap camera), automated bead detection and lifetime extraction in MATLAB, and session-matched Stern-Volmer calibration with Ru(dpp)(3)(ClO(4))(2) to convert lifetimes to oxygen concentration. The protocol outputs per-bead oxygen maps and longitudinal patterns stratified by bead location (intra-organoid vs. gel) and sample state (healthy vs. abnormal), enabling direct linkage between developmental growth and oxygen dynamics. Key features • End-to-end workflow linking hCOs generation, on-gel bead embedding, and FD-FLIM oxygen readout. • Longitudinal single-organoid tracking of oxygen tension with bead-level metadata. • Reference-based lifetime calibration and reproducible camera/LED settings. • Ready-to-reuse materials, recipes, timing, and analysis logic.