Optimized Workflow for Iterative Bleaching Extends Multiplexity Imaging of Highly Autofluorescent Clinical Samples.

The prevalence of pulmonary disease due to nontuberculous mycobacteria (NTM) has been increasing globally. Though NTM-induced pulmonary disease often presents with bronchiectasis, lung nodules, and cavitary disease, the host response associated with these distinct pulmonary injury patterns has not been well characterized in situ. We sought to evaluate mechanisms of NTM-induced pathology by performing deep phenotypic analysis of immune cell populations in lung tissue from individuals with NTM disease in comparison to a gold standard of granulomatous inflammation, tuberculous (TB) lung disease. Formalin-fixed, paraffin-embedded (FFPE) lung blocks from patients with either disseminated NTM, pulmonary NTM, or pulmonary TB disease were sectioned and stained following a modified version of the Iterative Bleaching Extends multi-pleXity (IBEX) imaging method. Optimization of the IBEX method was first required to address the significant endogenous fluorescence of lung sections due to the high density of collagen, elastin, and erythrocytes native to pulmonary tissue that is worsened by FFPE preservation and the age of the FFPE blocks. In this protocol, we detail a photoirradiation protocol and modified antigen retrieval method that reduces the autofluorescence of clinically archived samples. Furthermore, we provide guidance on antibody panel design, including common challenges such as cross-reactivity, epitope loss following photoirradiation, spectral overlap between adjacent fluorophores, and low signal-to-noise for certain targets. To facilitate efficient imaging of whole lung tissue sections, slides were imaged with a widefield microscope and postprocessed with open-source software to improve image quality. Together, this workflow addresses a critical need by documenting how to obtain highly multiplexed, high-resolution, whole-slide images from challenging samples using widely available instrumentation and reagents. Beyond quantitative imaging of clinical samples, these techniques can be applied to diverse sample types to overcome both endogenous and exogenous sources of fluorescence.