AIENP-Reinforced DISCO Method for Whole-Tissue 3D Reconstruction of Pulmonary Capillaries

The pulmonary vascular system plays a crucial role in maintaining normal physiological functions, and perturbations in this network often serve as indicators for various fatal diseases. Thus, accurate mapping and assessment of the intricate anatomical details of pulmonary vasculature is essential for the investigation of the underlying mechanism of these diseases. Yet it is considered a tough challenge as traditional imaging techniques offer limited representations of the vasculature network in the lung, while optical imaging methods face limitations from tissue depth. To overcome these obstacles, in this study, an AIENP-reinforced DISCO method, for whole-tissue 3D reconstruction of pulmonary capillaries is presented. Combining AIENPs, hydrogel-enhanced scaffolds, and solvent-based DISCO procedures, the method successfully visualizes the entire network of mouse pulmonary capillaries with a significantly shortened timeframe and cost. The whole process including labeling and clearing takes 6 days and it costs approximate to 5 USD to stain the lung vasculature of an adult mouse. Moreover, the study provides valuable insights for detecting pulmonary vascular abnormalities. This fast and cost-effective technique opens new avenues for developing better fluorophores compatible with tissue optical clearing and offers insights for in-depth research on pulmonary pathophysiology. Accurate mapping and assessment of the intricate anatomical details of pulmonary vasculature is essential for the investigation of underlying mechanisms of various diseases. Herein, an AIENP-reinforced DISCO method, combining AIENP, hydrogel-enhanced scaffolds, and solvent-based DISCO procedures, achieves unbiased 3D imaging of whole pulmonary capillaries in 6 days.image

Automated summary

Accurate mapping and assessment of the intricate anatomical details of pulmonary vasculature is essential for investigating the mechanisms of various diseases. In this study, an AIENP-reinforced DISCO method, combining AIENPs, hydrogel-enhanced scaffolds, and solvent-based DISCO procedures, achieves unbiased 3D imaging of the entire pulmonary capillaries.