Yuzhu Li, Nir Pillar, Tairan Liu, Guangdong Ma, Yuxuan Qi, Kevin de Haan, Yijie Zhang, Xilin Yang, Adrian J. Correa, Guangqian Xiao, Kuang-Yu Jen, Kenneth A. Iczkowski, Yulun Wu, William Dean Wallace, Aydogan Ozcan
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引用次数: 0
Abstract
Organ transplantation serves as the primary therapeutic strategy for
end-stage organ failures. However, allograft rejection is a common complication
of organ transplantation. Histological assessment is essential for the timely
detection and diagnosis of transplant rejection and remains the gold standard.
Nevertheless, the traditional histochemical staining process is time-consuming,
costly, and labor-intensive. Here, we present a panel of virtual staining
neural networks for lung and heart transplant biopsies, which digitally convert
autofluorescence microscopic images of label-free tissue sections into their
brightfield histologically stained counterparts, bypassing the traditional
histochemical staining process. Specifically, we virtually generated
Hematoxylin and Eosin (H&E), Masson's Trichrome (MT), and Elastic Verhoeff-Van
Gieson (EVG) stains for label-free transplant lung tissue, along with H&E and
MT stains for label-free transplant heart tissue. Subsequent blind evaluations
conducted by three board-certified pathologists have confirmed that the virtual
staining networks consistently produce high-quality histology images with high
color uniformity, closely resembling their well-stained histochemical
counterparts across various tissue features. The use of virtually stained
images for the evaluation of transplant biopsies achieved comparable diagnostic
outcomes to those obtained via traditional histochemical staining, with a
concordance rate of 82.4% for lung samples and 91.7% for heart samples.
Moreover, virtual staining models create multiple stains from the same
autofluorescence input, eliminating structural mismatches observed between
adjacent sections stained in the traditional workflow, while also saving
tissue, expert time, and staining costs.