Molecular imaging of oxidized collagen quantifies pulmonary and hepatic fibrogenesis
Howard H. Chen, Philip A. Waghorn, Lan Wei, Luis F. Tapias, Daniel T. Schühle, Nicholas J. Rotile, Chloe M. Jones, Richard J. Looby, Gaofeng Zhao, Justin M. Elliott, Clemens K. Probst, Mari Mino-Kenudson, Gregory Y. Lauwers, Andrew M. Tager, Kenneth K. Tanabe, Michael Lanuti, Bryan C. Fuchs, Peter Caravan
Howard H. Chen, Philip A. Waghorn, Lan Wei, Luis F. Tapias, Daniel T. Schühle, Nicholas J. Rotile, Chloe M. Jones, Richard J. Looby, Gaofeng Zhao, Justin M. Elliott, Clemens K. Probst, Mari Mino-Kenudson, Gregory Y. Lauwers, Andrew M. Tager, Kenneth K. Tanabe, Michael Lanuti, Bryan C. Fuchs, Peter Caravan
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Research Article Hepatology Pulmonology

Molecular imaging of oxidized collagen quantifies pulmonary and hepatic fibrogenesis

Abstract

Fibrosis results from the dysregulation of tissue repair mechanisms affecting major organ systems, leading to chronic extracellular matrix buildup, and progressive, often fatal, organ failure. Current diagnosis relies on invasive biopsies. Noninvasive methods today cannot distinguish actively progressive fibrogenesis from stable scar, and thus are insensitive for monitoring disease activity or therapeutic responses. Collagen oxidation is a universal signature of active fibrogenesis that precedes collagen crosslinking. Biochemically targeting oxidized lysine residues formed by the action of lysyl oxidase on collagen with a small-molecule gadolinium chelate enables targeted molecular magnetic resonance imaging. This noninvasive direct biochemical elucidation of the fibrotic microenvironment specifically and robustly detected and staged pulmonary and hepatic fibrosis progression, and monitored therapeutic response in animal models. Furthermore, this paradigm is translatable and generally applicable to diverse fibroproliferative disorders.

Authors

Howard H. Chen, Philip A. Waghorn, Lan Wei, Luis F. Tapias, Daniel T. Schühle, Nicholas J. Rotile, Chloe M. Jones, Richard J. Looby, Gaofeng Zhao, Justin M. Elliott, Clemens K. Probst, Mari Mino-Kenudson, Gregory Y. Lauwers, Andrew M. Tager, Kenneth K. Tanabe, Michael Lanuti, Bryan C. Fuchs, Peter Caravan

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Figure 3

Gd-Hyd distinguishes active pulmonary fibrogenesis from stable scar.

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Gd-Hyd distinguishes active pulmonary fibrogenesis from stable scar. (A)...
(A) To validate the pathogenesis in the lower-dose bleomycin model, H&E and Sirius Red/fast green (S/F) staining were performed in mice that received PBS (sham, n = 5) or were challenged with 1 unit/kg bleomycin intratracheally 1 week (1wk, n = 5), 2 weeks (2wk, n = 5), or 4 weeks prior (4wk, n = 7). Lung injury was assessed by Ashcroft score (see text), collagen proportional area (CPA) (B), lung hydroxyproline (HYP) content (C), lysyl oxidase (LOX) activity (D), and allysine content (E). (F) Gd-Hyd–enhanced coronal MR images showed minimal enhancement in the sham, robust enhancement at 2 weeks after bleomycin, and reduced enhancement at 4 weeks. (G) Change in contrast-to-noise ratio (ΔCNR) quantification of Gd-Hyd. Scale bar: 100 μm. *P < 0.05, **P < 0.01, ****P < 0.0001, ns, not significant; ANOVA.