Photoacoustic imaging of kidney fibrosis for assessing pretransplant organ quality
Eno Hysi, Xiaolin He, Muhannad N. Fadhel, Tianzhou Zhang, Adriana Krizova, Michael Ordon, Monica Farcas, Kenneth T. Pace, Victoria Mintsopoulos, Warren L. Lee, Michael C. Kolios, Darren A. Yuen
Eno Hysi, Xiaolin He, Muhannad N. Fadhel, Tianzhou Zhang, Adriana Krizova, Michael Ordon, Monica Farcas, Kenneth T. Pace, Victoria Mintsopoulos, Warren L. Lee, Michael C. Kolios, Darren A. Yuen
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Resource and Technical Advance Nephrology

Photoacoustic imaging of kidney fibrosis for assessing pretransplant organ quality

Abstract

Roughly 10% of the world’s population has chronic kidney disease (CKD). In its advanced stages, CKD greatly increases the risk of hospitalization and death. Although kidney transplantation has revolutionized the care of advanced CKD, clinicians have limited ways of assessing donor kidney quality. Thus, optimal donor kidney–recipient matching cannot be performed, meaning that some patients receive damaged kidneys that function poorly. Fibrosis is a form of chronic damage often present in donor kidneys, and it is an important predictor of future renal function. Currently, no safe, easy-to-perform technique exists that accurately quantifies renal fibrosis. We describe a potentially novel photoacoustic (PA) imaging technique that directly images collagen, the principal component of fibrotic tissue. PA imaging noninvasively quantifies whole kidney fibrotic burden in mice, and cortical fibrosis in pig and human kidneys, with outstanding accuracy and speed. Remarkably, 3-dimensional PA imaging exhibited sufficiently high resolution to capture intrarenal variations in collagen content. We further show that PA imaging can be performed in a setting that mimics human kidney transplantation, suggesting the potential for rapid clinical translation. Taken together, our data suggest that PA collagen imaging is a major advance in fibrosis quantification that could have widespread preclinical and clinical impact.

Authors

Eno Hysi, Xiaolin He, Muhannad N. Fadhel, Tianzhou Zhang, Adriana Krizova, Michael Ordon, Monica Farcas, Kenneth T. Pace, Victoria Mintsopoulos, Warren L. Lee, Michael C. Kolios, Darren A. Yuen

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Figure 3

Photoacoustic (PA) imaging detects progressive kidney fibrosis in mice.

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Photoacoustic (PA) imaging detects progressive kidney fibrosis in mice. ...
(A) PA imaging setup and orientations for the UUO-induced mouse kidney fibrosis model, in which the left kidney develops fibrosis. Mouse illustration generated in Biorender (www.biorender.com). (B) Representative PA and Picrosirius red (PSR) histology images at various time points after UUO surgery. Scale bar: 5 mm (PA images) and 100 μm (PSR histology images). (C) Average PA amplitude spectra as a function of optical wavelength. Data represent mean ± SEM for n = 5 mice, n = 5 kidneys/side, and n = 5 measurements/kidney side. (D) PA-derived collagen scores as a function of time. For all mice undergoing UUO surgery, the right kidney is normal, while the left kidney is fibrotic. Data represent mean ± SD for n = 5 mice/kidney side. (E) PSR histology–derived collagen score as a function of time. Data represent mean ± SEM for n = 5 mice. For D and E, a 2-way ANOVA with time as an independent variable was used to assess for time-dependent changes in PA and histologic measures of fibrosis; *P < 0.05, relative to the right kidney. For D, the P values for the Sham, day 7, and day 14 comparisons are P = 0.3, P = 0.002, and P = 0.00001, respectively. For E, the right to left kidney comparison P values are P = 0.1, P = 0.00001, and P = 0.000001 for Sham, day 7, and day 14 measurements, respectively. (F) Pearson correlation analysis between PA and histology scores for 2D imaging (P = 0.007 for PSR, P = 0.007 for collagen I, P = 0.03 for α-SMA).