PodoCount: A Robust, Fully Automated, Whole-Slide Podocyte Quantification Tool

Overview

Journal Kidney Int Rep

Publisher Elsevier

Specialty Nephrology

Date 2022 Jun 13

PMID 35694561

Authors

Briana A Santo

Darshana Govind

Parnaz Daneshpajouhnejad

Xiaoping Yang

Xiaoxin X Wang

Komuraiah Myakala

Bryce A Jones

Moshe Levi

Jeffrey B Kopp

Teruhiko Yoshida

Laura J Niedernhofer

David Manthey

Kyung Chul Moon

Seung Seok Han

Jarcy Zee

Avi Z Rosenberg

Pinaki Sarder

Affiliations

Soon will be listed here.

Abstract

Introduction: Podocyte depletion is a histomorphologic indicator of glomerular injury and predicts clinical outcomes. Podocyte estimation methods or podometrics are semiquantitative, technically involved, and laborious. Implementation of high-throughput podometrics in experimental and clinical workflows necessitates an automated podometrics pipeline. Recognizing that computational image analysis offers a robust approach to study cell and tissue structure, we developed and validated PodoCount (a computational tool for automated podocyte quantification in immunohistochemically labeled tissues) using a diverse data set.

Methods: Whole-slide images (WSIs) of tissues immunostained with a podocyte nuclear marker and periodic acid-Schiff counterstain were acquired. The data set consisted of murine whole kidney sections ( = 135) from 6 disease models and human kidney biopsy specimens from patients with diabetic nephropathy (DN) ( = 45). Within segmented glomeruli, podocytes were extracted and image analysis was applied to compute measures of podocyte depletion and nuclear morphometry. Computational performance evaluation and statistical testing were performed to validate podometric and associated image features. PodoCount was disbursed as an open-source, cloud-based computational tool.

Results: PodoCount produced highly accurate podocyte quantification when benchmarked against existing methods. Podocyte nuclear profiles were identified with 0.98 accuracy and segmented with 0.85 sensitivity and 0.99 specificity. Errors in podocyte count were bounded by 1 podocyte per glomerulus. Podocyte-specific image features were found to be significant predictors of disease state, proteinuria, and clinical outcome.

Conclusion: PodoCount offers high-performance podocyte quantitation in diverse murine disease models and in human kidney biopsy specimens. Resultant features offer significant correlation with associated metadata and outcome. Our cloud-based tool will provide end users with a standardized approach for automated podometrics from gigapixel-sized WSIs.

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