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Root Phenotyping Using Pose Estimation
  • +21
  • Elizabeth Marie Berrigan,
  • Lin Wang,
  • Hannah Carrillo,
  • Kimberly Echegoyen,
  • Mikayla Kappes,
  • Jorge Torres,
  • Angel Ai-Perreira,
  • Erica McCoy,
  • Emily Shane,
  • Charles Copeland,
  • Lauren Ragel,
  • Charidimos Georgousakis,
  • Sanghwa Lee,
  • Dawn Reynolds,
  • Avery Talgo,
  • Juan Gonzalez,
  • Ling Zhang,
  • Ashish Rajurkar,
  • Michel Ruiz,
  • Erin Daniels,
  • Liezl Maree,
  • Shree Pariyar,
  • Wolfgang Busch,
  • Talmo D. Pereira
Elizabeth Marie Berrigan

Corresponding Author:eberrigan@salk.edu

Author Profile
Lin Wang
Hannah Carrillo
Kimberly Echegoyen
Mikayla Kappes
Jorge Torres
Angel Ai-Perreira
Erica McCoy
Emily Shane
Charles Copeland
Lauren Ragel
Charidimos Georgousakis
Sanghwa Lee
Dawn Reynolds
Avery Talgo
Juan Gonzalez
Ling Zhang
Ashish Rajurkar
Michel Ruiz
Erin Daniels
Liezl Maree
Shree Pariyar
Wolfgang Busch
Talmo D. Pereira

Abstract

Image segmentation is commonly used to estimate the location and shape of plants and their external structures. Segmentation masks are then used to localize landmarks of interest and compute other geometric features that correspond to the plant’s phenotype. Despite its prevalence, segmentation-based approaches are laborious (requiring extensive annotation to train), and error-prone (derived geometric features are sensitive to instance mask integrity). Here we present a segmentation-free approach which leverages deep learning-based landmark detection and grouping, also known as pose estimation. We use a tool originally developed for animal motion capture called SLEAP (Social LEAP Estimates Animal Poses) to automate the detection of distinct morphological landmarks on plant roots. Using high-throughput phenotyping method Root Architecture 3-D Imaging Cylinder (RADICYL) across multiple species, we show that our approach can reliably and efficiently recover root system topology at greater accuracy, faster speed, and with fewer annotated samples than segmentation-based approaches. In order to make use of this landmark-based representation for root phenotyping, we developed a Python library (sleap-roots ) for trait extraction directly comparable to existing segmentation-based analysis software. We show that landmark-derived root traits are highly accurate and can be used for common downstream tasks including genotype classification and unsupervised trait mapping. Altogether, this work establishes the validity and advantages of pose estimation-based plant phenotyping. To facilitate adoption of this easy-to-use tool and to encourage further development, we make sleap-roots ,  all training data, models, and trait extraction code available at: https://github.com/talmolab/sleap-roots.
27 Oct 2023Submitted to NAPPN 2024
30 Oct 2023Published in NAPPN 2024