RootNav 2.0: Deep Learning for Automatic Navigation of Complex Plant Root Architectures

Overview

Journal Gigascience

Publisher Oxford University Press

Specialties Biology
Genetics

Date 2019 Nov 9

PMID 31702012

Citations 39

Authors

Robail Yasrab

Jonathan A Atkinson

Darren M Wells

Andrew P French

Tony P Pridmore

Michael P Pound

Affiliations

Soon will be listed here.

Abstract

Background: In recent years quantitative analysis of root growth has become increasingly important as a way to explore the influence of abiotic stress such as high temperature and drought on a plant's ability to take up water and nutrients. Segmentation and feature extraction of plant roots from images presents a significant computer vision challenge. Root images contain complicated structures, variations in size, background, occlusion, clutter and variation in lighting conditions. We present a new image analysis approach that provides fully automatic extraction of complex root system architectures from a range of plant species in varied imaging set-ups. Driven by modern deep-learning approaches, RootNav 2.0 replaces previously manual and semi-automatic feature extraction with an extremely deep multi-task convolutional neural network architecture. The network also locates seeds, first order and second order root tips to drive a search algorithm seeking optimal paths throughout the image, extracting accurate architectures without user interaction.

Results: We develop and train a novel deep network architecture to explicitly combine local pixel information with global scene information in order to accurately segment small root features across high-resolution images. The proposed method was evaluated on images of wheat (Triticum aestivum L.) from a seedling assay. Compared with semi-automatic analysis via the original RootNav tool, the proposed method demonstrated comparable accuracy, with a 10-fold increase in speed. The network was able to adapt to different plant species via transfer learning, offering similar accuracy when transferred to an Arabidopsis thaliana plate assay. A final instance of transfer learning, to images of Brassica napus from a hydroponic assay, still demonstrated good accuracy despite many fewer training images.

Conclusions: We present RootNav 2.0, a new approach to root image analysis driven by a deep neural network. The tool can be adapted to new image domains with a reduced number of images, and offers substantial speed improvements over semi-automatic and manual approaches. The tool outputs root architectures in the widely accepted RSML standard, for which numerous analysis packages exist (http://rootsystemml.github.io/), as well as segmentation masks compatible with other automated measurement tools. The tool will provide researchers with the ability to analyse root systems at larget scales than ever before, at a time when large scale genomic studies have made this more important than ever.

Citing Articles

Research on Fine-Grained Phenotypic Analysis of Temporal Root Systems - Improved YoloV8seg Applied for Fine-Grained Analysis of In Situ Root Temporal Phenotypes.

Yu Q, Zhang M, Wang L, Liu X, Zhu L, Liu L Adv Sci (Weinh). 2024; 12(5):e2408144.

PMID: 39665152 PMC: 11791994. DOI: 10.1002/advs.202408144.

Automated seminal root angle measurement with corrective annotation.

Smith A, Malinowska M, Ruud A, Janss L, Krusell L, Jensen J AoB Plants. 2024; 16(5):plae046.

PMID: 39465185 PMC: 11512109. DOI: 10.1093/aobpla/plae046.

Genome-Wide Association study for root system architecture traits in field soybean [Glycine max (L.) Merr.].

Rathore P, Shivashakarappa K, Ghimire N, Dumenyo K, Yadegari Z, Taheri A Sci Rep. 2024; 14(1):25075.

PMID: 39443649 PMC: 11500091. DOI: 10.1038/s41598-024-76515-6.

The State of the Art in Root System Architecture Image Analysis Using Artificial Intelligence: A Review.

Weihs B, Heuschele D, Tang Z, York L, Zhang Z, Xu Z Plant Phenomics. 2024; 6:0178.

PMID: 38711621 PMC: 11070851. DOI: 10.34133/plantphenomics.0178.

Fast and Efficient Root Phenotyping via Pose Estimation.

Berrigan E, Wang L, Carrillo H, Echegoyen K, Kappes M, Torres J Plant Phenomics. 2024; 6:0175.

PMID: 38629082 PMC: 11020144. DOI: 10.34133/plantphenomics.0175.

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