Development and Validation of a Deep Learning Based Automated Minirhizotron Image Analysis Pipeline

Bauer, Felix; Lärm, Lena; Morandage, Shehan; Lobet, Guillaume; Vanderborght, Jan; Vereecken, Harry; Schnepf, Andrea

doi:10.34133/2022/9758532

Cited by 31 publications

(32 citation statements)

References 51 publications

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“…Recent progress in machine learning is demonstrating the opportunities within the field for segmenting out root and noise and could further improve accuracy ( Wang et al, 2019 ; Smith et al, 2018 ). Whereas RGB imaging together with software tools like RootPainter has facilitated automated root system analysis in species with thicker roots ( Smith et al, 2020 ; Bauer et al, 2022 ), bioluminescence still has advantages with species with finer roots, like Arabidopsis , since it improves the contrast between the root and soil signal. Using transgenic lines homozygous for the luciferase transgene would lead to stronger signal and therefore better root detection.…”

Section: Discussionmentioning

confidence: 99%

Uncovering natural variation in root system architecture and growth dynamics using a robotics-assisted phenomics platform

LaRue

Lindner

Srinivas

et al. 2022

eLife

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The plant kingdom contains a stunning array of complex morphologies easily observed above-ground, but more challenging to visualize below-ground. Understanding the magnitude of diversity in root distribution within the soil, termed root system architecture (RSA), is fundamental to determining how this trait contributes to species adaptation in local environments. Roots are the interface between the soil environment and the shoot system and therefore play a key role in anchorage, resource uptake, and stress resilience. Previously, we presented the GLO-Roots (Growth and Luminescence Observatory for Roots) system to study the RSA of soil-grown Arabidopsis thaliana plants from germination to maturity (Rellán-Álvarez et al. 2015). In this study, we present the automation of GLO-Roots using robotics and the development of image analysis pipelines in order to examine the temporal dynamic regulation of RSA and the broader natural variation of RSA in Arabidopsis, over time. These datasets describe the developmental dynamics of two independent panels of accessions and reveal highly complex and polygenic RSA traits that show significant correlation with climate variables of the accessions' respective origins.

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Section: Discussionmentioning

confidence: 99%

Uncovering natural variation in root system architecture and growth dynamics using a robotics-assisted phenomics platform

LaRue

Lindner

Srinivas

et al. 2022

eLife

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“…We extracted RLD and RSA in an extremely simple fashion from segmented images, which contained noise but was compared with a similarly coarse above-ground index. More interpretive root phenotyping (Bauer et al ., 2022) can also be paired to this CNN. In theory, many further architectural traits can be extracted with such a workflow.…”

Section: Discussionmentioning

confidence: 99%

“…Minirhizotron imagery contains much more relevant structural information due to the extremely local scale and indeed these are regularly extracted manually. There is progress in doing this automatically (Seethepalli et al ., 2021; Bauer et al ., 2022) and we expect rapid advancement in future. Our analyses were also not particularly sensitive to roots overlapping or growing close due to overall low density.…”

Section: Discussionmentioning

confidence: 99%

“…We did not adjust for diagonal connections nor prune branches of the skeleton but otherwise this is similar to the simplest level of analysis using modern software for root imagery such as RhizovisionExplorer (Seethepalli et al ., 2021). This software can be directly paired to the rootpainter CNN and has been successfully use to process imagery from agricultural soils with similar accuracy to manual annotation (Bauer et al ., 2022) and can potentially extract many more features of interest. However, our datasets in natural ecosystems were both challenging to the CNN segmentation and for the human operator to choose appropriate settings for the software.…”

Section: Methodsmentioning

confidence: 99%

“…Recently, convolutional neural networks (CNNs) showed promising results to identify roots in a variety of settings (Delory et al ., 2016; Rahmanzadeh and Shojaedini, 2016; Vincent et al ., 2016; Huo and Cheng, 2019; Bauer et al ., 2022). In particular, field soil minirhizotron imagery has been analysed several times with good results (Wang et al ., 2019; Smith et al ., 2020; Gillert et al ., 2021; Han et al ., 2021; Peters et al ., 2022; Bauer et al ., 2022), but transferability between sites and out of agricultural soils is difficult to assess without widespread adoption in new settings. These have also never been applied to high frequency studies where variability between images (e.g.…”

Section: Introductionmentioning

confidence: 99%

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High Frequency Root Dynamics: Sampling and Interpretation Using Replicated Robotic Minirhizotrons

Nair

Strube

Hertel

et al. 2022

Preprint

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Minirhizotrons (paired camera systems and buried observatories) are the best current method to make repeatable measurements of fine roots in the field. Automating the technique is also the only way to gather high resolution data necessary for comparison with phenology-relevant above-ground remote sensing, and, when appropriately validated, to assess with high temporal resolution belowground biomass, which can support carbon budgets estimates. Minirhizotron technology has been available for half a century but there are many challenges to automating the technique for global change experiments. Instruments must be cheap enough to replicate on field scales given their shallow field of view, and automated analysis must both be robust to changeable soil and root conditions because ultimately, image properties extracted from minirhizotrons must have biological meaning. Both digital photography and computer technology are rapidly evolving, with huge potential for generating belowground data from images using modern technological advantages. Here we demonstrate a homemade automatic minirhizotron scheme, built with off-the-shelf parts and sampling every two hours, which we paired with a neural network-based image analysis method in a proof-of-concept mesocosm study. We show that we are able to produce a robust daily timeseries of root cover dynamics. The method is applied at the same model across multiple instruments demonstrating good reproducibility of the measurements and a good pairing with an above-ground vegetation index and root biomass recovery through time. We found a sensitivity of the root cover we extracted to soil moisture conditions and time of day (potentially relating to soil moisture), which may only be an issue with high resolution automated imagery and not commonly reported as encountered when training neural networks on traditional, time-distinct minirhizotron studies. We discuss potential avenues for dealing with such issues in future field applications of such devices. If such issues are dealt with to a satisfactory manner in the field, automated timeseries of root biomass and traits from replicated instruments could add a new dimension to phenology understanding at ecosystem level by understanding the dynamics of root properties and traits.

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Toward improved image‐based root phenotyping: Handling temporal and cross‐site domain shifts in crop root segmentation models

Banet,

Smith,

McGrail

et al. 2024

The Plant Phenome Journal

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Crop root segmentation models developed through deep learning have increased the throughput of in situ crop phenotyping studies. However, models trained to identify roots in one image dataset may not accurately identify roots in another dataset, especially when the new dataset contains known differences, called domain shifts. The objective of this study was to quantify how model performance changes when models are used to segment image datasets that contain domain shifts and evaluate approaches to reduce error associated with domain shifts. We collected maize root images at two growth stages (V7 and R2) in a field experiment and manually segmented images to measure total root length (TRL). We developed five segmentation models and evaluated each model's ability to handle a temporal (growth‐stage) domain shift. For the V7 growth stage, a growth‐stage‐specific model trained only on images captured at the V7 growth stage was best suited for measuring TRL. At the R2 growth stage, combining images from both growth stages into a single dataset to train a model resulted in the most accurate TRL measurements. We applied two of the field models to images from a greenhouse experiment to evaluate how model performance changed when exposed to a cross‐site domain shift. Field models were less accurate than models trained only on the greenhouse images even when crop growth stage was identical. Although models may perform well for one experiment, model error increases when applied to images from different experiments even when crop species, growth stage, and soil type are similar.

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Development and Validation of a Deep Learning Based Automated Minirhizotron Image Analysis Pipeline

Cited by 31 publications

References 51 publications

Uncovering natural variation in root system architecture and growth dynamics using a robotics-assisted phenomics platform

Uncovering natural variation in root system architecture and growth dynamics using a robotics-assisted phenomics platform

High Frequency Root Dynamics: Sampling and Interpretation Using Replicated Robotic Minirhizotrons

Toward improved image‐based root phenotyping: Handling temporal and cross‐site domain shifts in crop root segmentation models

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