Automated 3D Segmentation of Guard Cells Enables Volumetric Analysis of Stomatal Biomechanics

Overview

Journal Patterns (N Y)

Date 2022 Dec 26

PMID 36569557

Authors

Dolzodmaa Davaasuren

Yintong Chen

Leila Jaafar

Rayna Marshall

Angelica L Dunham

Charles T Anderson

James Z Wang

Affiliations

Soon will be listed here.

Abstract

Automating the three-dimensional (3D) segmentation of stomatal guard cells and other confocal microscopy data is extremely challenging due to hardware limitations, hard-to-localize regions, and limited optical resolution. We present a memory-efficient, attention-based, one-stage segmentation neural network for 3D images of stomatal guard cells. Our model is trained end to end and achieved expert-level accuracy while leveraging only eight human-labeled volume images. As a proof of concept, we applied our model to 3D confocal data from a cell ablation experiment that tests the "polar stiffening" model of stomatal biomechanics. The resulting data allow us to refine this polar stiffening model. This work presents a comprehensive, automated, computer-based volumetric analysis of fluorescent guard cell images. We anticipate that our model will allow biologists to rapidly test cell mechanics and dynamics and help them identify plants that more efficiently use water, a major limiting factor in global agricultural production and an area of critical concern during climate change.

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