Abstract

BackgroundStomatal behavior in grapevines has been identified as a good indicator of the water stress level and overall health of the plant. Microscope images are often used to analyze stomatal behavior in plants. However, most of the current approaches involve manual measurement of stomatal features. The main aim of this research is to develop a fully automated stomata detection and pore measurement method for grapevines, taking microscope images as the input. The proposed approach, which employs machine learning and image processing techniques, can outperform available manual and semi-automatic methods used to identify and estimate stomatal morphological features.ResultsFirst, a cascade object detection learning algorithm is developed to correctly identify multiple stomata in a large microscopic image. Once the regions of interest which contain stomata are identified and extracted, a combination of image processing techniques are applied to estimate the pore dimensions of the stomata. The stomata detection approach was compared with an existing fully automated template matching technique and a semi-automatic maximum stable extremal regions approach, with the proposed method clearly surpassing the performance of the existing techniques with a precision of 91.68% and an F1-score of 0.85. Next, the morphological features of the detected stomata were measured. Contrary to existing approaches, the proposed image segmentation and skeletonization method allows us to estimate the pore dimensions even in cases where the stomatal pore boundary is only partially visible in the microscope image. A test conducted using 1267 images of stomata showed that the segmentation and skeletonization approach was able to correctly identify the stoma opening 86.27% of the time. Further comparisons made with manually traced stoma openings indicated that the proposed method is able to estimate stomata morphological features with accuracies of 89.03% for area, 94.06% for major axis length, 93.31% for minor axis length and 99.43% for eccentricity.ConclusionsThe proposed fully automated solution for stomata detection and measurement is able to produce results far superior to existing automatic and semi-automatic methods. This method not only produces a low number of false positives in the stomata detection stage, it can also accurately estimate the pore dimensions of partially incomplete stomata images. In addition, it can process thousands of stomata in minutes, eliminating the need for researchers to manually measure stomata, thereby accelerating the process of analysing plant health.

Highlights

  • Stomatal behavior in grapevines has been identified as a good indicator of the water stress level and overall health of the plant

  • A microscope image of a leaf epidermis can provide a clear view of guard cells, epidermal cells, stomata and plant leaf veins

  • Due to the time constraints imposed by manual measurements, biologists are forced to select only a few stomata for measurement from each captured microscope image, and build statistical relationships and models using fewer data-points [13]

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Summary

Introduction

Stomatal behavior in grapevines has been identified as a good indicator of the water stress level and overall health of the plant. The behavior of stomata provides key information on the water stress level, food production rate and the overall health of the plant [1, 4,5,6]. The most common approach to achieve this goal involves manual measurement of stomata pore dimensions using softwares such as ­ImageJ® [9]. These type of tools require the user to manually mark the points of interest such as pore boundaries, stoma length and width so that the tool can produce the relevant measurement results. The solution would be to develop a fast, fully automated method which can accurately measure stomatal morphological features without any human intervention

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