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1. Development and stochastic validation of a parameterized model of maize stalk flexure and buckling

   https://doi.org/10.1093/insilicoplants/diad010  

   Ottesen, Michael; Carter, Joseph; Hall, Ryan; Liu, Nan-Wei; Cook, Douglas D (July 2023, in silico Plants)

   Zhu, Xin-Guang (Ed.)

   Maize stalk lodging is the structural failure of the stalk prior to harvest and is a major problem for maize (corn) producers and plant breeders. To address this problem, it is critical to understand precisely how geometric and material parameters of the maize stalk influence stalk strength. Computational models could be a powerful tool in such investigations, but current methods of creating computational models are costly, time-consuming and, most importantly, do not provide parameterized control of the maize stalk parameters. The purpose of this study was to develop and validate a parameterized 3D model of the maize stalk. The parameterized model provides independent control over all aspects of the maize stalk geometry and material properties. The model accurately captures the shape of actual maize stalks and is predictive of maize stalk stiffness and strength. The model was validated using stochastic sampling of material properties to account for uncertainty in the values and influence of mechanical tissue properties. Results indicated that buckling is influenced by material properties to a greater extent that flexural stiffness. Finally, we demonstrate that this model can be used to create an unlimited number of synthetic stalks from within the parameter space. This model will enable the future implementation of parameter sweep studies, sensitivity analysis and optimization studies, and can be used to create computational models of maize stalks with any desired combination of geometric and material properties. 

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2. Unveiling the phenotypic landscape of stalk lodging resistance in diverse maize hybrids

   https://doi.org/10.1016/j.fcr.2023.109168  

   Kunduru, Bharath; Kumar, Rohit; Brar, Manwinder S; Stubbs, Christopher J; Tabaracci, Kaitlin; Bokros, Norbert T; Bridges, William C; Cook, Douglas D; DeBolt, Seth; McMahan, Christopher S; et al (December 2023, Field Crops Research)

   Context: Stalk lodging causes up to 43 % of yield losses in maize (Zea mays L.) worldwide, significantly worsening food and feed shortages. Stalk lodging resistance is a complex trait specified by several structural, material, and geometric phenotypes. However, the identity, relative contribution, and genetic tractability of these intermediate phenotypes remain unknown. Objective: The study is designed to identify and evaluate plant-, organ-, and tissue-level intermediate phenotypes associated with stalk lodging resistance following standardized phenotyping protocols and to understand the variation and genetic tractability of these intermediate phenotypes. Methods: We examined 16 diverse maize hybrids in two environments to identify and evaluate intermediate phenotypes associated with stalk flexural stiffness, a reliable indicator of stalk lodging resistance, at physiological maturity. Engineering-informed and machine learning models were employed to understand relationships among intermediate phenotypes and stalk flexural stiffness. Results: Stalk flexural stiffness showed significant genetic variation and high heritability (0.64) in the evaluated hybrids. Significant genetic variation and comparable heritability for the cross-sectional moment of inertia and Young’s modulus indicated that geometric and material properties are under tight genetic control and play a combinatorial role in determining stalk lodging resistance. Among the twelve internode-level traits measured on the bottom and the ear internode, most traits exhibited significant genetic variation among hybrids, moderate to high heritability, and considerable effect of genotype × environment interaction. The marginal statistical model based on structural engineering beam theory revealed that 74–80 % of the phenotypic variation for flexural stiffness was explained by accounting for the major diameter, minor diameter, and rind thickness of the stalks. The machine learning model explained a relatively modest proportion (58–62 %) of the variation for flexural stiffness. 

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3. A Parameterised Model of Maize Stem Cross-sectional Morphology

   Ottesen, Michael A; Larson, Ryan A.; Stubbs, Christopher J; Cook, Douglas D (April 2022, Biosystems engineering)

   Stalk lodging, or failure of the stalk structure, is a serious problem in the production of maize (corn). Addressing this problem requires an understanding of the parameters that influence lodging resistance. Computational modelling is a powerful tool for this purpose, but current modelling methods have limited throughput and do not provide the ability to modify individual geometric features. A parameterised model of the maize stalk has the potential to overcome these limitations. The purposes of this study were to (a) develop a parameterised model of the maize stalk cross-section that could accurately simulate the physical response of multiple loading cases, and (b) use this model to rigorously investigate the relationships between cross-sectional morphology and predictive model accuracy. Principal component analysis was utilised to reveal underlying geometric patterns which were used as parameters in a cross-sectional model. A series of approximated cross-sections was created that represented various levels of geometric fidelity. The true and approximated cross-sections were modelled in axial tension/compression, bending, transverse compression, and torsion. For each loading case, the predictive accuracy of each approximated model was calculated. A sensitivity study was also performed to quantify the influence of individual parameters. The simplest model, an elliptical cross-section consisting of just three parameters: major diameter, minor diameter, and rind thickness, accurately predicted the structural stiffness of all four loading cases. The modelling approach used in this study model can be used to parameterise the maize cross-section to any desired level of geometric fidelity, and could be applied to other plant species. 

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4. Biomechanical phenotyping pipeline for stalk lodging resistance in maize

   https://doi.org/10.1016/j.mex.2024.102562  

   Tabaracci, Kaitlin; Bokros, Norbert T; Oduntan, Yusuf; Kunduru, Bharath; DeKold, Joseph; Mengistie, Endalkachew; McDonald, Armando; Stubbs, Christopher J; Sekhon, Rajandeep S; DeBolt, Seth; et al (June 2024, MethodsX)

   Stalk lodging (structural failure crops prior to harvest) significantly reduces annual yields of vital grain crops. The lack of standardized, high throughput phenotyping methods capable of quantifying biomechanical plant traits prevents comprehensive understanding of the genetic architecture of stalk lodging resistance. A phenotyping pipeline developed to enable higher throughput biomechanical measurements of plant traits related to stalk lodging is presented. The methods were developed using principles from the fields of engineering mechanics and metrology and they enable retention of plant-specific data instead of averaging data across plots as is typical in most phenotyping studies. This pipeline was specifically designed to be implemented in large experimental studies and has been used to phenotype over 40,000 maize stalks. The pipeline includes both lab- and field-based phenotyping methodologies and enables the collection of metadata. Best practices learned by implementing this pipeline over the past three years are presented. The specific instruments (including model numbers and manufacturers) that work well for these methods are presented, however comparable instruments may be used in conjunction with these methods as seen fit. • Efficient methods to measure biomechanical traits and record metadata related to stalk lodging. • Can be used in studies with large sample sizes (i.e., > 1,000). 

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5. A data-driven sensitivity analysis of maize stalk models reveals the dominant factors influencing stalk strength

   https://doi.org/10.1093/insilicoplants/diaf001  

   Carter, Joseph; Hall, Ryan; Cook, Douglas D (January 2025, in silico Plants)

   Zhu, Xin-Guang (Ed.)

   Abstract Morphological factors significantly impact maize stalk strength, but no study has fully characterized the impact of maize stalk shape on stalk strength. This study uses a data-driven and machine-learning modeling approach to characterize these relationships through a comprehensive sensitivity analysis of model inputs. Using 3D parameterized maize stalk models gave a higher level of control than previous studies by adding more parameters, but with the increase of the dimensionality. The large dimensionality of the models was greatly reduced via principal component analysis (PCA). Analysis revealed that model flexural stiffness, failure strength, and biomass were primarily determined by the first principal component. Material sensitivity analysis was also conducted on the models, and its results were consistent with past studies. The results of this study improve researchers’ understanding of the parameters that influence 3D parameterized maize stalk models. Statistical analysis indicates a strong relationship between the first principal component and section modulus, which further validates the 3D parameterized maize stalk model. Results also show that maize stalk morphology is primarily controlled by only one factor: the first principal component. This may limit researchers’ ability to increase stalk strength without increasing mass. 

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