Elastic property and fracture mechanics of lateral branch-branch junctions in cacti: A case study of Opuntia ficus-indica and Cylindropuntia bigelovii

Mylo, Max D.; Hoppe, Anna; Pastewka, Lars; Speck, Thomas; Speck, Olga

doi:10.3389/fpls.2022.950860

Cited by 4 publications

(8 citation statements)

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“…For example, although a stereo camera setup can provide a 3D visualization of the surface, it is always limited to the area of the sample visible to the cameras. Part of the motion and deformation remains unresolved, providing limited information, especially for multi-material systems or very heterogeneous materials, as is often the case with plant samples ( Sachse et al., 2020 ; Durak et al., 2022b ; Mylo et al., 2022b ). One way to overcome this is to use a multi-view DIC system, where one or more (stereo) camera setups are installed around the sample to provide additional viewing angles ( Chen et al., 2013 ; Patil et al., 2017 ; Janeliukstis and Chen, 2021 ).…”

Section: Digital Image Correlation: Basics and Proceduresmentioning

confidence: 99%

“…(C) Local strain of the three points during tensile testing, with the vertical grey line marking the strain state of (B) . (D–G) Strain analysis of branch-branch junctions in cacti under tensile loading (modified from Mylo et al., 2022b ). Strain distribution of a young junction of Opuntia ficus-indica (D) , an older junction of O. ficus-indica (E) and a junction of Cylindropuntia bigelovii (F) at about half the strain rate that led to failure.…”

Section: Recent Examples For Digital Image Correlation In Plant Sciencesmentioning

confidence: 99%

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Digital image correlation techniques for motion analysis and biomechanical characterization of plants

Mylo,

Poppinga

2024

Front. Plant Sci.

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Temporally and spatially complex 3D deformation processes appear in plants in a variety of ways and are difficult to quantify in detail by classical cinematographic methods. Furthermore, many biomechanical test methods, e.g. regarding compression or tension, result in quasi-2D deformations of the tested structure, which are very time-consuming to analyze manually regarding strain fields. In materials testing, the contact-free optical 2D- or 3D-digital image correlation method (2D/3D-DIC) is common practice for similar tasks, but is still rather seldom used in the fundamental biological sciences. The present review aims to highlight the possibilities of 2D/3D-DIC for the plant sciences. The equipment, software, and preparative prerequisites are introduced in detail and advantages and disadvantages are discussed. In addition to the analysis of wood and trees, where DIC has been used since the 1990s, this is demonstrated by numerous recent approaches in the contexts of parasite-host attachment, cactus joint biomechanics, fruit peel impact resistance, and slow as well as fast movement phenomena in cones and traps of carnivorous plants. Despite some technical and preparative efforts, DIC is a very powerful tool for full-field 2D/3D displacement and strain analyses of plant structures, which is suitable for numerous in-depth research questions in the fields of plant biomechanics and morphogenesis.

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Section: Digital Image Correlation: Basics and Proceduresmentioning

confidence: 99%

Section: Recent Examples For Digital Image Correlation In Plant Sciencesmentioning

confidence: 99%

Digital image correlation techniques for motion analysis and biomechanical characterization of plants

Mylo,

Poppinga

2024

Front. Plant Sci.

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“…Moreover, we find abrupt transitions leading to a spatio-temporal controlled shedding of individual plant organs (abscission), such as between branches and petioles resulting in leaf fall in autumn [ 70 , 71 ]. Another example is the chain-like arrangement of branches in certain cacti ( Opuntioideae ), in which shedding enables vegetative reproduction [ 10 , 11 , 72 ]. The concept of shedding plant organs (abscission [ 70 ] and autotomy [ 73 ]) and discarding animal appendages (autotomy [ 74 ]) is discussed as inspiration for future smart structures with controlled failures occurring in predefined positions in the structural scheme.…”

Section: Robustnessmentioning

confidence: 99%

“…For individual plants, an age of up to 5000 years has thus been assigned, whereby the oldest plants are all woody conifers [ 9 ]. Special cases involve plants that reproduce asexually with clonal reproduction [ 10 , 11 ], including community-sized individuals that have a lifespan of more than 40,000 years [ 8 , 9 ] and seeds that can maintain their viability for more than 2000 years [ 12 ]. Coalified conifer cones retain their hygroscopic capacity to open and close after more than 10 million years in the ground; however, it is important to note that this is already dead tissue [ 13 ].…”

Section: Introductionmentioning

confidence: 99%

Longevity of System Functions in Biology and Biomimetics: A Matter of Robustness and Resilience

Mylo

Speck

2023

Biomimetics

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Within the framework of a circular economy, we aim to efficiently use raw materials and reduce waste generation. In this context, the longevity of biomimetic material systems can significantly contribute by providing robustness and resilience of system functionality inspired by biological models. The aim of this review is to outline various principles that can lead to an increase in robustness (e.g., safety factor, gradients, reactions to environmental changes) and resilience (e.g., redundancy, self-repair) and to illustrate the principles with meaningful examples. The study focuses on plant material systems with a high potential for transfer to biomimetic applications and on existing biomimetic material systems. Our fundamental concept is based on the functionality of the entire system as a function of time. We use functionality as a dimensionless measure of robustness and resilience to quantify the system function, allowing comparison within biological material systems and biomimetic material systems, but also between them. Together with the enclosed glossary of key terms, the review provides a comprehensive toolbox for interdisciplinary teams. Thus, allowing teams to communicate unambiguously and to draw inspiration from plant models when developing biomimetic material systems with great longevity potential.

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“…Its first applications were in materials science, but over the years, DIC has been utilized more and more in other research fields, such as aerospace, including large-scale composite structures [ 6 ], civil engineering, such as bridge monitoring [ 12 , 13 ], human and animal biomechanics to analyse a wide variety of organs and tissues [ 14 , 15 ] and wood research, from entire trees to processed composites [ 16 ]. In recent years, DIC has also been used in plant analysis, namely to analyse plant tissue strains under tensile loading (e.g., mistletoe–host interface [ 17 ] or the branch–branch connections of cacti [ 18 ]) to analyse compression (e.g., citrus peels [ 19 ]), and to characterise plant movements, such as the snap-buckling closure [ 20 ] and reopening [ 21 ] of the Venus flytrap or the desiccation-driven motion of pine cone scales [ 22 , 23 ]. This has led to a better understanding of the functional principles of the plant material systems, which is a prerequisite for successful transfer to bioinspired materials.…”

Section: Introductionmentioning

confidence: 99%

Stereo Camera Setup for 360° Digital Image Correlation to Reveal Smart Structures of Hakea Fruits

Fischer,

Mylo,

Lorenz

et al. 2024

Biomimetics

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About forty years after its first application, digital image correlation (DIC) has become an established method for measuring surface displacements and deformations of objects under stress. To date, DIC has been used in a variety of in vitro and in vivo studies to biomechanically characterise biological samples in order to reveal biomimetic principles. However, when surfaces of samples strongly deform or twist, they cannot be thoroughly traced. To overcome this challenge, different DIC setups have been developed to provide additional sensor perspectives and, thus, capture larger parts of an object’s surface. Herein, we discuss current solutions for this multi-perspective DIC, and we present our own approach to a 360° DIC system based on a single stereo-camera setup. Using this setup, we are able to characterise the desiccation-driven opening mechanism of two woody Hakea fruits over their entire surfaces. Both the breaking mechanism and the actuation of the two valves in predominantly dead plant material are models for smart materials. Based on these results, an evaluation of the setup for 360° DIC regarding its use in deducing biomimetic principles is given. Furthermore, we propose a way to improve and apply the method for future measurements.

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Elastic property and fracture mechanics of lateral branch-branch junctions in cacti: A case study of Opuntia ficus-indica and Cylindropuntia bigelovii

Cited by 4 publications

References 41 publications

Digital image correlation techniques for motion analysis and biomechanical characterization of plants

Digital image correlation techniques for motion analysis and biomechanical characterization of plants

Longevity of System Functions in Biology and Biomimetics: A Matter of Robustness and Resilience

Stereo Camera Setup for 360° Digital Image Correlation to Reveal Smart Structures of Hakea Fruits

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