Quantification of plant morphology and leaf thickness with optical
				coherence tomography

Wit, Jos de; Tonn, Sebastian; Ackerveken, Guido Van den; Kalkman, Jeroen

doi:10.1364/ao.408384

Cited by 15 publications

(5 citation statements)

References 37 publications

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“…The leaf disc was water infiltrated by putting it in a syringe with water and lowering the pressure. When the pressure is released, the gas-exchange cavities are filled with water, reducing the refractive index contrast [30]. The leaf disc was mounted in water between two coverslips, at a sufficient distance from the coverslip to avoid saturation artifacts from the coverslip reflection.…”

Section: Samples and Acquisition Settingsmentioning

confidence: 99%

Computational 3D resolution enhancement for optical coherence tomography with a narrowband visible light source

Wit¹,

Glentis²,

Kalkman³

2023

Preprint

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Phase-preserving spectral estimation optical coherence tomography (SE-OCT) enables combining axial resolution improvement with computational depth of field (DOF) extension. We combine SE-OCT with interferometric synthetic aperture microscopy (ISAM) and computational adaptive optics (CAO) to obtain a high 3D resolution over a large depth range with a narrow bandwidth visible light super-luminescent diode (SLD). SE-OCT gives up to five times axial resolution improvement from 8 μm to 1.5 μm. The combination with ISAM gives a sub-micron lateral resolution over a 400 micrometer axial range, 16 times the conventional depth of field. CAO removes residual aberrations, resulting in high quality images. The results show that phase-preserving SE-OCT is sufficiently accurate for coherent post-processing, enabling the use of cost-effective SLDs in the visible light range for high spatial resolution OCT.

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Section: Samples and Acquisition Settingsmentioning

confidence: 99%

Computational 3D resolution enhancement for optical coherence tomography with a narrowband visible light source

Wit¹,

Glentis²,

Kalkman³

2023

Preprint

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“…IL: Illumination light and SL: Scattered light from the leaf ( Silva et al., 2016 ) (G) Elongation of a Chinese chive leaf ( Kadono and Kobayashi, 2009 ). (H) Cross-section image of an Arabidopsis leaf, acquired by OCT technique reprinted with permission from ( de Wit et al, 2020 © The Optical Society). e: Epidermal cell, m: Mesophyll cell, vb: Vascular bundle, mr: Midrib, ad: Adaxial side, ab: Abaxial side.…”

Section: Biospeckle Laser Imagingmentioning

confidence: 99%

“…The method has a high potential for identification of seed viability during an early stage of germination and thereby facilitates seed selection ( Lim et al., 2019 ; De Silva et al., 2022 ). Biospeckle OCT has been used to screen for internal structural changes of pea seeds during germination process ( Li X. et al., 2022 ), the effect of Zn concentration on lentil seed germination and seedling growth ( De Silva et al., 2021 ), detection of microstructural changes in leaves during senescence ( Anna et al., 2019 ) and measurements of the RI and thickness of leaves ( de Wit et al., 2020 ). Figure 1H shows the central cross-section of an infiltrated Arabidopsis leaf wherein cell layers, epidermal cells, mesophyll cells, as well as vascular bundles can be seen.…”

Section: Optical Coherence Tomographymentioning

confidence: 99%

Label-free optical interferometric microscopy to characterize morphodynamics in living plants

et al. 2023

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During the last century, fluorescence microscopy has played a pivotal role in a range of scientific discoveries. The success of fluorescence microscopy has prevailed despite several shortcomings like measurement time, photobleaching, temporal resolution, and specific sample preparation. To bypass these obstacles, label-free interferometric methods have been developed. Interferometry exploits the full wavefront information of laser light after interaction with biological material to yield interference patterns that contain information about structure and activity. Here, we review recent studies in interferometric imaging of plant cells and tissues, using techniques such as biospeckle imaging, optical coherence tomography, and digital holography. These methods enable quantification of cell morphology and dynamic intracellular measurements over extended periods of time. Recent investigations have showcased the potential of interferometric techniques for precise identification of seed viability and germination, plant diseases, plant growth and cell texture, intracellular activity and cytoplasmic transport. We envision that further developments of these label-free approaches, will allow for high-resolution, dynamic imaging of plants and their organelles, ranging in scales from sub-cellular to tissue and from milliseconds to hours.

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“…It also extends to industrial, pharmaceutical, and poultry applications (27)(28)(29)(30)(31). In the field of agriculture, OCT has been used in the diagnosis of various infections or diseases in onions, melon seeds, kaki plant leaves, apple leaves, and orchids were analyzed to control and limit the spread of diseases (32)(33)(34)(35)(36)(37)(38)(39)(40). To our knowledge, this technique has never been applied in the Philippines.…”

Section: Introductionmentioning

confidence: 99%

Leaf Structure and Attenuation Coefficients of Citrofortunella Microcarpa Leaves Using a Portable TD-OCT System

Galvez¹,

Lara²,

Mandia³

et al. 2022

ECS Trans.

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A non-invasive and simple point measurement using a portable TD-OCT system was used to measure the leaf structure and attenuation coefficient of healthy and unhealthy leaves of a Citrofortunella Microcarpa plant. Assuming homogeneity within the layers, the attenuation coefficient was obtained by linear fitting the logarithm of the A-scan or depth profile of the leaf. The attenuation coefficients of the epidermal and palisade layers of the healthy leaves were 27.07/mm and 15.36/mm, respectively, and for the unhealthy leaves they were 21.82/mm and 8.01/mm, respectively. Comparing the A-scan profiles obtained for the healthy and unhealthy leaves, a mixing of the epidermal and palisade layers within the unhealthy leaves was observed. These observations and the decrease in the attenuation coefficients of the unhealthy leaves are indications of deterioration in the photosynthetic rate that enhances the growth and development of the plants which can provide early detection of sickness benefitting Filipino farmers.

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Quantification of plant morphology and leaf thickness with optical coherence tomography

Cited by 15 publications

References 37 publications

Computational 3D resolution enhancement for optical coherence tomography with a narrowband visible light source

Computational 3D resolution enhancement for optical coherence tomography with a narrowband visible light source

Label-free optical interferometric microscopy to characterize morphodynamics in living plants

Leaf Structure and Attenuation Coefficients of Citrofortunella Microcarpa Leaves Using a Portable TD-OCT System

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