A qualitative analysis of the bud ontogeny of Dracaena marginata using high-resolution magnetic resonance imaging

Hesse, Linnéa; Leupold, Jochen; Speck, Thomas; Masselter, Tom

doi:10.1038/s41598-018-27823-1

Cited by 9 publications

(4 citation statements)

References 46 publications

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“…It is best known for its applications in Nuclear Magnetic Resonance Imaging (MRI, also abbreviated to MR imaging, or NMRi) in human medicine, but also has found many applications in plant science. Recent applications of MRI include imaging plant anatomy, for example of tree stems affected by disease (Kuroda et al, 2006), bud ontogeny (Hesse et al, 2018), imaging of fruits and crops (Glidewell, 2006), water content and cavitation events in stems (Holbrook et al, 2001;Choat et al, 2010;De Schepper et al, 2012;Hochberg et al, 2016;Van de Wal et al, 2017;Meixner et al, 2020), structure and function of roots in soils (Jahnke et al, 2009;Kaufmann et al, 2009;van Dusschoten et al, 2016), imaging xylem-and phloem sap flow in stems and petioles (Scheenen et al, 2000(Scheenen et al, , 2007Windt et al, 2006Windt et al, , 2009, or micro imaging of seeds (Sreenivasulu et al, 2010;Munz et al, 2017). For comprehensive overviews we refer to Van As (2007) and Borisjuk et al (2012).…”

Section: Introductionmentioning

confidence: 99%

A Mobile NMR Sensor and Relaxometric Method to Non-destructively Monitor Water and Dry Matter Content in Plants

et al. 2021

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Water content (WC) and dry matter content (DMC) are some of the most basic parameters to describe plant growth and yield, but are exceptionally difficult to measure non-invasively. Nuclear Magnetic Resonance (NMR) relaxometry may fill this methodological gap. It allows non-invasive detection of protons in liquids and solids, and on the basis of these measures, can be used to quantify liquid and dry matter contents of seeds and plants. Unfortunately, most existing NMR relaxometers are large, unwieldy and not suitable to measure intact plants or to be used under field conditions. In addition, currently the appropriate NMR relaxometric methods are poorly suited for non-expert use. We here present a novel approach to overcome these drawbacks. We demonstrate that a basic NMR relaxometer with the capability to accept intact plants, in combination with straightforward NMR and data processing methods, can be used as an NMR plant sensor to continuously, quantitatively and non-invasively monitor changes in WC and DMC. This can be done in vivo, in situ, and with high temporal resolution. The method is validated by showing that measured liquid and solid proton densities accurately reflect WC and DMC of reference samples. The NMR plant sensor is demonstrated in an experimental context by monitoring WC of rice leaves under osmotic stress, and by measuring the dynamics of water and dry matter accumulation during seed filling in a developing wheat ear. It is further demonstrated how the method can be used to estimate leaf water potential on the basis of changes in leaf water content.

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Section: Introductionmentioning

confidence: 99%

A Mobile NMR Sensor and Relaxometric Method to Non-destructively Monitor Water and Dry Matter Content in Plants

et al. 2021

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“…MRI is thus well suited for continuous or long‐term measurements. The technology has been used to image structure and anatomy (Robinson et al , ; Metzner et al , ; Hesse et al , ), plant water content (Schepper et al , ), and to measure phloem and xylem sap flow (Köckenberger et al , ; Scheenen et al , ; Windt et al , ). For detailed reviews and more examples see van As et al () and Borisjuk et al ().…”

Section: Introductionmentioning

confidence: 99%

A small‐scale MRI scanner and complementary imaging method to visualize and quantify xylem embolism formation

et al. 2020

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Magnetic resonance imaging (MRI) is a useful tool to image xylem embolism formation in plants. MRI scanners configured to accept intact plants are rare and expensive. Here, we investigate if affordable small-scale, custom-built low-field MRI scanners would suffice for the purpose.A small-scale, C-shaped permanent magnet was paired with open, plane parallel imaging gradients. The setup was small enough to fit between leaves or branches and offered open access for plant stems of arbitrary length. To counter the two main drawbacks of the system, low signal to noise and reduced magnetic field homogeneity, a multi-spin echo (MSE) pulse sequence was implemented, allowing efficient signal acquisition and quantitative imaging of water content and T 2 signal relaxation.The system was tested visualizing embolism formation in Fagus sylvatica during bench dehydration. High-quality images of water content and T 2 were readily obtained, which could be utilized to detect the cavitation of vessels smaller than could be spatially resolved. A multiplication of both map types yielded images in which filled xylem appeared with even greater contrast.T 2 imaging with small-scale MRI devices allows straightforward visualization of the spatial and temporal dynamics of embolism formation and the derivation of vulnerability curves.

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“…In D. reflexa and F. insignis (as tested by Masselter et al, 2011), fracture toughness values in the stem-branch attachments are in a similar range (with mean values of 10.53 and 9.32 kJ/m 2 , respectively) as the fracture toughness of "old" (DoF2) axes of H. helix, with a median value of 11.60 kJ/m 2 . This similarity indicates that self-supporting axes of relatively thin-stemmed, but otherwise very different plants (D. reflexa and F. insignis are monocotyledons with a fundamentally different stem anatomy from H. helix) (Haushahn et al, 2014;Hesse et al, 2016Hesse et al, , 2018Masselter et al, 2016) and a different ontogeny (D. reflexa does not produce climbing phases), have similar values of fracture toughness (a finding that also holds for Schefflera arboricola, data not shown). Therefore, it might be deduced that these comparable values result from similar mechanical constraints in self-supporting branched plants.…”

Section: Biomechanics Of Stem-branch Attachments: Modes Of Failure and Fracture Toughness Under The Bending Loadmentioning

confidence: 82%

“…Complementary techniques can allow a fuller understanding of the functional morphology and biomechanics of the Araliaceae family, for example, by testing the anatomy (inner structure) of H. helix ramifications under load via methods such as magnetic resonance imaging, thus allowing for a non-invasive loading of plant specimens in vivo, as well as a fundamental exploration of branch formation (Hesse et al, 2016(Hesse et al, , 2018. In conjunction, such analyses can provide a foundation for the development of biomimetic node structures for implementation in constructional engineering and architecture, e.g., by mimicking the "finger-like" attachment structures between branch and stem in the Araliaceae (Born et al, 2016;Bunk et al, 2017b).…”

Section: Biomechanics Of Stem-branch Attachments: Modes Of Failure and Fracture Toughness Under The Bending Loadmentioning

confidence: 99%

Branching morphology and biomechanics of ivy (Hedera helix) stem‐branch attachments

Bunk

Krassovitski

Speck

et al. 2019

American J of Botany

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Ivy (Hedera helix L., Araliaceae) is an abundant, evergreen, rootclimbing liana, widespread across most of Europe and western Asia (Schnitzler, 1995;Metcalfe, 2005). Its phenotype is mainly characterized by differences in the morphology and growth habits of the juvenile and adult phases (Jones, 1999;Metcalfe, 2005). Typically, juvenile plant stems initially grow as prostrate, plagiotropic shoots on the ground, and this phase can persist for a prolonged time (Wareing and Frydman, 1976). As they make contact with an adequate support, newly developed shoots grow as climbing axes, attached to the support via adventitious roots (Melzer et al., 2010(Melzer et al., , 2012. Juvenile shoots additionally occur in the form of "searchers" or vine tips-i.e., self-supporting tip regions of climbing axes (Gartner and Rowe, 2000). The adult phase of H. helix consists of orthotropic self-supporting shoots, which bear flowers and fruits for reproduction. Besides these differences in growth habits, the ontogenetic change from the juvenile to the adult reproductive phase is distinguished by other vegetative traits, for example, leaf shapelobed in juvenile and entire in adult phase (Stein and Fosket, 1969;Zotz et al., 2011), phyllotaxis-alternate in juvenile and helical in adult phase (Stein and Fosket, 1969;Poethig, 1990), and adventitious roots-present only in the juvenile phase (Stein and Fosket, 1969).Besides the relevance of H. helix to horticulture, including interest in its phase change, research on H. helix has focused mainly on its ecology (

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A qualitative analysis of the bud ontogeny of Dracaena marginata using high-resolution magnetic resonance imaging

Cited by 9 publications

References 46 publications

A Mobile NMR Sensor and Relaxometric Method to Non-destructively Monitor Water and Dry Matter Content in Plants

A Mobile NMR Sensor and Relaxometric Method to Non-destructively Monitor Water and Dry Matter Content in Plants

A small‐scale MRI scanner and complementary imaging method to visualize and quantify xylem embolism formation

Branching morphology and biomechanics of ivy (Hedera helix) stem‐branch attachments

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