The use of positron emission tomography for studies of long‐distance transport in plants: uptake and transport of <sup>18</sup>F

McKAY, R. M. L.; Palmer, G.R.; P., X.; Layzell, David B.; McKee, B.T.A.

doi:10.1111/j.1365-3040.1988.tb01911.x

Cited by 32 publications

(36 citation statements)

References 15 publications

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“…The plant PET developed at QST, which is called PETIS, utilizes the physical characteristics of positron-emitting radionuclides (which are simultaneously released by the annihilation of two 511-keV gamma rays in opposite (~180º degree) directions) to estimate the location of the chemical element of interest [24,25]. The positron imaging technology has a very high degree of sensitivity compared to other radionuclide-based imaging techniques.…”

Section: Positron Imagingmentioning

confidence: 99%

Recent Advances in Radioisotope Imaging Technology for Plant Science Research in Japan

Suzui

Tanoi

Furukawa

et al. 2019

QuBS

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Soil provides most of the essential elements required for the growth of plants. These elements are absorbed by the roots and then transported to the leaves via the xylem. Photoassimilates and other nutrients are translocated from the leaves to the maturing organs via the phloem. Non-essential elements are also transported via the same route. Therefore, an accurate understanding of the movement of these elements across the plant body is of paramount importance in plant science research. Radioisotope imaging is often utilized to understand element kinetics in the plant body. Live plant imaging is one of the recent advancements in this field. In this article, we recapitulate the developments in radioisotope imaging technology for plant science research in Japanese research groups. This collation provides useful insights into the application of radioisotope imaging technology in wide domains including plant science.

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Section: Positron Imagingmentioning

confidence: 99%

Recent Advances in Radioisotope Imaging Technology for Plant Science Research in Japan

Suzui

Tanoi

Furukawa

et al. 2019

QuBS

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“…It has been successfully used for decades by medical diagnostic and pharmaceutical industries due to its ability to assess physiological and metabolic function in the living, intact organism in real time. It has also been in sporadic use since the 1980s in plant research, to quantitatively assess the uptake, inter-organ transport, and storage of radio-labeled substances (McKay et al, 1988;Partelová et al, 2014). Recently, Converse et al (2015) used an animal PET imaging system to model and experimentally evaluate the uptake of atmospheric fluoride in plants by administrating to the petioles of Brassica oleracea.…”

Section: Introductionmentioning

confidence: 99%

Continuous monitoring of plant sodium transport dynamics using clinical PET

Ruwanpathirana

Plett

Williams

et al. 2020

Preprint

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BackgroundThe absorption, translocation, accumulation and excretion of substances are fundamental processes in all organisms including plants, and have been successfully studied using radiotracers labelled with and since 1939. Sodium is one of the most damaging ions to the growth and productivity of crops. Due to the significance of understanding sodium transport in plants, a significant number of studies have been carried out to examine sodium influx, compartmentation, and efflux using - or 24Na-labeled salts. Notably, however, most of these studies employed destructive methods, which has limited our understanding of sodium flux and distribution characteristics in real time, in live plants.Positron emission tomography (PET) has been used successfully in medical research and diagnosis for decades. Due to its ability to visualise and assess physiological and metabolic function, PET imaging has also begun to be employed in plant research. Here, we report the use of a clinical PET scanner with a tracer to examine -influx dynamics in barley plants (Hordeum vulgare L. spp. vulgare – cultivar Bass) under variable nutrient levels, alterations in the day/night light cycle, and the presence of sodium channel inhibitors.Results3D dynamic PET images of whole plants show readily visible translocation from roots to shoots in each examined plant, with rates influenced by both nutrient status and channel inhibition. PET images show that plants cultivated in low-nutrient media transport more than plants cultivated in high-nutrient media, and that uptake is suppressed in the presence of a cation-channel inhibitor. A distinct diurnal pattern of influx was discernible in curves displaying rates of change of relative radioactivity. Plants were found to absorb significantly more during the light period, and anticipate the change in the light/dark cycle by adjusting the sodium influx rate downward in the dark period, an effect not previously described experimentally.ConclusionsWe demonstrate the utility of clinical PET/CT scanners for real-time monitoring of the temporal dynamics of sodium transport in plants. The effects of nutrient deprivation and of ion channel inhibition on sodium influx into barley plants are shown in two proof-of-concept experiments, along with the first-ever 3D-imaging of the light and dark sodium uptake cycles in plants. This method carries significant potential for plant biology research and, in particular, in the context of genetic and treatment effects on sodium acquisition and toxicity in plants.*The authors contributed equally

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“…Recently, alternative non‐destructive methods for detecting morphological and structural differences in plants have been reported, such as optical coherence tomography (OCT), X‐ray tomography, positron emission tomography, magnetic resonance imaging, and ultrasound . Lee et al reported an accuracy of approximately 78% for detecting abnormal melon seeds using OCT. An X‐ray apparatus was used to assess mechanical and stink bug damage in soybean seed, although the results showed only the potential of the X‐ray image analysis technique, which required 40 s to measure one sample .…”

Section: Introductionmentioning

confidence: 99%

Non‐destructive evaluation of bacteria‐infected watermelon seeds using visible/near‐infrared hyperspectral imaging

et al. 2016

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The use of positron emission tomography for studies of long‐distance transport in plants: uptake and transport of ¹⁸F

Cited by 32 publications

References 15 publications

Recent Advances in Radioisotope Imaging Technology for Plant Science Research in Japan

Recent Advances in Radioisotope Imaging Technology for Plant Science Research in Japan

Continuous monitoring of plant sodium transport dynamics using clinical PET

Non‐destructive evaluation of bacteria‐infected watermelon seeds using visible/near‐infrared hyperspectral imaging

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The use of positron emission tomography for studies of long‐distance transport in plants: uptake and transport of 18F

Cited by 32 publications

References 15 publications

Recent Advances in Radioisotope Imaging Technology for Plant Science Research in Japan

Recent Advances in Radioisotope Imaging Technology for Plant Science Research in Japan

Continuous monitoring of plant sodium transport dynamics using clinical PET

Non‐destructive evaluation of bacteria‐infected watermelon seeds using visible/near‐infrared hyperspectral imaging

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The use of positron emission tomography for studies of long‐distance transport in plants: uptake and transport of ¹⁸F