Assimilation of Multiwall Carbon Nanopipes to Developing Plants

The concentration of carbon nanopipes (CNPs) can be detected and quantitatively measured in various matrices, including biological ones, using the methodology of formation of a gamma-emitting radioactive isotope marker in a CNP. The methodology has been tested in a 10-day experiment on the sprouting...

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Published in:Nanotechnologies in Russia 2018-07, Vol.13 (7-8), p.448-451
Main Authors: Antsiferova, A. A., Buzulukov, Yu. P., Gusev, A. A., Demin, V. F., Kashkarov, P. K., Kormazeva, E. S.
Format: Article
Language:English
Subjects:
2018
Carbon
Chemistry and Materials Science
Industrial and Production Engineering
Kazan
Machines
Manufacturing
Materials of the Conference “Nanomaterials and Living Systems” (NLS-2018)
Materials Science
Methodology
Nanomaterials
Nanotechnology
Organs
Processes
Radioisotopes
Seeds
Substrates
Wheat
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cited_by cdi_FETCH-LOGICAL-c353t-4037d3d33c625c77fe9eee8bca49a0b783e54665a82cc67d1c7be64404888e7e3
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container_issue 7-8
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container_title Nanotechnologies in Russia
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creator Antsiferova, A. A.
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description The concentration of carbon nanopipes (CNPs) can be detected and quantitatively measured in various matrices, including biological ones, using the methodology of formation of a gamma-emitting radioactive isotope marker in a CNP. The methodology has been tested in a 10-day experiment on the sprouting of wheat seeds on an artificial substrate damped by a water suspension of radioactively marked Taunit-M multiwall CNPs (MCNP) (Russia). Changes in the activities of samples of developing plant organs—root system, coleoptile and root base, and stem with leaves—makes it possible to define the quantitative concentration of MCNPs passing from a substrate with a known concentration of the given nanomaterial into a plant. The results show promising outlooks for applying this methodology for quantitative measurements of CNP mass/concentration in various media and biological objects.
doi_str_mv 10.1134/S199507801804002X
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ispartof Nanotechnologies in Russia, 2018-07, Vol.13 (7-8), p.448-451
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source Springer Nature; Alma/SFX Local Collection
subjects 2018
Carbon
Chemistry and Materials Science
Industrial and Production Engineering
Kazan
Machines
Manufacturing
Materials of the Conference “Nanomaterials and Living Systems” (NLS-2018)
Materials Science
Methodology
Nanomaterials
Nanotechnology
Organs
Processes
Radioisotopes
Seeds
Substrates
Wheat
title Assimilation of Multiwall Carbon Nanopipes to Developing Plants
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