Urbi Kundu;Jari Torniainen;Karl Bertling;Mayuri Kashyap;Bogdan C. Donose;Tim Gillespie;Dragan Indjin;Lianhe Li;Edmund H. Linfield;Alexander Giles Davies;Paul Dean;Aparajita Bandyopadhyay;Amartya Sengupta;Aleksandar D. Rakić
{"title":"利用太赫兹激光反馈干涉仪绘制细胞水动力学图,检测植物的遗传变异","authors":"Urbi Kundu;Jari Torniainen;Karl Bertling;Mayuri Kashyap;Bogdan C. Donose;Tim Gillespie;Dragan Indjin;Lianhe Li;Edmund H. Linfield;Alexander Giles Davies;Paul Dean;Aparajita Bandyopadhyay;Amartya Sengupta;Aleksandar D. Rakić","doi":"10.1109/TTHZ.2024.3412826","DOIUrl":null,"url":null,"abstract":"This study investigated the use of terahertz (THz) imaging as a rapid, high-fidelity technique for discriminating between genetic variants of the \n<italic>Allium</i>\n genus based on cellular water dynamics. It has been demonstrated earlier that plant genetic variations can be related to the biochemical and biomechanical alterations of the cell and that in turn affect the water dynamics within the cell. In this article, we show that the water dynamics, when considered in the form of the temporal evolution of the trajectory of the plant's response to THz radiation probe, and measured by a coherent THz transceiver, provides unique signature of the genetic makeup of the plant. Therefore, by exploring these trajectories, we discriminate between closely related variants of the same genus. The technique used for THz probing was the laser feedback interferometry with THz quantum cascade lasers, which enabled fast acquisition of high-resolution THz amplitude and phase images, which were processed into evaporation profiles describing the time-dependent dehydration of the samples. The trajectory of this profile in amplitude–phase reflectivity domain discriminates between different members of the \n<italic>Allium</i>\n genus. 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Detecting Genetic Variation in Plants by Mapping Cell Water Dynamics With Terahertz Laser Feedback Interferometry
This study investigated the use of terahertz (THz) imaging as a rapid, high-fidelity technique for discriminating between genetic variants of the
Allium
genus based on cellular water dynamics. It has been demonstrated earlier that plant genetic variations can be related to the biochemical and biomechanical alterations of the cell and that in turn affect the water dynamics within the cell. In this article, we show that the water dynamics, when considered in the form of the temporal evolution of the trajectory of the plant's response to THz radiation probe, and measured by a coherent THz transceiver, provides unique signature of the genetic makeup of the plant. Therefore, by exploring these trajectories, we discriminate between closely related variants of the same genus. The technique used for THz probing was the laser feedback interferometry with THz quantum cascade lasers, which enabled fast acquisition of high-resolution THz amplitude and phase images, which were processed into evaporation profiles describing the time-dependent dehydration of the samples. The trajectory of this profile in amplitude–phase reflectivity domain discriminates between different members of the
Allium
genus. This enables real-time genetic discrimination in agricultural and genome conservation applications.
期刊介绍:
IEEE Transactions on Terahertz Science and Technology focuses on original research on Terahertz theory, techniques, and applications as they relate to components, devices, circuits, and systems involving the generation, transmission, and detection of Terahertz waves.