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Plant electrophysiology: bibliometric analysis, methods and applications in the monitoring of plant-environment interactions
Electrofisiología vegetal: análisis bibliométrico, métodos y aplicaciones en el monitoreo de las interacciones planta-ambiente
DOI:
https://doi.org/10.15446/dyna.v88n218.92405Palabras clave:
Vegetal Electrophysiology, Electric Potentials, Action Potentials, Variation Potentials, Plant Electrical Measurements (en)electrofisiología vegetal;, potenciales eléctricos;, potenciales de acción;, potenciales de variación;, medidas eléctricas de plantas. (es)
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Plants have mechanisms to perceive and transmit information between their organs and tissues to respond quickly to abiotic and biotic external stimuli from the environment, producing different electrical potential types. It is reported on the generation and conduction of electrochemical impulses within different tissues and organs of the plant, which have been acquired using different methods to use them in various applications in the improvement of the agro-industrial sector and the development of different types of phytosensors. In this review paper, the various studies that have been carried out since Pfeffer, Burdon-Sanderson, Darwin, Haberlandt, and Bose discovered electrical activity in plants until today are reported. Plants provide mechanisms to perform biosensors based on responding to environmental changes, opening a great path for the design of low-cost and highly sensitive sensors and sensor networks, the current trend is towards experimental analysis using various stimuli.
Las plantas tienen mecanismos de percepción y transmisión de información entre sus órganos y tejidos para responder rápidamente a estímulos externos abióticos y bióticos, produciendo diferentes tipos de potenciales eléctricos. Se ha reportado en literatura sobre la generación y conducción de impulsos electroquímicos dentro de diferentes tejidos y órganos de la planta, los cuales han sido adquiridos mediante diferentes métodos para utilizarlos en diversas aplicaciones, donde se cuenta la mejora del sector agroindustrial y el desarrollo de diferentes tipos de fitosensores. En este artículo de revisión, se reportan los diversos estudios que se han llevado a cabo desde que Pfeffer, Burdon-Sanderson, Darwin, Haberlandt y Bose descubrieron la actividad eléctrica en las plantas hasta el día de hoy. Las plantas brindan mecanismos para realizar biosensores basados en la respuesta a los cambios ambientales, abriendo un gran camino para el diseño de sensores y redes de sensores de bajo costo y alta sensibilidad, la tendencia actual apunta hacia el análisis experimental utilizando diversos estímulos.
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