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Utilizing conductivity of seawater for bioelectric measurement of fish
To manage health conditions of farmed fish and other living creatures, a simple method to measure bioelectric signals of the creatures in seawater is expected. A novel method to measure bioelectric signals by utilizing the conductivity of seawater surrounding the entire body of a fish is proposed. A...
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Published in: | Scientific reports 2020-10, Vol.10 (1), p.16363-16363, Article 16363 |
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description | To manage health conditions of farmed fish and other living creatures, a simple method to measure bioelectric signals of the creatures in seawater is expected. A novel method to measure bioelectric signals by utilizing the conductivity of seawater surrounding the entire body of a fish is proposed. As for the proposed method, a needle-type internal electrode is inserted into the fish’s muscle at a certain measurement point, and an external electrode is sunk in seawater. The internal electrode is isolated from the seawater by virtue of being inserted in the fish. Bioelectric signals generated between the external and internal electrodes are then measured. By sharing the external electrode with the internal electrode, it is possible to measure bioelectric signals with half the number of bioelectrodes used by conventional methods. To demonstrate the practicality of the proposed method, two internal electrodes were inserted into different parts (above the gills and near the tail) of three fish (
Parajulis poecilepterus
, ca. 20 cm fork length) kept in a tank. The proposed method obtained reliable bioelectric signals corresponding to electrocardiograms (ECGs) and electromyograms (EMGs) from each part of the individual fish. |
doi_str_mv | 10.1038/s41598-020-73485-3 |
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Parajulis poecilepterus
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Parajulis poecilepterus
, ca. 20 cm fork length) kept in a tank. 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A novel method to measure bioelectric signals by utilizing the conductivity of seawater surrounding the entire body of a fish is proposed. As for the proposed method, a needle-type internal electrode is inserted into the fish’s muscle at a certain measurement point, and an external electrode is sunk in seawater. The internal electrode is isolated from the seawater by virtue of being inserted in the fish. Bioelectric signals generated between the external and internal electrodes are then measured. By sharing the external electrode with the internal electrode, it is possible to measure bioelectric signals with half the number of bioelectrodes used by conventional methods. To demonstrate the practicality of the proposed method, two internal electrodes were inserted into different parts (above the gills and near the tail) of three fish (
Parajulis poecilepterus
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subjects | 631/158 631/1647 631/601 639/166 692/700 704/829 Animals Aquaculture Aquaculture - methods Conductivity Electric Conductivity Electric Impedance Electrodes Electromyography Fish Fishes - physiology Gills Humanities and Social Sciences multidisciplinary Science Science (multidisciplinary) Seawater |
title | Utilizing conductivity of seawater for bioelectric measurement of fish |
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