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‘Proof of concept’ of how tube-net diameter affects growth and agar content in industrially important farmed red seaweed Gracilaria dura

Several emerging therapeutic applications of agar and its derivatives make it one of the sought-after hydrocolloids, commanding the highest price in global markets. In India farming of local agarophyte species is commercially successful supporting domestic demand coupled with natural harvesting. Sev...

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Published in:	Journal of applied phycology 2021-08, Vol.33 (4), p.2349-2358
Main Authors:	Shah, Yashesh, Yadav, Anshul, Kumar, Madhava Anil, Kavale, Monica Gajanan, Prasad, Kamalesh, Mantri, Vaibhav. A.
Format:	Article
Language:	English
Subjects:	Agar Algae Biomass Biomedical and Life Sciences Commercial farms Cultivars Diameters Distribution Ecology Farming Freshwater & Marine Ecology Gels Global marketing Gracilaria dura Growth rate Herbivores Life Sciences Nets Plant Physiology Plant Sciences Seaweeds Segregation Therapeutic applications Velocity Velocity distribution Water velocity
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cited_by	cdi_FETCH-LOGICAL-c319t-b746309aca727b156ef6ea7573faef45bb1309024cc1b1d8f3c985e5fa5597f83
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container_title	Journal of applied phycology
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creator	Shah, Yashesh Yadav, Anshul Kumar, Madhava Anil Kavale, Monica Gajanan Prasad, Kamalesh Mantri, Vaibhav. A.
description	Several emerging therapeutic applications of agar and its derivatives make it one of the sought-after hydrocolloids, commanding the highest price in global markets. In India farming of local agarophyte species is commercially successful supporting domestic demand coupled with natural harvesting. Several investigations have addressed issues with cultivar development and biological attributes, but technology improvements in farming are seldom attempted. The aim of the present investigation was to study the effect of tube-net diameter on growth and agar obtained from the industrially important red alga Gracilaria dura . CFD modelling also was used to predict the water velocity distribution in tube-nets. Daily growth rate (DGR) in 10-cm diameter (10 cm-DN) tube-nets was 2.5 ± 0.15% day −1 and 3.39 ± 0.10% day −1 in 8 cm diameter (8 cm-DN) tube-nets. In the 8 cm-DN, the biomass outside the tube was 51.83 ± 2.69% higher than biomass inside the tube and in 10 cm-DN, biomass inside the tube was 53.53 ± 2.16% higher. Two-dimensional CFD simulations confirmed that the velocity distribution in and around the tube-net was higher in 8 cm-DN than 10 cm-DN leading to better growth in the former. The agar yield after tissue segregation showed a 14.06% increase for the biomass harvested from inside the tube than outside in the 10 cm-DN, while it was 17.75% in the 8 cm-DN. Similarly, agar gel strength recorded a 38.47% increase in the biomass harvested from outside the tube compared with the inside biomass in the 10 cm-DN, and the increase was 11.96% in the 8 cm-DN. Further studies using various tube-net diameters are necessary to select the optimal diameter for undertaking commercial farming of G. dura in the open sea.
doi_str_mv	10.1007/s10811-021-02443-x
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Daily growth rate (DGR) in 10-cm diameter (10 cm-DN) tube-nets was 2.5 ± 0.15% day −1 and 3.39 ± 0.10% day −1 in 8 cm diameter (8 cm-DN) tube-nets. In the 8 cm-DN, the biomass outside the tube was 51.83 ± 2.69% higher than biomass inside the tube and in 10 cm-DN, biomass inside the tube was 53.53 ± 2.16% higher. Two-dimensional CFD simulations confirmed that the velocity distribution in and around the tube-net was higher in 8 cm-DN than 10 cm-DN leading to better growth in the former. The agar yield after tissue segregation showed a 14.06% increase for the biomass harvested from inside the tube than outside in the 10 cm-DN, while it was 17.75% in the 8 cm-DN. Similarly, agar gel strength recorded a 38.47% increase in the biomass harvested from outside the tube compared with the inside biomass in the 10 cm-DN, and the increase was 11.96% in the 8 cm-DN. 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subjects	Agar Algae Biomass Biomedical and Life Sciences Commercial farms Cultivars Diameters Distribution Ecology Farming Freshwater & Marine Ecology Gels Global marketing Gracilaria dura Growth rate Herbivores Life Sciences Nets Plant Physiology Plant Sciences Seaweeds Segregation Therapeutic applications Velocity Velocity distribution Water velocity
title	‘Proof of concept’ of how tube-net diameter affects growth and agar content in industrially important farmed red seaweed Gracilaria dura
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