Light spectrum combinations and intensity effects on Brassicaceae microgreen biomass yield and secondary metabolite accumulation: a review
Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › fagfællebedømt
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Light spectrum combinations and intensity effects on Brassicaceae microgreen biomass yield and secondary metabolite accumulation : a review. / Cowden, R.; Ghaley, B. B.
Proceedings of the International Symposium on Advances in Vertical Farming. red. / E. Hayashi; L.F.M. Marcelis. International Society for Horticultural Science (ISHS), 2023. s. 201-210 (Acta Horticulturae, Bind 1369).Publikation: Bidrag til bog/antologi/rapport › Konferencebidrag i proceedings › Forskning › fagfællebedømt
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TY - GEN
T1 - Light spectrum combinations and intensity effects on Brassicaceae microgreen biomass yield and secondary metabolite accumulation
AU - Cowden, R.
AU - Ghaley, B. B.
N1 - Conference code: 31
PY - 2023
Y1 - 2023
N2 - Microgreens are gaining increasing attention because of their short production cycle and their beneficial attributes such as high nutritional content, secondary metabolite production, and gastronomic applications. Among the key production parameters for microgreen production under controlled environments, light quality and quantity are key factors affecting beneficial attributes. Hence, the objective of this study was to synthesize the effects of light on outcomes in Brassicaceae microgreens. Therefore, we carried out a literature review from 36 different studies to collect, harmonize, and synthesize information on the effects of light spectrum combinations and intensities on 12 commonly grown Brassicaceae microgreens. We have presented results on the influence of light intensities and spectrum combinations on biomass and secondary metabolite production. For instance, results showed that there was a positive nonlinear correlation between the amount of light (cumulative light integral (CLI)=daily light integral * growing period in days) and dry weight (DW). We showed that an increase in CLI corresponds to an increase in DW (kg m-2) production up to 300 mol m-2 (R2=0.88), beyond which gains are minimal. Furthermore, we used multilinear regression models to show that more variation in DW, Carotenoid, and Anthocyanin outcomes was explained by the light spectrum combinations than light intensity. Furthermore, Brassicaceae microgreens showed a higher content of Carotenoids and Anthocyanins where multiple light spectra combinations were significantly associated with secondary metabolite production. Our results show that there are valuable benefits from including UV, far-red, and green spectra when producing microgreen biomass, carotenoids, or anthocyanins. The results provide a summarized overview on light intensity and spectrum combination effects on microgreens with a focus on accounting for variety-specific variation in microgreens which can inform future research designs and production environments based on desired outcomes.
AB - Microgreens are gaining increasing attention because of their short production cycle and their beneficial attributes such as high nutritional content, secondary metabolite production, and gastronomic applications. Among the key production parameters for microgreen production under controlled environments, light quality and quantity are key factors affecting beneficial attributes. Hence, the objective of this study was to synthesize the effects of light on outcomes in Brassicaceae microgreens. Therefore, we carried out a literature review from 36 different studies to collect, harmonize, and synthesize information on the effects of light spectrum combinations and intensities on 12 commonly grown Brassicaceae microgreens. We have presented results on the influence of light intensities and spectrum combinations on biomass and secondary metabolite production. For instance, results showed that there was a positive nonlinear correlation between the amount of light (cumulative light integral (CLI)=daily light integral * growing period in days) and dry weight (DW). We showed that an increase in CLI corresponds to an increase in DW (kg m-2) production up to 300 mol m-2 (R2=0.88), beyond which gains are minimal. Furthermore, we used multilinear regression models to show that more variation in DW, Carotenoid, and Anthocyanin outcomes was explained by the light spectrum combinations than light intensity. Furthermore, Brassicaceae microgreens showed a higher content of Carotenoids and Anthocyanins where multiple light spectra combinations were significantly associated with secondary metabolite production. Our results show that there are valuable benefits from including UV, far-red, and green spectra when producing microgreen biomass, carotenoids, or anthocyanins. The results provide a summarized overview on light intensity and spectrum combination effects on microgreens with a focus on accounting for variety-specific variation in microgreens which can inform future research designs and production environments based on desired outcomes.
KW - hydroponics
KW - LED light recipes
KW - microgreens
KW - multilinear regression models
U2 - 10.17660/ActaHortic.2023.1369.25
DO - 10.17660/ActaHortic.2023.1369.25
M3 - Article in proceedings
AN - SCOPUS:85164772134
T3 - Acta Horticulturae
SP - 201
EP - 210
BT - Proceedings of the International Symposium on Advances in Vertical Farming
A2 - Hayashi, E.
A2 - Marcelis, L.F.M.
PB - International Society for Horticultural Science (ISHS)
Y2 - 14 August 2022 through 20 August 2022
ER -
ID: 378378485