Effect of LED Illumination on the Accumulation of Functional Chemicals in Plants
? These authors contributed equally to this paper
Received date: 2014-05-05
Accepted date: 2014-08-06
Online published: 2015-04-10
The effect of LED illumination on plant growth and development has been investigated for years. However, most of the works focused on plant morphology. Recently, investigations have shifted to the effect on the accumulation of plant functional chemicals. This paper reviews the latest research in this area and the problems encountered. Some research ideas and possible future directions are discussed.
Kui Lin, Yong Xu . Effect of LED Illumination on the Accumulation of Functional Chemicals in Plants[J]. Chinese Bulletin of Botany, 2015 , 50(2) : 263 -271 . DOI: 10.3724/SP.J.1259.2015.00263
1 | 胡可, 韩科厅, 戴思兰 (2010). 环境因子调控植物花青素苷合成及呈色的机理. 植物学报 45, 307-317. |
2 | 黄海智, 孙玉敬, 刘东红, 叶兴乾 (2011). 多酚的基本生物化学作用机制. 生物技术进展 1, 334-341. |
3 | 季宏伟, 李良璧, 匡廷云 (2001). 莲胚芽叶绿素合成对光照的依赖性. 植物学报 43, 693-698. |
4 | Afreen F, Zobayed SMA, Kozai T (2005). Spectral quality and UV-B stress stimulate glycyrrhizin concentration of Glycyrrhiza uralensis in hydroponic and pot system.Plant Physiol Biochem 43, 1074-1081. |
5 | Alokam S, Chinnappa CC, Reid DM (2002). Red/far-red light mediated stem elongation and anthocyanin accumulation in Stellaria longipes: differential response of alpine and prairie ecotypes.Can J Bot 80, 72-81. |
6 | Amaki W, Yamazaki N, Ichimura M, Watanabe H (2011). Effects of light quality on the growth and essential oil content in sweet basil.Acta Hortic 907, 91-94. |
7 | Awad MA, Wagenmakers PS, de Jager A (2001). Effects of light on flavonoid and chlorogenic acid levels in the skin of ‘Jonagold’ apples.Sci Hortic 88, 289-298. |
8 | Bourget CM (2008). An introduction to light-emitting diodes.HortScience 43, 1944-1946. |
9 | Brodrick J (2007). Next-generation lighting initiative at the U.S. department of energy: catalyzing science into the marketplace. J Display Technol 3, 91-97. |
10 | Bula RJ, Morrow RC, Tibbitts TW, Barta DJ, Ignatius RW, Martin TS (1991). Light-emitting diodes as a radiation source for plants.HortScience 26, 203-205. |
11 | Cheng YJ, Xu GW, Zhu DP, Zhu WJ, Luo L (2006). Thermal analysis for indirect liquid cooled multichip module using computational fluid dynamic simulation and response surface methodology.IEEE T Compon Pack T 29, 39-46. |
12 | Cheng YK, Cheng KWE (2006). General study for using LED to replace traditional lighting devices. In: Proceedings of the 2nd International Conference on Power Electronics Systems and Applications. Hong Kong: IEEE. pp. 173-177. |
13 | Cinatl J, Morgenstern B, Bauer G, Chandra P, Rabenau H, Doerr HW (2003). Glycyrrhizin, an active component of liquorice roots, and replication of SARS-associated coro- navirus.Lancet 361, 2045-2046. |
14 | Connor AM, Finn CE, Alspach PA (2005). Genotypic and environmental variation in antioxidant activity and total phenolic content among blackberry and hybridberry cultivars.J Am Soc Hortic Sci 130, 527-533. |
15 | Cope KR, Bugbee B (2013). Spectral effects of three types of white light-emitting diodes on plant growth and deve- lopment: absolute versus relative amounts of blue light.HortScience 48, 504-509. |
16 | Duan XW, Jiang YM, Su XG, Zhang ZQ, Shi J (2007). Antioxidant properties of anthocyanins extracted from lit- chi (Litchi chinenesis Sonn.) fruit pericarp tissues in relation to their role in the pericarp browning.Food Chem 101, 1365-1371. |
17 | Ebisawa M, Shoji K, Kato M, Shimomura K, Goto F, Yoshihara T (2008). Supplementary ultraviolet radiation B together with blue light at night increased quercetin content and flavonol synthase gene expression in leaf lettuce (Lactuca sativa L.). Environ Control Biol 46, 1-11. |
18 | Folta KM, Koss LL, McMorrow R, Kim HH, Kenitz JD, Wheeler R, Sager JC (2005). Design and fabrication of adjustable red-green-blue LED light arrays for plant research.BMC Plant Biol 5, 17. |
19 | Frank HA, Cogdell RJ (1996). Carotenoids in photosynthesis.Photochem Photobiol 63, 257-264. |
20 | Fu XY, Liu XJ, Wu Y (2009). Research and analysis of the design development and perspective technology for LED lighting products. In: Proceedings of the IEEE 10th International Conference on Computer-Aided Industrial Design & Conceptual Design. Wenzhou: IEEE. pp. 1330-1334. |
21 | Fu Y, Hsieh TC, Guo JQ, Kunicki J, Lee MYWT, Darzyn- kiewicz Z, Wu JM (2004). Licochalcone-A, a novel flavonoid isolated from licorice root (Glycyrrhiza glabra), causes G2 and late-G1 arrests in androgen-independent PC-3 prostate cancer cells.Biochem Biophys Res Com- mun 322, 263-270. |
22 | Fujisawa K, Tandon BN (1994). Therapeutic approach to the chronic active liver disease: summary of a satellite symposium. In: Nishioka K, Suzuki H, Mishiro S, Oda T, eds. Viral Hepatitis and Liver Disease. Tokyo: Springer- Verlag. pp. 662-665. |
23 | Galdiano Júnior RF, Mantovani C, Lopes Pivetta KF, de Macedo Lemos EG (2012). In vitro growth and acclimatization of Cattleya loddigesii Lindley (Orchidaceae) with actived charcoal in two light spectra. Ciência Rural 42, 801-807. |
24 | Gaziano JM, Hennekens CH (1993). The role of β-carotene in the prevention of cardiovascular disease.Ann NY Acad Sci 691, 148-155. |
25 | Giliberto L, Perrotta G, Pallara P, Weller JL, Fraser PD, Bramley PM, Fiore A, Tavazz M, Giuliano G (2005). Manipulation of the blue light photoreceptor cryptochrome 2 in tomato affects vegetative development, flowering time, and fruit antioxidant content.Plant Physiol 137, 199-208. |
26 | Giovannucci E (1999). Tomatoes, tomato-based products, lycopene, and cancer: review of the epidemiologic literature.J Natl Cancer Inst 91, 317-331. |
27 | Goto E (2012). Plant production in a closed plant factory with artificial lighting.Acta Hortic 956, 37-50. |
28 | Gupta SD, Jatothu B (2013). Fundamentals and applications of light-emitting diodes (Leds) in in vitro plant growth and morphogenesis.Plant Biotechnol Rep 7, 211-220. |
29 | Hajlaoui H, Trabelsi N, Noumi E, Snoussi M, Fallah H, Ksouri R, Bakhrouf A (2009). Biological activities of the essential oils and methanol extract of tow cultivated mint species (Mentha longifolia and Mentha pulegium) used in the Tunisian folkloric medicine.World J Microbiol Biotechnol 25, 2227-2238. |
30 | Hart DJ, Scott KJ (1995). Development and evaluation of an HPLC method for the analysis of carotenoids in foods, and the measurement of the carotenoid content of vegetables and fruits commonly consumed in the UK.Food Chem 54, 101-111. |
31 | Havaux M (1998). Carotenoids as membrane stabilizers in chloroplasts.Trends Plant Sci 3, 147-151. |
32 | Hayashi M, Iwashita K, Katsube N, Yamaki K, Kobori M (2002). Kinjiso (Gynurci bicolor DC.) colored extract induce apoptosis in HL60 leukemia cells.Nippon Syo- kuhin Kagaku Kogaku Kaishi 49, 519-526. |
33 | Hikosaka S, Ito K, Goto E (2010). Effects of ultraviolet light on growth, essential oil concentration, and total antioxi- dant capacity of Japanese Mint.Environ Control Biol 48, 185-190. |
34 | Howitt CA, Pogson BJ (2006). Carotenoid accumulation and function in seeds and non-green tissues.Plant Cell Environ 29, 435-445. |
35 | Ilieva I, Ivanova T, Naydenov Y, Dandolov I, Stefanov D (2010). Plant experiments with light-emitting diode module in Svet space greenhouse.Adv Space Res 46, 840-845. |
36 | Jang D, Park SJ, Yook SJ, Lee KS (2014a). The orientation effect for cylindrical heat sinks with application to LED light bulbs.Int J Heat Mass Tran 71, 496-502. |
37 | Jang D, Yook SJ, Lee KS (2014b). Optimum design of a radial heat sink with a fin-height profile for high-power LED lighting applications.Appl Energ 116, 260-268. |
38 | Jang D, Yu SH, Lee KS (2012). Multidisciplinary optimization of a pin-fin radial heat sink for LED lighting applications. Int J Heat Mass Tran 55, 515-521. |
39 | Jeong SW, Park S, Jin JS, Seo ON, Kim GS, Kim YH, Bae H, Lee G, Kim ST, Lee WS, Shin SC (2012). Influences of four different light-emitting diode lights on flowering and polyphenol variations in the leaves of chrysanthemum (Chrysanthemum morifolium).J Agric Food Chem 60, 9793-9800. |
40 | Johkan M, Shoji K, Goto F, Hashida S, Yoshihara T (2010). Blue light-emitting diode light irradiation of seedlings improves seedling quality and growth after transplanting in red leaf lettuce.HortScience 45, 1809-1814. |
41 | Juntunen E, Tapaninen O, Sitomaniemi A, Jamsa M, Heikkinen V, Karppinen M, Karioja P (2014). Copper-core mcpcb with thermal vias for high-power cob LED modules.IEEE Transactions on Power Electronics 29, 1410-1417. |
42 | Keyhaninejad N, Richins RD, O'Connell MA (2012). Carotenoid content in field-grown versus greenhouse-grown peppers: different responses in leaf and fruit.HortScience 47, 852-855. |
43 | Kobayashi K, Amore T, Lazaro M (2013). Light-emitting diodes (LEDs) for miniature hydroponic lettuce.Opt Pho- tonics J 3, 74-77. |
44 | Kojima M, Nakano Y, Fujii H (2010). Light stimulation triggered expression of genes coding for vacuolar proton-pump enzymes V-ATPase and V-PPase in buckwheat.Biosci Biotechnol Biochem 74, 1507-1511. |
45 | Kopsell DA, Kopsell DE (2008). Genetic and environmental factors affecting plant lutein/zeaxanthin. Agro Food Ind Hi Tech 19, 44-46. |
46 | Kurata H, Mochizuki A, Okuda N, Seki M, Furusaki S (2000). Intermittent light irradiation with second- or hour-scale periods controls anthocyanin production by strawberry cells.Enzyme Microb Technol 26, 621-629. |
47 | Ledford HK, Niyogi KK (2005). Singlet oxygen and photo-oxidative stress management in plants and algae.Plant Cell Environ 28, 1037-1045. |
48 | Lefsrud MG, Kopsell DA, Sams CE (2008). Irradiance from distinct wavelength light-emitting diodes affect secondary metabolites in kale.HortScience 43, 2243-2244. |
49 | Li J, Hikosaka S, Goto E (2011). Effects of light quality and photosynthetic photon flux on growth and carotenoid pigments in spinach (Spinacia oleracea L).Acta Hortic 907, 105-110. |
50 | Li Q, Kubota C (2009). Effects of supplemental light quality on growth and phytochemicals of baby leaf lettuce.En- viron Exp Bot 67, 59-64. |
51 | Liu LX, Niu Y, Zou J, Zhu ZM, Yang YT (2014). A novel monolithic white LED driver with dual dimming mode.Analog Integr Circ S 79, 37-44. |
52 | Mactier H, Weaver LT (2005). Vitamin A and preterm infants: what we know, what we don’t know, and what we need to know.Arch Dis Child Fetal Neonatal Ed 90, F103-F108. |
53 | Maeda G (2006). Anti-oxidation activity of Okinawa traditional vegetables.Bull Okinawa Agric Res Cntr 8, 65-70. |
54 | Massa GD, Kim HH, Wheeler RM, Mitchell CA (2008). Plant productivity in response to LED lighting.HortSci- ence 43, 1951-1956. |
55 | Mayne ST (1996). β-carotene, carotenoids, and disease prevention in humans.FASEB J 10, 690-701. |
56 | McNellis TW, Deng XW (1995). Light control of seedling morphogenetic pattern.Plant Cell 7, 1749-1761. |
57 | Mitchell CA, Both AJ, Bourget CM, Burr JF, Kubota C, Lopez RG, Morrow RC, Runkle ES (2012). LEDs: the future of greenhouse lighting.Chron Horticult 52, 6-12. |
58 | Morrow RC (2008). LED lighting in horticulture.HortScience 43, 1947-1950. |
59 | Narendran N, Gu Y (2005). Life of LED-based white light sources. J Display Technol 1, 167-171. |
60 | Ning N, Tong ZX, Yu DJ, Wu SY, Chen WB, Feng CY (2014). Highly AC voltage fluctuation-resistant LED driver with sinusoid-like reference.J Power Electron 14, 257-264. |
61 | Nishioka N, Nishimura T, Ohyama K, Malayeri SH, Goto E, Sumino M, Inagaki N, Morota T (2008). Light quality affected growth and contents of essential oil components of Japanese mint plants.Acta Hort 797, 431-436. |
62 | Pérez-Balibrea S, Moreno DA, García-Viguera C (2008). Influence of light on health-promoting phytochemicals of broccoli sprouts. J Sci Food Agric 88, 904-910. |
63 | Pyo YH, Lee TC, Logendra L, Rosen RT (2004). Anti- oxidant activity and phenolic compounds of Swiss chard (Beta vulgaris subspecies cycla) extracts. Food Chem 85, 19-26. |
64 | Ramalho JC, Marques NC, Semedo JN, Matos MC, Quartin VL (2002). Photosynthetic performance and pigment composition of leaves from two tropical species is determined by light quality.Plant Biol 4, 112-120. |
65 | Reichling J (1999). Plant-microbe interactions and secondary metabolites with antiviral, antibacterial and antifungal properties. In: Wink M, ed. Functions of Plant Secondary Metabolites and their Exploitation in Biotechnology, Annual Plant Reviews. Sheffield: Sheffield Academic Press Ltd. pp. 187-273. |
66 | Ren J, Guo SS, Xu CL, Yang CJ, Ai WD, Tang YK, Qin LF (2014). Effects of different carbon dioxide and LED lighting levels on the anti-oxidative capabilities of Gynura bicolor DC.Adv Space Res 53, 353-361. |
67 | Rice-Evans AC, Miller NJ, Paganga G (1997). Antioxidant properties of phenolic compounds.Trends Plant Sci 2, 152-159. |
68 | Rodríguez-Vidal E, Otaduy D, Ortiz D, González F, Moreno F, Saiz JM (2014). Optical performance of a versatile illumination system for high divergence LED sources.Optik 125, 1657-1662. |
69 | Shoji K, Goto E, Hashida S, Goto F, Yoshihara T (2010). Effect of red light and blue light on the anthocyanin accumulation and expression of anthocyanin biosynthesis genes in red-leaf lettuce. J SHITA 22, 107-113. |
70 | Shoji K, Goto E, Hashida S, Goto F, Yoshihara T (2011). Effect of light quality on the polyphenol content and antioxidant activity of sweet basil (Ocimum basilicum L.). Acta Hortic 907, 95-99. |
71 | Shur MS, Zukauskas A (2005). Solid-state lighting: toward superior illumination.Proc IEEE 93, 1691-1703. |
72 | Spiazzi G, Buso S, Meneghesso G (2005). Analysis of a high-power-factor electronic ballast for high brightness light emitting diodes. In: IEEE 36th Power Electronics Specialists Conference. Recife: IEEE. pp. 1494-1499. |
73 | Stenbaek A, Jensen PE (2010). Redox regulation of chlorophyll biosynthesis.Phytochemistry 71, 853-859. |
74 | Steranka FM, Bhat J, Collins D, Cook L, Craford MG, Fletcher R, Gardner N, Grillot P, Goetz W, Keuper M, Khare R, Kim A, Krames M, Harbers G, Ludowise M, Martin PS, Misra M, Mueller G, Mueller-Mach R, Rudaz S, Shen YC, Steigerwald D, Stockman S, Subramanya S, Trottier T, Wierer JJ (2002). High power LEDs- technology status and market applications.Physica Status Solidi (a) 194, 380-388. |
75 | Tamulaitis G, Duchovskis P, Bliznikas Z, Breive K, Ulinskaite R, Brazaityte A, Novičkovas A, Žukauskas A (2005). High-power light-emitting diode based facility for plant cultivation.J Phys D: Appl Phys 38, 3182-3187. |
76 | Tsao JY (2004). Solid-state lighting: lamps, chips, and materials for tomorrow.IEEE Circuits and Devices Magazine 20, 28-37. |
77 | Tuan PA, Thwe AA, Kim YB, Kim JK, Kim SJ, Lee S, Chung SO, Park SU (2013). Effects of white, blue, and red light-emitting diodes on carotenoid biosynthetic gene expression levels and carotenoid accumulation in sprouts of tartary buckwheat (Fagopyrum tataricum Gaertn.).J Agric Food Chem 61, 12356-12361. |
78 | Vänninen I, Pinto DM, Nissinen AI, Johansen NS, Shipp L (2010). In the light of new greenhouse technologies. 1. Plant-mediated effects of artificial lighting on arthropods and tritrophic interactions.Ann Appl Biol 157, 393-414. |
79 | Wang YC, Zhang HX, Zhao B, Yuan XF (2001). Improved growth of Artemisia annua L hairy roots and artemisinin production under red light conditions.Biotechnol Lett 23, 1971-1973. |
80 | Watanabe H (2011). Light-controlled plant cultivation system in Japan―development of a vegetable factory using LEDs as a light source for plants.Acta Hortic 907, 37-44. |
81 | Wu MC, Hou CY, Jiang CM, Wang YT, Wang CY, Chen HH, Chang HM (2007). A novel approach of LED light radiation improves the antioxidant activity of pea seed- lings.Food Chem 101, 1753-1758. |
82 | Wu SJ, Hsu HC, Fu SL, Yeh JN (2014). Numerical simulation of high power LED heat-dissipating system.Mater Lett 10, 497-502. |
83 | Yanovsky MJ, Alconada-Magliano TM, Mazzella MA, Gatz C, Thomas B, Casal JJ (1998). Phytochrome A affects stem growth, anthocyanin synthesis, sucrose-phosphate- synthase activity and neighbour detection in sunlight- grown potato.Planta 205, 235-241. |
84 | Yeh N, Chung JP (2009). High-brightness LEDs-energy efficient lighting sources and their potential in indoor plant cultivation.Renew Sust Energ Rev 13, 2175-2180. |
85 | Zhou Y, Singh BR (2002). Red light stimulates flowering and anthocyanin biosynthesis in American cranberry. Plant Growth Regul 38, 165-171. |
86 | Ziegler RG (1991). Vegetables, fruits, and carotenoids and the risk of cancer.Am J Clin Nutr 53, 251S-259S. |
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