Light regulation method for promoting accumulation of cannabinoid substances

Abstract

A method for promoting the accumulation of cannabinoid substances is disclosed. The method comprises the step of adding an irradiation of green light, which has a peak wavelength at 505-526 nm, into the indoor growing environment of cannabis to improve the levels of tetrahydrocannabinol (THC) and cannabidiol (CBD), cannabinoid substances in cannabis. While maintaining the light intensity and other growth conditions, the yields and/or levels of THC and CBD, cannabinoid substances in cannabis, can be increased by up to 21.35%.

Claims

1. A light regulation method for promoting accumulation of cannabinoid substances, comprising: adding an irradiation of a green light into an indoor growing environment of cannabis to improve the accumulation of levels and yields of tetrahydrocannabinol (THC) and cannabidiol (CBD); wherein a peak wavelength of the green light lies at 515 nm; wherein the step of adding the irradiation of green light having a peak wavelength at 505-526 nm comprises a combined irradiation with other wavelength bands or independent irradiation; in the combined irradiation with other wavelength bands, a light source comprises 18-42% green light; wherein the light source used in the indoor growing environment is a LED light source; the LED light source consists of 12.6% blue light, 37% green light, and 50.4% red light; the ratio of a photon number of the blue light to a photon number of the red light is 1:4; an initial light intensity is 80 μmol/m.sup.2s, a maximum light intensity is 1000 μmol/m.sup.2s, and a photoperiod is 10-16 h/d.

2. The method of claim 1, wherein a blue light has a peak wavelength at 440-460 nm, a red light has a peak wavelength at 655-690 nm.

3. The method of claim 1, wherein the LED light source is realized directly by a LED chip or by using the LED chip to excite a phosphor material.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a spectral distribution diagram from a LED light source which is realized directly by a LED chip according to the present disclosure.

(2) FIG. 2 is a spectral distribution diagram from a LED light source which is realized by using the LED chip to excite a phosphor material according to the present disclosure.

DETAILED DESCRIPTION OF THE INVENTION

(3) The present disclosure will be further described in detail below with reference to the drawings and specific embodiments, in order to better understand the objective, the technical solution and the advantage of the present disclosure. It should be understood that the specific embodiments described herein are merely illustrative and are not intended to limit the scope of the disclosure.

(4) In the early stage of treatment to cannabis seedling, top branches of strong cannabis mother plant are selected as stem cuttings for plant cutting, or cannabis seeds are selected for sowing. The seedling stage is about 2 weeks. The cannabis seedlings with good rooting conditions are transplanted into the substrate or rock wool for the vegetative growth phase (the vegetative growth stage is about 4 weeks). Each rock wool block has 1 plant, and a density for the transplanted cannabis seedlings is 9 plants/m.sup.2. The plant is topped when the plant is about 20 cm high for triggering the growth of side branches. After the vegetative growth stage is finished, the plant is moved to the flower promotion stage for flower promotion treatment. The planting density of the plant in the flower promotion stage is 4-6 plants/m.sup.2. A distinguishment to the male and female flowers is required. The male flowers will be removed, and the female plants will be cultivated. The cultivation environment is set to have a day and night temperature at 24-26° C./21-22° C., humidity at 60-70%, CO.sub.2 concentration at 10000 ppm. Throughout the growth process, the LED light source directly realized by the LED chip is an artificial light source. The spectrum distribution diagram directly realized by the LED chip is shown in FIG. 1. The LED light source as shown provides a light environment for the growth of cannabis. An initial light intensity is set to 80-100 μmol/m.sup.2s. As the plant height increases, the light intensity may reach 500-1000 μmol/m.sup.2s in the late stage, and the photoperiod is 10-16 h/d. After 7-9 weeks of growth at the flowering stage, the accumulation of CBD and THC level, the cannabinoid substances in plants, would be promoted.

Embodiment 1

(5) Top branches of strong cannabis mother plant are selected as stem cuttings for plant cutting. After the plant cutting is finished (the plant cutting stage is about 2 weeks), the cannabis seedlings with good rooting conditions are transplanted into the rock wool or the substrate for the vegetative growth phase (the vegetative growth stage is about 4 weeks). Each rock wool block has 1 plant, and a density for the transplanted cannabis seedlings is 9 plants/m.sup.2. The plant is topped when the plant is about 20 cm high for triggering the growth of side branches. After the vegetative growth stage is finished, the plant is moved to the flower promotion stage for flower promotion treatment. The planting density of the plant in the flower promotion stage is 4 plants/m.sup.2. A distinguishment to the male and female flowers is required. The male flowers are removed, and the female plants is cultivated as before. The cultivation environment is set to have a day and night temperature at 24-26° C./21-22° C., humidity at 60-70%, CO.sub.2 concentration at 10000 ppm. Throughout the growth process, the LED light source is used to provide a light environment for the growth of the plant. An initial light intensity is set to 100 μmol/m.sup.2s. As the plant height increases, the light intensity reaches 550 μmol/m.sup.2s in the late stage, and the photoperiod is 12 h/d. Blue LED light source with a peak wavelength at 445 nm, yellow-green LED light source with a peak wavelength at 545 nm, and yellow-green LED light source with a peak wavelength 571 nm are provided as control examples 1-3, respectively. Green LED light sources with peak wavelengths at 505 nm, 515 nm, 523 nm, 526 nm are provided as experimental examples 1-4, respectively. When harvesting, the CBD and THC levels in the cannabis plant are determined, and the dry weight of the inflorescence is collected at the same time to calculate the yields of CBD and THC per plant. The experimental results are shown in Table 1.

(6) TABLE-US-00001 TABLE 1 Peak CBD THC CBD THC Ind. WL/ level level Inflorescence yield yield Irradiation nm (%) (%) DW g/plant g/plant g/plant Cont. Ex. 1 445 5.11 4.47 58.65 3.00 2.62 Cont. Ex. 2 545 5.19 4.56 73.53 3.82 3.35 Cont. Ex. 3 571 5.21 4.55 71.42 3.72 3.25 Exptl. Ex. 1 505 5.46 4.75 72.59 3.96 3.45 Exptl. Ex. 2 515 5.68 4.91 76.38 4.34 3.75 Exptl. Ex. 3 523 5.61 4.84 76.49 4.29 3.69 Exptl. Ex. 4 526 5.44 4.77 75.49 4.11 3.60

(7) The results suggest that the green light sources in experimental examples 1-4 are more effective than the light sources in control examples 1-3 in improving the levels of THC and CBD. Besides, the green light with peak wavelength at 515 nm is the most effective one which improves the levels of THC and CBD up to 11.15%. At the same time, the green light sources in experimental examples 1-4 are also good for the accumulation of inflorescence weight in cannabis, and improving the yields of CBD and THC per plant.

Embodiment 2

(8) Top branches of strong cannabis mother plant are selected as stem cuttings for plant cutting. After the plant cutting is finished (the plant cutting stage is about 2 weeks), the cannabis seedlings with good rooting conditions are transplanted into the rock wool or the substrate for the vegetative growth phase (the vegetative growth stage is about 4 weeks). Each rock wool block has 1 plant, and a density for the transplanted cannabis seedlings is 9 plants/m.sup.2. The plant is topped when the plant is about 20 cm high for triggering the growth of side branches. After the vegetative growth stage is finished, the plant is moved to the flower promotion stage for flower promotion treatment. The planting density of the plant in the flower promotion stage is 4 plants/m.sup.2. A distinguishment to the male and female flowers is required. The male flowers are removed, and the female plants is cultivated as before. The cultivation environment is set to have a day and night temperature at 24-26° C./21-22° C., humidity at 60-70%, CO.sub.2 concentration at 10000 ppm. Throughout the growth process, the LED light source is used to provide a light environment for the growth of the plant. An initial light intensity is set to 100 μmol/m.sup.2s. As the plant height increases, the light intensity reaches 750 μmol/m.sup.2s in the late stage, and the photoperiod is 12 h/d. Five control examples (Cont. Ex. 4-8 as shown in Table 2) and five experimental examples (Exptl. Ex. 5-9 as shown in Table 2) are provided. Green lights with different ratio are arranged. The blue light has a peak wavelength at 450 nm. The red light has a peak wavelength at 660 nm. The green light has a peak wavelength at 526 nm. At the same time, a ratio of the photon numbers between the red light (600-780 nm) and the photon number of the blue light (400-499 nm) is 4:1. When harvesting, the levels of THC and CBD in the cannabis are determined, and the dry weight of the inflorescence is collected at the same time to calculate the yields of THC and CBD per single plant. The experimental results are shown in Table 2.

(9) TABLE-US-00002 TABLE 2 Spectral composition and Peak characteristics X1, X2, X3, Ratio of Ratio of Ratio of 400-499 nm 500-599 nm 600-780 nm photons in photons in photons in 380-780 380-780 380-780 Biological indicators nm light nm light nm light CBD THC Inflorescence CBD THC source source source level level DW yield yield SN (%) (%) (%) (%) (%) g/plant g/plant g/plant Cont. 20 0 80 10.43 3.42 140.69 14.67 4.81 Ex. 4 Cont. 18.8 6 75.2 10.66 3.49 135.19 14.41 4.72 Ex. 5 Cont. 17.6 12 70.4 10.98 3.62 137.48 15.10 4.98 Ex. 6 Cont. 10.2 49 40.8 10.85 3.56 133.76 14.51 4.76 Ex. 7 Cont. 8.8 56 35.2 10.54 3.46 132.49 13.96 4.58 Ex. 8 Exptl. 16.4 18 65.6 11.24 3.88 147.36 16.56 5.72 Ex. 5 Exptl. 15 25 60 11.45 4.01 146.57 16.78 5.88 Ex 6 Exptl. 13.8 31 55.2 11.67 4.08 149.21 17.41 6.09 Ex 7 Exptl. 12.6 37 50.4 11.78 4.15 148.34 17.47 6.16 Ex 8 Exptl. 11.6 42 46.4 11.41 4.03 145.09 16.55 5.85 Ex 9

(10) The results suggest that it is possible to improve the levels of THC and CBD by adding into the combination of red light and blue light with different ratio of green light as shown in experimental examples 5-9, compared with the control examples 4-8. Compared with the control example 4, the CBD level and THC level in the experimental example 8 have been increased up to 12.94% and 21.35%, respectively. At the same time, it is beneficial to improve the accumulation of inflorescence weight of cannabis and increase the yields of CBD and THC per plant by adding into the combination of red light and blue light with different ratio of green light.

Embodiment 3

(11) Top branches of strong cannabis mother plant are selected as stem cuttings for plant cutting. After the plant cutting is finished (the plant cutting stage is about 2 weeks), the cannabis seedlings with good rooting conditions are transplanted into the rock wool or the substrate for the vegetative growth phase (the vegetative growth stage is about 4 weeks). Each rock wool block has 1 plant, and a density for the transplanted cannabis seedlings is 9 plants/m.sup.2. The plant is topped when the plant is about 20 cm high for triggering the growth of side branches. After the vegetative growth stage is finished, the plant is moved to the flower promotion stage for flower promotion treatment. The planting density of the plant in the flower promotion stage is 4 plants/m.sup.2. A distinguishment to the male and female flowers is required. The male flowers are removed, and the female plants is cultivated as before. The cultivation environment is set to have a day and night temperature at 24-26° C./21-22° C., humidity at 60-70%, CO.sub.2 concentration at 10000 ppm. Throughout the growth process, the LED light source is used to provide a light environment for the growth of the plant. An initial light intensity is set to 100 μmol/m.sup.2s. As the plant height increases, the light intensity reaches 800 μmol/m.sup.2s in the late stage, and the photoperiod is 12 h/d. A light source composed of 20% blue light and 80% red light is provided as the control example 9, wherein the blue light has a peak wavelength at 445 nm, the red light has a peak wavelength at 660 nm. On this basis, same ratio of green lights having different peak wavelengths being added in the control example 3 are provided as experimental examples 11-15 (Table 3). The experimental examples 11-20 also satisfy that a ratio of photon numbers between the red light (600-780 nm) and the blue light (400-499 nm) is 4:1. When harvesting, the levels of CBD and THC in the cannabis are determined, and the dry weight of the inflorescence is collected at the same time to calculate the yields of CBD and THC per plant. The experimental results are shown in Table 3.

(12) TABLE-US-00003 TABLE 3 Spectral composition and Peak characteristics X1, X2, X3, Ratio of Ratio of Ratio of 400-499 500-599 600-780 nm nm nm photons photons photons in in in 380-780 380-780 380-780 Biological indicators nm light nm light nm light Green CBD THC Inflorescence CBD THC source source source peak level level DW yield yield SN (%) (%) (%) WL (%) (%) g/plant g/plant g/plant Cont. 20 0 80 — 7.79 6.12 110.53 8.61 6.76 Ex. 9 Cont. 16 20 64 535 8.18 6.38 114.06 9.33 7.28 Ex. 10 Cont. 16 20 64 545 8.13 6.33 113.72 9.25 7.20 Ex. 11 Cont. 16 20 64 571 8.09 6.29 110.25 8.92 6.93 Ex. 12 Exptl. 16 20 64 505 8.34 6.54 112.45 9.38 7.35 Ex. 10 Exptl. 16 20 64 511 8.51 6.70 114.38 9.73 7.66 Ex. 11 Exptl. 16 20 64 515 8.65 6.78 115.42 9.98 7.83 Ex 12 Exptl. 16 20 64 520 8.48 6.67 116.87 9.91 7.80 Ex 13 Exptl. 16 20 64 523 8.43 6.64 117.06 9.87 7.77 Ex 14 Exptl. 16 20 64 526 8.35 6.48 114.39 9.55 7.41 Ex 15

(13) The results suggest that, compared with control examples 9-12, the light sources in experimental examples 10-15 will greatly improve the levels of THC and CBD in cannabis. More specifically, compared with control example 9, the light source in experimental example 12 improves the levels of CBD and THC up to 11.04% and 10.78%, respectively. At the same time, the green light is beneficial to improve the accumulation of inflorescence weight of cannabis and increase the yields of CBD and THC per plant.

(14) In summary, plants experience different light qualities through photoreceptors such as phytochromes and cryptochromes. The light absorbed by plants is concentrated in the visible part of the wavelength range of 380 to 780 nm. Red light accounts for about 85% of the absorbed physiological radiation light energy, and blue light accounts for about 12%. Therefore, the red light and blue light are essential light qualities for plant growth. The red light is mainly used to generate assimilate and accumulate biomass, and the blue light is a necessary condition for chlorophyll synthesis and chloroplast formation. The blue light affects the morphology of plants by controlling the stomata shape. At the same time, the blue light can also promote the accumulation of secondary metabolites in plants. Green light has always been a controversial light quality. Some scholars believe that it will inhibit the growth of plants, cause short plants and reduce the yield of leafy vegetables. In the present disclosure, under the proof of the above-mentioned embodiments, it is preferable to supplement 18-42% of green light on the basis of red and blue light, which is more effective for promoting accumulation of levels and yields of CBD and THC in cannabis. Therefore, different plants may have different optimal spectral formula during growth. The special spectral formula for cannabis as provided may enable the cannabis to accumulate and synthesize more THC and CBD, secondary metabolites in the cannabis, during the industrial cultivation.

(15) It should be noted that the aforementioned embodiments are merely preferred embodiments of the present disclosure, and those embodiments are not to be deemed as limiting the scope of the invention. The scope of the disclosure should be limited by the by the scope of the claims. It will be apparent to those skilled in the art that other modifications and changes may be made without departing from the spirit and scope of the disclosure.