CN116965409A

CN116965409A - Pesticide composition containing menthone

Info

Publication number: CN116965409A
Application number: CN202311019794.1A
Authority: CN
Inventors: 刘润强; 周锋; 罗奥迪; 毋正花; 徐莉; 周琳
Original assignee: Henan Institute of Science and Technology
Current assignee: Henan Institute of Science and Technology
Priority date: 2023-08-14
Filing date: 2023-08-14
Publication date: 2023-10-31

Abstract

The invention belongs to the technical field of pesticides, and particularly relates to a pesticide composition containing menthone. A pesticide composition containing menthone contains osthole or eugenol and menthone as effective components. The osthole or eugenol and menthone are compounded according to a certain quality, a synergistic effect is shown on various plant pathogenic fungi, the control effect on plant diseases can be improved, data support is provided for effective control of wheat stem rot, wheat scab, peanut root rot, peanut southern blight and corn scab, and the osthole or eugenol and menthone compound feed additive has important significance on high quality and high yield of crops such as wheat, peanut and corn.

Description

Pesticide composition containing menthone

Technical Field

The invention belongs to the technical field of pesticides, and particularly relates to a pesticide composition containing menthone.

Background

The occurrence of diseases causes great threat to agricultural production, and the use of chemical pesticides plays an important role in preventing, controlling crop diseases, ensuring stable yield and high yield of agricultural and forestry crops and the like. However, long-term application of chemical pesticides is easy to cause poisoning of people and livestock, high residue, environmental pollution and other consequences, and hidden danger is brought to ecological environment and human health.

The plant source bactericide is one medicine prepared with some parts of plant with bactericidal and bacteriostatic activity and extracted effective components and separated and purified monomer matter and through processing. The botanical fungicide gradually becomes a hot spot for controlling plant diseases due to the unique advantages of high efficiency, low toxicity, low residue, high selectivity, small influence on environment and the like. At present, scholars at home and abroad have conducted a great deal of research on the aspect of controlling fungal diseases by using a plant source bactericide, and find a plurality of plant resources with bactericidal action, which provides important basis for disease control research by using the plant source bactericide.

Currently, a plurality of plant source bactericides including ethylicin, kasugamycin, eugenol, carvacrol, osthole and the like exist in the market, are popularized and applied to the prevention and treatment of various crop diseases, and achieve remarkable prevention and treatment effects. For example Wang Zhifeng, eugenol has a strong antifungal effect and has a control effect of 78% on tomato late blight; peng Zhiguo and the like report that the control effect of the 1% osthole on powdery mildew of cucumber in a greenhouse reaches 79.33%; sun Xuemei the control effect of the ethylicin, kasugamycin, ningnanmycin and Zhongshengmycin on strawberry leaf spot disease can reach more than 80% through root dipping treatment; meanwhile, the latest researches of Zheng Anke and the like show that 9 plant source bactericides such as eugenol, allicin and osthole to be tested have an inhibiting effect on sunflower rust bacteria, 0.3% eugenol has the strongest toxicity, and the inhibiting effect is as high as more than 85%, and further show that the plant source bactericides have stronger potential for preventing and controlling plant diseases.

Menthone belongs to monoterpene compounds, widely exists in volatile oils of various plants such as peppermint, schizonepeta, baical skullcap root, wrinkled giant hyssop and the like, and researches show that the menthone has the effects of resisting viruses, resisting inflammation, promoting bile flow, promoting permeation and the like. At present, menthone and derivatives thereof are relatively widely applied in medicine and mainly used as local anesthetic, protective agent and the like, but are reported in the research process of plant diseases.

The prior researches of the inventor find that the menthone has better antibacterial effects on wheat stem basal rot, wheat scab, peanut root rot, peanut southern blight, corn scab and the like, and has better disease prevention and control potential. In order to further use menthone to develop plant disease prevention and control, the inventor develops compound researches on menthone, magnolol, carvacrol, oregano oil, osthole, eugenol, resveratrol, garlicin and other plant source bactericides, and partial compound combinations of the plant source bactericides show a strong synergistic effect, and the research results provide data support for effective prevention and control of wheat stem rot, wheat scab, peanut root rot, peanut southern blight and corn scab and have important significance for high quality and high yield of crops such as wheat, peanut and corn.

The information disclosed in this background section is only for enhancement of understanding of the general background of the invention and should not be taken as an acknowledgement or any form of suggestion that this information forms the prior art already known to a person of ordinary skill in the art.

Disclosure of Invention

The invention aims to provide a menthone-containing pesticide composition which can effectively inhibit the growth of pathogenic bacteria such as wheat stem rot, wheat scab, peanut root rot, peanut southern blight, corn scab and the like, effectively prevent and control various plant fungal diseases, and has important significance for the high quality and high yield of crops such as wheat, peanut, corn and the like.

In order to achieve the above purpose, the present invention provides the following technical solutions:

a pesticide composition containing menthone contains osthole or eugenol and menthone as effective components.

Preferably, the mass ratio of osthole to menthone is 1-9:9-1.

Preferably, the mass ratio of eugenol to menthone is 1-9:9-1.

The invention also provides application of the menthone-containing pesticide composition in preventing and controlling fungal diseases of crops.

Preferably, the crop fungal diseases include wheat stem rot, wheat scab, peanut root rot, peanut southern blight and corn scab.

Compared with the prior art, the invention has the following beneficial effects:

the osthole or eugenol and menthone are compounded according to a certain quality, a synergistic effect is shown on pathogenic bacteria of various plant fungal diseases, the control effect on plant diseases can be improved, data support is provided for effective control of wheat stem rot, wheat scab, peanut root rot, peanut southern blight and corn scab, and the osthole or eugenol and menthone compound feed additive has important significance on high quality and high yield of crops such as wheat, peanut and corn.

Detailed Description

The following is a clear and complete description of the technical solutions of the present patent.

Examples

1. Test strain

TABLE 1 test strains

2. Test agent

98% osthole (Shanghai Yuan Ye Biotechnology Limited), 98.5% eugenol (Shanghai Yuan Ye Biotechnology Limited), 99% menthone (Wuhan Rong Bright Biotechnology Co., ltd.).

After the test agent is dissolved, diluting the test agent into a single-agent mother solution by using 0.1% Tween-80 aqueous solution, setting a plurality of groups of proportions, and setting 5 mass concentration gradients of each single-agent mother solution and each proportion mixture according to an equal proportion method.

3. Test method

Adding 9mL of pre-melted PDA culture medium into a sterile conical flask, sequentially quantitatively sucking 1mL of liquid medicine from low concentration to high concentration, respectively adding into the conical flask, fully shaking uniformly, pouring into 1 culture dishes with the diameter of 9cm, preparing medicine-containing flat plates with corresponding concentrations, simultaneously setting treatment without medicines as blank control, and treating 10 flat plates with each liquid medicine with the mass concentration. Cutting bacterial cake at the colony edge of the tested bacterial strain by using a puncher with the diameter of 5mm, inoculating the bacterial cake to the centers of a medicine-containing flat plate and a blank control flat plate, covering a dish cover, and placing the dish cover in a constant temperature oven at 25 ℃ for cultivation. When the diameter of the blank control colony grows to about 2/3 of the diameter of the culture dish, measuring the colony diameter by a crisscross method, and calculating the inhibition rate of different treatments on hypha growth.

4. Data analysis

Data statistics analysis is carried out by adopting DPS software to obtain a virulence regression equation and virulence EC of the medicament on target bacteria ₅₀ Values and co-toxicity coefficients (CTCs) were calculated according to the grand cloud Pei method.

In the above formula: the toxicity index measured by the ATI-mixed agent; EC of S-standard agent ₅₀ The unit is mg/L; EC of M-mixture ₅₀ The unit is mg/L.

TTI＝TI _A ×P _A +TI _B ×P _B

In the above formula: theoretical toxicological index of TTI-blends; TI (TI) _A -a toxicity index of the agent; p (P) _A -a percentage of agent in the mix in percent (%); TI (TI) _B -a toxicity index of the B agent; p (P) _B The percentage of agent B in the mixture is expressed as a percentage (%).

In the above formula: CTC-co-toxicity coefficient; the ATI-mixed agent actually measures the toxicity index; TTI-blend theoretical virulence index.

5. Measurement results

The synergy of the agents was evaluated based on the calculated co-toxicity coefficient (CTC), CTC.ltoreq.80 being antagonism, CTC.ltoreq.120 being additive, CTC.ltoreq.120 being synergy, the results are shown in tables 2-17.

TABLE 2 determination of indoor biological Activity of cnidium lactone and menthone Complex to Rhizoctonia cerealis

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Osthole	24.8923	100.0000	--	--
Menthone	59.6386	41.7386	--	--
					Osthole 9: menthone 1	20.1431	123.5773	94.1739	131.2225
Osthole 8: menthone 2	21.8283	114.0368	88.3477	129.0773
					Osthole 7: menthone 3	22.2765	111.7424	82.5216	135.4100
Osthole 6: menthone 4	21.7146	114.6339	76.6954	149.4664
					Osthole 5: menthone 5	23.3722	106.5039	70.8693	150.2821
Osthole 4: menthone 6	38.7564	64.2276	65.0431	98.7461
					Osthole 3: peppermint (peppermint)Ketone 7	34.4018	72.3576	59.2170	122.1905
Osthole 2: menthone 8	44.3738	56.0968	53.3909	105.0683
					Osthole 1: menthone 9	57.7690	43.0894	47.5647	90.5910

From Table 2, it can be seen that the aligned micronucleus bacteria show excellent antibacterial activity after the osthole and the menthone are compounded. When the compounding ratio of osthole to menthone is 4: 6. 2:8 and 1:9, the compound combination and alignment sclerotium rolfsii show additive effect; the co-toxicity coefficients of the other compound combinations and the aligned sclerotium rolfsii are all larger than 120, and the synergistic effect is shown.

Table 3 determination of indoor biological Activity of osthole and menthone Complex against Fusarium pseudograminearum

From Table 3, it can be seen that osthole and menthone show excellent antibacterial activity against Fusarium pseudograminearum after being compounded. When the compounding ratio of osthole to menthone is 9: 1. 8: 2. 2:8 and 1: at 9, the addition is performed; the co-toxicity coefficient of the other compound combinations on the fusarium pseudograminearum is more than 120, and the synergistic effect is shown.

TABLE 4 determination of indoor biological Activity of cnidium lactone and menthone compounded Rhizoctonia solani

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Osthole	37.6274	100.0000	--	--
Menthone	30.6867	122.6179	--	--
					Osthole 9: menthone 1	30.3438	124.0036	102.2618	121.2609
Osthole 8: menthone 2	26.2394	143.4004	104.5236	137.1943
					Osthole 7: menthone 3	26.4953	142.0154	106.7854	132.9914
Osthole 6: menthone 4	27.2942	137.8586	109.0472	126.4211
					Osthole 5: menthone 5	26.8867	139.9480	111.3090	125.7293
Osthole 4: menthone 6	30.5143	123.3107	113.5708	108.5761
					Osthole 3: menthone 7	33.1192	113.6120	115.8326	98.0830
Osthole 2: menthone 8	36.2103	103.9135	118.0944	87.9920
					Osthole 1: menthone 9	48.0668	78.2815	120.3561	65.0415

From table 4, it can be seen that osthole and menthone show excellent antibacterial activity against rhizoctonia solani after being compounded. When the compounding ratio of osthole to menthone is 9-5:1-5, the co-toxicity coefficients of the compound combination against rhizoctonia solani are all larger than 120, and the synergistic effect is shown.

TABLE 5 determination of indoor biological Activity of osthole and menthone Complex Fusarium pseudograminearum

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Osthole	15.1544	100.0000	--	--
Menthone	58.2502	26.0160	--	--
					Osthole 9: menthone 1	13.3715	113.3336	92.6016	122.3884
Osthole 8: menthone 2	13.7767	110.0002	85.2032	129.1034
					Osthole 7: menthone 3	15.1544	100.0000	77.8048	128.5268
Osthole 6: menthone 4	14.4328	104.9997	70.4064	149.1337
					Osthole 5: menthone 5	13.7757	110.0082	63.0080	174.5940
Osthole 4: menthone 6	13.9887	108.3332	55.6096	194.8101
					Osthole 3: menthone 7	17.1559	88.3335	48.2112	183.2217
Osthole 2: menthone 8	16.8382	90.0001	40.8128	220.5191
					Osthole 1: menthone 9	19.7666	76.6667	33.4144	229.4418

From table 5, it can be seen that osthole and menthone show excellent antibacterial activity against fusarium pseudograminearum after being compounded. The co-toxicity coefficient of all tested compound combinations to the fusarium pseudograminearum is more than 120, and the synergistic effect is shown.

Table 6 determination of indoor biological Activity of Fusarium roseum by cnidium lactone and menthone Complex

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Osthole	10.8644	100.0000	--	--
Menthone	110.2090	9.8580	--	--
					Osthole 9: menthone 1	10.6534	101.9806	90.9858	112.0841
Osthole 8: menthone 2	8.3764	129.7025	81.9716	158.2286
					Osthole 7: menthone 3	8.5062	127.7233	72.9574	175.0656
Osthole 6: menthone 4	8.9212	121.7818	63.9432	190.4531
					Osthole 5: menthone 5	9.2992	116.8316	54.9290	212.6956
Osthole 4: menthone 6	10.9730	99.0103	45.9148	215.6392
					Osthole 3: menthone 7	12.4693	87.1292	36.9006	236.1186
Osthole 2: menthone 8	15.4550	70.2970	27.8864	252.0834

Table 6 shows that osthole and menthone show excellent antibacterial activity against Fusarium rubrum after being compounded. When the compounding ratio of osthole to menthone is 8-1:2-9, the co-toxicity coefficient of the compound combination on Fusarium rubrum is more than 120, and the synergistic effect is shown.

TABLE 7 indoor biological Activity determination of osthole and menthone Complex Fusarium equisetum

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Osthole	26.1725	100.0000	--	--
Menthone	145.5956	17.9762	--	--
					Osthole 9: menthone 1	22.2745	117.4998	91.7976	127.9988
Osthole 8: menthone 2	20.5275	127.4997	83.5952	152.5203
					Osthole 7: menthone 3	26.1725	100.0000	75.3928	132.6386
Osthole 6: menthone 4	33.7710	77.4999	67.1905	115.3436
					Osthole 5: menthone 5	45.5174	57.5000	58.9881	97.4773
Osthole 4: menthone 6	55.1000	47.5000	50.7857	93.5303
					Osthole 3: menthone 7	95.1727	27.5000	42.5833	64.5793
Osthole 2: menthone 8	116.3222	22.5000	34.3809	65.4433
					Osthole 1: menthone 9	174.4833	15.0000	26.1785	57.2988

From Table 7, it is clear that osthole and menthone show excellent antibacterial activity against Fusarium equisetum after being compounded. When the compounding ratio of osthole to menthone is 9-7:1-3, the co-toxicity coefficient of the compound combination on the fusarium equiseti is more than 120, and the synergistic effect is shown.

Table 8 determination of indoor biological Activity of Fusarium on the layer compounded with osthole and menthone

From table 8, it can be seen that osthole and menthone show excellent antibacterial activity against fusarium. When the compounding ratio of osthole to menthone is 8: 2. 6:4 and 5:5, the compound combination shows a synergistic effect on fusarium.

Table 9 determination of indoor biological Activity of Fusarium oxysporum compounded with osthole

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Osthole	25.7242	100.0000	--	--
Menthone	144.7977	17.7656	--	--
					Osthole 9: menthone 1	25.0968	102.4999	91.7766	111.6842
Osthole 8: menthone 2	21.8929	117.5002	83.5531	140.6293
					Osthole 7: menthone 3	27.8099	92.5002	75.3297	122.7938
Osthole 6: menthone 4	25.0968	102.4999	67.1062	152.7427
					Osthole 5: menthone 5	36.7488	70.0001	58.8828	118.8804
Osthole 4: menthone 6	44.7377	57.5001	50.6594	113.5033
					Osthole 3: menthone 7	57.1648	45.0001	42.4359	106.0424
Osthole 2: menthone 8	79.1513	32.5000	34.2125	94.9946
					Osthole 1: menthone 9	85.7473	30.0000	25.9891	115.4333

From Table 9, it is clear that osthole and menthone show excellent antibacterial activity against Fusarium oxysporum after being compounded. When the compounding ratio of osthole to menthone is 8-6:2-4, the compound combination shows a synergistic effect on fusarium oxysporum.

TABLE 10 determination of indoor biological Activity of eugenol and menthone Complex to Rhizoctonia cerealis

From table 10, it can be seen that the aligned micronucleus exhibits excellent antibacterial activity after the eugenol and menthone are compounded. When the compounding ratio of eugenol and menthone is 2: at 8, the addition is exhibited; the co-toxicity coefficients of the other compound combinations and the aligned sclerotium rolfsii are all larger than 120, and the synergistic effect is shown.

TABLE 11 determination of indoor biological Activity of Fusarium pseudograminearum by eugenol and menthone complexation

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Eugenol	37.4238	100.0000	--	--
Menthone	80.5613	46.4538	--	--
					Eugenol 9: menthone 1	48.1114	77.7857	94.6454	82.1865
Eugenol 8: menthone 2	28.0650	133.3469	89.2908	149.3401
					Eugenol 7: menthone 3	33.6780	111.1224	83.9361	132.3892
Eugenol 6: menthone 4	31.5731	118.5306	78.5815	150.8378
					Eugenol 5: menthone 5	26.5879	140.7550	73.2269	192.2176
Eugenol 4: menthone 6	30.6164	122.2345	67.8723	180.0948
					Eugenol 3: menthone 7	91.4891	40.9052	62.5177	65.4298
Eugenol 2: menthone 8	101.0340	37.0408	57.1631	64.7985
					Eugenol 1: menthone 9	53.1758	70.3775	51.8084	135.8418

As can be seen from table 11, eugenol and menthone show excellent antibacterial activity against fusarium pseudograminearum after being compounded. When the mixing ratio of eugenol and menthone is 3:7 and 2:8, exhibit antagonism; when the mixing ratio of eugenol and menthone is 9: at 1, the addition is shown; the co-toxicity coefficient of the other compound combinations on the fusarium pseudograminearum is more than 120, and the synergistic effect is shown.

Table 12 determination of indoor biological Activity of eugenol and menthone compounded against Rhizoctonia solani

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Eugenol	11.0604	100.0000	--	--
Menthone	30.6867	36.0430	--	--
					Eugenol 9: menthone 1	10.8629	101.8181	93.6043	108.7750
Eugenol 8: menthone 2	6.6122	167.2726	87.2086	191.8075
					Eugenol 7: menthone 3	8.0043	138.1807	80.8129	170.9885
Eugenol 6: menthone 4	7.6040	145.4550	74.4172	195.4589
					Eugenol 5: menthone 5	9.3588	118.1818	68.0215	173.7419
Eugenol 4: menthone 6	6.4034	172.7270	61.6258	280.2836
					Eugenol 3: menthone 7	15.2081	72.7270	55.2301	131.6801
Eugenol 2: menthone 8	14.2505	77.6141	48.8344	158.9334
					Eugenol 1: menthone 9	11.9848	92.2869	42.4387	217.4594

From table 12, it can be seen that eugenol and menthone show excellent antibacterial activity against rhizoctonia solani after being compounded. When the mixing ratio of eugenol and menthone is 9:1, which exhibits additive action; the co-toxicity coefficient of the other compound combinations to the rhizoctonia solani is more than 120, and the synergistic effect is shown.

TABLE 13 determination of indoor biological Activity of Fusarium pseudograminearum by eugenol and menthone complexation

From table 13, it can be seen that eugenol and menthone show excellent antibacterial activity against fusarium pseudograminearum after being compounded. The co-toxicity coefficient of all tested compound combinations to the fusarium pseudograminearum is more than 120, and the synergistic effect is shown.

TABLE 14 determination of indoor biological Activity of Fusarium roseum by eugenol and menthone complexation

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Eugenol	40.5637	100.0000	--	--
Menthone	110.2090	36.8062	--	--
					Eugenol 9: menthone 1	13.8510	292.8576	93.6806	312.6128
Eugenol 8: menthone 2	14.5613	278.5720	87.3612	318.8737
					Eugenol 7: menthone 3	11.1351	364.2868	81.0418	449.5046
Eugenol 6: menthone 4	17.7466	228.5717	74.7225	305.8942
					Eugenol 5: menthone 5	9.3097	435.7144	68.4031	636.9806
Eugenol 4: menthone 6	12.9066	314.2865	62.0837	506.2303
					Eugenol 3: menthone 7	13.2068	307.1425	55.7643	550.7869
Eugenol 2: menthone 8	19.5825	207.1426	49.4449	418.9360
					Eugenol 1: menthone 9	63.0991	64.2857	43.1255	149.0664

As can be seen from table 14, eugenol and menthone showed excellent bacteriostatic activity against fusarium erythropolis after being compounded. The co-toxicity coefficient of all tested compound combinations on Fusarium rubrum is more than 120, and the synergistic effect is shown.

Table 15 determination of indoor biological Activity of Fusarium equisetum by complexing eugenol with menthone

From table 15, it can be seen that eugenol and menthone show excellent antibacterial activity against fusarium equiseti after being compounded. The co-toxicity coefficient of all tested compound combinations to the fusarium equiseti is more than 120, and the synergistic effect is shown.

TABLE 16 determination of indoor biological Activity of Fusarium species by complexing eugenol with menthone

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Eugenol	255.7452	100.0000	--	--
Menthone	114.0774	177.5054	--	--
					Eugenol 9: menthone 1	45.6310	560.4637	107.7505	520.1493
Eugenol 8: menthone 2	8.7752	2914.4088	115.5011	2523.2740
					Eugenol 7: menthone 3	9.5065	2690.2141	123.2516	2182.7006
Eugenol 6: menthone 4	11.4077	2241.8647	131.0022	1711.3188
					Eugenol 5: menthone 5	9.9198	2578.1286	138.7527	1858.0744
Eugenol 4: menthone 6	7.1298	3586.9898	146.5033	2448.4028
					Eugenol 3: menthone 7	114.0774	224.1857	154.2538	145.3356
Eugenol 2: menthone 8	38.0258	672.5571	162.0043	415.1476
					Eugenol 1: menthone 9	12.0081	2129.7724	169.7549	1254.6163

As can be seen from table 16, eugenol and menthone showed excellent bacteriostatic activity against fusarium sp. The co-toxicity coefficient of the fusarium on the opposite layer of all tested compound combinations is more than 120, and the synergistic effect is shown, especially when the mass ratio is 8:2, the co-toxicity coefficient reaches 2523.2740, and the synergy is most remarkable.

Table 17 determination of indoor biological Activity of Fusarium oxysporum compounded with eugenol and menthone

Medicament name and ratio	EC ₅₀ (mg/L)	ATI	TTI	CTC
					Eugenol	117.3203	100.0000	--	--
Menthone	144.7977	81.0236	--	--
					Eugenol 9: menthone 1	93.0471	126.0870	98.1024	128.5260
Eugenol 8: menthone 2	41.5133	282.6089	96.2047	293.7579
					Eugenol 7: menthone 3	84.3240	139.1304	94.3071	147.5291
Eugenol 6: menthone 4	87.0441	134.7826	92.4094	145.8537
					Eugenol 5: menthone 5	67.4592	173.9130	90.5118	192.1440
Eugenol 4: menthone 6	56.2160	208.6956	88.6142	235.5104
					Eugenol 3: menthone 7	93.0471	126.0870	86.7165	145.4014
Eugenol 2: menthone 8	91.5469	128.1532	84.8189	151.0905
					Eugenol 1: menthone 9	112.4320	104.3478	82.9212	125.8396

From Table 17, it is clear that eugenol and menthone show excellent antibacterial activity against Fusarium oxysporum after being compounded. The co-toxicity coefficient of all tested compound combinations to fusarium oxysporum is more than 120, and the synergistic effect is shown.

In conclusion, the osthole or eugenol and the menthone are compounded according to a certain mass, so that a synergistic effect is shown on pathogenic bacteria of various plant fungal diseases, the control effect on plant diseases can be improved, data support is provided for effective control of wheat stem rot, wheat scab, peanut root rot, peanut southern blight and corn scab, and the osthole or eugenol and eugenol are of great significance to high quality and high yield of crops such as wheat, peanut and corn.

The foregoing descriptions of specific exemplary embodiments of the present invention are presented for purposes of illustration and description. It is not intended to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain the specific principles of the invention and its practical application to thereby enable one skilled in the art to make and utilize the invention in various exemplary embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims and their equivalents.

Claims

1. The sterilizing composition containing menthone is characterized in that the effective component is compounded by osthole or eugenol and menthone.

2. The menthone-containing bactericidal composition according to claim 1, wherein the mass ratio of osthole to menthone is 1-9:9-1.

3. The menthone-containing bactericidal composition according to claim 1, wherein the mass ratio of eugenol to menthone is 1-9:9-1.

4. Use of a bactericidal composition containing menthone according to any of claims 1-3 for controlling fungal diseases of crops.

5. The use according to claim 4, wherein the crop fungal diseases include wheat stem rot, wheat scab, peanut root rot, peanut southern blight and corn scab.