Plant-Based Pesticide

Abstract

Cucurbitaceae family snake gourd (Trichosanthes anguina L.), grown in many Asian countries and Southern US States; characteristic aroma, green, tender stems, forked tendrils, heart-shaped shaped or palmately broad leaves; long lacy fringed, five-petalled, day-night open, white unisexual flowers; multifarious health benefiting fruits; resists major fungal, bacterial, and viral diseases, repels aphids, insects, and beetles (Cerotoma trifurcata) from pumpkin, squash, and bean plants if interposed among the target vines (U.S. patent application Ser. No. 17/942,119); claimed commercial use of the intensely aromatic distinct variety of Trichosanthes cucumerina summer plant extract/oil or synthetically prepared the same aromatic product for uniformly spraying upon the target vines and testing on other target fruit vines, fruit plants, and fruit trees, and vegetable plants throughout the year; potential replacement for bee-killing, water resources polluting, human, aquatics, and wildlife infecting chemical pesticides like Sevin, Malathion, Diazinon, and Neonicotinoids (Neonics), and replacement for manually killing of pests.

Claims

1. A new and distinct variety of fruit vine of the Cucurbitaceae class (Trichosanthes anguina L.), substantially as herein shown and described, characterized by intense aroma, rapid growth; tender stems, forked tendrils, heart-shaped or palmately broad green leaves, and five-petalled, long lacy fringed white unisexual day-night open flowers; oddly shaped waxy green or white skinned fruits; major fungal, bacterial, viral diseases resistant; aphids, insects, beetles (Cerotoma trifurcata) repellant from pumpkin, squash, and bean plants if the said vine is interposed among these target vines (U.S. patent application Ser. No. 17/942,119). The plant replaces bee-killing, water resources-polluting, and humans-, aquatics-, and wildlife-endangering pesticides like Sevin, Malathion, Diazinon, and Neonicotinoids (Neonics); also, eliminates manual killing of pests. Claimed commercial use of the 1. Characteristic aroma-containing plant extract/oil can be uniformly sprayed upon the said target plants and on other potential target plants, vegetables, and fruit trees throughout the year. 2. Synthetically prepared the same aromatic product can be used for the same purpose as in #1 above.

Description

BRIEF DESCRIPTION OF THE PHOTOGRAPHS

[0021] About 60 pests-repellant plants are mentioned in https://en.wikipedia.org/wiki/List_of_pest-repelling_plants. Snake gourd is not there.

[0022] The accompanying illustrations show typical specimens of the vegetative growth, flowers, and variety in colors and sizes as true as reasonably possible. Also, the illustrations show the pesticide uses and water resources contamination.

[0023] FIG. 1. Whitestripped greenskinned snake gourd in the applicant's garden.

[0024] FIG. 2. Whitestripped whiteskinned snake gourd in the applicant's garden.

[0025] FIGS. 3 and 4. Mature, ripe yellow colored snake gourd in the applicant's garden.

[0026] FIG. 5. The applicant's garden ripe snake gourd dried to take out seed.

[0027] FIG. 6. Seeds taken out from inside of a ripe snake gourd from the applicant's garden.

[0028] FIG. 7. Baby plant without tendrills in the applicant's garden.

[0029] FIG. 8. Vigorously growing plant with tendrills climbing a vertical trellis in the applicant's garden.

[0030] FIGS. 9 and 10. Vertically rising vigorously growing snake gourd plant with tendrills in the applicant's garden.

[0031] FIG. 11. Snake gourd's heart-shaped leaf in the applicant's garden.

[0032] FIG. 12. Snake gourd's 3-lobed leaf in the applicant's garden.

[0033] FIG. 13. Snake gourd's 6-lobed leaf in the applicant's garden.

[0034] FIG. 14. Snake gourd's 7-lobed leaf, five-petalled white unisexual flowers with long lacy fringes in the applicant's garden.

[0035] FIG. 15. Beetles made holes in hyacinth bean plant leaves in the applicant's garden.

[0036] FIG. 16. Spotless heart-shaped snake gourd leaves and the three-piece heart-shaped hyacinth flat bean leaves in the applicant's garden.

[0037] FIG. 17. Heart-shaped leaf, forked tendrils, and baby snake gourd of white variety, female flower with thick stem in the applicant's garden.

[0038] FIG. 18. No pumpkin beetles to lay eggs on the under side of leaves.

[0039] FIG. 19. Male flowers borne on short stalks of about equal length at equal distances along an elongated axis (peduncle length 10 to 30 cm) and open in succession toward the apex in the applicant's garden.

[0040] FIG. 20. Pumpkin leaves eaten by pumpkim bugs (https:www.shutterstock.com/image-photo/large-pumpkin-leaf-that-has-been-2133979395);

[0041] FIG. 21. Aphid-attacked hyacinth beans (http://www.aisekrishi.org/Pests/view/189/%E0%A6%B6_%E0%A6%AE_%E0%A6%B0_%E0%A6%9C_%E0%A6%AC_%E0%A6%AA_%E0%A6%95/language:bn);

[0042] FIG. 22. Bugs inside an asia hyacinth flat bean a(http://www.aisekrishi.org/Pests/view/183/%E0%A6%B6_%E0%A6%AE_%E0%A6%B0_%E 0%A6%AB%E0%A6%B2_%E0%A6%9B_%E0%A6%A6_%E0%A6%B0%E0%A6%95_%E0%A6%B0_%E0%A6%AA_%E0%A6%95/language:bn)

[0043] FIGS. 23 and 24. Pumpkin and squash bugs (ALMANAC, https://www.almanac.com/pest/squash-bugs);

[0044] FIG. 25. Flowering hyacinth bean vine in the applicants garden.

[0045] FIGS. 26 and 27. Hyacinth beans free from any pest attack in the applicants garden.

[0046] FIG. 28. Sales of pesticide industries (https://nepis.epa.gov/Exe/tiff2png.cgi/300065AN.PNG?-r+150+-g+3+D%3A%5CZYFILES%5CINDEX%20DATA%5C00THRU05%5CTIFF%5C00000683%5 C300065AN.TIF).

[0047] FIG. 29. Percentage of time (streams) or samples (ground water) with one or more detections—pesticide in water.

[0048] FIG. 30. Percentage of samples with one or more detections—oganochlorine compounds in fish and sediment. https://nepis.epa.gov/Exe/tiff2png.cgi/300065AN.PNG?-r+150+-g+3+D%3A%5CZYFILES%5CINDEX%20DATA%5C00THRU05%5CTIFF%5C00000683%5C300065AN.TIF).

[0049] FIG. 31. Percentage of stream sites or wells with one or more pesticides exceeding a human-health benchmark

[0050] FIG. 32. Percentage of stream sites with one or more pesticide compounds exceeding an aquatic life benchmark;

[0051] FIG. 33. Percentage of stream sites with one or more organochlorine pesticide compounds exceeding a wildlife benchmark 4.8% (https://pubs.usgs.gov/fs/2006/3028/#:˜:text=The%20insecticides%20diazinon%2C%20chlorpyr ifos%2C%20carbaryl,water%20as%20their%20parent%20pesticides

DETAILED DESERIVTION OF THE INVENTION

[0052] Latin name of the plant claimed: Trichosanthes anguina L

[0053] Variety: Trichosanthes cucumerina var. anguina (L.) Haines—cultivated variant [0054] Trichosanthes cucumerina var. cucumerina—wild variant

[0055] The plants phenotype is determined by both their genomic makeup (genotype) and environmental factors with variations in environmental, climatic, and cultural conditions, as it has not been tested under all possible environmental conditions.

[0056] Snake gourd, (Trichosanthes cucumerina), also known as serpent gourd, rapid-growing fruit vine belonging to the gourd family (Cucurbitaceae);

[0057] Scientific Classification: Kingdom: Plantae; Division: Magnoliophyta; Class: Mangnoliopsida; Order: Curcubitales; Family: Curcubitaceae; Genus: Trichosanthes; Species: Cucumerina;

[0058] Regional Names: Trichosanthes cucumerina is known as Chicinga in Bengali, Chichinda or Padwal in Hindi, Potlakaaya in Telugu, Pudalankaai in Tamil and Padavalanga in Malayalam, potlakaaya in Telugu, pudalankaai in Tamil, aduvalakaay in Indias Karnataks state, padavalanga, in Malayalam, Galartori in Punjabi, padavali in Gujarathi, Chachinda in Hindi; as serpent vegétal in France, Schlangengurke in Germany, Karasu-uri-zoku in Japan, Patola in Srilanka, Zucchetta cinese in Italy, Abobora-serpente in Portugal, Kaarmekurkku in Finland, Buap nguu Ma not in Thailand, Yilan kabagi in Turkey, Calabaza anguina in Spain (Devi, 2017)

[0059] Taxonomy: The plants family, predominantly distributed in the tropics, commonly known as melons, gourds or cucurbits that includes cucumbers, squashes (including pumpkins), luffas, melons (including watermelons); one of the most genetically diverse groups of food plant in the plant kingdom; Trichosanthes (100 species), Cayaponia (60 species), Momordica (47 species), Gurania (40 species), Sicyos (40 species) and Cucumis (34 species) major major genera under this family (Devi, 2017).

[0060] Biostatistics:0 Two cultivated species Trichosanthes anguina L. and Trichosanthes dioica Roxb.; Important wild species Trichosanthes bracteata (Lam.) Voigt. (Syn. Trichosanthes palmata Roxb.), largely variable Trichosanthes cucumerina L., Trichosanthes lobata, Trichosanthes wallichiana (syn. Trichosanthes multiloba Clarke), Trichosanthes nervifolia L., Trichosanthes cordata Roxb., Trichosanthes japonica and Trichosanthes shikokiana; botanical name Trichosanthes cucumerina L., most common is Trichosanthes anguina L. (Devi, 2017).

[0061] Cytology: Trichosanthes chromosomes, n=11 and 2n=22; Trichosanthes bracteate and Trichosanthes cucumeroides n=22 and 2n=44. Tetraploids (2n=44) and hexaploids (2n=66) in Trichosanthes palmate. Induced polyploids in Trichosanthes anguina quadrivalents, trivalents, bivalents and univalent; Only Trichosanthes anguina and Trichosanthes cucumerina monoecious, all others dioecious. Species with 2n-=22 chromosomes metacentric to submetacentric medium-sized (5.74 mm to 1.48 mm) chromosomes; only three pairs of chromosomes with secondary constriction in Trichosanthes anguina and Trichosanthes cucumerina; XY sex chromosomes in Trichosanthes cucumeriodes and Trichosanthes japonica at meiosis and in Trichosanthes multiloba at metaphase. Trichosanthes anguina, Trichosanthes cucumerina and Trichosanthes lobata crossable among themselves with fertile hybrids indicating their close relationship (Devi, 2017).

[0062] Seeds: Imbedded in soft red pulp in ripe snake gourd, half-ellipsoid, somewhat compressed, undulate, hard, corrugated, about 1 cm long, about ¾ cm across, greyish-brown, black, sculptured, undulate (FIG. 6).

[0063] Seedlings: Seeds planting about 1 m apart at depth about 2.5 cm in well-drained, humus-rich adequate moisture content soil with Ph 6.5-7.0 in sunny locations with at least 6 hrs direct sunlight; tiny and few or no fruits for lesser amount of sunlight; dicotyledonous seedlings with two embryonic leaves in about two weeks in temperature between 80° F. and 95° F. (27° C. to 35° C.); longer timing of weeks for seedlings in lower temperature. For temperatures nearing 100° F. and above, leaves get wilted in the scorching sun.

[0064] Plant: Monoecious annual, branchy, slender, green, disagreeable odor, stems up to 5 or 6 meters long, diameter of 5 mm, possibly largest number of fruits producer among all Cucurbitaceae; vigorous growth; climb up vertical supports using tendrils and twining stems to sprawl over its top or the trellises (FIGS. 7-10, FIGS. 1 and 2); plant very variable in the shape of the fruit, some named varieties. traditional cultivars 6 -10 fruits per year, some improved cultivars more fruits per year; garden grown, vegetable, medicinal, and ornamental plant; drought intolerant. Manual weed control required. Watering required to keep the soil humid, no flooding.

[0065] Leaves: Base broadly heart-shaped or palmately broad 3, 5, 6, or 7-lobed leaves rounded or obtuse appear, rounded outline, 8 to 12 cm long and broad, sinuses broad or narrow and rounded (FIGS. 11 through 14).

[0066] Tendrils: Forked tendrils appearance before the characteristic odor at about 1 m high (FIGS. 8 through 10).

[0067] Manure: Periodic application of composted vegetable matter and 13-13-13.

[0068] Flowers: (FIGS. 14, 17, 19, 16, 1). Flowering by 1.5 m high, five-petalled white unisexual flowers with long lacy fringes; small, white flowers in bloom day and night; male and female flowers separate; male flowers borne on short stalks of about equal length at equal distances along an elongated axis (peduncle length 10 to 30 cm) and open in succession toward the apex; female ones apart by the long lump on the stem; solitary, sessile, single celled ovary, long and with hairy stigmas.

[0069] Pollination: Insects pollinated; manual pollination by snapping off the male flowers and gently rubbing them on the female ones to transfer the pollen; female flower wilting after successful pollination; lump growth on the stem begins to grow; appearances of baby snake gourds; rapid growth (FIGS. 14 and 17).

[0070] Fruit: Oddly shaped fruits—very slender, long, cylindrical berry, often twisted, green or white when immature, pickable at about 30 cm (FIGS. 1 and 2); immature fruits harvestable about two months after sowing seeds; cropping continues for up to four months or more depending on the weather; delayed picking hardened fruit prior to turning yellowish red (FIGS. 3, 4, and 5); 10 fruits or more per plant; 30 cm mature fruit 5-8 cm middle diameter, thickness, growth dependent weights.

[0071] Edible: Young whole fruits cut into pieces for cooking; mature fruits' red, soft sweet testing pulp eaten as a tomato substitute in African countries; bright red pulp around mature seeds extracted for tomato-like cooking.

[0072] Pests: The described snake gourds herein resistant to powdery mildew, and repellent to leaf beetles, aphids, snails, slugs, and caterpillars.

[0073] Snake Gourd Nutritional Content:

[0074] The snake gourd nutrition facts for a 100 g serving are as follows: Calories 86.2 kcal, Macronutrients: Total Fat 3.9 g, Saturated Fat 0.5 g. Total carbohydrate 12.5 g, Dietary Fiber 0.6 g, Protein 2.0 g, Cholesterol 0.0 mg, Sodium 33.0 mg, Potassium 359.1 mg, Vitamins: Vitamin A 9.8%, Vitamin B6 11.3%, Vitamin C 30.5%, Vitamin E 1.1%, Minerals: Calcium 5.1% Magnesium 6.7%, Phosphorus 5.0%, Zinc 7.2%, Iron 5.7%, Manganese 12.5%, and Iodine 5.9% (Bharat, 2022).

[0075] Snake Gourd Health Benefits

[0076] Accelerates weight loss, augments heart function, detoxifies kidneys, enhances digestive system, strengthens respiratory processes, complements ketogenic diet, soothes depression and anxiety, resolves acid reflux, mitigates Polycystic ovary syndrome (PCOS); seed remedies hypertension, cures diarrhea, manages diabetes symptoms; snake gourd naturally moisturizes skin, combats skin infections, promotes hair growth, tackles excessive dandruff, snake gourd hair gel; in Ayurveda: snake gourd juice baffles fevers, fights jaundice, remedies heart ailments, treats alopecia, recovers joint illnesses, uplifts immunity, regulates thyroid, alleviates insomnia (Bharat, 2022)

[0077] National Pesticide Use

[0078] The USA uses annually more than one-half billion kg (more than one billion lbs.) of pesticides. The fruit and vegetable growers use the lions share of pesticides per acre (Kiely et al., 2004). In 2012, the US pesticide expenses at the producer level were nearly $9 billion (Pesticides Industry Sales and Usage 2008-2012 Market Estimates in https://www.epa.gov/sites/default/files/2017-01/documents/pesticides-industry-sales-usage-2016_0.pdf). Mechanization, fertilizers, and pesticides involves the primary costs in U.S. food crop production. The inclusion of the irrigation cost raises the total costs 2-3 times higher. When irrigation is employed, the cost is 2 to 3 times the cost of all the other inputs in U.S. food crop production.

[0079] Table 2 shows the expenditures on pesticide uses year-wise for two decades ending in 2001, and FIG. 28 shows the sales of pesticide industries during that period (https://nepis.epa.gov/Exe/tiff2png.cgi/300065AN.PNG?-r+150+-g+3+D%3A%5CZYFILES%5CINDEX%20DATA%5C00THRU05%5CTIFF%5C00000683%5C300065AN.TIF).

TABLE-US-00002 TABLE 2 Annual expenditures on pesticides uses. Annual User Expenditure on Pesticides in the U.S. by Pesticide Type, 1982-2001 Estimates Agricultural Market Sector Fungicides Year Herbicides/PGR Insecticides and Other Total 1982 2,465 1,109 268 3,842 1983 2,800 1,261 450 4,511 1984 3,390 903 418 4,711 1985 2,900 990 615 4,505 1986 2,775 914 600 4,289 1987 2,935 1,145 650 4,730 1988 3,080 1,010 775 4,865 1989 3,255 978 800 5,033 1990 3,463 1.067 842 5,372 1991 3,644 687 884 5,215 1992 3,915 1,058 829 5,802 1993 3,987 1,123 895 6,005 1994 4,808 1,293 1,036 7,137 1995 5,112 1,607 1,107 7,826 1996 5,399 1,480 1,128 8,007 1997 5,610 1,551 1,124 8,285 1998 5,632 1,427 1,209 8,268 1999 5,012 1,370 1,243 7,625 2000 5,007 1,411 1,194 7,612 2001 4,987 1,326 1,091 7,404 Note: Excludes wood preservatives, specialty biocides, and chlorine/hypochlorites Source: EPA estimates based on Croplife America annual surveys and EPA proprietary data

[0080] Snake Gourd Extracts/Oils Pesticides Replacement

[0081] Snake gourd effective repellant for pumpkin and squash bugs (pictured in ALMANAC), hyacinth bean bugs and aphids Bean|Diseases and Pests, Description, Uses, Propagation (psu.edu) (Bean|Diseases and Pests, Description, Uses, Propagation (psu.edu)); snake gourd extracts/oils pesticides replacement for sevin, malathion, diazinon, and neonicotinoids (Neonics) used in growing pumpkins, squash, and beans, and keeps water bodies and stream safe. So, environmental savior.

[0082] Snake gourd is a summer fruit vine. The Trichosanthes cucumerina vine cannot be used for testing on other fruit vines and trees that bloom in the winter. The only way to test on them is to use the vine leaves and fruits oils/extracts with the aroma intact or a synthetically prepared compound with the same aroma.

[0083] Snake Gourd Extracts/Oils Bee Population Savior

[0084] Almonds are 100%, and 90% of apples, blueberries, and avocados 90% pollinated by bees. Out of every four bites of food, one bite is bees' contribution. If bees are gone from the agriculture sector, food prices will soar up ten time or more. Many US commercial farms use the pesticides called neonicotinoids (neonics) that have led to mass deaths of these pollinators. Pollen grains contain trace amounts of pesticide. Pollen is carried to beehives for food accumulating it to a critical level within the beeswax. Pesticides affect bees in many ways—their sole chemical and physical signals-based communication, foraging behavior, and their larval development. Further, pesticides lower the bees immune systems, weaken the hive, and leave it wide open to parasitic infection. (https://www.planetbee.org/why-bees-are-dying (https://secure.foodandwaterwatch.org/act/epa-save-bees?gclid=CjwKCAjw9e6SBhB2EiwA5myr9jVUJqntQcQVv4ed3ZTZ5iZHjNxgp0B-JFuQrZhqqYqFXNZQaCSm7BoCO_QQAvD_BwE).

[0085] Since the snake guard vines are not harmful to any living beings, bees are not going to be affected.

[0086] Snake Gourd Extracts/Oils Reduces Water Resources Contamination

[0087] In their fact Fact Sheet “The Quality of Our Nations Waters—Pesticides in the Nation's Streams and Ground Water, 1992-2001.”—USGS highlights national findings on pesticide occurrence, distribution and sources, and the potential for effects on humans, aquatic life, and fish-eating wildlife. Pesticides accumulate in stream-drained watersheds in substantial agricultural or urban areas to a greater level than groundwater (FIGS. 29 and 30). NAWQA's assessment of potential effects is based on comparing measured concentrations to water-quality benchmarks which are estimates of the concentrations above which pesticides may have adverse effects on humans (FIG. 31), aquatic life (FIG. 32), or fish-eating wildlife (FIG. 33). (https://pubs.usgs.gov/fs/2006/3028/#:˜:text=The%20insecticides%20diazinon%2C%20chlorpyr ifos%2C%20carbaryl,water%20as%20their%20parent%20pesticides).

[0088] Snake Gourd Extracts/Oils Human-, Aquatics-, and Wildlife-Friendly

[0089] Human-health benchmarks were seldom exceeded in ground water. One or more pesticides exceeded a benchmark in about 1 percent of the 2,356 domestic and 364 public-supply wells that were sampled. The greatest proportion of wells with a pesticide concentration greater than a benchmark was for those tapping shallow ground water beneath urban areas (4.8 percent). The urban wells with benchmark exceedances included 1 public-supply, 3 domestic, and 37 observation wells. All concentrations greater than a benchmark were accounted for by dieldrin (72 wells), dinoseb (4), atrazine (4), lindane (2), and diazinon (1). Pesticides typically found in trace levels raise concerns for their potential effects of chronic health problem from long-term use at relatively low concentration.

REFERENCES

[0090] 1. Khan, S. M. and Jehangir, M. 2000. Efficacy of different concentrations of sevin dust against red pumpkin beetle (Aulacophora foveicollis (Lucas) causes damage to muskmelon Cucumis melo crop. Pakistan Journal of Biological Science., 3(1): 183-185. [0091] 2. Hasan, M. K., Uddin M. M., and Hague, M. A. 2011. EFFICACY OF MALATHION FOR CONTROLLING RED PUMPKIN BEETLE, Aulacophora foveicollis (LUCAS) IN CUCURBITACEOUS VEGETABLES, Progress. Agric. 22(1 & 2): 11-18, 2011 ISSN 1017-8139 [0092] 3. OC Pest Management Guidelines, available in (http://ipm.ucanr.edu/PMG/r116301111.html [0093] 4. Smart Gardener, Plant Guide available in https://www.smartgardener.com/plants/6865-bean-specialty-hyacinth—lablab-purpureus/pests/538-aphidsFig. [0094] 5. Gill. R. J. and Raine. N. E. Chronic impairment of bumblebee natural foraging behavior induced by sublethal pesticide exposure. Functional Ecology, 2014; DOI: 10.1111/1365-2435.12292. [0095] 6. Stackpoole, S. M., Shoda, M. E., Medalie. L., Stone, W. W. 2017. Pesticides in US Rivers: Regional differences in use, occurrence, and environmental toxicity, 2013 to 2017, Science of The Total Environment, Volume 787, 15 Sep. 2021, 147147 https://doi.org/10.1016/j.scitotenv.2021.147147 [0096] 7. Bharat. D. 2022. Snake Gourd: Health Benefits, Nutrition, Uses For Skin And Hair, Recipes, Side Effects, available from https://www.netmeds.com/health-library/post/snake-gourd-health-benefits-nutrition-uses-for-skin-and-hair-recipes-side-effects [0097] 8. Devi, N. D. 2017. Medicinal Values of Trichosanthus cucumerina L. (Snake Gourd)—A Review, British Journal of Pharmaceutical Research, 16(5): 1-10, 2017; Article no.BJPR.3357, ISSN: 2231-2919, NLM ID: 10163175