- Author: Surendra Dara
Novaluron (Rimon 0.83 EC, Chemtura USA Corp, Middlebury, CT) is a popular insecticide used by the strawberry growers for managing nymphal stages of the lygus bug. It is an insect growth regulator that inhibits chitin synthesis and thus interferes with the growth and development of the immature stages. It is effective against egg, nymphal or larval stages. According to some earlier studies, Chemtura restricted the use of adjuvants with novaluron. This has been a concern for the growers especially when novaluron has to be tank mixed with other pesticides and adjuvants. Chemtura's request to amend the label to remove the adjuvant/surfactant statement has been approved by the Environmental Protection Agency (EPA). Growers will soon be able to use adjuvants with novaluron when the new label is ready.
Background about EPA's requirement of adjuvant studies
Unless an adjuvant is not supposed to be used with a pesticide, EPA' s Office of Pesticide Programs (OPP) requires inclusion of adjuvants in the field trials for registering pesticides. This is mainly because of the impact of adjuvants on the pesticide residue levels. Because of this impact, there was a concern in EPA to require new studies with adjuvants for products that were previously registered without the adjuvant data. Crop Life America, Chemical Distributors and Producers Association analyzed historical data from OPP and concluded that adjuvants increase the pesticide residues, but the inherent variability in pesticide residues is more than what is caused by the adjuvants. Based on these analyses, Health Effects Division and Chemistry Science Advisory Council decided not to require new studies with adjuvants for products previously registered without them. As a result when registrants ask for label amendments related to the adjuvant use, EPA would use the fast track process.
What is an agricultural adjuvant?
Adjuvants are substances used with pesticides to improve their efficacy by improving the formulation, atomization, or biological action. Adjuvants act as spreading or wetting agents which reduce foaming, drift, and droplet size and increase the pesticide deposition, retention, and absorption. Agricultural adjuvants are categorized based on the chemical class into surfactants, oils, acidifiers and buffers, fertilizer adjuvants, and others. There are some green adjuvants that are safe to the environment.
Based on how an adjuvant is produced and its impact on the environment, Beck et al (2012) provided a definition for green adjuvants. “According to the production-based approach, adjuvants are defined as green if they are manufactured using renewable raw materials as much as possible while making efficient use of energy, preferably renewable energy. According to the environmental impact approach, adjuvants are defined as green (1) if they have a low human and environmental impact, (2) if they do not increase active ingredient environmental mobility and/or toxicity to humans and non-target organisms, (3) if they do not increase the exposure to these active substances and (4) if they lower the impact of formulated pesticides by enhancing the performance of active ingredients, thus potentially lowering the required dosage of active ingredients.”
References
Beck, B., W. Steurbaut, and P. Spanoghe. 2012. How to define green adjuvants. Pest. Manag. Sci. 68: 1107-1110.
Grains Research and Development Corporation. 2012. Adjuvants – oils, surfactants and other additives for farm chemicals – revised 2012 edition. Australian Government.
Ishaaya, I., S. Yablonski, Z. Mendelson, Y. Mansour , and A. R. Horowitz. 1996. Novaluron (MCW-275), a novel benzoyl urea, suppressing developing stages of Lepidopteran, whitefly and leafminer pests. pp. 1013-1020. In: Brighton Crop Protection Conf., Pests & Diseases, The British Crop Protection Council.
Martin, D. E., J. D. Lopez, Jr., Y. Lan, B. K. Fritz., W. C. Hoffmann, and S. E. Duke. 2010. Novaluron as an ovicide for bollworm on cotton: deposition and efficacy of field-scale aerial applications. J. Cotton Sci. 14: 99-106.
Spanoghe P, M. De Schampheleire, P. Van derMeeren, W. Steurbaut. 2007. Influence of agricultural adjuvants on droplet spectra. Pest. Manag. Sci. 63: 4–16.
- Author: Surendra Dara
Small, but damaging pest. Female (top), male and female in copulation (middle), and mature nymph (bottom) of Bagrada bug. Photo by Surendra Dara
In the third week of September, nearly two weeks after they were first reported in Santa Barbara County, Bagrada bugs were found in the Arroyo Grande area in San Luis Obispo County. Organic growers are especially worried due to limited management options. Conventional growers are also concerned at the sudden appearance of overwhelming numbers of Bagrada bugs in some cases, but good control with insecticides such as dinotefuran has been reported.
Feeding damage on broccoli. Photo by Surendra Dara
Even death does not separate some of them. Photo by Surendra Dara
Here is some more information in addition to what I have written in my previous articles:
- Adults can survive for nearly four months under optimal conditions.
- Since it is a new pest, we do not know its overwintering efficiency in Santa Barbara and San Luis Obispo Counties. Bagrada bugs overwinter as adults, but periods of winter in our area could be very cold for them.
- Although brassicas are known to be preferred hosts, they can feed on a variety of other hosts.
- In Ventura County, they were reported on strawberries in large numbers, but it was not clear if they were feeding and causing damage to the crop. Because this pest is multiplying in large numbers and spreading around, they can be seen on atypical host plants in their way. If they happen to stay on these hosts for a long period, it is quite possible the bugs explore feeding on them.
- Bagrada bugs seem to be aggregating in weed hosts like wild mustard and alyssum even when crop plants such as broccoli and kale are nearby. So, using the wild hosts as trap crops can be a strategy as long as they do not serve as a source of infestation for crop plants.
- They seem to be responding well to synthetic pyrethroids, neonicotinoids, and organophosphate compounds. Since we do not know the future status of this pest, rotating chemicals with different modes of action is very important to minimize potential resistance problems.
- For organic growers, mechanical removal and use of pyrethrins and azadirachtin (for immature stages) seem to be available options at this moment. Azadirachtin is a natural growth regulator and should be used mainly against immature stages. Other organically approved materials do not seem to be effective based on available information.
- Careful monitoring, especially in sensitive areas such as those close to wild hosts, removal of wild or weed hosts, and rotating crops with non-host plants, can reduce the risk of infestation.
- New infestations can occur from infested nursery plants. So, care must be taken to prevent spread through the movement of plant material.
Bagrada bugs on strawberries during their migration to a more suitable host. Feeding damage has not been reported. Photo by Lane Stoeckle
- Author: Surendra Dara
Bagrada bugs on peppers (Photo by Brendan Kreute, PCA in Ventura Co)
It was in last January when I first wrote about the invasive pest Bagrada bug (Bagrada hilaris). It was only reported in Imperial, Riverside, and Orange Counties at that time. In the past two months or so, I have received several phone calls and emails from various places outside Santa Barbara County about Bagrada bug infestations in the home gardens and fields on arugula, broccoli, kale, Monterey pine, mustard, peppers, radish, and strawberries. In some cases, they were also seen inside the homes.
Early this week, Santa Barbara County Ag Commissioner Entomologist, Brian Cabrera received specimens from Solvang and found infestations of Bagrada bug on mustard in other areas making an official record of this pest in the county. This pest currently has a B rating by CDFA.
Like lygus bug, Bagrada bug can also migrate to crop plants from alternate hosts such as wild mustard. So, proximity to such wild hosts can lead to possible infestations when wild plants dry out.
Bagrada bug adult in Santa Barbara Co (Photo by Brian Cabrera, Santa Barbara County Ag Commissioner Entomologist)
Management options: There are varying reports on the effectiveness of various products especially for organic crops. Someone reported effective control with mechanical exclusion and azadirachtin. However, University Arizona Entomologist, John Palumbo did not see effective control by organically approved products when compared to the combination of dinotefuran and bifenthrin in his studies.
Cultural control through pest monitoring and early detection, removal of weed hosts, mechanical removal through handpicking or vacuuming, cultivation to destroy eggs in the soil, and overhead irrigation to dislodge nymphs and adults from the plants are some of the options suggested in the literature.
Please read my earlier article for more details on this pest at http://ucanr.org/blogs/strawberries-vegetables/index.cfm?tagname=Bagrada%20bug
If you see Bagrada bug, please contact me or your local Ag Commissioner's office.
/h4>/h4>- Author: Surendra Dara
Spotted wing drosophila (SWD), Drosophila suzukii has become a potential concern for strawberries following its damage to cherries, blackberries, raspberries, and blueberries in coastal California. Other species of Drosophila are morphologically not equipped to attack ripening strawberries. Their ovipositors or egg laying parts are not strong enough to penetrate unripe or ripening berries. They may damage overripe strawberries left on the crop, but since such berries are not marketed, they have not been an issue for growers. However, SWD has a heavily sclerotized, serrated ovipositor that enables it to lay eggs in fruits that are not fully ripe.
In response to the concern that SWD could be a potential pest to strawberries, I monitored some fields in Santa Maria last year. Five fields – four conventional and one organic – in various parts of Santa Maria were monitored for five months from March to July, 2011. Two kinds of traps, one with apple cider vinegar and the other with yeast-sugar extract were used in each location and were observed every week. During this monitoring there were no signs of SWD in any of these traps. However, I recently received some specimens from a Santa Maria grower in which I found what seemed to be the females of SWD among other Drosophila sp. There were no males with their obvious characteristic of spotted wings, but the following and other characters of the females suggest these were SWD:
- Hard and dark (sclerotized) ovipositor with prominent serrations or saw-teeth that enable the fly to lay eggs in intact ripening fruit.
- Antennae with branched bristle-like part called arista.
According to Dr. Brian Cabrera, Santa Barbara County Ag Commissioner Entomologist, there haven't been any SWD infestations that were brought to his attention. So, it appears to be the first report of SWD in Santa Maria strawberries. Sanitation, trapping, and chemical control are among the available options to manage SWD. Close monitoring is necessary in vulnerable areas. More details about identifying and managing SWD can be found in the listed references. Here is a brief note about this pest.
SWD belongs to the group of flies that are generally known as vinegar flies or lesser fruit flies. It was initially known as cherry fruit fly in 1930s and is now referred to as spotted wing drosophila.
Origin and distribution: It is traditionally known to be a pest in Asia, but it is now reported in Neo Tropics, North America, and Europe. In the US, it has been found in Hawaii, Washington, Oregon, California, and Florida.
Host range: They generally infest thin-skinned fruit and prefer temperate climate. Host range includes apple, blackberry, blueberry, cherry, dogwood, grape, mulberry, peach, persimmons, plum, raspberry, and strawberry.
Biology: SWD prefer 68-86 oF and overwinter as adults. Various sources suggested 5-10 generations per year. According to Kanzawa (1939) egg laying starts in spring and can last for 10-59 days. Females lay an average of 384 eggs at 7-16 per day. Eggs hatch in 2-72 hours and larval stage lasts for 3-13 days. Pupation takes place inside the fruit or in the soil and lasts for 3-15 days. Life cycle takes anywhere from 21-25 days at 59 oF to 7 days at 82 oF.
Damage: Other fruit flies usually infest overripe and fallen fruit, but SWD infests fresh fruit because of its powerful ovipositor. Adults feed on fallen fruit but lay their eggs under the skin of intact fruit. Softening and collapse of the tissue results from larval feeding inside the fruit. Oviposition holes can be seen on the fruit with close observation. In addition to the direct damage, SWD makes the infested fruit vulnerable to other pests and diseases. Monitoring SWD is very important to avoid harvesting and marketing infested berries.
Maggots (of unknown species) in infested fruits showing up in processed strawberry container. Photo by Surendra Dara
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References
Calabria G., J. Máca, G. Bächli, L. Serra and M. Pascual. 2012. First records of the potential pest species Drosophila suzukii (Diptera: Drosophilidae) in Europe. J. Appl. Entomol. 136:139-147.
Kanzawa, T. 1939. Studies on Drosophila suzukii Mats. 49 pp. (http://www.cabdirect.org/abstracts/19410501073.html;jsessionid=81E9221496390100F7C13052E18F8079)
http://www.agf.gov.bc.ca/cropprot/swd_identification.pdf
http://www.al.gov.bc.ca/cropprot/swd.htm
http://entnemdept.ufl.edu/creatures/fruit/flies/drosophila_suzukii.htm
http://www.freshfromflorida.com/pi/pest-alerts/drosophila-suzukii.html
http://www.ipm.ucdavis.edu/EXOTIC/drosophila.html
- Author: Surendra Dara
False chinch bug (Nysius sp.) infestation on strawberries (Photo by Sal Ponce, Pacific Coast Produce.
False chinch bugs migrated to new strawberry field (above) from dried weeds in an old strawberry field (Photo by Surendra Dara)
There was an isolated incident of heavy infestation in a Santa Maria strawberry field with false chinch bug, Nysius sp. (very likely N. raphanus). False chinch bug is normally not a pest of strawberries or cultivated crops. They usually multiply on herbaceous weeds during spring time and move on the nearby cultivated crops when the weed hosts dry out. In the current incident, an old, leftover strawberry field with severe weed growth right next to the cultivated strawberry field harbored false chinch bug populations which moved to the new strawberry field. The grower immediately treated the field with malathion and bifenthrin (Brigade) that effectively controlled the migrating pest. This is a classic example of weeds and alternate hosts serving as a source of pest populations. It emphasizes the importance of cultural practices such as managing weeds and alternate hosts of pests and good agronomic practices for controlling pests without pesticide application. Such cultural practices are also important for avoiding early infestations of lygus bug, a major pest of strawberries in California's Central Coast.
If you notice false chinch bugs in strawberries or other crops this article should help you in identifying and taking appropriate action.
False chinch bugs are true bugs belonging to the order Hemiptera and family Lygaèidae. Members of Lygaèidae are generally known as seed bugs. Crops pests like lygus bug (Lygus spp. - family Miridae) and chinch bug (Blissus spp. - family Blissidae), and beneficial predator, big-eyed bug (Geocoris spp. - family Geocoridae) are some other commonly known lygaeids.
Host range: False chinch bugs are usually found on grassy and cruciferous weeds in spring and move in large numbers to nearby vegetation when the weed hosts dry out. They can be a nuisance to farms, orchards, landscapes, and gardens.
Damage: Nymphs and adults feed on foliage, stems, fruit, and seeds using their piercing and sucking mouthparts. Feeding causes discoloration, scorched appearance, wilting, and in severe cases death of the plant.
Biology: Eggs are laid in loose soil and hatch in 4-7 days. Nymphs have brownish gray bodies with orange or reddish markings. Developing wing pads are dark brown. The abdomen has a transverse white page in the middle and an alternating brown and grey pattern in the margins. Nymphs molt a few times and mature into adults in about three weeks. Adults are 3-5 mm long, grayish brown, with a slender body and silvery gray wings. Margins of the folded wings appear like an X. Note that true chinch bugs have a triangular black marking near the middle of the outer wing margin.
False chinch bug nymphs with gray brown mottling and dark developing wing pads and adult (bottom right) with silvery grey wings (Photo by Surendra Dara)
Management: Mass migration of false chinch bugs lasts for a short period and many plants can with stand minor damage. Chinch bug infestations usually do not require any treatment, unless plants are at a vulnerable stage or there is a serious damage. Some of the common pesticides can be effective, but it is important to refer to the product label and pest management guidelines specific to the crop.