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Surfaces Incorporating Treated Leaves for Chemical-free Physical Capture of Pest Arthropods
A breakthrough technology utilizing chemically treated leaves which retain their insect-entrapping properties, providing an effective and less expensive solution for pest control without the use of chemical insecticides.
Highly Effective Broad Spectrum Mosquito Larvacide
Prof. Brian Federici and his colleagues from the University of California, Riverside have developed a highly effective commercial larvicide based on two mosquitocidal bacteria, Bacillus thuringiensis subsp. israelensis (Bti) and Lysinibacillus sphaericus (Ls). By using specific chimeric proteins, this method allows for a broad-spectrum targeting domain for insecticidal proteins. Results have shown that this larvicide will have high efficacy against most major mosquitoes that transmit diseases, including Malaria, Yellow Fever, Filariasis, and newly emerging viruses such as the Zika virus. This technology serves to confront the growing need for preventing deadly diseases from being spread by insects in order to save lives. Fig 1: Midgut histopathology caused by Cyt1Aa-BinA chimera in 8 hours post-treatment at the LC95 concentration; Control midgut epithelium, (i) and (ii), respectively, 100x and 400x magnification. Midgut epithelium of a treated larva (iii) and (iv), respectively 100x and 600x magnification.
Combination Therapy as Enhanced Antidote to Poisoning
Certain pesticides can be harmful, and there is a need for effective antidotes that can reverse accidental over-exposure by farm workers. UC San Diego researchers have recently developed a therapeutic modality that is a combination of compositions that may be effective as an antidote.
Novel Molluscicide
UCR will be accepting commercialization plans for this case no. 2016-025 until 08/11/2023. Background: Slugs and snails are among the most problematic invasive agricultural and horticultural pests. They cause crop loss, reduce crop yield and quality, cause product shipment rejection, and transmit plant and human pathogens. The most commonly used chemical molluscicides are toxic to pets and other organisms. These chemical pesticides are also harmful to the environment, are not cost effective, and with variable effficacy that is highly influenced by environmental conditions such as moisture. Brief Description: UCR researchers have developed a novel potential biopesticide that targets slugs and snails using the recently discovered US strain of the nematode species Phasmarhabditis hermaphrodita. The European strain of this nematode (Nemaslug ®) is being used to successfully manage slugs and snails in Europe. Recent surveys show that consumers in the US are willing to pay more for a more effective and environmentally safe pest management alternative for these invasive gastropods. Phasmarhabditis hermaphrodita (singly or in combination with P. californica or P. papillosa) can be used effectively to manage slug and snail infestations, notably European brown garden snail (Cornu aspersum), Giant African land snail (Lissachatina fulica), gray field slug (Deroceras reticulatum) and greenhouse slug (Lehmannia valentiana).
Development Of Pheromone-Assisted Techniques To Improve Efficacy Of Insecticide Baits Targeting Urban Pest And Species
Background: The pest control industry incurs an estimated $1.7B in damages every year. Current pest management techniques result in insecticide runoff and environmental contamination, which calls for improved bait technologies. Since most urban pests of interest use pheromones for organization and coordination of their colonies, many researchers have explored the possibility of using synthetic trail pheromones as an alternative strategy to mitigate this issue. Brief Description: UCR Researchers have developed insecticidal baits that use highly target-specific control technologies. This novel pheromone-assisted technique (PAT) has little impact on the environment and non-target organisms. By combining the attractant pheromone of ants and existing bait matrices, they increased discovery and consumption of the baits by foraging ants, thus maximizing efficacy of the baits applied. Moreover, they have produced significant results at extremely low concentrations of the pheromone-assisted bait in comparison to the ones that are currently being used.
Development Of Biodegradable Bait Station For Liquid Ant Bait
Background: Current bait station designs and other pest control tools are not very ideal nor advanced – they leak, become excessively hydrated or dehydrated, and need frequent maintenance. The global pest control services market is expected to grow annually at 5.3% and the industry is always looking for unique ways to conquer them. Brief Description: UCR Researchers have developed a novel, protected bait station that has controlled liquid bait release. The compact design contains a sugary, insecticide liquid bait that diffuses through an absorbent polymer or gel matrix. Only ants have access to the station and once an ant consumes the bait, the station biodegrades thus eliminating bait station cleanup.
Identification Of New Synthetic Elicitors Of Plant Immune Responses
Brief description not available
Method for Efficient Loading of Bioactives into Lipid Membrane Microcapsules
Researchers at the University of California, Davis have developed a method of delivering targeted bioactives that is applicable to the agricultural, food processing, cosmetic, veterinary and medical industries.
Bacterial Biocontrol of Plant Pathogens
Researchers at the University of California, Davis have developed a safe, simple and cost-effective method of preventing fungal wilt - without resorting to chemical or transgenic means./p>
Titanium Dioxide (TiO2) Photocatalysts for Water Purification
Pesticide Detection: Methyl Iodide and Methyl Bromide
Paper based sensors for detection of low concentrations of methyl iodide and methyl bromide, dibromo ethylene and other alkylating agents in air.