Compositions and methods for controlling mosquitoes are provided herein.

A slow-release silk thread and a method for preparing the slow-release silk thread are provided. The slow-release silk thread includes a substrate layer, a slow-release layer, and a protective layer. The slow-release layer is provided between the substrate layer and the protective layer. The slow-release layer includes porous microspheric particles in which a functional agent is adsorbed. The slow-release silk thread obtains a composite structure through the method and realizes slow release of the functional agent by taking advantage of an adsorption performance of a special granular powder, thereby prolonging effective duration of the functional agent.

A slow-release silk thread and a method for preparing the slow-release silk thread are provided. The slow-release silk thread includes a substrate layer, a slow-release layer, and a protective layer. The slow-release layer is provided between the substrate layer and the protective layer. The slow-release layer includes porous microspheric particles in which a functional agent is adsorbed. The slow-release silk thread obtains a composite structure through the method and realizes slow release of the functional agent by taking advantage of an adsorption performance of a special granular powder, thereby prolonging effective duration of the functional agent.

A slow-release silk thread and a method for preparing the slow-release silk thread are provided. The slow-release silk thread includes a substrate layer, a slow-release layer, and a protective layer. The slow-release layer is provided between the substrate layer and the protective layer. The slow-release layer includes porous microspheric particles in which a functional agent is adsorbed. The slow-release silk thread obtains a composite structure through the method and realizes slow release of the functional agent by taking advantage of an adsorption performance of a special granular powder, thereby prolonging effective duration of the functional agent.

Disclosed herein are antimicrobial compositions that are substantially odorless. The antimicrobial compositions can comprise, for example, a first essential oil and a second essential oil, wherein the composition is substantially odorless. In some examples, the composition can further comprise a third essential oil. The compositions described herein can, for example, reduce the population of microbes, such as Staphylococcus aureus or Escherichia coli, by 5 log or more. Also disclosed herein are beverages and food products including the compositions disclosed herein. Also disclosed herein is milk including the compositions disclosed herein. Also disclosed herein are methods for treating or preventing a microbial infection in a subject, the methods comprising administering to the subject an effective amount of any of the compositions disclosed herein. Also disclosed herein are methods for combating bovine mastitis, the methods comprising applying any of the compositions disclosed herein to cow udders.

Disclosed herein are antimicrobial compositions that are substantially odorless. The antimicrobial compositions can comprise, for example, a first essential oil and a second essential oil, wherein the composition is substantially odorless. In some examples, the composition can further comprise a third essential oil. The compositions described herein can, for example, reduce the population of microbes, such as Staphylococcus aureus or Escherichia coli, by 5 log or more. Also disclosed herein are beverages and food products including the compositions disclosed herein. Also disclosed herein is milk including the compositions disclosed herein. Also disclosed herein are methods for treating or preventing a microbial infection in a subject, the methods comprising administering to the subject an effective amount of any of the compositions disclosed herein. Also disclosed herein are methods for combating bovine mastitis, the methods comprising applying any of the compositions disclosed herein to cow udders.

A plant activator composition increases the concentration of terpenes a terpinoids in aromatic plant oils, and hence resulting in an increased concentration of terpene and terpinoids in the harvested dried plant or fruit. The composition contains one of more bio-active compounds that are optionally extracted from plants selected from one or more of the group consisting of mango, citrus (including grapefruit), Catharanthus roseus and Pelargonium odoratissimum, but alternatively may include one or more synthetic compounds selected from the group consisting of geranyl acetate, geraniol, beta-sitosterol, alpha-amyrin, beta amyrin, carotenoid, geranyl acetate, alpha-humulene, mevalonate kinase and geranyl. Depending on the type of plant being treated, the formulation is added during watering and feeding in optimum doses during the vegetative growth, flowering, and fruit set and/or swell stages.

A plant activator composition increases the concentration of terpenes a terpinoids in aromatic plant oils, and hence resulting in an increased concentration of terpene and terpinoids in the harvested dried plant or fruit. The composition contains one of more bio-active compounds that are optionally extracted from plants selected from one or more of the group consisting of mango, citrus (including grapefruit), Catharanthus roseus and Pelargonium odoratissimum, but alternatively may include one or more synthetic compounds selected from the group consisting of geranyl acetate, geraniol, beta-sitosterol, alpha-amyrin, beta amyrin, carotenoid, geranyl acetate, alpha-humulene, mevalonate kinase and geranyl. Depending on the type of plant being treated, the formulation is added during watering and feeding in optimum doses during the vegetative growth, flowering, and fruit set and/or swell stages.

A plant activator composition increases the concentration of terpenes a terpinoids in aromatic plant oils, and hence resulting in an increased concentration of terpene and terpinoids in the harvested dried plant or fruit. The composition contains one of more bio-active compounds that are optionally extracted from plants selected from one or more of the group consisting of mango, citrus (including grapefruit), Catharanthus roseus and Pelargonium odoratissimum, but alternatively may include one or more synthetic compounds selected from the group consisting of geranyl acetate, geraniol, beta-sitosterol, alpha-amyrin, beta amyrin, carotenoid, geranyl acetate, alpha-humulene, mevalonate kinase and geranyl. Depending on the type of plant being treated, the formulation is added during watering and feeding in optimum doses during the vegetative growth, flowering, and fruit set and/or swell stages.

A pest-combating composition including sodium lauryl sulfate and one or more of C.sub.6-12 fatty acids, preferably lauric and/or capric and/or caprylic acid, soy methyl ester, and 2-undecanone, and methods of combating pests utilizing same, are disclosed. The compositions can include a carrier oil such as silicon oil, soy methyl ester, or a vegetable oil, and can be in the form of an emulsion. The composition may be constituted as a spray composition, an aerosol, a lotion, a paste, or another compositional form. Pests that may be usefully combated with such composition include flying insects, including flies, mosquitoes, and wasps, ants, including arthropods such as fire ants, ticks, fleas, cockroaches, silver fish, thrips, gnats, aphids, Japanese beetles, and agricultural and horticultural arthropods and insects including beetles (potato and bean), flea beetles, fleahoppers, squash bugs, slugs, leaf hoppers, harlequin bugs, milk weed bugs, spiders, mites, lice, rodents, and deer.