Fact-checked by Grok 2 weeks ago

Orius insidiosus

Orius insidiosus, commonly known as the insidious flower bug or minute pirate bug, is a small predatory in the within the order , native to the , from southern through North, Central, and South America, and the , where it plays a key role in by preying on small arthropods such as , , mites, and .

Taxonomy and Distribution

Classified under the genus Orius, O. insidiosus belongs to the suborder and is distinguished from related species like O. tristicolor primarily by its prevalence in eastern and midwestern , extending southward to , , , and the . This species is well-adapted to temperate and subtropical climates, with populations active from March to November in northern regions and year-round in southern areas.

Physical Description and Life Cycle

Adults of O. insidiosus measure approximately 2–3 mm in length, featuring an body that is predominantly black with distinctive white patches on the wings, which extend slightly beyond the ; they possess a long, piercing-sucking for feeding. Eggs, about 0.4 mm long, are inserted into tissues, hatching in 6–10 days into wingless, teardrop-shaped nymphs that progress through five instars over at least 10 days, turning from pale yellow to brown; the full from to typically spans 20–21 days under optimal conditions around 21–27°C, allowing for multiple generations annually. Adults live 3–4 weeks and can lay up to 129 eggs, with females inserting them 2–3 days after mating; in cooler seasons, they enter under short day lengths of less than 13 hours.

Ecology and Economic Importance

O. insidiosus is a generalist predator that thrives in diverse habitats including crops like peppers, strawberries, corn, and , as well as flowering weeds and orchards, where it actively hunts small, soft-bodied pests and can consume over 30 spider mites per day. While primarily carnivorous, it exhibits facultative phytophagy, supplementing its diet with and during prey scarcity, which enhances its survival and reproduction in floral environments. In , it is commercially reared and released at rates of 1–2 individuals per square meter to suppress populations at ratios as low as 1:180 for suppression or 1:40 for control, proving especially effective against in greenhouse and field settings; conservation efforts involve planting flowers to attract them and avoiding broad-spectrum insecticides like neonicotinoids. As of , recent studies continue to explore its efficacy, including predation performance under artificial lighting and tolerance to select insecticides, enhancing its role in modern .

Taxonomy and Description

Taxonomy

Orius insidiosus (Say, 1832) is the accepted binomial name for this species of minute pirate bug, first described by American naturalist in his work on North American insects. The species holds a position within the taxonomic hierarchy as follows: Kingdom Animalia, Phylum Arthropoda, Class Insecta, Order Hemiptera, Suborder Heteroptera, Family Anthocoridae, Genus Orius, Species O. insidiosus. No synonyms are commonly recognized in contemporary classifications, reflecting its stable nomenclature since the original description. Within the genus Orius, O. insidiosus is distinguished from close relatives such as O. tristicolor primarily through morphological differences in the male paramere, where O. tristicolor exhibits a long, sweeping, and slender compared to the stouter and shorter flagellum in O. insidiosus. Genetic analyses further support this distinction, revealing approximately 83% in the 1 (ITS-1) sequences between the two species. These differences underscore the species' unique identity in North American anthocorid faunas.

Physical Characteristics

Orius insidiosus adults measure approximately 2–3 mm in length and exhibit an oval body shape, with a predominantly black featuring distinctive white patches on the wings that extend beyond the . These insects possess piercing-sucking mouthparts, manifested as a prominent suited for extracting fluids from prey, which underscores their role as effective predators. Key identification features include four-segmented antennae that appear relatively short, three-segmented tarsi, and the presence of ocelli, distinguishing them within the family. Nymphs of O. insidiosus are wingless and teardrop-shaped, displaying a color gradient from pale yellow-orange in the first —measuring about 0.4 mm—to darker brown tones in later , approaching nearly adult dimensions by the fifth . Early instars are translucent upon hatching, gradually acquiring more opaque pigmentation as they develop. Males and females are similar in overall appearance and size, lacking pronounced morphological differences beyond subtle variations in genitalia used for taxonomic purposes.

Distribution and Habitat

Geographic Distribution

Orius insidiosus is native to , where it is widespread across the (excluding ), southern , and . In the U.S., it is most abundant in the eastern regions but extends westward through the southwestern states to and southern . In , populations occur in provinces such as , , , and (the latter likely introduced and not fully established). This native distribution reflects its adaptation to diverse temperate and subtropical environments within the continent. The species has an extended range into Central and South America, as well as the , including , , and various islands. These expansions are attributed to unintentional introductions facilitated by agricultural trade and commerce, which have transported the bugs via infested crops and plants since at least the , when early observations were documented following its original description in 1832. Favorable climate conditions in these regions have further supported establishment, particularly in areas with suitable host plants. As of 2025, no significant natural range shifts have been reported for O. insidiosus, maintaining its core distribution in the . However, there are increasing observations of the species in global greenhouse systems, where it is commercially introduced as a biological control agent against pests like , particularly in and other non-native regions. This controlled dispersal ties to its association with agricultural crops but does not indicate wild establishment outside the .

Preferred Habitats

Orius insidiosus thrives primarily in agricultural fields such as those planted with , soybeans, corn, and , where it exploits abundant prey and floral resources. It is also common in orchards producing fruits and grapes, as well as areas with flowering weeds like and , which provide and for sustenance. These habitats support high populations due to the presence of soft-bodied pests and diverse vegetation. Within these environments, O. insidiosus prefers microhabitats on flowers and foliage where prey density is elevated, particularly pollen-rich structures such as silk and flowers. It shows a strong attraction to like over sweet peppers, favoring flowering stages that offer both nutritional supplements and oviposition sites. Pollen feeding enhances survival and reproduction in these niches when prey is scarce. Abiotic conditions significantly influence habitat suitability, with optimal temperatures ranging from 21°C to 30°C (70°F to 86°F) for development and activity. Moderate above 60% is preferred, supporting nymphal development and adult longevity, while the species avoids extreme cold by overwintering in protected sites and is less tolerant of . Recent studies highlight its expanding role in protected cropping systems, including greenhouses for tomatoes and strawberries, where it aids in pest management under controlled conditions.

Life Cycle and Reproduction

Developmental Stages

Orius insidiosus undergoes incomplete , progressing through , five nymphal instars, and adult stages. The stage begins when females insert elongate, bean-shaped eggs, approximately 0.4 mm long, into plant tissues such as stems, leaves, or flowers, with the operculum often exposed. These eggs are translucent and hatch after an of 3–5 days at 25°C, though durations extend to 6–7 days at lower temperatures around 21°C. Upon hatching, first-instar nymphs are tiny, pale, and teardrop-shaped, lacking wings and measuring less than 1 mm in length. They develop through five instars over a total nymphal period of 10–15 days under optimal conditions, with progressive increases in size up to about 3 mm and color shifts from translucent or pale yellow to orange-reddish brown in later instars. Development accelerates at higher temperatures, taking approximately 12 days at 25°C but lengthening below 20°C due to reduced metabolic rates. Adults emerge via after the final nymphal molt, with full development from to adult typically spanning 17–21 days at temperatures of 21–27°C, depending on the exact temperature. The entire phase ( plus nymphs) spans about 16–18 days at 25°C, but can exceed three weeks under cooler conditions. Prey availability also influences nymphal progression, as insufficient food prolongs durations and reduces survival rates. In temperate regions, O. insidiosus completes multiple generations—up to 10–12 during the —allowing rapid population buildup in suitable habitats. Adults enter reproductive in late summer or fall when photoperiods drop below 13 hours of daylight, overwintering in sheltered sites in northern ranges and resuming activity in spring. Development slows significantly below 15°C, with thermal thresholds around 12–13°C for most stages, effectively halting progress near the lower limits of their thermal tolerance.

Reproductive Biology

Adult Orius insidiosus typically mate shortly after emergence from the final nymphal stage, with involving chemical cues produced by females. Females emit a volatile , primarily (E)-2,7-octadienal, which attracts males over short distances, while a non-volatile deposited on surfaces guides males to locate potential mates by stimulating arrestment and searching behavior. Males respond to these semiochemicals regardless of their prior status, and multiple matings by females are common, enhancing reproductive output through repeated . Oviposition commences approximately 2-3 days after , with females using their to insert eggs singly into tender tissues, including stems, leaf veins, petioles, and flower parts. Over their adult lifespan, females lay between 30 and 150 eggs, depending on nutritional quality and environmental conditions, at a rate of about 2 eggs per day under optimal circumstances. Fecundity in O. insidiosus is optimal at temperatures of 25-30°C, where females achieve the highest production, often exceeding 100 s per individual, while lower temperatures prolong pre-oviposition periods and reduce total output. Prey scarcity significantly diminishes by limiting energy for , and typically spans 30-50 days on abundant diets. The is generally 1:1, with no evidence of . Recent research on semiochemicals, including plant volatiles induced by interactions, has advanced strategies for augmenting O. insidiosus populations in biological control programs.

Diet and Feeding

Primary Prey

Orius insidiosus primarily targets small, soft-bodied arthropods, with (Thysanoptera: Thripidae) serving as the most significant prey, particularly species in the genus Frankliniella such as F. occidentalis (), F. tritici, and F. bispinosa (adults and larvae). This predator effectively suppresses populations at release ratios of 1:40 to 1:180, maintaining densities below economic thresholds in crops like peppers and strawberries. Spider mites, notably the two-spotted spider mite (), represent another key prey item, with both nymphs and adults of O. insidiosus capable of consuming over 30 individuals per day, often paralyzing additional prey before fully feeding. Suppression of on beans has been observed at densities of 2 predators per 40 mites. The predator also consumes insect eggs from various and , as well as nymphs of (e.g., Aphis glycines on soybeans), leafhoppers, (e.g., Bemisia tabaci), and small caterpillars. Preference for these soft-bodied targets stems from the predator's piercing-sucking mouthparts, which facilitate extraction of body fluids, leaving exoskeletons intact. Predation efficiency varies by life stage and prey density, exhibiting a Type II where consumption increases initially but saturates at higher densities; adults generally consume more than fifth-instar nymphs. Adult females can ingest approximately 20 per day, while overall rates for range from 12 to 30 prey items daily depending on availability. Nymphs exhibit lower rates, typically 5–15 prey per day, reflecting their smaller size and developmental constraints. These rates underscore O. insidiosus as a voracious , particularly effective against invasive like Scirtothrips dorsalis based on laboratory studies in contexts showing a Type II , and as demonstrated in 2024 field trials in peppers integrating reduced-risk insecticides without compromising predation. In foraging, O. insidiosus employs active hunting strategies on plant surfaces, including leaves, stems, and flowers, where it responds to prey-infested odors and aggregates at hotspots of high prey density. This behavior enhances encounter rates with concealed prey in foliage folds or upper canopies. Field evaluations have highlighted its expanding efficacy against emerging pests like Bemisia tabaci, contributing to suppression in diverse cropping systems through predation.

Supplementary Nutrition

Orius insidiosus exhibits omnivorous feeding habits, supplementing its primarily predatory diet with plant materials during periods of prey scarcity. Pollen serves as the primary supplementary food source, providing essential water and nutrients that support survival and development. For instance, pollen from maize (Zea mays) and plants in the Asteraceae family, such as Bidens pilosa, enables nymphs to complete development to adulthood, though at a slower rate compared to prey-based diets. A 2025 study confirmed that while pollen alone sustains development and reproduction, combined prey-pollen diets enhance longevity and fecundity compared to pollen-only feeding. In addition to pollen, O. insidiosus engages in facultative phytophagy by piercing tissues or flowers to extract sap, primarily from and mesophyll layers. This behavior causes only minor damage to host plants and allows the bug to access sugars, , and water. On (Glycine max), individuals have been observed feeding on contents and occasionally mesophyll tissues, demonstrating adaptability to crop environments. Consumption of supplementary resources significantly enhances and reproductive output. supplementation increases lifespan by up to 35% and boosts oviposition rates, with mixed -thrips diets yielding larger s and higher (e.g., 123–141 eggs per on optimal combinations). While alone sustains nymphal development, it prolongs developmental time (e.g., 12–15 days versus 10 days on prey) and limits . Among optimal supplementary resources, silk and pods stand out as high-quality alternatives to prey, supporting both feeding and oviposition. silk provides and attracts adults, aiding persistence in field crops, while pods serve as effective substrates for nutrient intake and egg-laying, improving overall fitness. These resources are particularly valuable in (IPM), where recent studies (2022–2025) highlight provisioning's role in conservation biological control by enhancing predator establishment and reducing reliance on chemical inputs.

Behavior

Predatory Strategies

Orius insidiosus employs active foraging tactics on plant foliage, pursuing small arthropod prey such as thrips through rapid movement and direct contact. Adults and nymphs use chemoreception to detect prey cues, including volatile organic compounds (VOCs) like nonanal and 4-vinylanisole emitted from thrips-infested plants, which guide them to infested patches. Once located, they grasp prey with their front legs and use piercing-sucking mouthparts to insert a beak into the host's body, extracting hemolymph and liquefied tissues multiple times until the exoskeleton remains. This method allows efficient fluid extraction, with behavioral shifts from extensive searching to intensive foraging observed after exposure to thrips cues, enhancing prey encounter rates. Individuals aggregate in response to high prey , with both adults and nymphs co-occurring in prey-rich patches on crops like strawberries and peppers. This density-dependent aggregation facilitates localized population buildup, as O. insidiosus disperses quickly to colonize areas with abundant . Such clustering improves predation efficiency in hotspots, where functional responses shift from Type II (saturating at low densities) to Type III (accelerating with learning and cues), allowing greater control of escalating numbers. Defensive behaviors in O. insidiosus include rapid locomotion to evade larger predators, enabling quick escapes across foliage surfaces. This fast-moving nature, characteristic of all stages, reduces during , though it also makes them aggressive in confrontations. O. insidiosus exhibits voracious feeding, with a single adult capable of consuming over 30 small prey such as mites or several per day under optimal conditions, often killing additional individuals (up to 30–50 ) beyond nutritional needs. This high efficiency enables one adult to suppress small populations in localized areas, such as within flowers or leaves, contributing to effective biological control in and field settings. Intraguild predation occurs among O. insidiosus and other predators like lacewing larvae (Chrysoperla carnea), where generalist hemipterans including Orius species reduce lacewing survival primarily through direct predation rather than resource competition. Seminal research highlights competitive interactions in shared habitats, potentially disrupting multi-predator pest suppression, though effects vary by species and prey availability.

Interactions with Humans and Environment

Orius insidiosus occasionally bites humans when handled, particularly in agricultural environments such as fields or greenhouses where individuals may come into direct contact with the . These bites result in painful but harmless punctures, with no need for medical treatment beyond minimizing skin exposure to prevent further incidents. In terms of environmental responses, adults of O. insidiosus are winged and capable of active flight, facilitating dispersal between crops and habitats, often aided by currents. They can also spread via infested plants in agricultural trade or transport. Additionally, these bugs are attracted to lights at night, which may influence their distribution near human settlements or illuminated areas. Orius insidiosus shows compatibility with (IPM) programs, tolerating certain reduced-risk pesticides while being highly sensitive to broad-spectrum insecticides like pyrethroids and neonicotinoids, which should be avoided to preserve populations. efforts for O. insidiosus benefit from promoting habitat diversity, such as through or floral provisioning with plants like , where populations are more abundant compared to systems that pose threats by limiting resources and increasing vulnerability to pesticides.

Ecological Role and Applications

Ecosystem Contributions

Orius insidiosus plays a vital role in natural ecosystems by acting as a generalist predator that suppresses populations of small herbivorous pests, such as thrips, in uncultivated and semi-natural habitats. In early spring, it inhabits flowering weeds like hairy vetch and crimson clover, where it regulates thrips outbreaks that could otherwise damage vegetation. As a mid-level predator in food webs, it consumes soft-bodied insects including aphids, mites, and lepidopteran eggs, thereby maintaining balance among arthropod communities in diverse vegetational settings. This natural regulation extends to agroecosystems adjacent to wild areas, where higher predator densities in mixed plantings correlate with reduced pest pressures without human intervention. The species contributes to by mitigating herbivory on , which promotes overall vegetation health and supports associated and . By preying on and other herbivores, O. insidiosus indirectly protects reproductive structures, allowing for sustained seed production and stability. Additionally, its reliance on floral resources like and from wildflowers creates overlap with pollinators, fostering shared use that enhances multifunctionality in non-crop areas. Vegetational , such as the presence of weeds alongside crops, boosts O. insidiosus abundance—up to 170% higher for adults—reinforcing its role in conserving predatory guilds and promoting resilient -insect interactions. Population dynamics of O. insidiosus exhibit density-dependent , where increased prey availability drives higher and dispersal, stabilizing levels across seasons. Overwintering as diapausing adults in protected sites like residual leaf litter and under enhances population resilience, enabling recolonization of habitats in despite environmental stressors. This strategy, combined with photoperiod-sensitive , allows persistence in variable climates. In broader ecological contexts, the presence and abundance of O. insidiosus serve as an indicator of balanced agroecosystems, reflecting effective natural enemy complexes in diverse landscapes.

Biological Control Uses

Orius insidiosus serves as a key agent in (IPM) programs, particularly for controlling in crops such as peppers and strawberries. It also targets mites in settings and in field crops, leveraging its predatory behavior to suppress multiple populations. Mass rearing of O. insidiosus relies on factitious hosts like the eggs of Ephestia kuehniella, enabling efficient production for commercial release; this method has supported widespread availability since the early . Suppliers ship adults in containers with inert materials, and rearing incorporates supplementary or artificial diets to boost and survival. Preventive inundative releases typically involve 1–2 individuals per m² to establish populations early in the season, with higher rates of 500–2000 per acre applied for active infestations in field and systems. Releases are timed at the onset of pest detection, often using banker plants like 'Purple Flash' to support reproduction and dispersal. Field trials demonstrate high efficacy, with O. insidiosus achieving up to 96% reduction in populations on under various light conditions, and 86% control of adult in production. This predator integrates well with reduced-risk insecticides, maintaining populations while avoiding broad-spectrum chemicals that can reduce efficacy by up to 80%.

References

  1. [1]
    Insidious Flower Bug, Minute Pirate Bug: Orius insidiosus
    Orius insidiosus is in the family Anthocoridae. Species of the genus Orius are commonly referred to as minute pirate bugs, while the common name for Orius ...Missing: taxonomy ecology
  2. [2]
    [PDF] The Minute Pirate Bug (Orius) - Virginia Tech
    Description and Life Cycle. Adults are small (2-3 mm long), oval-shaped, black bugs with white markings on the wing patches. (Figure 1).Missing: taxonomy ecology
  3. [3]
    Minute Pirate Bug and Insidious Flower Bug - Cornell CALS
    The minute pirate bug, Orius tristicolor, and the insidious flower bug, Orius insidiosus, are true bugs in the family Anthocoridae. Both species are common ...Missing: taxonomy ecology
  4. [4]
    Species Orius insidiosus - BugGuide.Net
    Dec 24, 2008 · Species Orius insidiosus ... Early nymphs have slight yellowish tinge, getting progressively darker in each successive instar. Adults are mahogany ...
  5. [5]
    Orius insidiosus - NatureServe Explorer
    Scientific Name: Orius insidiosus (Say, 1832) Kingdom: Animalia Phylum: Arthropoda Class: Insecta Order: Hemiptera Family: Anthocoridae Genus: OriusMissing: taxonomy hierarchy Thomas synonyms
  6. [6]
    Orius insidiosus (Say, 1832) - GBIF
    Orius insidiosus (Say, 1832). Dataset; GBIF Backbone Taxonomy: Rank; SPECIES. Classification. kingdom; Animalia: phylum; Arthropoda: class; Insecta: order ...Missing: original | Show results with:original
  7. [7]
    Morphological and Genetic Reappraisal of the Orius Fauna of the ...
    Jan 7, 2016 · 1 A very common species in eastern North America, Orius insidiosus ( Say, 1832 ), has been collected in some geographic locations west of the ...Missing: original | Show results with:original
  8. [8]
    Identity of Two Sympatric Species of Orius (Hemiptera: Heteroptera
    insidiosus published sequence and the one produced here (Figure 4). The sequence for O. tristicolor showed 14 bp different between the two sequences.
  9. [9]
    File: <Anthocoridae
    Orius insidiosus was also the most effective natural enemy of a number of species of thrips attacking truck crops and fruit trees, and this was also true in ...
  10. [10]
    Thrips control - Sierra Biological
    First instar nymphs are approximately 0.5 mm long and pale yellow; subsequent nymphal stages become progressively darker, with the final two stages being tan to ...Missing: sizes | Show results with:sizes
  11. [11]
    Orius insidiosus, Insidious Flower Bug (Hemiptera: Anthocoridae)
    Feb 14, 2025 · The insidious flower bug (Orius insidiosus) is a member of the predatory bug family Anthocoridae (Hemiptera), collectively known as minute pirate bugs.Missing: taxonomy | Show results with:taxonomy
  12. [12]
    Minute Pirate Bug: A Beneficial Generalist Insect Predator
    Sep 1, 2021 · Orius nymphs are tear drop-shaped with red eyes. Newly hatched nymphs are colorless, but their bodies darken to a yellow, and later reddish- ...<|control11|><|separator|>
  13. [13]
    Minute pirate bugs (Hemiptera: Anthocoridae)
    Male and female minute pirate bugs of the same species are similar in appearance. The insects are quite small (seldom over 0.5 cm in length) with oval to ...
  14. [14]
    Mortality of Orius insidiosus by contact with spinosad in the ... - PMC
    Orius insidiosus Say (Hemiptera: Anthocoridae), the “flower bug”, is an insect widely distributed throughout the United States, Mexico, and Central and South ...Missing: geographic | Show results with:geographic
  15. [15]
    [PDF] Artificial lighting affects the predation performance of the ... - bioRxiv
    Oct 3, 2024 · Orius insidiosus (Say) is widely used in Europe, North America, and South America, where it has been used for biological control of plant ...
  16. [16]
    Orius insidiosus - Predatory Bug for Thrips Control - Koppert
    They resemble smaller versions of the adults but lack fully developed wings. Nymphs are yellow initially, turning darker (orange to brown) as they mature. They ...
  17. [17]
    The Minute Pirate Bug (Orius) | VCE Publications - Virginia Tech
    Oct 8, 2024 · Minute pirate bugs (also known as flower bugs) are small, fast-moving predacious insects in the order Hemiptera and family Anthocoridae.Description And Life Cycle · Habitat · Biological Control With...Missing: binomial name hierarchy 1832 synonyms
  18. [18]
    Orius tristicolor and O. insidiosus - Biological Control
    In the Midwest, O. insidiosus is more common, while O. tristicolor is more common in the western states. In greenhouses, Orius spp. are used as generalist ...
  19. [19]
    Preference of Orius insidiosus and Orius tristicolor (Hemiptera
    Jan 13, 2021 · Orius tristicolor may act as a complementary biocontrol agent or competitor on sweet pepper. Y-tube experiments showed no preference for plant volatiles in any ...
  20. [20]
    [PDF] Insidious Flower Bug Biological Control Agent of Greenhouse Insect ...
    Nymphs become adults in 15 to 20 days, with adults living up to 28 days. Optimal temperatures for development are between 60 and 85 degrees Fahrenheit (15 and ...
  21. [21]
    Orius insidiosus - an overview | ScienceDirect Topics
    'Orius insidiosus' is defined as an anthocorid predator known for its facultative phytophagy, which provides it with water and nutrients when prey are scarce, ...
  22. [22]
    Development and thermal requirements of Orius insidiosus (Say ...
    Aug 6, 2025 · Males and females presented a development time about 12 days at 25°C. The developmental thresholds (To) for egg stage was estimated at 11.78°C, ...
  23. [23]
    How Efficient Is Fertilization by Traumatic Insemination in Orius ...
    Mar 20, 2019 · insidiosus appears to have highly evolved female paragenital morphology, we hypothesized that (1) costs of mating for females should be ...Missing: dimorphism | Show results with:dimorphism
  24. [24]
    Orius insidiosus | CABI Compendium
    This datasheet on Orius insidiosus covers Identity, Distribution, Hosts/Species Affected, Biology & Ecology, Natural Enemies, Further Information.<|control11|><|separator|>
  25. [25]
    Attraction Behavior and Functional Response of Orius insidiosus to ...
    Functional response analysis revealed a shift in O. insidiosus foraging behavior based on the duration of thrips interaction with rose flowers.Missing: dimorphism | Show results with:dimorphism
  26. [26]
    Daily Prey Consumption and Functional Response of Orius insidiosus
    Feb 13, 2025 · Orius insidiosus Say (Hemiptera: Anthocoridae), commonly known as the minute pirate bug, is a generalist predator [7] abundant in many parts of ...
  27. [27]
    Reduced-risk insecticides can effectively manage thrips without ...
    In a follow-up bioassay, we exposed minute pirate bugs (Orius insidiosus (Say)), to insecticide residues and measured their mortality and predation of WFT.
  28. [28]
    Can Generalist Predators Control Bemisia tabaci? - PMC - NIH
    Nov 23, 2020 · Our review suggests that a bio-diverse community of generalist predators commonly attacks B. tabaci, with the potential to exert substantial control in the ...3. Experimental Evidence For... · Table 2 · 4.1. Life-Table Analysis Of...
  29. [29]
    Orius insidiosus - Anthocoridae), a Key Thrips Predator - MDPI
    Mean (±SE) oviposition per day per female of Orius insidiosus adult reared on different diets. ... Mean (±SE) of the length of reproductive period of Orius ...
  30. [30]
    Plant feeding site selection on soybean by the facultatively ...
    O. insidiosus did feed on xylem contents, as shown by ingestion of safranin-labeled xylem fluid. A few of the insects showed signs of feeding on the mesophyll, ...<|control11|><|separator|>
  31. [31]
    The function of supplemental foods for improved crop establishment ...
    Dec 12, 2018 · Towards improving crop establishment of two major predators used in North America, Orius insidiosus and Dicyphus hesperus, this study examined ...
  32. [32]
    Exploring the Role of Supplemental Foods for Improved ...
    Mar 22, 2021 · Pollen is a particularly valuable food source for supporting both Type III generalist phytoseiid predators, for whom pollen feeding can support ...Abstract · Dicyphus Spp · Orius Spp
  33. [33]
    Effect of Two Oviposition Feeding Substrates on Orius insidiosus ...
    Jun 14, 2019 · When biological parameters were measured, pepper fruits proved to be a more appropriate substrate than bean for the 2 Orius species studied. We ...
  34. [34]
    Foraging behavior responses of Orius insidiosus to thrips cues - ADS
    The experiments revealed that O. insidiosus adults exhibited behavioral changes indicative of switching from extensive to intensive foraging after direct ...
  35. [35]
    (PDF) Influence of intraguild predation among generalist insect ...
    Aug 9, 2025 · Decreased survival of lacewing larvae was primarily a result of predation rather than competition. IGP created significant interactions between ...
  36. [36]
    [PDF] Orius insidiosus, Insidious Flower Bug (Hemiptera - LSU AgCenter
    The insidious flower bug (Orius insidiosus) is a member of the predatory bug family Anthocoridae (Hemiptera), collectively known as minute pirate bugs. Adults ...Missing: historical Thomas
  37. [37]
    Occasional Biting Pests - MU Extension
    Sep 1, 2003 · The most common species that bites humans is the insidious flower bug, Orius insidiosus (Figure 5). It has a black body with contrasting ...Missing: interactions | Show results with:interactions<|control11|><|separator|>
  38. [38]
    Little Bugs with a Big Bite: Minute Pirate Bugs - Bug Eric
    Nov 11, 2014 · It occurs east of the Rocky Mountains, plus parts of California, and has been introduced to British Columbia. Because it is available ...Missing: distribution | Show results with:distribution
  39. [39]
    Understanding Orius - Koppert Canada
    Jul 12, 2024 · Thripor is very sensitive to pesticides and sulphur. Applications of most broad-spectrum insecticides, such as pyrethroids, neonicotinoids, ...
  40. [40]
    Compatibility of six reduced-risk insecticides with Orius strigicollis ...
    Dec 15, 2021 · Cyetpyrafen and indoxacarb in combination with O. strigicollis is promising in IPM. Abstract. Contact toxicity assessments of six reduced risk ...
  41. [41]
    Population responses by Orius insidiosus to vegetational diversity
    Mar 21, 2025 · Orius insidiosus adults and nymphs were more abundant in diversified plots than in monocultures. A similar number of O. insidiosus eggs were ...
  42. [42]
    Diversified floral provisioning enhances performance of the ...
    The goal of this research was to examine the role of two potential insectary plant species on the performance of the insidious flower bug, Orius insidiosus (Say ...Missing: microhabitat | Show results with:microhabitat
  43. [43]
    Seasonal Distribution and Overwintering of Orius insidiosus (Say) in ...
    ABSTRACT. The overwintering and seasonal habitats of Orius insidiosus. (Say), timing of diapause in field populations, and seasonal population dynamics in ...
  44. [44]
    Population responses by Orius insidiosus to vegetational diversity
    Aug 10, 2025 · Crop diversification can improve biological pest control, by providing resources and habitat to enhance the performance of natural enemies.
  45. [45]
    https://www.sciencedirect.com/science/article/abs/pii/S1049964419307649
  46. [46]
    Photoperiodic Effect on Diapause Induction and Development in the ...
    Aug 7, 2025 · With climate change leading to poleward range expansion of species, populations are exposed to new daylength regimes along latitudinal gradients ...<|control11|><|separator|>
  47. [47]
    https://www.researchgate.net/publication/43274772_Population_responses_by_Orius_insidiosus_to_vegetational_diversity
  48. [48]
    Orius insidiosus: A Natural Thrips Killer - GrowerTalks
    Nov 1, 2017 · During a field walk, I explained how we use beds of lobularia as a habitat to attract natural Orius with the goal of assisting with thrips ...
  49. [49]
    [PDF] Influence of the eggs of Ephestia kuehniella (Lepidoptera
    Feb 8, 2021 · Inspite of this, lepidopteran eggs have been used as the standard food in the commercial mass- rearing of Orius spp. since the early 1990s ( ...
  50. [50]
    Enhanced biocontrol services in artificially selected strains of Orius ...
    Jul 24, 2022 · WFT larvae are more vulnerable than adults because they move less and more slowly, while adults are more active and so more likely to evade ...Enhanced Biocontrol Services... · Insect Rearing · Discussion<|separator|>
  51. [51]
    Orius for Thrips control - Biological Pest Control
    Orius insidiosus, also called the minute pirate bug, is an aggressive thrips predator – possibly the most effective. It attacks and kills all mobile stages of ...Missing: synonyms | Show results with:synonyms
  52. [52]
    [PDF] Consistent thrips biological control by Orius insidiosus on cucumber ...
    Jun 23, 2025 · Orius insidiosus successfully established under all tested lighting conditions, consistently reducing thrips populations and limiting leaf ...
  53. [53]
    Managing Thrips Parvispinus: New Research on Cultural and ...
    Jun 20, 2025 · O. insidiosus reduced adult thrips populations by 86%. A. baccarum achieved 91% control. In 8-week-long greenhouse cage studies:.
  54. [54]
    Reduced-risk insecticides can effectively manage thrips without ...
    Jul 18, 2025 · Reduced-risk insecticides can effectively manage thrips without compromising Orius predation in pepper production. July 2025; Biological ...