Calliphora vomitoria: Difference between revisions
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==Description== |
==Description== |
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[[File:Calliphora vomitoria male head.jpg|thumb|Lateral close-up of a male ''C. vomitoria'' |alt=|left|243x243px]] |
[[File:Calliphora vomitoria male head.jpg|thumb|Lateral close-up of a male ''C. vomitoria'' |alt=|left|243x243px]] |
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Blue bottle flies are typically {{convert|10|-|14|mm| |
Blue bottle flies are typically {{convert|10|-|14|mm|in|frac=16|abbr=on}} long, almost twice the size of a [[housefly]]. The head and [[thorax]] are dull gray, and the back of the head has long yellow-orange [[seta]]e.<ref>{{cite journal|first1=Terry |last1=Whitworth|url=http://www.blowflies.net/images/Publications/Keys.pdf |title=Keys to genera and species of blow flies (Diptera: Calliphoridae) of America north of Mexico|journal= Proceedings of the Entomological Society of Washington|volume=108 |issue=3|pages= 689–725|date= 2006}}</ref><ref>Krzysztof Szpila: [http://www.eafe.org/Members_area_files/Szpila_key_blowflies_imago.pdf Key for identification of European and Mediterranean blowflies (Diptera, Calliphoridae) of forensic importance. Adult flies]</ref> The [[abdomen]] is bright metallic blue with black markings. Its body and legs are covered with black bristly hairs. It has short, clubbed [[Antenna (biology)|antennae]] and four [[Tarsus (skeleton)|tarsi]] per leg. The eyes are red and the wings are transparent. The legs and antennae are black and pink. The chest is bright purple and has spikes for protection from other flies.<ref>Jean-Henri Fabre, 1907 - La mouche verte et violette</ref><ref name="MC">Michael Chinery, Insectes de France et d'Europe occidentale, Paris, Flammarion, 2012, ({{ISBN|978-2-0812-8823-2}}), p. 214-215</ref> To differentiate ''C. vomitoria'' from other closely related species such as ''[[Calliphora vicina]]'', ''C. vomitoria'' can be identified by characteristic "orange cheeks", which are the orange hairs below the eyes. Additionally, ''C. vomitoria'' has a dark basicosta (base of the wing) while ''C. vicina'' has a yellow basicosta. All these characteristics can be identified through a simple photograph.<ref>{{Cite web|url=https://www.naturespot.org.uk/species/calliphora-vomitoria|title=Calliphora vomitoria {{!}} NatureSpot|website=www.naturespot.org.uk|access-date=2020-02-24}}</ref><ref>{{Cite web|url=https://www.naturespot.org.uk/species/calliphora-vicina|title=Calliphora vicina {{!}} NatureSpot|website=www.naturespot.org.uk|access-date=2020-02-24}}</ref> |
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==Distribution and habitat== |
==Distribution and habitat== |
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==Interaction with humans == |
==Interaction with humans == |
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===Forensics=== |
===Forensics=== |
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These flies are among the most important insect evidence in [[forensic science]], specifically for obtaining time of colonization (TOC) and [[Post-mortem interval|post mortem interval]] (PMI).<ref name=":3" /> ''Calliphora'' species are the most important in temperate regions because of their growth rate in accordance to temperature. By knowing the temperature, the amount of time since the eggs were laid can be estimated. In addition, ''C. vomitoria'' has higher threshold temperature for growth than many species; likewise, it is present in many regions. There is a limit to their usage, though, as few species can survive in cold temperatures; most cannot continue development unless it is warmer than roughly |
These flies are among the most important insect evidence in [[forensic science]], specifically for obtaining time of colonization (TOC) and [[Post-mortem interval|post mortem interval]] (PMI).<ref name=":3" /> ''Calliphora'' species are the most important in temperate regions because of their growth rate in accordance to temperature. By knowing the temperature, the amount of time since the eggs were laid can be estimated. In addition, ''C. vomitoria'' has higher threshold temperature for growth than many species; likewise, it is present in many regions. There is a limit to their usage, though, as few species can survive in cold temperatures; most cannot continue development unless it is warmer than roughly {{cvt|2|C|F}}.<ref>{{Cite journal|last=Kamal|first=Adel S.|date=1958-05-01|title=Comparative Study of Thirteen Species of Sarcosaprophagous Calliphoridae and Sarcophagidae (Diptera) I. Bionomics|url=https://academic.oup.com/aesa/article/51/3/261/17264|journal=Annals of the Entomological Society of America|language=en|volume=51|issue=3|pages=261–271|doi=10.1093/aesa/51.3.261|issn=0013-8746}}</ref> |
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Degradation of carcasses can be divided into six separate stages: stage of decomposition, fresh stage, bloated stage, active decay stage, advanced decay stage, and remains stage. Adult ''C. vomitoria'' first starts to appear at carcasses during the bloated stage, followed by larvae 1 to 3 days after. During the active decay stage, blow fly larvae population reaches its peak.<ref>{{Cite journal|last1=Matuszewski|first1=Szymon|last2=Bajerlein|first2=Daria|last3=Konwerski|first3=Szymon|last4=Szpila|first4=Krzysztof|date=2008-09-18|title=An initial study of insect succession and carrion decomposition in various forest habitats of Central Europe|journal=Forensic Science International|volume=180|issue=2|pages=61–69|doi=10.1016/j.forsciint.2008.06.015|pmid=18715728|issn=0379-0738}}</ref> |
Degradation of carcasses can be divided into six separate stages: stage of decomposition, fresh stage, bloated stage, active decay stage, advanced decay stage, and remains stage. Adult ''C. vomitoria'' first starts to appear at carcasses during the bloated stage, followed by larvae 1 to 3 days after. During the active decay stage, blow fly larvae population reaches its peak.<ref>{{Cite journal|last1=Matuszewski|first1=Szymon|last2=Bajerlein|first2=Daria|last3=Konwerski|first3=Szymon|last4=Szpila|first4=Krzysztof|date=2008-09-18|title=An initial study of insect succession and carrion decomposition in various forest habitats of Central Europe|journal=Forensic Science International|volume=180|issue=2|pages=61–69|doi=10.1016/j.forsciint.2008.06.015|pmid=18715728|issn=0379-0738}}</ref> |
Revision as of 12:53, 17 June 2021
Calliphora vomitoria | |
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Female | |
Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Animalia |
Phylum: | Arthropoda |
Class: | Insecta |
Order: | Diptera |
Family: | Calliphoridae |
Genus: | Calliphora |
Species: | C. vomitoria
|
Binomial name | |
Calliphora vomitoria | |
Synonyms[1][2] | |
|
Calliphora vomitoria, known as the blue bottle fly,[3] orange-bearded blue bottle,[4] or bottlebee is a species of blow fly, a species in the family Calliphoridae. Calliphora vomitoria is the type species of the genus Calliphora. It is common throughout many continents including Europe, Americas, and Africa. They are fairly large flies, nearly twice the size of the housefly. They can be easily identified by their shiny, blue bodies.
While adult flies feed on nectar, females deposit their eggs on rotting corpses, making them important forensic insects, as their eggs and timing of oviposition can be used to estimate time of death.
Description
Blue bottle flies are typically 10–14 mm (3⁄8–9⁄16 in) long, almost twice the size of a housefly. The head and thorax are dull gray, and the back of the head has long yellow-orange setae.[5][6] The abdomen is bright metallic blue with black markings. Its body and legs are covered with black bristly hairs. It has short, clubbed antennae and four tarsi per leg. The eyes are red and the wings are transparent. The legs and antennae are black and pink. The chest is bright purple and has spikes for protection from other flies.[7][8] To differentiate C. vomitoria from other closely related species such as Calliphora vicina, C. vomitoria can be identified by characteristic "orange cheeks", which are the orange hairs below the eyes. Additionally, C. vomitoria has a dark basicosta (base of the wing) while C. vicina has a yellow basicosta. All these characteristics can be identified through a simple photograph.[9][10]
Distribution and habitat
Calliphora vomitoria can be found throughout the world, including most of Europe, Alaska, Greenland, the south of Mexico, United States, and southern Africa.[11][12] It prefers higher elevations relative to other Calliphoridae species, such as Lucilia sericata and Chrysomya albiceps. They are among the most abundant flies found in these regions.[13]
Temperature has a significant effect on distribution. As is the case with most flies, C. vomitoria are found most abundantly during spring and summer, and least abundant during fall and winter.[14] The preferred habitat of C. vomitoria varies depending on the season. During winter and summer, they can be found mostly in rural areas (and riparian areas to a lesser extent). During spring and fall, they are found in riparian areas.[15]
Life cycle
Blue bottle flies have the complete cycle of egg, larva, pupa, and adult. Development usually takes around 2 weeks.[16] Larvae are protein-rich and can theoretically be used as feed. A female blue bottle fly lays her eggs where she feeds, usually in decaying meat, garbage, or feces. Pale whitish larvae, commonly called maggots, soon hatch from the eggs and immediately begin feeding on carcasses of dead animals and on the decomposing matter where they were hatched.[17] After a few days of feeding, they are fully grown. At that time they crawl away to a drier place where they burrow into soil or similar matter and pupate into tough brown cocoons. The pupal stage is the longest stage of the development cycle.[14]
After two or three weeks, the adults emerge from the pupal stage to mate, beginning the cycle again. During cold weather, pupae and adults can hibernate until higher temperatures revive them.[8]
Metamorphosis and cell death
Undergoing metamorphosis requires a tremendous amount of change for the fly, such as cell death. While it is commonly believed that programmed cell death and apoptosis are the same, they are not always so. At the beginning of metamorphosis during the larvae stage, salivary gland cells of Calliphora vomitoria larvae are self-programmed to destroy. After enough feeding, the larvae come to rest and an initial protein synthesis stage surges, culminating in the production of high amounts of protein. This occurs from day 1 to about day 8. Then, on day 9, cell death of salivary gland cells occurs. This pattern of synthesis and destruction is not to be confused with apoptosis, as no DNA degeneration is seen and cells are shown to vacuolate and swell (compared to condense and shrink in the case of apoptosis). Instead, selective expression and DNA synthesis is seen to support programmed cell death (of salivary gland cells).[18]
Diet
Like other blowflies, C. vomitoria colonize animal remains, including humans. While adult C. vomitoria feed on nectar, the larvae feed on corpses, the medium in which they grow. However, it has been shown that feeding on processed substrates (food that are modified for human consumption by increasing shelf life and taste through salting, curing, smoking, etc) provided much better growth than unprocessed substrates such as raw unmodified liver. Because different substrates drastically affected growth, C. vomitoria is best characterized as a specialist that best utilizes processed substrates (minced meats, for example). Its close relative, Calliphora vicina, is a generalist, being able to utilize mixed substrates with equal growth rates.[19] In the case of overcrowding, C. vomitoria competition results in compensation by increased speed of development, leading to smaller larvae and adults. This has complications in forensics because different parts of the body would grow at different rates.[20] Additionally, it has been shown that the fly larvae are able to colonize even buried remains. Growth rates between surface and buried larvae grew at a similar increased pace.[21] Usually, these flies lay their eggs around wounds on fresh corpses shortly after death. Right before the pupal stage, the fly larvae that leaves the carrion can burrow into the soil in order to pupate. Then, adult flies emerge.[14] In decaying carcasses, it was found that Calliphoridae flies dominate, especially C. vomitoria. In both spring and fall, C. vomitoria is the primary species found on carcasses. In some cases, C. vomitoria shares carcasses with other calliphorid species such as Lucilia caesar.[22]
Bluebottle fly adults feed on nectar, and they are pollinators of flowers. They are especially attracted to flowers that have strong odors, such as those that have adapted to smell like rotting meat. Plants pollinated by the fly include the skunk cabbage (Symplocarpus foetidus), American pawpaw (Asimina triloba), dead horse arum (Helicodiceros muscivorus), goldenrod and some species of the carrot family.[23] These insects tend to fly in packs in order to detect possible food sources more efficiently. If one fly detects food, it disperses a pheromone, which will alert the others to the meal.[8]
Parental care
Blow flies like C. vomitoria lay their eggs at carrion sites, which are scarce in most places so these corpses end up with many eggs of various species. As a result, high larval density arises. In fact, when there are many other individuals around the site, pregnant females increase oviposition rate (which increases number of offsprings), likely triggered by contact and chemical stimulation.[24] The large number of larvae, though, ends up being beneficial for each individual. The larvae feed by secretion of enzymes that break down tissues of the corpse, so by aggregating in large numbers these secretions are more effective, leading to easier feeding. Additionally, the large aggregation helps generate heat and keep the larvae warm, as the flies generally prefer warmer temperature. One complication with the high number of individuals is that competition is still a factor, as larvae on the periphery may be left out of the feeding, and by the end of the developmental cycle they emerge undernourished and undersized.[20]
Physiology
Night flight
It has been suggested that C. vomitoria rarely fly at night, regardless of the presence of an existing corpse. This suggests that they do not deposit eggs on corpses during the night. Its application to forensic science then stems from the idea that the rough time of oviposition can be determined by narrowing oviposition to day time.[25]
Hormones
The median neuro-secretory cells (MNC) of the brain of Calliphora species contain peptide hormones that resemble insulin. This was proven when researchers were able to bind these insulin-like peptides with antibodies of bovine insulin. This shows that an insect hormone can be structurally analogous to a prominent mammalian hormone[20] and it brings up the possibility of these insulin-like or polypeptide-like materials serving as central nervous system regulatory hormones before they were metabolic regulatory hormones.[26][27]
Adhesive organ
On the terminal region of the 5th tarsal segment, the C. vomitoria contain pulvilli, which are the cushion-like hairy feet on insects and many arthropods located at base of their two claws. The hair that project from the ventral surface is the key for the adhesion abilities of these flies. Additionally, they have large claws that help to hold on to irregular surfaces to prevent falling. C. vomitoria, like other blowflies, also secrete non-volatile lipids through the hairs that are important for further adhesion. By a combination of the physical grip of the claws and hairs and the surface tension created by the lipid secretions, they are able to adhere to smooth surfaces with ease.[28][29]
Interaction with humans
Forensics
These flies are among the most important insect evidence in forensic science, specifically for obtaining time of colonization (TOC) and post mortem interval (PMI).[14] Calliphora species are the most important in temperate regions because of their growth rate in accordance to temperature. By knowing the temperature, the amount of time since the eggs were laid can be estimated. In addition, C. vomitoria has higher threshold temperature for growth than many species; likewise, it is present in many regions. There is a limit to their usage, though, as few species can survive in cold temperatures; most cannot continue development unless it is warmer than roughly 2 °C (36 °F).[30]
Degradation of carcasses can be divided into six separate stages: stage of decomposition, fresh stage, bloated stage, active decay stage, advanced decay stage, and remains stage. Adult C. vomitoria first starts to appear at carcasses during the bloated stage, followed by larvae 1 to 3 days after. During the active decay stage, blow fly larvae population reaches its peak.[31]
In buried corpses, information of time since burial and how the body was kept (above/below ground before burial) can also be collected through the identification of C. vomitoria.[21] The study of these flies, however, is limited to areas where entomologists are readily available, as life histories can differ in separate regions. These life histories differ in subtle ways due to differences in climate such as temperature and elevation. These restrictions should be thus considered so the proper time of colonization (TOC) and post mortem interval (PMI) can be established.[14]
This bluebottle fly can also cause human or animal myiasis (parasitization in a living individual). Forensic scientists sometimes identify it in the course of their work, such as in one case of an autopsy of a neglected child.[32][33]
Identification
C. vomitoria is often not the only species present at carrion, so some process of identification of the correct species is needed in order to avoid false estimates of the time of death due to them having different developmental cycles. In the past, simple morphological differences are used to differentiate between species. However, it is very difficult in crime scenes because more often than not these sites are not ideal, with preservation of insect species far from good. Methods that can best differentiate between the species are DNA, mitochondrial DNA, and the COI gene. The COI gene used in conjunction with restriction enzymes has been shown to be a relatively fast and simple method of distinguishing between blowfly species with good accuracy.[34]
Post mortem interval
Post mortem interval (PMI) is the time between death and discovery of a corpse. C. vomitoria is important for PMI estimations because it is among the first species to lay eggs on the corpse. There are two ways of estimating PMI. One is killing the larvae, and then comparing the larvae's length and temperature to those in the standardized data. Another way to calculate PMI is to calculate the accumulated degree hours/days (ADH/D) that a larva needs to reach a certain developmental stage. The later method is the more widely accepted way to estimate PMI.[20]
Legal importance
As one of the most abundant flies and their tendency to be first on the case (carrion), they are very useful in legal investigations. Other Calliphora species, while important as parasites of humans, are not as important simply because they are less often found. However, there is not a clear consensus on fly distribution, as different areas attracts different species of flies, and so field research should be conducted in local areas to confirm the presence or absence of these important forensic resources.[15]
Pollination of crops
Calliphora vomitoria can sometimes act as pollinators of different crops, working especially well with strongly scented crops. The flies feed on the nectar of these crops and then proceed to spread their seeds when they fly. These seed dispersal events can lead to seed infestation of cauliflower.[35]
Gallery
References
- ^ "Calliphora vomitoria". Integrated Taxonomic Information System. Retrieved May 31, 2008.
- ^ Kurahshi, Hiromu (May 28, 2007). "109. Family CALLIPHORIDAE". Australasian/Oceanian Diptera Catalog. Hawaii Biological Survey. Retrieved May 31, 2008.
- ^ "Species Calliphora vomitoria - Blue Bottle Fly - BugGuide.Net". bugguide.net. Retrieved 10 November 2019.
- ^ "Calliphora vomitoria". National Biodiversity Network. Retrieved 10 November 2019.
- ^ Whitworth, Terry (2006). "Keys to genera and species of blow flies (Diptera: Calliphoridae) of America north of Mexico" (PDF). Proceedings of the Entomological Society of Washington. 108 (3): 689–725.
- ^ Krzysztof Szpila: Key for identification of European and Mediterranean blowflies (Diptera, Calliphoridae) of forensic importance. Adult flies
- ^ Jean-Henri Fabre, 1907 - La mouche verte et violette
- ^ a b c Michael Chinery, Insectes de France et d'Europe occidentale, Paris, Flammarion, 2012, (ISBN 978-2-0812-8823-2), p. 214-215
- ^ "Calliphora vomitoria | NatureSpot". www.naturespot.org.uk. Retrieved 2020-02-24.
- ^ "Calliphora vicina | NatureSpot". www.naturespot.org.uk. Retrieved 2020-02-24.
- ^ Fauna europaea
- ^ Calalogue of life
- ^ Baz, Arturo; Cifrián, Blanca; Díaz-äranda, Luisa María; Martín-Vega, Daniel (2007-01-01). "The distribution of adult blow-flies (Diptera: Calliphoridae) along an altitudinal gradient in Central Spain". Annales de la Société Entomologique de France. Nouvelle Série. 43 (3): 289–296. doi:10.1080/00379271.2007.10697524. ISSN 0037-9271.
- ^ a b c d e Ames, C.; Turner, B. (2003). "Low temperature episodes in development of blowflies: implications for postmortem interval estimation". Medical and Veterinary Entomology. 17 (2): 178–186. doi:10.1046/j.1365-2915.2003.00421.x. ISSN 1365-2915. PMID 12823835. S2CID 10805033.
- ^ a b Brundage, Adrienne; Bros, Shannon; Honda, Jeffrey Y. (2011-10-10). "Seasonal and habitat abundance and distribution of some forensically important blow flies (Diptera: Calliphoridae) in Central California". Forensic Science International. 212 (1): 115–120. doi:10.1016/j.forsciint.2011.05.023. ISSN 0379-0738. PMID 21683536.
- ^ "Calliphora vomitoria (Linnaeus, 1758) | Insects as Food and Feed". e-insects.wageningenacademic.com. Retrieved 2020-01-15.
- ^ Progressive Pest Control
- ^ Bowen, I. D.; Morgan, S. M.; Mullarkey, K. (1993-01-01). "Cell death in the salivary glands of metamorphosing calliphora vomitoria". Cell Biology International. 17 (1): 13–34. doi:10.1006/cbir.1993.1002. ISSN 1065-6995. PMID 8495226.
- ^ Niederegger, Senta; Wartenberg, Nelly; Spiess, Roland; Mall, Gita (2013-08-01). "Influence of food substrates on the development of the blowflies Calliphora vicina and Calliphora vomitoria (Diptera, Calliphoridae)". Parasitology Research. 112 (8): 2847–2853. doi:10.1007/s00436-013-3456-6. ISSN 1432-1955. PMID 23681195.
- ^ a b c d Ireland, Sarah; Turner, Bryan (2006-06-02). "The effects of larval crowding and food type on the size and development of the blowfly, Calliphora vomitoria". Forensic Science International. 159 (2): 175–181. doi:10.1016/j.forsciint.2005.07.018. ISSN 0379-0738. PMID 16221536.
- ^ a b Gunn, Alan; Bird, Jerry (2011-04-15). "The ability of the blowflies Calliphora vomitoria (Linnaeus), Calliphora vicina (Rob-Desvoidy) and Lucilia sericata (Meigen) (Diptera: Calliphoridae) and the muscid flies Muscina stabulans (Fallén) and Muscina prolapsa (Harris) (Diptera: Muscidae) to colonise buried remains". Forensic Science International. 207 (1): 198–204. doi:10.1016/j.forsciint.2010.10.008. ISSN 0379-0738. PMID 21071161.
- ^ Jarmusz, Mateusz; Bajerlein, Daria (2019-07-01). "Decomposition of hanging pig carcasses in a forest habitat of Poland". Forensic Science International. 300: 32–42. doi:10.1016/j.forsciint.2019.04.013. ISSN 0379-0738. PMID 31075565.
- ^ "Blue bottle fly data - Encyclopedia of Life". eol.org. Retrieved 2020-02-17.
- ^ Barton Browne, L.; Bartell, R. J.; Shorey, H. H. (1969-06-01). "Pheromone-mediated behaviour leading to group oviposition in the blowfly Lucilia cuprina". Journal of Insect Physiology. 15 (6): 1003–1014. doi:10.1016/0022-1910(69)90140-1. ISSN 0022-1910.
- ^ Wooldridge, J.; Scrase, L.; Wall, R. (2007-10-25). "Flight activity of the blowflies, Calliphora vomitoria and Lucilia sericata, in the dark". Forensic Science International. 172 (2): 94–97. doi:10.1016/j.forsciint.2006.12.011. ISSN 0379-0738. PMID 17267152.
- ^ Duve, H.; Thorpe, A.; Neville, R.; Lazarus, N. R. (1981-09-01). "Isolation and partial characterization of pancreatic polypeptide-like material in the brain of the blowfly Calliphora vomitoria". Biochemical Journal. 197 (3): 767–770. doi:10.1042/bj1970767. ISSN 0264-6021. PMC 1163195. PMID 7325987.
- ^ Duve, H.; Johnsen, A. H.; Scott, A. G.; Yu, C. G.; Yagi, K. J.; Tobe, S. S.; Thorpe, A. (1993-03-15). "Callatostatins: neuropeptides from the blowfly Calliphora vomitoria with sequence homology to cockroach allatostatins". Proceedings of the National Academy of Sciences. 90 (6): 2456–2460. Bibcode:1993PNAS...90.2456D. doi:10.1073/pnas.90.6.2456. ISSN 0027-8424. PMC 46106. PMID 8460157.
- ^ Walker, G.; Yulf, A. B.; Ratcliffe, J. (1985). "The adhesive organ of the blowfly, Calliphora vomitoria: a functional approach (Diptera: Calliphoridae)". Journal of Zoology. 205 (2): 297–307. doi:10.1111/j.1469-7998.1985.tb03536.x. ISSN 1469-7998.
- ^ Walker, G. (1993-01-01). "Adhesion to smooth surfaces by insects — a review". International Journal of Adhesion and Adhesives. 13 (1): 3–7. doi:10.1016/0143-7496(93)90002-Q. ISSN 0143-7496.
- ^ Kamal, Adel S. (1958-05-01). "Comparative Study of Thirteen Species of Sarcosaprophagous Calliphoridae and Sarcophagidae (Diptera) I. Bionomics". Annals of the Entomological Society of America. 51 (3): 261–271. doi:10.1093/aesa/51.3.261. ISSN 0013-8746.
- ^ Matuszewski, Szymon; Bajerlein, Daria; Konwerski, Szymon; Szpila, Krzysztof (2008-09-18). "An initial study of insect succession and carrion decomposition in various forest habitats of Central Europe". Forensic Science International. 180 (2): 61–69. doi:10.1016/j.forsciint.2008.06.015. ISSN 0379-0738. PMID 18715728.
- ^ Benecke, Mark; Lessig, Rüdiger (2001). "Child neglect and forensic entomology". Forensic Science International. 120 (1–2): 155–159. doi:10.1016/S0379-0738(01)00424-8. PMID 11457624.
- ^ Bowen, Ivor D.; Mullarkey, Kate; Morgan, S. M. (1996). "Programmed cell death during metamorphosis in the blow-fly Calliphora vomitoria". Microscopy Research and Technique. 34 (3): 202–217. doi:10.1002/(sici)1097-0029(19960615)34:3<202::aid-jemt3>3.0.co;2-r. ISSN 1097-0029. PMID 8743408.
- ^ Ames, Carole; Turner, Bryan; Daniel, Barbara (2006-12-20). "The use of mitochondrial cytochrome oxidase I gene (COI) to differentiate two UK blowfly species – Calliphora vicina and Calliphora vomitoria". Forensic Science International. 164 (2): 179–182. doi:10.1016/j.forsciint.2006.01.005. ISSN 0379-0738. PMID 16504435.
- ^ Wolf, Jan M. Van Der; Zouwen, Patricia S. Van Der (2010). "Colonization of Cauliflower Blossom (Brassica oleracea) by Xanthomonas campestris pv. campestris, via Flies (Calliphora vomitoria) Can Result in Seed Infestation". Journal of Phytopathology. 158 (11–12): 726–732. doi:10.1111/j.1439-0434.2010.01690.x. ISSN 1439-0434.