Biology:Head louse

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Short description: Insect parasite of humans

Head louse
Male human head louse.jpg
Scientific classification e
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Psocodea
Family: Pediculidae
Genus: Pediculus
Species:
Subspecies:
P. h. capitis
Trinomial name
Pediculus humanus capitis
De Geer, 1767
Synonyms

Pediculus capitis (De Geer, 1767)

Pediculus humanus capitis by Des Helmore

The head louse (Pediculus humanus capitis) is an obligate ectoparasite of humans.[1] Head lice are wingless insects that spend their entire lives on the human scalp and feed exclusively on human blood.[1] Humans are the only known hosts of this specific parasite, while chimpanzees and bonobos host a closely related species, Pediculus schaeffi. Other species of lice infest most orders of mammals and all orders of birds.

Lice differ from other hematophagic ectoparasites such as fleas in spending their entire lifecycle on a host.[2] Head lice cannot fly, and their short, stumpy legs render them incapable of jumping, or even walking efficiently on flat surfaces.[2]

The non-disease-carrying head louse differs from the related disease-carrying body louse (Pediculus humanus humanus) in preferring to attach eggs to scalp hair rather than to clothing. The two subspecies are morphologically almost identical, but do not normally interbreed. From genetic studies, they are thought to have diverged as subspecies about 30,000–110,000 years ago, when many humans began to wear a significant amount of clothing.[3][4] A much more distantly related species of hair-clinging louse, the pubic or crab louse (Pthirus pubis), also infests humans. It is morphologically different from the other two species and is much closer in appearance to the lice which infest other primates.[5] Louse infestation of the body is known as pediculosis, pediculosis capitis for head lice, pediculosis corporis for body lice, and phthiriasis for pubic lice.[6]

Adult morphology

File:Head louse crawling on hairbrush.webm Like other insects of the suborder Anoplura, adult head lice are small (2.5–3 mm long), dorsoventrally flattened (see anatomical terms of location), and wingless.[7] The thoracic segments are fused, but otherwise distinct from the head and abdomen, the latter being composed of seven visible segments.[8] Head lice are grey in general, but their precise color varies according to the environment in which they were raised.[8] After feeding, consumed blood causes the louse body to take on a reddish color.[8]

Head

Male head louse, adult
Female head louse, adult

One pair of antennae, each with five segments, protrudes from the insect's head. Head lice also have one pair of eyes. Eyes are present in all species within the Pediculidae family, but are reduced or absent in most other members of the Anoplura suborder.[7] Like other members of the Anoplura, head louse mouthparts are highly adapted for piercing the skin and sucking blood.[7] These mouth parts are retracted into the insect's head except during feeding.[8][9]

Thorax

Head louse gripping a human hair

Six legs project from the fused segments of the thorax.[8] As is typical in the Anoplura, these legs are short and terminate with a single claw and opposing "thumb".[8] Between its claw and thumb, the louse grasps the hair of its host.[8] With their short legs and large claws, lice are well adapted to clinging to the hair of their host. These adaptations leave them incapable of jumping, or even walking efficiently on flat surfaces. Lice can climb up strands of hair very quickly, allowing them to move quickly and reach another host.[2]

Abdomen

Seven segments of the louse abdomen are visible.[8] The first six segments each have a pair of spiracles through which the insect breathes.[8] The last segment contains the anus and (separately) the genitalia.[8]

Sex differences

In male lice, the front two legs are slightly larger than the other four. This specialized pair of legs are used for holding the female during copulation. Males are slightly smaller than females and are characterized by a pointed end of the abdomen and a well-developed genital apparatus visible inside the abdomen. Females are characterized by two gonopods in the shape of a W at the end of their abdomens.

Eggs and nits

Head louse egg (nit) attached to hair shaft of host

Like most insects, head lice are oviparous. Females lay about three or four eggs per day. Louse eggs (also known as nits), are attached near the base of a host hair shaft.[10][11] Eggs are usually laid on the base of the hair, 3–5 mm off the scalp surface.[10][11] In warm climates, and especially the tropics, eggs may be laid 6 inches (15 cm) or more down the hair shaft.[12]

To attach an egg, the adult female secretes a glue from her reproductive organ. This glue quickly hardens into a "nit sheath" that covers the hair shaft and large parts of the egg except for the operculum, a cap through which the embryo breathes.[11] The glue was previously thought to be chitin-based, but more recent studies have shown it to be made of proteins similar to hair keratin.[11]

Each egg is oval-shaped and about 0.8 mm in length.[11] They are bright, transparent, and tan to coffee-colored so long as they contain an embryo, but appear white after hatching.[11][12] Head lice hatch typically six to nine days after oviposition.[10][13]

After hatching, the louse nymph leaves behind its egg shell, still attached to the hair shaft. The empty egg shell remains in place until physically removed by abrasion or the host, or until it slowly disintegrates, which may take six or more months.[13]

Empty shells are mat, collapsed and white in color. The term nit may include any of the following:[14]

  • Viable eggs that will eventually hatch
  • Remnants of already-hatched eggs (nits)
  • Nonviable eggs (dead embryo) that will never hatch

Of these three, only eggs containing viable embryos have the potential to infest or reinfest a host.[15] However, a no nit policy is a common public health measure to prevent transmission of lice. Some authors have therefore restricted the definition of nit to describe only a hatched or nonviable egg:

Louse hatching
In many languages, the terms used for the hatched eggs, which were obvious for all to see, have subsequently become applied to the embryonated eggs that are difficult to detect. Thus, the term "nit" in English is often used for both. However, in recent years, my colleagues and I have felt the need for some simple means of distinguishing between the two without laborious qualification. We have, therefore, come to reserve the term "nit" for the hatched and empty egg shell and refer to the developing embryonated egg as an "egg".
—Ian F. Burgess (1995)[13]
The empty eggshell, termed a nit...
—J. W. Maunder (1983)[2]
...nits (dead eggs or empty egg cases)...
—Kosta Y. Mumcuoglu and others (2006)[16]

Others have retained the broad definition, while simultaneously attempting to clarify its relevance to infestation:

In the United States the term "nit" refers to any egg regardless of its viability.
—Terri Lynn Meinking (1999)[12]
Because nits are simply egg casings that can contain a developing embryo or be empty shells, not all nits are infective.
—L. Keoki Williams and others (2001)[10]
Head lice eggs (nits) are brown or white (empty shells) and attached to the hair
—NHS (2018)[17]

In British and Irish slang the term "nit" is often used, across different age groups, to refer to the head lice themselves.[18][19][20][21]

Development and nymphs

Development of Pediculus humanus humanus (body lice), which is similar to that of head lice (Pediculus humanus capitis)

Head lice, like other insects of the order Phthiraptera, are hemimetabolous.[1][9] Newly hatched nymphs will moult three times before reaching the sexually mature adult stage.[1] Thus, mobile head lice populations may contain eggs, nits, three nymphal instars, and the adults (male and female) (imago).[1] Metamorphosis during head louse development is subtle. The only visible differences between different instars and the adult, other than size, is the relative length of the abdomen, which increases with each molt,[1] as well as the existence of reproductive organs in the adults. Aside from reproduction, nymph behavior is similar to the adult. Like adults, nymphs feed also only on human blood (hematophagia), and cannot survive long away from a host.[1] Outside their hosts lice cannot survive more than 24 hrs.[22] The time required for head lice to complete their nymph development to the imago lasts for 12–15 days.[1]

Nymph mortality in captivity is about 38%, especially within the first two days of life.[1] In the wild, mortality may instead be highest in the third instar.[1] Nymph hazards are numerous. Failure to completely hatch from the egg is invariably fatal.[1] Death during molting can also occur, although it is reportedly uncommon.[1] During feeding, the nymph gut can rupture, dispersing the host's blood throughout the insect body. This results in death within a day or two.[1] Whether the high mortality recorded under experimental conditions is representative of conditions in the wild is unclear.[1]

Reproduction and lifespan

Copulation in Pediculus humanus humanus (Pediculus humanus capitis is similar), female is on top, with the male below. Dilation of the female's vagina has already occurred, and the male's dilator rests against his back (dorsal surface), out of the way. The male vesica, which contains the penis proper (not seen), is fully inserted into the vagina. Note the male's attachment with his specialized claws on the first leg pair to the specialized notch on the female's third leg pair.

Head lice reproduce sexually, and copulation is necessary for the female to produce fertile eggs. Parthenogenesis, the production of viable offspring by virgin females, does not occur in Pediculus humanus.[1] Pairing can begin within the first 10 hours of adult life.[1] After 24 hours, adult lice copulate frequently, with mating occurring during any period of the night or day.[1][23] Mating attachment frequently lasts more than an hour.[23] Young males can successfully pair with older females, and vice versa.[1]

Experiments with P. h. humanus (body lice) emphasize the attendant hazards of lice copulation. A single young female confined with six or more males will die in a few days, having laid very few eggs.[1] Similarly, death of a virgin female was reported after admitting a male to her confinement.[23] The female laid only one egg after mating, and her entire body was tinged with red—a condition attributed to rupture of the alimentary canal during the sexual act.[23] Old females frequently die following, if not during, copulation.[23] During its lifespan of 4 weeks a female louse lays 50-150 eggs. Eggs hatch within 6–9 days, each nymphal stage last for 4–5 days and accordingly the period from egg to adults lasts for 18–24 days. Adult lice live for an additional 3–4 weeks.[24]

Factors affecting infestation

Main page: Medicine:Head lice infestation

The number of children per family, the sharing of beds and closets, hair washing habits, local customs and social contacts, healthcare in a particular area (e.g. school), and socioeconomic status were found to be significant factors in head louse infestation. Girls are two to four times more frequently infested than boys. Children between 4 and 14 years of age are the most frequently infested group.[25]

Behaviour

Feeding

All stages except eggs are blood-feeders and bite the skin four to five times daily to feed. They inject saliva which contains an anticoagulant and suck blood. The digested blood is excreted as dark red frass.[26]

Position on host

Although any part of the scalp may be colonized, lice favor the nape of the neck and the area behind the ears, where the eggs are usually laid. Head lice are repelled by light and move towards shadows or dark-coloured objects in their vicinity.[23][27]

Transmission

Lice have no wings or powerful legs for jumping, so they move using the claws on their legs to move from hair to hair.[26] Normally, head lice infest a new host only by close contact between individuals, making social contacts among children and parent-child interactions more likely routes of infestation than shared combs, hats, brushes, towels, clothing, beds, or closets. Head-to-head contact is by far the most common route of lice transmission.[28]

Distribution

About 6–12 million people, mainly children, are treated annually for head lice in the United States alone. In the UK, it is estimated that two thirds of children will experience at least one case of head lice before leaving primary school.[29] High levels of louse infestations have also been reported from all over the world, including Australia, Denmark, France, Ireland, Israel, and Sweden.[15][30]

Archaeogenetics

Analysis of the DNA of lice found on Peruvian mummies may indicate that some diseases (such as typhus) may have passed from the New World to the Old World, instead of the other way around.[31][32]

Genome

The sequencing of the genome of the body louse was first proposed in the mid-2000s[33] and the annotated genome was published in 2010.[34] An analysis of the body and head louse transcriptomes revealed these two organisms are extremely similar genetically.[35]

Mitochondrial clades

Human lice are divided into three deeply divergent mitochondrial clades known as A, B, and C.[36][37] Three subclades have been identified, D (a sister clade of A), E (a sister clade of C), and F (a sister clade of B).[38][39][40]

Clade A

  • head and body: worldwide
  • found in ancient Roman Judea[32]

Clade D (sister of clade A)

  • head and body: Central Africa, Ethiopia, United States

Clade B

  • head only: worldwide
  • found in ancient Roman Judea and 4,000-year-old Chilean mummy

Clade F (sister of clade B)

  • head and body: South America

Clade C

  • head only: Ethiopia, Nepal, Thailand

Clade E (sister of clade C)

  • head only: West Africa

See also

References

  1. 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 1.13 1.14 1.15 1.16 1.17 1.18 Buxton, Patrick A. (1947). "The biology of Pediculus humanus". The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 24–72. 
  2. 2.0 2.1 2.2 2.3 Maunder, J. W. (1983). "The Appreciation of Lice". Proceedings of the Royal Institution of Great Britain 55: 1–31. 
  3. "Molecular evolution of Pediculus humanus and the origin of clothing". Current Biology 13 (16): 1414–7. August 2003. doi:10.1016/S0960-9822(03)00507-4. PMID 12932325. 
  4. Stoneking, Mark (29 December 2004). "Erratum: Molecular Evolution of Pediculus humanus and the Origin of Clothing". Current Biology 14 (24): 2309. doi:10.1016/j.cub.2004.12.024. 
  5. Buxton, Patrick A. (1947). "The crab louse Phthirus pubis". The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 136–141. 
  6. "pediculosis – Definition from the Merriam-Webster Online Dictionary". http://www.merriam-webster.com/dictionary/pediculosis. 
  7. 7.0 7.1 7.2 Buxton, Patrick A. (1947). "The Anoplura or Sucking Lice". The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 1–4. 
  8. 8.0 8.1 8.2 8.3 8.4 8.5 8.6 8.7 8.8 8.9 Buxton, Patrick A. (1947). "The Anatomy of Pediculus humanus". The Louse; an account of the lice which infest man, their medical importance and control (2nd ed.). London: Edward Arnold. pp. 5–23. 
  9. 9.0 9.1 "Lice (Pediculosis)". Whitehouse Station, NJ USA: Merck & Co.. 2008. http://www.merckvetmanual.com/mvm/index.jsp?cfile=htm/bc/71900.htm&word=pediculosis. 
  10. 10.0 10.1 10.2 10.3 "Lice, nits, and school policy". Pediatrics 107 (5): 1011–5. May 2001. doi:10.1542/peds.107.5.1011. PMID 11331679. 
  11. 11.0 11.1 11.2 11.3 11.4 11.5 "Head lice: scientific assessment of the nit sheath with clinical ramifications and therapeutic options". Journal of the American Academy of Dermatology 53 (1): 129–33. July 2005. doi:10.1016/j.jaad.2005.01.134. PMID 15965432. 
  12. 12.0 12.1 12.2 Meinking, Terri Lynn (May–June 1999). "Infestations". Current Problems in Dermatology 11 (3): 75–118. doi:10.1016/S1040-0486(99)90005-4. 
  13. 13.0 13.1 13.2 Burgess, I. F. (1995). "Human lice and their management". Advances in Parasitology Volume 36. 36. pp. 271–342. doi:10.1016/S0065-308X(08)60493-5. ISBN 978-0-12-031736-3. 
  14. "Overdiagnosis and consequent mismanagement of head louse infestations in North America". The Pediatric Infectious Disease Journal 19 (8): 689–93; discussion 694. August 2000. doi:10.1097/00006454-200008000-00003. PMID 10959734. 
  15. 15.0 15.1 Burgess, I. F. (2004). "Human lice and their control". Annu. Rev. Entomol. 49: 457–81. doi:10.1146/annurev.ento.49.061802.123253. PMID 14651472. 
  16. "Head louse infestations: the 'no nit' policy and its consequences". International Journal of Dermatology 45 (8): 891–6. August 2006. doi:10.1111/j.1365-4632.2006.02827.x. PMID 16911370. 
  17. "Head lice and nits". 2017-10-19. https://www.nhs.uk/conditions/head-lice-and-nits/. 
  18. "Head lice: How to spot nits in hair and what to do about them". News Shopper. 13 September 2018. https://www.newsshopper.co.uk/news/16858287.head-lice-how-to-spot-nits-in-hair-and-what-to-do-about-them/. 
  19. "Nit treatments are like diets. The truth is, nothing works". The Guardian. 21 June 2018. https://www.theguardian.com/commentisfree/2018/jun/21/nit-treatments-are-like-diets-the-truth-is-nothing-works. 
  20. "How to get rid of head lice". 25 December 2021. https://adsn.io/get-rid-of-head-lice/. 
  21. "Back to school herbalism — natural ways to nuke nits". Irish Examiner. 1 September 2018. https://www.irishexaminer.com/breakingnews/lifestyle/healthandlife/back-to-school-herbalism-natural-ways-to-nuke-nits-865912.html. 
  22. "International recommendations for an effective control of head louse infestations". International Journal of Dermatology 60 (3): 272–80. March 2020. doi:10.1111/ijd.15096. PMID 32767380. 
  23. 23.0 23.1 23.2 23.3 23.4 23.5 Bacot, A. (1917). "Contributions to the bionomics of Pediculus humanus (vestimenti) and Pediculus capitis". Parasitology 9 (2): 228–258. doi:10.1017/S0031182000006065. 
  24. "Epidemiological studies on head lice infestation in Israel. I. Parasitological examination of children". International Journal of Dermatology 29 (7): 502–6. September 1990. doi:10.1111/j.1365-4362.1990.tb04845.x. PMID 2228380. 
  25. "Effective treatment of head louse with pediculicides.". Journal of Drugs in Dermatology 5 (5): 451–2. May 2006. PMID 16703782. 
  26. 26.0 26.1 Weems, H. V. Jr.; Fasulo, T. R. (June 2007). "Human Lice: Body Louse, Pediculus humanus humanus Linnaeus and Head Louse, Pediculus humanus capitis De Geer (Insecta: Phthiraptera (=Anoplura): Pediculidae)". University of Florida, Institute of Food and Agricultural Sciences. http://entomology.ifas.ufl.edu/creatures/urban/human_lice.htm. 
  27. Nuttall, George H. F. (1919). "The biology of Pediculus humanus, Supplementary notes". Parasitology 11 (2): 201–221. doi:10.1017/s0031182000004194. https://zenodo.org/record/1428634. 
  28. "NJ Head Lice | Philadelphia and South New Jersey Hair Lice". Lice Lifters New Jersey. http://www.liceliftersnewjersey.com/lice-myths-facts/. 
  29. "Two thirds of British children will catch head lice during school years, study finds" (in en-GB). 2017-04-20. http://instituteofmums.com/2017/04/20/two-thirds-of-british-children-will-catch-head-lice-during-school-years-study-finds/. 
  30. "International guidelines for effective control of head louse infestations". Journal of Drugs in Dermatology 6 (4): 409–14. April 2007. PMID 17668538. 
  31. Anderson, Andrea (February 8, 2008). "DNA from Peruvian Mummy Lice Reveals History". GenomeWeb LLC. http://www.genomeweb.com/dna-peruvian-mummy-lice-reveals-history. 
  32. 32.0 32.1 "High Ancient Genetic Diversity of Human Lice, Pediculus humanus, from Israel Reveals New Insights into the Origin of Clade B Lice.". PLOS ONE 14 (2016 Oct 14;11(10):e01646595): e0164659. 2016. doi:10.1371/journal.pone.0164659. PMID 27741281. Bibcode2016PLoSO..1164659A. 
  33. "Sequencing of a new target genome: the Pediculus humanus humanus (Phthiraptera: Pediculidae) genome project". Journal of Medical Entomology 43 (6): 1103–11. November 2006. doi:10.1603/0022-2585(2006)43[1103:SOANTG2.0.CO;2]. PMID 17162941. 
  34. "Genome sequences of the human body louse and its primary endosymbiont provide insights into the permanent parasitic lifestyle". Proceedings of the National Academy of Sciences of the United States of America 107 (27): 12168–73. July 2013. doi:10.1073/pnas.1003379107. PMID 20566863. Bibcode2010PNAS..10712168K. 
  35. "Comparison of the transcriptional profiles of head and body lice". Insect Molecular Biology 21 (2): 257–68. April 2012. doi:10.1111/j.1365-2583.2012.01132.x. PMID 22404397. 
  36. Morand, Serge; Krasnov, Boris R.; Littlewood, D. Timothy J. (26 February 2015). Parasite Diversity and Diversification: Evolutionary Ecology Meets Phylogenetics. Cambridge University Press. p. 208. ISBN 978-1-316-23993-3. https://books.google.com/books?id=fwq0BgAAQBAJ&pg=PA208. Retrieved 30 December 2017. 
  37. Knapp, Michael; Boutellis, Amina; Drali, Rezak; Rivera, Mario A.; Mumcuoglu, Kosta Y.; Raoult, Didier (2013). "Evidence of Sympatry of Clade A and Clade B Head Lice in a Pre-Columbian Chilean Mummy from Camarones". PLOS ONE 8 (10): e76818. doi:10.1371/journal.pone.0076818. ISSN 1932-6203. PMID 24204678. Bibcode2013PLoSO...876818B. 
  38. Gao, Feng; Amanzougaghene, Nadia; Mumcuoglu, Kosta Y.; Fenollar, Florence; Alfi, Shir; Yesilyurt, Gonca; Raoult, Didier; Mediannikov, Oleg (2016). "High Ancient Genetic Diversity of Human Lice, Pediculus humanus, from Israel Reveals New Insights into the Origin of Clade B Lice". PLOS ONE 11 (10): e0164659. doi:10.1371/journal.pone.0164659. ISSN 1932-6203. PMID 27741281. Bibcode2016PLoSO..1164659A. 
  39. Liao, Chien-Wei; Cheng, Po-Ching; Chuang, Ting-Wu; Chiu, Kuan-Chih; Chiang, I-Chen; Kuo, Juo-Han; Tu, Yun-Hung; Fan, Yu-Min et al. (2017). "Prevalence of Pediculus capitis in schoolchildren in Battambang, Cambodia". Journal of Microbiology, Immunology and Infection 52 (4): 585–591. doi:10.1016/j.jmii.2017.09.003. ISSN 1684-1182. PMID 29150362. 
  40. Amanzougaghene, Nadia; Fenollar, Florence; Davoust, Bernard; Djossou, Félix; Ashfaq, Muhammad; Bitam, Idir; Raoult, Didier; Mediannikov, Oleg (June 2019). "Mitochondrial diversity and phylogeographic analysis of Pediculus humanus reveals a new Amazonian clade "F"". Infection, Genetics and Evolution 70: 1–8. doi:10.1016/j.meegid.2019.02.006. PMID 30769089. https://pubmed.ncbi.nlm.nih.gov/30769089/. Retrieved 26 January 2022. 

External links

Wikidata ☰ Q27358 entry