Temporal range: Silurian–recent
|Hirudo medicinalis sucking blood|
Leeches are segmented parasitic or predatory worms that comprise the subclass Hirudinea within the phylum Annelida. They are closely related to the oligochaetes, which include the earthworm, and like them have soft, muscular, segmented bodies that can lengthen and contract. Both groups are hermaphrodites and have a clitellum, but leeches typically differ from the oligochaetes in having suckers at both ends and in having ring markings that do not correspond with their internal segmentation. The body is muscular and relatively solid, and the coelom, the spacious body cavity found in other annelids, is reduced to small channels.
The majority of leeches live in freshwater habitats, while some species can be found in terrestrial or marine environments. The best-known species, such as the medicinal leech, Hirudo medicinalis, are hematophagous, attaching themselves to a host with a sucker and feeding on blood, having first secreted the peptide hirudin to prevent the blood from clotting. The jaws used to pierce the skin are replaced in other species by a proboscis which is pushed into the skin. A minority of leech species are predatory, mostly preying on small invertebrates.
The eggs are enclosed in a cocoon, which in aquatic species is usually attached to an underwater surface; members of one family, Glossiphoniidae, exhibit parental care, the eggs being brooded by the parent. In terrestrial species, the cocoon is often concealed under a log, in a crevice or buried in damp soil. Almost seven hundred species of leech are currently recognised, of which some hundred are marine, ninety terrestrial and the remainder freshwater.
Leeches have been used in medicine from ancient times until the 19th century to draw blood from patients. In modern times, leeches find medical use in treatment of joint diseases such as epicondylitis and osteoarthritis, extremity vein diseases, and in microsurgery, while hirudin is used as an anticoagulant drug to treat blood-clotting disorders.
Diversity and phylogeny
Some 680 species of leech have been described, of which around 100 are marine, 480 freshwater and the remainder terrestrial. Among Euhirudinea, the true leeches, the smallest is about 1 cm (1⁄2 in) long, and the largest is the giant Amazonian leech, Haementeria ghilianii, which can reach 30 cm (12 in). Except for Antarctica, leeches are found throughout the world but are at their most abundant in temperate lakes and ponds in the northern hemisphere. The majority of freshwater leeches are found in the shallow, vegetated areas on the edges of ponds, lakes and slow-moving streams; very few species tolerate fast-flowing water. In their preferred habitats, they may occur in very high densities; in a favourable environment with water high in organic pollutants, over 10,000 individuals were recorded per square metre (over 930 per square foot) under rocks in Illinois. Some species aestivate during droughts, burying themselves in the sediment, and can lose up to 90% of their bodyweight and still survive. Among the freshwater leeches are the Glossiphoniidae, dorso-ventrally flattened animals mostly parasitic on vertebrates such as turtles, and unique among annelids in both brooding their eggs and carrying their young on the underside of their bodies.
The terrestrial Haemadipsidae are mostly native to the tropics and subtropics, while the aquatic Hirudinidae have a wider global range; both of these feed largely on mammals, including humans. A distinctive family is the Piscicolidae, marine or freshwater ectoparasites chiefly of fish, with cylindrical bodies and usually well-marked, bell-shaped, anterior suckers. Not all leeches feed on blood; the Erpobdelliformes, freshwater or amphibious, are carnivorous and equipped with a relatively large, toothless mouth to ingest insect larvae, molluscs, and other annelid worms, which are swallowed whole. In turn, leeches are prey to fish, birds, and invertebrates.
The name for the subclass, Hirudinea, comes from the Latin hirudo (genitive hirudinis), a leech; the element -bdella found in many leech group names is from the Greek βδέλλα bdella, also meaning leech. The name Les hirudinées was given by Jean-Baptiste Lamarck in 1818. Leeches were traditionally divided into two infraclasses, the Acanthobdellidea (primitive leeches) and the Euhirudinea (true leeches). The Euhirudinea are divided into the proboscis-bearing Rhynchobdellida and the rest, including some jawed species, the "Arhynchobdellida", without a proboscis.
The phylogenetic tree of the leeches and their annelid relatives is based on molecular analysis (2019) of DNA sequences. Both the former classes "Polychaeta" (bristly marine worms) and "Oligochaeta" (including the earthworms) are paraphyletic: in each case the complete groups (clades) would include all the other groups shown below them in the tree. The Branchiobdellida are sister to the leech clade Hirudinida, which approximately corresponds to the traditional subclass Hirudinea. The main subdivision of leeches is into the Rhynchobdellida and the Arhynchobdellida, though the Acanthobdella are sister to the clade that contains these two groups.
The most ancient annelid group consists of the free-living polychaetes that evolved in the Cambrian period, being plentiful in the Burgess Shale about 500 million years ago. Oligochaetes evolved from polychaetes and the leeches branched off from the oligochaetes. Both the oligochaetes and the leeches, having no hard parts, do not fossilise well. The oldest leech fossils are from the Jurassic period around 150 million years ago, but a fossil with external ring markings found in Wisconsin in the 1980s, with what appears to be a large sucker, seems to extend the group's evolutionary history back to the Silurian, some 437 million years ago.
Anatomy and physiology
Leeches show a remarkable similarity to each other in morphology, very different from typical annelids which are cylindrical with a fluid-filled space, the coelom (body cavity). In leeches, the coelom is reduced to four slender longitudinal channels, and the interior of the body is filled with a solid dermis in between the various organs. Typically, the body is dorso-ventrally flattened and tapers at both ends. Longitudinal and circular muscles in the body wall are supplemented by diagonal muscles, giving the leech the ability to adopt a large range of body shapes and show great flexibility. Most leeches have a sucker at both the anterior (front) and posterior (back) ends, but some primitive leeches have a single sucker at the back.
Like other annelids, the leech is a segmented animal, but unlike other annelids, the segmentation is masked by external ring markings (annulations). The number of annulations varies, both between different regions of the body and between species. In one species, the body surface is divided into 102 annuli, but the body consists of 33 segments, a number constant across all leech species. Of these segments, the first five are designated as the head and include the anterior brain, several ocelli (eyespots) dorsally and the sucker ventrally. The following 21 mid-body segments each contain a nerve ganglion, and between them contain two reproductive organs, a single female gonopore and nine pairs of testes. The last seven segments contain the posterior brain and are fused to form the animal's tail sucker.
The body wall consists of a cuticle, an epidermis and a thick layer of fibrous connective tissue in which are embedded the circular muscles, the diagonal muscles and the powerful longitudinal muscles. There are also dorso-ventral muscles. The coelomic channels run the full length of the body, the two main ones being on either side; these have taken over the function of the hemal system (blood vessels) in other annelids. Part of the lining epithelium consists of chloragogen cells which are used for the storage of nutrients and in excretion. There are 10 to 17 pairs of metanephridia (excretory organs) in the mid-region of the leech. From these, ducts typically lead to a urinary bladder, which empties to the outside at a nephridiopore.
Reproduction and development
Leeches are protandric hermaphrodites, with the male reproductive organs, the testes, maturing first and the ovaries later. In hirudinids, a pair will line up with the clitellar regions in contact, with the anterior end of one leech pointing towards the posterior end of the other; this results in the male gonopore of one leech being in contact with the female gonopore of the other. The penis passes a spermatophore into the female gonopore and sperm is transferred to, and probably stored in, the vagina.
Some jawless leeches (Rhynchobdellida) and proboscisless leeches (Arhynchobdellida) lack a penis, and in these, sperm is passed from one individual to another by hypodermic injection. The leeches intertwine and grasp each other with their suckers. A spermatophore is pushed by one through the integument of the other, usually into the clitellar region. The sperm is liberated and passes to the ovisacs, either through the coelomic channels or interstitially through specialist "target tissue" pathways.
Some time after copulation, the small, relatively yolkless eggs are laid. In most species, an albumin-filled cocoon is secreted by the clitellum and receives one or more eggs as it passes over the female gonopore. In the case of the North American Erpobdella punctata, the clutch size is about five eggs, and some ten cocoons are produced. Each cocoon is fixed to a submerged object, or in the case of terrestrial leeches, deposited under a stone or buried in damp soil. The cocoon of Hemibdella soleae is attached to a suitable fish host. The glossiphoniids brood their eggs, either by attaching the cocoon to the substrate and covering it with their ventral surface, or by securing the cocoon to their ventral surface, and even carrying the newly hatched young to their first meal.
When breeding, most marine leeches leave their hosts and become free-living in estuaries. Here they produce their cocoons, after which the adults of most species die. When the eggs hatch, the juveniles seek out potential hosts when these approach the shore. Leeches mostly have an annual or biannual life cycle.
Feeding and digestion
About three quarters of leech species are parasites that feed on the blood of a host, while the remainder are predators. Leeches either have a pharynx that they can protrude, commonly called a proboscis, or a pharynx that they cannot protrude, which in some groups is armed with jaws.
In the proboscisless leeches, the jaws (if any) of Arhynchobdellids are at the front of the mouth, and have three blades set at an angle to each other. In feeding, these slice their way through the skin of the host, leaving a Y-shaped incision. Behind the blades is the mouth, located ventrally at the anterior end of the body. It leads successively into the pharynx, a short oesophagus, a crop (in some species), a stomach and a hindgut, which ends at an anus located just above the posterior sucker. The stomach may be a simple tube, but the crop, when present, is an enlarged part of the midgut with a number of pairs of ceca that store ingested blood. The leech secretes an anticoagulant, hirudin, in its saliva which prevents the blood from clotting before ingestion. A mature medicinal leech may feed only twice a year, taking months to digest a blood meal.
The bodies of predatory leeches are similar, though instead of a jaw many have a protrusible proboscis, which for most of the time they keep retracted into the mouth. Such leeches are often ambush predators that lie in wait until they can strike prey with the proboscises in a spear-like fashion. Predatory leeches feed on small invertebrates such as snails, earthworms and insect larvae. The prey is usually sucked in and swallowed whole. Some Rhynchobdellida however suck the soft tissues from their prey, making them intermediate between predators and blood-suckers.
Blood-sucking leeches use their anterior suckers to connect to hosts for feeding. Once attached, they use a combination of mucus and suction to stay in place while they inject hirudin into the hosts' blood. In general, blood-feeding leeches are non host-specific, and do little harm to their host, dropping off after consuming a blood meal. Some marine species however remain attached until it is time to reproduce. If present in great numbers on a host, these can be debilitating, and in extreme cases, cause death.
Leeches are unusual in that they do not produce amylases, lipases or endopeptidases. This lack of endopeptidases means the mechanism of protein digestion cannot follow the same sequence as it would in all other animals in which endopeptidases first split proteins into peptides, and the exopeptidases then degrade the peptides. Leeches produce intestinal exopeptidases which remove amino acids from the long protein molecules one by one, possibly aided by proteases from endosymbiotic bacteria in the hindgut. This evolutionary choice of exopeptic digestion in Hirudinea distinguishes these carnivorous clitellates from oligochaetes, and may explain why digestion in leeches is so slow.
A deficiency of digestive enzymes and of B complex vitamins is compensated for by enzymes and vitamins produced by endosymbiotic microflora. In Hirudo medicinalis, these supplementary factors are produced by an obligatory mutualistic relationship with two bacterial species, Aeromonas veronii and a still-uncharacterised Rikenella species. Non-bloodsucking leeches, such as Erpobdella punctata, are host to three bacterial symbionts, Pseudomonas, Aeromonas, and Klebsiella spp. (a slime producer). The bacteria are passed from parent to offspring in the cocoon as it is formed.
A leech's nervous system is formed of a few large nerve cells; their large size makes leeches convenient as model organisms for the study of invertebrate nervous systems. The main nerve centre consists of the cerebral ganglion above the gut and another ganglion beneath it, with connecting nerves forming a ring around the pharynx a little way behind the mouth. A nerve cord runs backwards from this in the ventral coelomic channel, with 21 pairs of ganglia in segments six to 26. In segments 27 to 33, other paired ganglia fuse to form the caudal ganglion. Several sensory nerves connect directly to the cerebral ganglion; there are sensory and motor nerve cells connected to the ventral nerve cord ganglia in each segment.
Leeches have between two and ten pigment spot ocelli, arranged in pairs towards the front of the body. There are also sensory papillae arranged in a lateral row in one annulation of each segment. Each papilla contains many sensory cells. Some rhynchobdellids have the ability to change colour dramatically by moving pigment in chromatophore cells; this process is under the control of the nervous system but its function is unclear as the change in hue seems unrelated to the colour of the surroundings.
Leeches can detect touch, vibration, movement of nearby objects, and chemicals secreted by their hosts; freshwater leeches crawl or swim towards a potential host standing in their pond within a few seconds. Species that feed on warm-blooded hosts move towards warmer objects. Many leeches avoid light, though some blood feeders move towards light when they are ready to feed, presumably increasing the chances of finding a host.
Leeches live in damp surroundings and in general respire through their body wall. The exception to this is in the Piscicolidae, where branching or leaf-like lateral outgrowths from the body wall form gills. Some rhynchobdellid leeches have an extracellular haemoglobin pigment, but this only provides for about half of the leech's oxygen transportation needs, the rest occurring by diffusion.
Leeches move using their longitudinal and circular muscles in a modification of the locomotion by peristalsis, self-propulsion by alternately contracting and lengthening parts of the body, seen in other annelids such as earthworms. They use their posterior and anterior suckers (one on each end of the body) to enable them to progress by looping or inching along, in the manner of geometer moth caterpillars. The posterior end is attached to the substrate, and the anterior end is projected forward peristaltically by the circular muscles until it touches down, as far as it can reach, and the anterior end is attached. Then the posterior end is released, pulled forward by the longitudinal muscles, and reattached; then the anterior end is released, and the cycle repeats. Leeches explore their environment with head movements and body waving. The Hirudinidae and Erpobdellidae can swim rapidly with up-and-down or sideways undulations of the body; the Glossiphoniidae in contrast are poor swimmers and curl up and fall to the sediment below when disturbed.
Video of looping movement
Interactions with humans
Leech bites are generally alarming rather than dangerous, though a small percentage of people have severe allergic or anaphylactic reactions and require urgent medical care. Symptoms of these reactions include red blotches or an itchy rash over the body, swelling around the lips or eyes, a feeling of faintness or dizziness, and difficulty in breathing. An externally attached leech will detach and fall off on its own accord when it is satiated on blood, which may take from twenty minutes to a few hours; bleeding from the wound may continue for some time. Internal attachments, such as inside the nose, are more likely to require medical intervention.
Bacteria, viruses, and protozoan parasites from previous blood sources can survive within a leech for months, so leeches could potentially act as vectors of pathogens. Nevertheless, only a few cases of leeches transmitting pathogens to humans have been reported.
Leech saliva is commonly believed to contain anaesthetic compounds to numb the bite area, but this has never been proven. Although morphine-like substances have been found in leeches, they have been found in the neural tissues, not the salivary tissues. They are used by the leeches in modulating their own immunocytes and not for anaesthetising bite areas on their hosts. Depending on the species and size, leech bites can be barely noticeable or they can be fairly painful.
In human culture
The medicinal leech Hirudo medicinalis, and some other species, have been used for clinical bloodletting for at least 2,500 years: Ayurvedic texts describe their use for bloodletting in ancient India. In ancient Greece, bloodletting was practised according to the theory of humours found in the Hippocratic Corpus of the fifth century BC, which maintained that health depended on a balance of the four humours: blood, phlegm, black bile and yellow bile. Bloodletting using leeches enabled physicians to restore balance if they considered blood was present in excess.
Pliny the Elder reported in his Natural History that the horse leech could drive elephants mad by climbing up inside their trunks to drink blood. Pliny also noted the medicinal use of leeches in ancient Rome, stating that they were often used for gout, and that patients became addicted to the treatment. In Old English, lǣce was the name for a physician as well as for the animal, though the words had different origins, and lǣcecraft, leechcraft, was the art of healing.
William Wordsworth's 1802 poem "Resolution and Independence" describes one of the last of the leech-gatherers, people who travelled Britain catching leeches from the wild, and causing a sharp decline in their abundance, though they remain numerous in Romney Marsh. By 1863, British hospitals had switched to imported leeches, some seven million being imported to hospitals in London that year.
In the nineteenth century, demand for leeches was sufficient for hirudiculture, the farming of leeches, to become commercially viable. Leech usage declined with the demise of humoral theory, but made a small-scale comeback in the 1980s after years of decline, with the advent of microsurgery, where venous congestion can arise due to inefficient venous drainage. Leeches can reduce swelling in the tissues and promote healing, helping in particular to restore circulation after microsurgery to reattach body parts. Other clinical applications include varicose veins, muscle cramps, thrombophlebitis, and joint diseases such as epicondylitis and osteoarthritis.
Leech secretions contain several bioactive substances with anti-inflammatory, anticoagulant and antimicrobial effects. One active component of leech saliva is a small protein, hirudin. It is widely used as an anticoagulant drug to treat blood-clotting disorders, and manufactured by recombinant DNA technology.
In 2012 and 2018, Ida Schnell and colleagues trialled the use of Haemadipsa leeches to gather data on the biodiversity of their mammalian hosts in the tropical rainforest of Vietnam, where it is hard to obtain reliable data on rare and cryptic mammals. They showed that mammal mitochondrial DNA, amplified by the polymerase chain reaction, can be identified from a leech's blood meal for at least four months after feeding. They detected Annamite striped rabbit, small-toothed ferret-badger, Truong Son muntjac, and serow in this way.
Exposure to synthetic estrogen as used in contraceptive medicines, which may enter freshwater ecosystems from municipal wastewater, can affect leeches' reproductive systems. Although not as sensitive to these compounds as fish, leeches showed physiological changes after exposure, including longer sperm sacs and vaginal bulbs, and decreased epididymis weight.
- The caption below the lithograph reads "There's redundancy of blood and humours, we'll bleed you to-morrow, till then, very little food."
- Chiangkul, Krittiya; Trivalairat, Poramad; Purivirojkul, Watchariya (2018). "Redescription of the Siamese shield leech Placobdelloides siamensis with new host species and geographic range". Parasite. 25: 56. doi:10.1051/parasite/2018056. ISSN 1776-1042. PMC 6254108. PMID 30474597.
- Sket, Boris; Trontelj, Peter (2008). "Global diversity of leeches (Hirudinea) in freshwater". Hydrobiologia. 595 (1): 129–137. doi:10.1007/s10750-007-9010-8. S2CID 46339662.
- Fogden, S.; Proctor, J. (1985). "Notes on the Feeding of Land Leeches (Haemadipsa zeylanica Moore and H. picta Moore) in Gunung Mulu National Park, Sarawak". Biotropica. 17 (2): 172–174. doi:10.2307/2388511. JSTOR 2388511.
- Ruppert, Fox & Barnes 2004, p. 471
- Siddall, Mark E. (1998). "Glossiphoniidae". American Museum of Natural History. Retrieved 1 May 2018.
- Ruppert, Fox & Barnes 2004, p. 480
- Meyer, Marvin C. (July 1940). "A Revision of the Leeches (Piscicolidae) Living on Fresh-Water Fishes of North America". Transactions of the American Microscopical Society. 59 (3): 354–376. doi:10.2307/3222552. JSTOR 3222552.
- Oceguera, A.; Leon, V.; Siddall, M. (2005). "Phylogeny and revision of Erpobdelliformes (Annelida, Arhynchobdellida) from Mexico based on nuclear and mitochondrial gene sequences". Revista Mexicana de Biodiversidad. 76 (2): 191–198. doi:10.22201/ib.20078706e.2005.002.307. Retrieved 23 October 2020.
- "Leeches". Australian Museum. 14 November 2019. Retrieved 3 June 2020.
- Scarborough, John (1992). Medical and Biological Terminologies: Classical Origins. University of Oklahoma Press. p. 58. ISBN 978-0-8061-3029-3.
- Lamarck, Jean-Baptiste (1818). Histoire naturelle des animaux sans vertèbres ... précédée d'une introduction offrant la détermination des caractères essentiels de l'animal, sa distinction du végétal et des autres corps naturels, enfin, l'exposition des principes fondamentaux de la zoologie. Volume 5. Paris: Verdière.
- Kolb, Jürgen (2018). "Hirudinea". WoRMS. World Register of Marine Species. Retrieved 7 May 2018.
- Phillips, Anna J.; Dornburg, Alex; Zapfe, Katerina L.; Anderson, Frank E.; James, Samuel W.; Erséus, Christer; Moriarty Lemmon, Emily; Lemmon, Alan R.; Williams, Bronwyn W. (2019). "Phylogenomic Analysis of a Putative Missing Link Sparks Reinterpretation of Leech Evolution". Genome Biology and Evolution. 11 (11): 3082–3093. doi:10.1093/gbe/evz120. ISSN 1759-6653. PMC 6598468. PMID 31214691.
- Margulis, Lynn; Chapman, Michael J. (2009). Kingdoms and Domains: An Illustrated Guide to the Phyla of Life on Earth. Academic Press. p. 308. ISBN 978-0-08-092014-6.
- Thorp, James H.; Covich, Alan P. (2001). Ecology and Classification of North American Freshwater Invertebrates. Academic Press. p. 466. ISBN 978-0-12-690647-9.
- Mikulic, D. G.; Briggs, D. E. G.; Kluessendorf, J. (1985). "A new exceptionally preserved biota from the Lower Silurian of Wisconsin, U.S.A." Philosophical Transactions of the Royal Society of London B. 311 (1148): 75–85. Bibcode:1985RSPTB.311...75M. doi:10.1098/rstb.1985.0140.
- Ruppert, Fox & Barnes 2004, pp. 471–472
- Brusca, Richard (2016). Hirudinoidea: Leeches and Their Relatives. Invertebrates. Sinauer Associates. pp. 591–597. ISBN 978-1-60535-375-3.
- Ruppert, Fox & Barnes 2004, pp. 474–475
- Buchsbaum, Ralph; Buchsbaum, Mildred; Pearse, John; Pearse, Vicki (1987). Animals Without Backbones (3rd ed.). The University of Chicago Press. pp. 312–317. ISBN 978-0-226-07874-8.
- Payton, Brian (1981). Muller, Kenneth; Nicholls, John; Stent, Gunther (eds.). Neurobiology of the Leech. Cold Spring Harbor Laboratory. pp. 35–50. ISBN 978-0-87969-146-2.
- Ruppert, Fox & Barnes 2004, pp. 477–478
- Sawyer, R. T. (1970). "Observations on the Natural History and Behavior of Erpobdella punctata (Leidy) (Annelida: Hirudinea)". The American Midland Naturalist. 83 (1): 65–80. doi:10.2307/2424006. JSTOR 2424006.
- Gelder, Stuart R.; Gagnon, Nicole L.; Nelson, Kerri (2002). "Taxonomic Considerations and Distribution of the Branchiobdellida (Annelida: Clitellata) on the North American Continent". Northeastern Naturalist. 9 (4): 451–468. doi:10.1656/1092-6194(2002)009[0451:TCADOT]2.0.CO;2. JSTOR 3858556.
- Rohde, Klaus (2005). Marine Parasitology. CSIRO Publishing. p. 185. ISBN 978-0-643-09927-2.
- Ruppert, Fox & Barnes 2004, pp. 475–477
- Govedich, Fredric R.; Bain, Bonnie A. (14 March 2005). "All about leeches" (PDF). Archived from the original (PDF) on 21 August 2010. Retrieved 19 January 2010.
- Sawyer, Roy T. "Leech biology and behaviour" (PDF). biopharm-leeches.com. Archived from the original (PDF) on 10 September 2011.
- Dziekońska-Rynko, Janina; Bielecki, Aleksander; Palińska, Katarzyna (2009). "Activity of selected hydrolytic enzymes from leeches (Clitellata: Hirudinida) with different feeding strategies". Biologia. 64 (2). doi:10.2478/s11756-009-0048-0.
- Ruppert, Fox & Barnes 2004, pp. 472–474
- Elder, H. Y. (1980). Elder, H. Y.; Trueman, E. R. (eds.). Peristaltic Mechanisms. Society for Experimental Biology, Seminar Series: Volume 5, Aspects of Animal Movement. CUP Archive. pp. 84–85. ISBN 978-0-521-29795-0.
- Sawyer, Roy (1981). Kenneth, Muller; Nicholls, John; Stent, Gunther (eds.). Neurobiology of the Leech. Cold Spring Harbor Laboratory. pp. 7–26. ISBN 978-0-87969-146-2.
- Smith, Douglas Grant (2001). Pennak's Freshwater Invertebrates of the United States: Porifera to Crustacea. John Wiley & Sons. p. 305. ISBN 978-0-471-35837-4.
- Burke, Don (2005). The complete Burke's backyard: the ultimate book of fact sheets. Murdoch Books. ISBN 978-1-74045-739-2.
- Fujimoto, Gary; Robin, Marc; Dessery, Bradford (2003). The Traveler's Medical Guide. Prairie Smoke Press. ISBN 978-0-9704482-5-5.
- Victorian Poisons Information Centre: Leeches Victorian Poisons Information Centre. Retrieved 28 July 2007
- Chow, C. K.; Wong, S. S.; Ho, A. C.; Lau, S. K. (2005). "Unilateral epistaxis after swimming in a stream". Hong Kong Medical Journal. 11 (2): 110–112. PMID 15815064. Lay summary – Reuters.
- Ahl-Khleif, A.; Roth, M.; Menge, C.; Heuser, J.; Baljer, G.; Herbst, W. (2011). "Tenacity of mammalian viruses in the gut of leeches fed with porcine blood". Journal of Medical Microbiology. 60 (6): 787–792. doi:10.1099/jmm.0.027250-0. PMID 21372183.
- Nehili, Malika; Ilk, Christoph; Mehlhorn, Heinz; Ruhnau, Klaus; Dick, Wolfgang; Njayou, Mounjohou (1994). "Experiments on the possible role of leeches as vectors of animal and human pathogens: a light and electron microscopy study". Parasitology Research. 80 (4): 277–290. doi:10.1007/bf02351867. ISSN 0044-3255. PMID 8073013. S2CID 19770060.
- Meir, Rigbi; Levy, Haim; Eldor, Amiram; Iraqi, Fuad; Teitelbaum, Mira; Orevi, Miriam; Horovitz, Amnon; Galun, Rachel (1987). "The saliva of the medicinal leech Hirudo medicinalis—II. Inhibition of platelet aggregation and of leukocyte activity and examination of reputed anaesthetic effects". Comparative Biochemistry and Physiology C. 88 (1): 95–98. doi:10.1016/0742-8413(87)90052-1. PMID 2890494.
- Laurent, V.; Salzet, B.; Verger-Bocquet, M.; Bernet, F.; Salzet, M. (2000). "Morphine-like substance in leech ganglia. Evidence and immune modulation". European Journal of Biochemistry. 267 (8): 2354–2361. doi:10.1046/j.1432-1327.2000.01239.x. PMID 10759861.
- Siddall, Mark; Borda, Liz; Burreson, Gene; Williams, Juli. "Blood Lust II". Laboratory of Phylohirudinology, American Museum of Natural History. Retrieved 15 December 2013.
- Yi-Te Lai; Jiun-Hong Chen (2010). 臺灣蛭類動物志: Leech Fauna of Taiwan-Biota Taiwanica. 國立臺灣大學出版中心. p. 89. ISBN 978-986-02-2760-4.
- "Proverbs 30:15 | Ellicott's Commentary for English Readers". BibleHub. Retrieved 27 April 2018.
- "Leech". Merriam-Webster. Retrieved 27 April 2018.
- Payton, Brian (1981). Muller, Kenneth; Nicholls, John; Stent, Gunther (eds.). Neurobiology of the Leech. Cold Spring Harbor Laboratory. pp. 27–34. ISBN 978-0-87969-146-2.
- Mory, Robert N.; Mindell, David; Bloom, David A. (2014). "The Leech and the Physician: Biology, Etymology, and Medical Practice with Hirudinea medicinalis". World Journal of Surgery. 24 (7): 878–883. doi:10.1007/s002680010141. hdl:2027.42/42411. PMID 10833259. S2CID 18166996.
- Marren, Peter; Mabey, Richard (2010). Bugs Britannica. Chatto & Windus. pp. 45–48. ISBN 978-0-7011-8180-2.
- Pliny (1991). Natural History: A Selection. Translated by Healy, John F. Penguin Books. p. 283. ISBN 978-0-14-044413-1.
- Mory, Robert N.; Mindell, David; Bloom, David A. (2014). "The Leech and the Physician: Biology, Etymology, and Medical Practice with Hirudinea medicinalis". World Journal of Surgery. 24 (7): 878–883. doi:10.1007/s002680010141. hdl:2027.42/42411. ISSN 0364-2313. PMID 10833259. S2CID 18166996.
- Jourdier, August; Coste, M. (March 1859). "Hirudiculture (Leech-Culture) (from La Pisciculture et la Production des Sanguesues (Fish farming and leech production). Paris : Hachette et Cie". The Journal of Agriculture. New Series. William Blackwood and Sons. 8 (July 1857–March 1859 ): 641–648.
- anon (2016). Medicine: The Definitive Illustrated History. Dorling Kindersley. p. 35. ISBN 978-0-241-28715-6.
- Cho, Joohee (4 March 2008). "Some Docs Latching Onto Leeches". ABC News. Retrieved 27 April 2018.
- Adams, Stephen L. (1988). "The Medicinal Leech: A Page from the Annelids of Internal Medicine". Annals of Internal Medicine. 109 (5): 399–405. doi:10.7326/0003-4819-109-5-399. PMID 3044211.
- Teut, M.; Warning, A. (2008). "Leeches, phytotherapy and physiotherapy in osteo-arthrosis of the knee—a geriatric case study". Forsch Komplementärmed. 15 (5): 269–272. doi:10.1159/000158875. PMID 19001824.
- Michalsen, A.; Moebus, S.; Spahn, G.; Esch, T.; Langhorst, J.; Dobos, G.J. (2002). "Leech therapy for symptomatic treatment of knee osteoarthritis: Results and implications of a pilot study". Alternative Therapies in Health and Medicine. 8 (5): 84–88. PMID 12233807.
- Sig, A. K.; Guney, M.; Uskudar Guclu, A.; Ozmen, E. (2017). "Medicinal leech therapy—an overall perspective". Integrative Medicine Research. 6 (4): 337–343. doi:10.1016/j.imr.2017.08.001. PMC 5741396. PMID 29296560.
- Abdualkader, A. M.; Ghawi, A. M.; Alaama, M.; Awang, M.; Merzouk, A. (2013). "Leech Therapeutic Applications". Indian Journal of Pharmacological Science. 75 (2 (March–April)): 127–137. PMC 3757849. PMID 24019559.
- Haycraft, John B. (1883). "IV. On the action of a secretion obtained from the medicinal leech on the coagulation of the blood". Proceedings of the Royal Society of London. 36 (228–231): 478–487. doi:10.1098/rspl.1883.0135.
- Fischer, Karl-Georg; Van de Loo, Andreas; Bohler, Joachim (1999). "Recombinant hirudin (lepirudin) as anticoagulant in intensive care patients treated with continuous hemodialysis". Kidney International. 56 (Suppl. 72): S46–S50. doi:10.1046/j.1523-1755.56.s72.2.x. PMID 10560805.
- Sohn, J.; Kang, H.; Rao, K.; Kim, C.; Choi, E.; Chung, B.; Rhee, S. (2001). "Current status of the anticoagulant hirudin: its biotechnological production and clinical practice". Applied Microbiology and Biotechnology. 57 (5–6): 606–613. doi:10.1007/s00253-001-0856-9. ISSN 0175-7598. PMID 11778867. S2CID 19304703.
- Schnell, Ida Bærholm; Thomsen, Philip Francis; Wilkinson, Nicholas; Rasmussen, Morten; Jensen, Lars R. D.; Willerslev, Eske; Bertelsen, Mads F.; Gilbert, M. Thomas P. (2012). "Screening mammal biodiversity using DNA from leeches". Current Biology. 22 (8): R262–R263. doi:10.1016/j.cub.2012.02.058. ISSN 0960-9822. PMID 22537625.
- Schnell, Ida Bærholm; Bohmann, Kristine (2018). Schultze, Sebastian E.; Richter, Stine R.; Murray, Dáithí C.; Sinding, Mikkel‐Holger S.; Bass, David; Cadle, John E.; Campbell, Mason J.; Dolch, Rainer; Edwards, David P.; Gray, Thomas N.E.; Hansen, Teis; Hoa, Anh Nguyen Quang; Noer, Christina Lehmkuhl; Heise‐Pavlov, Sigrid; Pedersen, Adam F. Sander; Ramamonjisoa, Juliot Carl; Siddall, Mark E.; Tilker, Andrew; Traeholt, Carl; Wilkinson, Nicholas; Woodcock, Paul; Yu, Douglas W.; Bertelsen, Mads Frost; Bunce, Michael; Gilbert, M. Thomas P. "Debugging diversity – a pan‐continental exploration of the potential of terrestrial blood‐feeding leeches as a vertebrate monitoring tool" (PDF). Molecular Ecology Resources. 18 (6): 1282–1298. doi:10.1111/1755-0998.12912. PMID 29877042. S2CID 46972335.
- Kidd, Karen A.; Graves, Stephanie D.; McKee, Graydon I.; Dyszy, Katarzyna; Podemski, Cheryl L. (2020). "Effects of Whole-Lake Additions of Ethynylestradiol on Leech Populations". Environmental Toxicology and Chemistry. 39 (8): 1608–1619. doi:10.1002/etc.4789. ISSN 1552-8618. PMID 32692460.
- Ruppert, Edward E.; Fox, Richard S.; Barnes, Robert D. (2004). Invertebrate Zoology, 7th Edition. Cengage Learning. ISBN 978-81-315-0104-7.
- Media related to Hirudinea at Wikimedia Commons
- Data related to Hirudinea at Wikispecies
- The dictionary definition of leech at Wiktionary