Skip to Main Content

We have a new app!

Take the Access library with you wherever you go—easy access to books, videos, images, podcasts, personalized features, and more.

Download the Access App here: iOS and Android

Current Medical Diagnosis & Treatment 2024 > CMDT Media Library >

larva

1-137 of 137 Results

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–28. Life cycle of Diphyllobothrium latum (broad fish tapeworm). Immature eggs are passed in feces . Under appropriate conditions, the eggs mature (approximately 18–20 days)  and yield oncospheres, which develop into a coracidia . After ingestion by a suitable freshwater crustacean (the copepod first intermediate host) the coracidia develop into procercoid larvae . Following ingestion of the copepod by a suitable second intermediate host, typically minnows and other small freshwater fish, the procercoid larvae are released from the crustacean and migrate into the fish flesh where they develop into a plerocercoid larvae (sparganum) . The plerocercoid larvae are the infective stage for humans. Because humans do not generally eat undercooked minnows and similar small freshwater fish, these do not represent an important source of infection. Nevertheless, these small second intermediate hosts can be eaten by larger predator species, eg, trout, perch, walleyed pike . In this case, the sparganum can migrate to the musculature of the larger predator fish, and humans can acquire the disease by eating these later intermediate infected host fish raw or undercooked . After ingestion of the infected fish, the plerocercoid develop into immature adults and then into mature adult tapeworms, which will reside in the small intestine. The adults of D latum attach to the intestinal mucosa by means of the two bilateral groves (bothria) of their scolex . The adults can reach more than 10 M in length, with more than 3000 proglottids. Immature eggs are discharged from the proglottids (up to 1,000,000 eggs per day per worm)  and are passed in the feces . Eggs appear in the feces 5–6 weeks after infection. In addition to humans, many other mammals can also serve as definitive hosts for D latum. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Diphyllobothrium latum.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–29. Life cycle of Hymenolepis diminuta and Hymenolepis nana. A: Eggs of H nana are immediately infective when passed with the stool and cannot survive more than 10 days in the external environment . When eggs are ingested by an arthropod intermediate host  (various species of beetles and fleas may serve as intermediate hosts), they develop into cysticercoids, which can infect humans or rodents upon ingestion  and develop into adults in the small intestine. A morphologically identical variant, H nana var. fraterna, infects rodents and uses arthropods as intermediate hosts. When eggs are ingested  (in contaminated food or water or from hands contaminated with feces), the oncospheres contained in the eggs are released. The oncospheres (hexacanth larvae) penetrate the intestinal villus and develop into cysticercoid larvae . Upon rupture of the villus, the cysticercoids return to the intestinal lumen, evaginate their scoleces , attach to the intestinal mucosa and develop into adults that reside in the ileal portion of the small intestine producing gravid proglottids . Eggs are passed in the stool when released from proglottids through its genital atrium or when proglottids disintegrate in the small intestine . An alternate mode of infection consists of internal autoinfection, where the eggs release their hexacanth embryo, which penetrates the villus continuing the infective cycle without passage through the external environment . The life span of adult worms is 4–6 weeks, but internal autoinfection allows the infection to persist for years. B: Eggs of H diminuta are passed out in the feces of the infected definitive host (rodents, man) . The mature eggs are ingested by an intermediate host (various arthropod adults or larvae) , and oncospheres are released from the eggs and penetrate the intestinal wall of the host , which develop into cysticercoid larvae. Species from the genus Tribolium are common intermediate hosts for H diminuta. The cysticercoid larvae persist through the arthropod’s morphogenesis to adulthood. H diminuta infection is acquired by the mammalian host after ingestion of an intermediate host carrying the cysticercoid larvae . Humans can be accidentally infected through the ingestion of insects in precooked cereals, or other food items, and directly from the environment (eg, oral exploration of the environment by children). After ingestion, the tissue of the infected arthropod is digested releasing the cysticercoid larvae in the stomach and small intestine. Eversion of the scoleces  occurs shortly after the cysticercoid larvae are released. Using the four suckers on the scolex, the parasite attaches to the small intestine wall. Maturation of the parasites occurs within 20 days and the adult worms can reach an average of 30 cm in length . Eggs are released in the small intestine from gravid proglottids  that disintegrate after breaking off from the adult worms. The eggs are expelled to the environment in the mammalian host’s feces .(From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Hymenolepis nana.

Current Medical Diagnosis & Treatment 2024 > Noninvasive Cestode Infections

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–34. Life cycle of Ascaris lumbricoides (the giant roundworm of humans). Adult worms , live in the lumen of the small intestine. A female may produce approximately 200,000 eggs per day, which are passed with the feces . Unfertilized eggs may be ingested but are not infective. Fertile eggs embryonate and become infective after 18 days to several weeks , depending on the environmental conditions (optimum: moist, warm, shaded soil). After infective eggs are swallowed , the larvae hatch , invade the intestinal mucosa, and are carried via the portal, then systemic circulation to the lungs . The larvae mature further in the lungs (10–14 days), penetrate the alveolar walls, ascend the bronchial tree to the throat, and are swallowed . Upon reaching the small intestine, they develop into adult worms. Between 2 and 3 months are required from ingestion of the infective eggs to oviposition by the adult female. Adult worms can live 1–2 years. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Ascaris lumbricoides.

Current Medical Diagnosis & Treatment 2024 > Ascariasis

View in Context

eFigure 37–36. Life cycle of Trichuris trichiura. The unembryonated eggs are passed with the stool . In the soil, the eggs develop into a 2-cell stage , an advanced cleavage stage , and then they embryonate ; eggs become infective in 15–30 days. After ingestion (soil-contaminated hands or food), the eggs hatch in the small intestine, and release larvae  that mature and establish themselves as adults in the colon . The adult worms (approximately 4 cm in length) live in the cecum and ascending colon. The adult worms are fixed in that location, with the anterior portions threaded into the mucosa. The females begin to oviposit 60–70 days after infection. Female worms in the cecum shed between 3000 and 20,000 eggs per day. The life span of the adults is about 1 year. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of nematode or roundworm, Trichuris trichiura.

Current Medical Diagnosis & Treatment 2024 > Trichuriasis

View in Context

eFigure 37–36. Life cycle of Trichuris trichiura. The unembryonated eggs are passed with the stool . In the soil, the eggs develop into a 2-cell stage , an advanced cleavage stage , and then they embryonate ; eggs become infective in 15–30 days. After ingestion (soil-contaminated hands or food), the eggs hatch in the small intestine, and release larvae  that mature and establish themselves as adults in the colon . The adult worms (approximately 4 cm in length) live in the cecum and ascending colon. The adult worms are fixed in that location, with the anterior portions threaded into the mucosa. The females begin to oviposit 60–70 days after infection. Female worms in the cecum shed between 3000 and 20,000 eggs per day. The life span of the adults is about 1 year. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of nematode or roundworm, Trichuris trichiura.

Current Medical Diagnosis & Treatment 2024 > Trichuriasis

View in Context

eFigure 37–36. Life cycle of Trichuris trichiura. The unembryonated eggs are passed with the stool . In the soil, the eggs develop into a 2-cell stage , an advanced cleavage stage , and then they embryonate ; eggs become infective in 15–30 days. After ingestion (soil-contaminated hands or food), the eggs hatch in the small intestine, and release larvae  that mature and establish themselves as adults in the colon . The adult worms (approximately 4 cm in length) live in the cecum and ascending colon. The adult worms are fixed in that location, with the anterior portions threaded into the mucosa. The females begin to oviposit 60–70 days after infection. Female worms in the cecum shed between 3000 and 20,000 eggs per day. The life span of the adults is about 1 year. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of nematode or roundworm, Trichuris trichiura.

Current Medical Diagnosis & Treatment 2024 > Trichuriasis

View in Context

eFigure 37–36. Life cycle of Trichuris trichiura. The unembryonated eggs are passed with the stool . In the soil, the eggs develop into a 2-cell stage , an advanced cleavage stage , and then they embryonate ; eggs become infective in 15–30 days. After ingestion (soil-contaminated hands or food), the eggs hatch in the small intestine, and release larvae  that mature and establish themselves as adults in the colon . The adult worms (approximately 4 cm in length) live in the cecum and ascending colon. The adult worms are fixed in that location, with the anterior portions threaded into the mucosa. The females begin to oviposit 60–70 days after infection. Female worms in the cecum shed between 3000 and 20,000 eggs per day. The life span of the adults is about 1 year. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of nematode or roundworm, Trichuris trichiura.

Current Medical Diagnosis & Treatment 2024 > Trichuriasis

View in Context

eFigure 37–36. Life cycle of Trichuris trichiura. The unembryonated eggs are passed with the stool . In the soil, the eggs develop into a 2-cell stage , an advanced cleavage stage , and then they embryonate ; eggs become infective in 15–30 days. After ingestion (soil-contaminated hands or food), the eggs hatch in the small intestine, and release larvae  that mature and establish themselves as adults in the colon . The adult worms (approximately 4 cm in length) live in the cecum and ascending colon. The adult worms are fixed in that location, with the anterior portions threaded into the mucosa. The females begin to oviposit 60–70 days after infection. Female worms in the cecum shed between 3000 and 20,000 eggs per day. The life span of the adults is about 1 year. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of nematode or roundworm, Trichuris trichiura.

Current Medical Diagnosis & Treatment 2024 > Trichuriasis

View in Context

eFigure 37–36. Life cycle of Trichuris trichiura. The unembryonated eggs are passed with the stool . In the soil, the eggs develop into a 2-cell stage , an advanced cleavage stage , and then they embryonate ; eggs become infective in 15–30 days. After ingestion (soil-contaminated hands or food), the eggs hatch in the small intestine, and release larvae  that mature and establish themselves as adults in the colon . The adult worms (approximately 4 cm in length) live in the cecum and ascending colon. The adult worms are fixed in that location, with the anterior portions threaded into the mucosa. The females begin to oviposit 60–70 days after infection. Female worms in the cecum shed between 3000 and 20,000 eggs per day. The life span of the adults is about 1 year. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of nematode or roundworm, Trichuris trichiura.

Current Medical Diagnosis & Treatment 2024 > Trichuriasis

View in Context

eFigure 37–36. Life cycle of Trichuris trichiura. The unembryonated eggs are passed with the stool . In the soil, the eggs develop into a 2-cell stage , an advanced cleavage stage , and then they embryonate ; eggs become infective in 15–30 days. After ingestion (soil-contaminated hands or food), the eggs hatch in the small intestine, and release larvae  that mature and establish themselves as adults in the colon . The adult worms (approximately 4 cm in length) live in the cecum and ascending colon. The adult worms are fixed in that location, with the anterior portions threaded into the mucosa. The females begin to oviposit 60–70 days after infection. Female worms in the cecum shed between 3000 and 20,000 eggs per day. The life span of the adults is about 1 year. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of nematode or roundworm, Trichuris trichiura.

Current Medical Diagnosis & Treatment 2024 > Trichuriasis

View in Context

eFigure 37–37. Life cycles of Ancylostoma duodenale and Necator americanus (human hookworms). Eggs are passed in the stool , and under favorable conditions (moisture, warmth, shade), larvae hatch in 1–2 days. The released rhabditiform larvae grow in the feces or the soil, or both , and after 5–10 days (and two molts) they become filariform (third-stage) larvae that are infective . These infective larvae can survive 3–4 weeks in favorable environmental conditions. On contact with the human host, the larvae penetrate the skin and are carried through the blood vessels to the heart and then to the lungs. They penetrate into the pulmonary alveoli, ascend the bronchial tree to the pharynx, and are swallowed . The larvae reach the small intestine, where they reside and mature into adults. Adult worms live in the lumen of the small intestine, where they attach to the intestinal wall with resultant blood loss by the host . Most adult worms are eliminated in 1–2 years, but the longevity may reach several years. Some A duodenale larvae, following penetration of the host skin, can become dormant (in the intestine or muscle). In addition, infection by A duodenale may probably also occur by the oral and transmammary route. N americanus, however, requires a transpulmonary migration phase. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of intestinal hookworm.

Current Medical Diagnosis & Treatment 2024 > Hookworm Disease

View in Context

eFigure 37–37. Life cycles of Ancylostoma duodenale and Necator americanus (human hookworms). Eggs are passed in the stool , and under favorable conditions (moisture, warmth, shade), larvae hatch in 1–2 days. The released rhabditiform larvae grow in the feces or the soil, or both , and after 5–10 days (and two molts) they become filariform (third-stage) larvae that are infective . These infective larvae can survive 3–4 weeks in favorable environmental conditions. On contact with the human host, the larvae penetrate the skin and are carried through the blood vessels to the heart and then to the lungs. They penetrate into the pulmonary alveoli, ascend the bronchial tree to the pharynx, and are swallowed . The larvae reach the small intestine, where they reside and mature into adults. Adult worms live in the lumen of the small intestine, where they attach to the intestinal wall with resultant blood loss by the host . Most adult worms are eliminated in 1–2 years, but the longevity may reach several years. Some A duodenale larvae, following penetration of the host skin, can become dormant (in the intestine or muscle). In addition, infection by A duodenale may probably also occur by the oral and transmammary route. N americanus, however, requires a transpulmonary migration phase. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of intestinal hookworm.

Current Medical Diagnosis & Treatment 2024 > Hookworm Disease

View in Context

eFigure 37–37. Life cycles of Ancylostoma duodenale and Necator americanus (human hookworms). Eggs are passed in the stool , and under favorable conditions (moisture, warmth, shade), larvae hatch in 1–2 days. The released rhabditiform larvae grow in the feces or the soil, or both , and after 5–10 days (and two molts) they become filariform (third-stage) larvae that are infective . These infective larvae can survive 3–4 weeks in favorable environmental conditions. On contact with the human host, the larvae penetrate the skin and are carried through the blood vessels to the heart and then to the lungs. They penetrate into the pulmonary alveoli, ascend the bronchial tree to the pharynx, and are swallowed . The larvae reach the small intestine, where they reside and mature into adults. Adult worms live in the lumen of the small intestine, where they attach to the intestinal wall with resultant blood loss by the host . Most adult worms are eliminated in 1–2 years, but the longevity may reach several years. Some A duodenale larvae, following penetration of the host skin, can become dormant (in the intestine or muscle). In addition, infection by A duodenale may probably also occur by the oral and transmammary route. N americanus, however, requires a transpulmonary migration phase. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of intestinal hookworm.

Current Medical Diagnosis & Treatment 2024 > Hookworm Disease

View in Context

eFigure 37–37. Life cycles of Ancylostoma duodenale and Necator americanus (human hookworms). Eggs are passed in the stool , and under favorable conditions (moisture, warmth, shade), larvae hatch in 1–2 days. The released rhabditiform larvae grow in the feces or the soil, or both , and after 5–10 days (and two molts) they become filariform (third-stage) larvae that are infective . These infective larvae can survive 3–4 weeks in favorable environmental conditions. On contact with the human host, the larvae penetrate the skin and are carried through the blood vessels to the heart and then to the lungs. They penetrate into the pulmonary alveoli, ascend the bronchial tree to the pharynx, and are swallowed . The larvae reach the small intestine, where they reside and mature into adults. Adult worms live in the lumen of the small intestine, where they attach to the intestinal wall with resultant blood loss by the host . Most adult worms are eliminated in 1–2 years, but the longevity may reach several years. Some A duodenale larvae, following penetration of the host skin, can become dormant (in the intestine or muscle). In addition, infection by A duodenale may probably also occur by the oral and transmammary route. N americanus, however, requires a transpulmonary migration phase. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of intestinal hookworm.

Current Medical Diagnosis & Treatment 2024 > Hookworm Disease

View in Context

eFigure 37–37. Life cycles of Ancylostoma duodenale and Necator americanus (human hookworms). Eggs are passed in the stool , and under favorable conditions (moisture, warmth, shade), larvae hatch in 1–2 days. The released rhabditiform larvae grow in the feces or the soil, or both , and after 5–10 days (and two molts) they become filariform (third-stage) larvae that are infective . These infective larvae can survive 3–4 weeks in favorable environmental conditions. On contact with the human host, the larvae penetrate the skin and are carried through the blood vessels to the heart and then to the lungs. They penetrate into the pulmonary alveoli, ascend the bronchial tree to the pharynx, and are swallowed . The larvae reach the small intestine, where they reside and mature into adults. Adult worms live in the lumen of the small intestine, where they attach to the intestinal wall with resultant blood loss by the host . Most adult worms are eliminated in 1–2 years, but the longevity may reach several years. Some A duodenale larvae, following penetration of the host skin, can become dormant (in the intestine or muscle). In addition, infection by A duodenale may probably also occur by the oral and transmammary route. N americanus, however, requires a transpulmonary migration phase. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of intestinal hookworm.

Current Medical Diagnosis & Treatment 2024 > Hookworm Disease

View in Context

eFigure 37–37. Life cycles of Ancylostoma duodenale and Necator americanus (human hookworms). Eggs are passed in the stool , and under favorable conditions (moisture, warmth, shade), larvae hatch in 1–2 days. The released rhabditiform larvae grow in the feces or the soil, or both , and after 5–10 days (and two molts) they become filariform (third-stage) larvae that are infective . These infective larvae can survive 3–4 weeks in favorable environmental conditions. On contact with the human host, the larvae penetrate the skin and are carried through the blood vessels to the heart and then to the lungs. They penetrate into the pulmonary alveoli, ascend the bronchial tree to the pharynx, and are swallowed . The larvae reach the small intestine, where they reside and mature into adults. Adult worms live in the lumen of the small intestine, where they attach to the intestinal wall with resultant blood loss by the host . Most adult worms are eliminated in 1–2 years, but the longevity may reach several years. Some A duodenale larvae, following penetration of the host skin, can become dormant (in the intestine or muscle). In addition, infection by A duodenale may probably also occur by the oral and transmammary route. N americanus, however, requires a transpulmonary migration phase. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of intestinal hookworm.

Current Medical Diagnosis & Treatment 2024 > Hookworm Disease

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more complex than that of most nematodes with its alternation between free-living and parasitic cycles, and its potential for autoinfection and multiplication within the host. Two types of cycles exist. Free-living cycle: The rhabditiform larvae passed in the stool  (see “Parasitic cycle” below) can either become infective filariform larvae (direct development) , or free-living adult males and females  that mate and produce eggs  from which rhabditiform larvae hatch  and eventually become infective filariform larvae . The filariform larvae penetrate the human host skin to initiate the parasitic cycle (see below) . Parasitic cycle: Filariform larvae in contaminated soil penetrate the human skin , and by various, often random routes, migrate to the small intestine . Historically it was believed that the L3 larvae migrate via the bloodstream to the lungs, where they are eventually coughed up and swallowed. However, there is also evidence that L3 larvae can migrate directly to the intestine via connective tissues. In the small intestine, they molt twice and become adult female worms . The females live threaded in the epithelium of the small intestine and by parthenogenesis produce eggs , which yield rhabditiform larvae. The rhabditiform larvae can either be passed in the stool  (see “Free-living cycle” above), or can cause autoinfection . In autoinfection, the rhabditiform larvae become infective filariform larvae, which can penetrate either the intestinal mucosa (internal autoinfection) or the skin of the perianal area (external autoinfection); in either case, the filariform larvae may disseminate throughout the body. To date, occurrence of autoinfection in humans with helminthic infections is recognized only in S stercoralis and Capillaria philippinensis infections. In the case of Strongyloides, autoinfection may explain the possibility of persistent infections for many years in persons who have not been in an endemic area and of hyperinfections in immunodepressed individuals. (From Global Health, Division of Parasitic Diseases and Malaria, CDC.) A flowchart of the life cycle of Strongyloides.

Current Medical Diagnosis & Treatment 2024 > Strongyloidiasis

View in Context

eFigure 37–38. Life cycle of Strongyloides stercoralis (small roundworm of humans). The Strongyloides life cycle is more co