Abstract
Trematodes or flukes normally infect the alimentary canal and associated organs, but some flukes can also infect lungs during their life cycle. Trematode infections are commonly seen in the African countries, Asia and Southeast Asia, and less commonly in the Americas. Trematodes require an intermediate host in their life cycle, with vertebrates as the definitive host. Diagnosis depends on the identification of eggs characteristic of each fluke, either in the stool or in the sputum.
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6.1 Introduction
The trematodes belong to the phylum Platyhelminthes or flatworms. Their characteristics include a flattened body with an outer tegument and two suckers, which is a characteristic feature of this group. Most trematodes are hermaphroditic, with well-developed reproductive organs and digestive system. Trematodes inhabit the alimentary canal of vertebrates and may involve other organs such as liver, biliary tract, lung, and urinary tract. Trematode infections are prevalent worldwide [1–3].
There are three groups of trematodes: Monogenea, Aspidogastrea, and Digenea.
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Monogenea are external parasites of fish, with direct life cycles.
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Aspidogastrea are endoparasites with their entire ventral surface as the adhesive organ.
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Digenea are also endoparasites with simple adhesive organs and require one or more intermediate hosts.
This chapter is focused on the Digenean trematodes. Most Digenean trematodes, including Fasciola species, Clonorchis sinensis, and Schistosomes, primarily parasitize the liver and intestines in the human host, with the exception of Paragonimus westermani, which infect the lungs. These parasites have a complex life cycle, involve a mollusk host, and may have up to six larval stages. The trematode eggs have a smooth hard shell, and majority of them are operculate.
6.2 Specific Pathogenic Parasites
6.2.1 Paragonimus westermani
Paragonimus westermani is the commonest species of the genus Paragonimus, parasitizing both humans and animals, causing pulmonary paragonimiasis. There are 16 species of Paragonimus that are pathogenic to humans. The infection is seen in the Far East including China, Japan, Korea, Taiwan, Philippines, Indonesia, and parts of Southeast Asia including India and Nepal [4]. Paragonimus sp. infection has been also reported from Canada, North and Central America [5], and parts of South America. Paragonimus africanus has been reported from Nigeria, Libya, Liberia, and Zaire [1–3].
The adult fluke is egg-shaped, thick, fleshy, and red brown in color, measuring 7.5–20 mm long and 2.5–5 mm thick. The body wall has a thick tegument up to 40 um, two or more layers of smooth muscle, and a row of tegumental cells. There is a ventral and oral sucker and well-developed ovary, testes, uterus, vitellaria, and excretory bladder within the parenchyma. The eggs are golden brown, oval with thick birefringent shell, and 80–120 um by 45–65 um, with a flat operculum at one end (Figs. 6.1, 6.2, and 6.3).
The adult worms live in pairs or triplets in the respiratory tract of humans, encapsulated within a cyst. Eggs laid by the worms are either coughed up or swallowed and excreted in the feces. In the external environment, the eggs become embryonated, hatch in 2–3 weeks, releasing a ciliated miracidia, and seek the intermediate host, the snail. Within the snail, the miracidia develop into the cercariae, which invade the second intermediate host, a crustacean such as a crab or crayfish evolving into the metacercariae, the infective stage for mammalian host. Human infection occurs by eating inadequately cooked crab or crayfish. Human infection can also occur from ingesting raw or partially cooked meat of infected pigs and dogs. Once ingested, the metacercariae excyst in the duodenum, penetrate through the intestinal wall into the peritoneal cavity, and migrate through the diaphragm into the thoracic cavity and lungs, where they become encapsulated and develop into adults. Most adult worms die in 5–6 years, but some may live for up to 20 years. P. westermani requires encapsulation of two or three worms for insemination; therefore, when they are single, these worms migrate extensively in the thoracic cavity to find a mate, producing much inflammation. P. pulmonalis prevalent in Japan, Korea, and Taiwan is parthenogenetic and does not require another worm for insemination [1].
6.2.1.1 Clinical Manifestations
The clinical manifestations of paragonimiasis are nonspecific, and some patients may be asymptomatic. With heavy infection, patients develop cough, dyspnea, chest pain, fever and night sweats, and hemoptysis. Bronchitis and bronchiectasis may develop over time. Peripheral eosinophilia of up to 25 % may be seen. Chest X-rays may show diffuse infiltrates, consolidation, nodules, pleural effusion, or empyema. The disease clinically resembles pulmonary tuberculosis. The active infection with nodules can be mistaken for malignancy on positron emission tomography with computed tomography scans (PET-CT) [6, 7]. There may be dissemination of infection to the brain, heart, abdominal cavity, and subcutaneous tissue, with patients presenting with unusual clinical manifestations [8].
6.2.1.2 Pathology
The pathologic changes depend on the degree of infestation, host immunity, and duration of infection. In the lungs, there is local suppurative inflammation surrounding the adult worm and eggs, with abundant plasma cells, neutrophils, eosinophils, macrophages, and foreign body giant cells. Older lesions may not show the parasites, but have a thick fibrous wall and chronic inflammatory infiltrate, and calcifications [1]. Since many worms lodge near the large bronchioles or bronchi, the inflammatory reaction is mostly around the airways, and the cysts may rupture and discharge eggs into the airways; there is often pleural inflammation, thickening, and fibrosis, associated with the invasion of the worms during migration. Fine needle aspiration (FNA) of lung lesions and pleural fluid or pleural biopsy may yield the characteristic eggs of P. westermani, surrounded by inflammatory cells. Figures 6.1, 6.2, and 6.3 show a cell block prepared from a lung FNA. The eggs of P. westermani have a flattened operculum at one end, a birefringent cell wall, and appeared to be embryonated.
6.2.1.3 Diagnosis
The suppurative inflammation and hemoptysis may be mistaken for bacterial pneumonia, pulmonary tuberculosis, and other parasitic infections, such as strongyloidiasis and dirofilariasis. Diagnosis depends on finding the characteristic ovoid, brownish, thick-shelled, and operculated eggs in the sputum, pleural fluid, and/or feces. Fine needle aspirate of the nodule may yield the eggs or parasite for a definitive diagnosis [9]. Serologic tests, particularly ELISA, are useful for diagnosis [10]. Recently, loop-mediated isothermal amplification (LAMP) assay has been used to provide a rapid and sensitive tool for detection of P. westermani DNA in sputum and pleural fluid [11].
6.2.2 Schistosomiasis
Schistosomiasis is infection of humans by trematodes belonging to the Schistosoma superfamily of trematodes. There are three main species pathogenic to humans, S. mansoni, S. japonicum, and S. haematobium, and three additional species that are less common with restricted geographic ranges. An estimated 200 million people in Africa, the Americas, and the Far East are infected with Schistosomes. Humans in these areas have been affected for many millennia; calcified ova have been found in the remains of Egyptian mummies. S. mansoni is the only species found in the Western Hemisphere, in Brazil, West Indies, and Puerto Rico. S. japonicum is found in Asia, including the Philippines and China. S. haematobium is found throughout most of Africa, southern Europe, and western Asia. In the USA, approximately 400,000 people are infected, primarily immigrants from other endemic countries [1, 12].
The Schistosomes are the only trematodes that live in the bloodstream of warm-blooded hosts. They differ from other trematodes in having separate sexes. The male worm resembles a rolled leaf and harbors the female in the ventral canal (the gynaecophoric canal). They require definitive and intermediate hosts to complete their life cycle [1]. Lung involvement is seen in infections with S. mansoni, S. japonicum, and S. mekongi.
6.2.2.1 Life Cycle
Adult worms of S. mansoni and S. japonicum live in the venous plexuses draining the rectum and colon, anterior mesenteric vessels, and portal vein, while those of S. haematobium live in the vesical plexus draining the urinary bladder. Since S. haematobium infection of the lung is not reported, we will focus on the other two Schistosome species in this chapter.
The eggs laid by the female worm enter the intestinal lumen from the vessels by a process of extrusion through the venule wall and pass in the feces. Once the eggs reach freshwater, they hatch, releasing a miracidium which enters a snail, and start asexual multiplication, with release of cercariae in the water. Humans are infected when the cercariae penetrate the skin, enter circulation to reach the portal vein in the liver, and mature into adult worms. The majority of adult worms live 2–4 years, but some may live longer. The adult males of the S. mansoni and S. japonicum are up to 15 mm, and females are up to 10 mm in length, and both have oral and ventral suckers. The adults of S. japonicum are longer and narrower. The eggs of S. mansoni are 114–175 um long and 45–68 um wide, yellowish brown, and have a lateral spine, with an acid-fast shell when stained with Ziehl-Neelsen stain. The eggs of S. japonicum are smaller measuring 55–85 um by 40–60 um and oval with a lateral spine.
6.2.2.2 Clinical Manifestations
Clinical manifestations of both S. mansoni and S. japonicum are related to the host reaction to the eggs, with formation of granulomas in the infected tissues. Heavy primary infection can cause high fever, hepatosplenomegaly, lymphadenopathy, eosinophilia, and dysentery (Katayama syndrome) and correlates with tissue migration of the worms. Chronic infection may be associated with diarrhea, weight loss, anemia, hepatosplenomegaly, portal hypertension, and ascites. Asymptomatic infections are common in most endemic areas [1, 12]. Pulmonary infection results from embolization of large number of eggs into the pulmonary vasculature with development of pulmonary hypertension, hemoptysis, cyanosis, and congestive heart failure. These complications occur in approximately 5 %, a small minority of schistosomiasis cases, and reportedly more common with S. mansoni infection [12]. The presence of hepatic infection and portal hypertension with portocaval collaterals is necessary for the development of pulmonary symptoms. Heavy infection of the lung may be associated with granulomatous pulmonary arteritis [13, 14].
6.2.2.3 Pathology
During active infection, granulomas at different stages of evolution may be seen in the colon, liver, and in the lungs. Early granulomas, both in the lung and in pulmonary arterioles, have many eosinophils, macrophages, and epithelioid cells, with the mature miracidium or the egg present in the center. On an average, the granulomas are 250–375 um in diameter. Pulmonary arterioles may show microthrombi, necrotizing arteriolitis, medial hypertrophy and hyalinization, and intimal thickening. Severe pulmonary hypertensive changes including plexiform lesions may develop [1]. S. mansoni granulomas are scattered and discrete, up to 550 um in diameter, and contain a single egg, while the S. japonicum granulomas form composite granulomas containing more than one or clusters of eggs in the center [1, 14–18].
Figure 6.4 shows multiple composite granulomas surrounding clusters of calcified eggs within liver portal tracts. There is fibrosis of adjacent hepatic tissue. Similar granulomas are seen in lung infections. The composite granulomas are seen in S. haematobium and S. japonicum infections.
6.2.2.4 Diagnosis
Diagnosis is based on the history of exposure and travel to endemic areas. Definitive diagnosis of schistosomiasis can be made by finding the characteristic eggs in the feces or urine, using concentration method if necessary. The eggs need to be measured to determine the species. When eggs cannot be found with the concentration method, a rectal biopsy may be required. Tissue diagnosis depends on finding the typical eggs or parasite. The eggs of S. mansoni and S. japonicum are acid-fast positive and those of S. haematobium are negative with modified Ziehl-Neelsen technique [1]. Serologic tests using ELISA can be diagnostic. A loop-mediated isothermal amplification (LAMP) assay may be used for detection of S. japonicum DNA in serum [19].
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Haque, A.K. (2013). The Trematodes. In: Barrios, R., Haque, A. (eds) Parasitic Diseases of the Lungs. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-37609-2_6
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