1766 PART 5 Infectious Diseases
in turn enter and infect intestinal epithelial cells. The parasite’s further
development involves both asexual and sexual cycles, which produce
forms capable of infecting other epithelial cells and of generating
oocysts that are passed in the feces. Cryptosporidium species infect a
number of animals, and C. parvum can spread from infected animals
to humans. Since oocysts are immediately infectious when passed in
feces, person-to-person transmission takes place in day-care centers
and among household contacts and medical providers. Waterborne
transmission (especially that of C. hominis) accounts for infections in
travelers and for common-source epidemics. Oocysts are quite hardy
and resist killing by routine chlorination. Both drinking water and
recreational water (e.g., pools, waterslides) have been increasingly recognized as sources of infection.
Pathophysiology Although intestinal epithelial cells harbor cryptosporidia in an intracellular vacuole, the means by which secretory
diarrhea is elicited remain uncertain. No characteristic pathologic
changes are found by biopsy. The distribution of infection can be spotty
within the principal site of infection, the small bowel. Cryptosporidia
are found in the pharynx, stomach, and large bowel of some patients
and at times in the respiratory tract. Especially in patients with AIDS,
involvement of the biliary tract can cause papillary stenosis, sclerosing
cholangitis, or cholecystitis.
Clinical Manifestations Asymptomatic infections can occur in
both immunocompetent and immunocompromised hosts. In immunocompetent persons, symptoms develop after an incubation period of
~1 week and consist principally of watery nonbloody diarrhea, sometimes in conjunction with abdominal pain, nausea, anorexia, fever, and/
or weight loss. In these hosts, the illness usually subsides after 1–2 weeks.
In contrast, in immunocompromised hosts (especially those with AIDS
and CD4+ T-cell counts <100/μL), diarrhea can be chronic, persistent,
and remarkably profuse, causing clinically significant fluid and electrolyte depletion. Stool volumes may range from 1 to 25 L/d. Weight loss,
wasting, and abdominal pain may be severe. Biliary tract involvement
can manifest as mid-epigastric or right-upper-quadrant pain.
Diagnosis (Table 229-1) Evaluation starts with fecal examination
for small oocysts, which are smaller (4–5 μm in diameter) than the
fecal stages of most other parasites. Because conventional stool examination for ova and parasites (O+P) does not detect Cryptosporidium,
specific testing must be requested. Detection is enhanced by evaluation
of stools (obtained on multiple days) by several techniques, including
modified acid-fast and direct immunofluorescent stains and enzyme
immunoassays. NAATs are also useful. Cryptosporidia can also be
identified by light and electron microscopy at the apical surfaces of
intestinal epithelium from biopsy specimens of the small bowel and,
less frequently, the large bowel.
TREATMENT
Cryptosporidiosis
Nitazoxanide, approved by the U.S. Food and Drug Administration
(FDA) for the treatment of cryptosporidiosis, is available in tablet
form for adults (500 mg twice daily for 3 days) and as an elixir for
children. This agent has not been effective for the treatment of
immunosuppressed patients or HIV-infected patients, in whom
improved immune status due to antiretroviral therapy can lead to
amelioration of cryptosporidiosis. Otherwise, treatment includes
supportive care with replacement of fluids and electrolytes and
administration of antidiarrheal agents. Biliary tract obstruction
may require papillotomy or T-tube placement. Prevention requires
minimizing exposure to infectious oocysts in human or animal
feces. Use of submicron water filters may minimize acquisition of
infection from drinking water.
■ CYSTOISOSPORIASIS
The coccidian parasite Cystoisospora belli causes human intestinal disease. Infection is acquired by the consumption of oocysts, after which
the parasite invades intestinal epithelial cells and undergoes both
sexual and asexual cycles of development. Oocysts excreted in stool
are not immediately infectious but must undergo further maturation.
Although C. belli infects many animals, little is known about the
epidemiology or prevalence of this parasite in humans. It is most
common in tropical and subtropical countries. Acute infections can
begin abruptly with fever, abdominal pain, and watery nonbloody
diarrhea and can last for weeks or months. In patients who have AIDS
or are immunocompromised for other reasons, infections often are not
self-limited but rather resemble cryptosporidiosis, with chronic, profuse watery diarrhea. Eosinophilia, which is not found in other enteric
protozoan infections, may be detectable. The diagnosis (Table 229-1)
is usually made by detection of the large (~25 μm) oocysts in stool by
modified acid-fast staining. Oocyst excretion may be low-level and
intermittent; if repeated stool examinations are unrevealing, sampling
of duodenal contents by aspiration or small-bowel biopsy (often with
electron microscopic examination) may be necessary. NAATs are effective newer diagnostic tools.
TREATMENT
Cystoisosporiasis
Trimethoprim-sulfamethoxazole (TMP-SMX, 160/800 mg two
times daily for 10 days; and, for HIV-infected patients, then continuing three times daily for 3 weeks) is effective. For patients intolerant of sulfonamides, pyrimethamine (50–75 mg/d) can be used.
Relapses can occur in persons with AIDS and necessitate maintenance therapy with TMP-SMX (160/800 mg three times per week).
■ CYCLOSPORIASIS
Cyclospora cayetanensis, a cause of diarrheal illness, is globally distributed: illness due to C. cayetanensis has been reported in the United
States, Asia, Africa, Latin America, and Europe. The epidemiology of this
parasite has not yet been fully defined, but waterborne transmission and
foodborne transmission (e.g., by basil, sweet peas, and imported raspberries) have been recognized. The full spectrum of illness attributable
to Cyclospora has not been delineated. Some infected patients may be
without symptoms, but many have diarrhea, flulike symptoms, and flatulence and belching. The illness can be self-limited, can wax and wane,
or, in many cases, can involve prolonged diarrhea, anorexia, and upper
gastrointestinal symptoms, with sustained fatigue and weight loss in
some instances. Diarrheal illness may persist for >1 month. Cyclospora
can cause enteric illness in patients infected with HIV.
The parasite is detectable in epithelial cells of small-bowel biopsy
samples and elicits secretory diarrhea by unknown means. The absence
of fecal blood and leukocytes indicates that disease due to Cyclospora
is not caused by destruction of the small-bowel mucosa. The diagnosis (Table 229-1) can be made by detection of spherical 8- to 10-μm
oocysts in the stool, although routine stool O+P examinations are not
sufficient. Specific fecal examinations must be requested to detect the
oocysts, which are variably acid-fast and are fluorescent when viewed
with ultraviolet light microscopy. NAATs are proving to be sensitive.
Cyclosporiasis should be considered in the differential diagnosis of
prolonged diarrhea, with or without a history of travel by the patient
to other countries.
TREATMENT
Cyclosporiasis
Cyclosporiasis is treated with TMP-SMX (160/800 mg twice daily
for 7–10 days). HIV-infected patients may experience relapses
after such treatment and thus may require longer-term suppressive
maintenance therapy.
■ MICROSPORIDIOSIS
Microsporidia are obligate intracellular spore-forming protozoa that
infect many animals and cause disease in humans, especially as
1767CHAPTER 229 Protozoal Intestinal Infections and Trichomoniasis
Intracellular
multiplication
via merogony and
sporogony
Microsporidia
Enterocytozoon bieneusi, Encephalitozoon spp., etc.
Encephalitozoon intestinalis
in epithelial cells, endothelial
cells, or macrophages
E. bieneusi
in epithelial cell
Polar tubule pierces
host epithelial cell,
injects sporoplasm
Presumed
ingestion or
respiratory
acquisition of
spores
Person-to-person,
zoonotic,
waterborne, or
food-borne
transmission?
Diagnostic spores present
in stool, urine, respiratory fluids,
cerebrospinal fluid, or
various tissue specimens
Sloughed cells
degenerate;
spores shed in
bodily fluids
Spore-laden
host epithelial
cells sloughed
into lumina of
gastrointestinal,
respiratory, or
genitourinary tract
While E. bieneusi is
primarily in the gastrointestinal tract,
other species may invade the lung
or eye or disseminate to cause:
Chronic diarrhea
Cholangitis
Sinusitis
Bronchitis
Nephritis
Cystitis/prostatitis
Keratoconjunctivitis
Encephalitis
FIGURE 229-3 Life cycle of microsporidia. (Reproduced with permission from RL Guerrant et al [eds]: Tropical
Infectious Diseases: Principles, Pathogens and Practice, 2nd ed, Elsevier 2006.)
opportunistic pathogens in AIDS. Microsporidia
are members of a distinct phylum, Microspora,
which contains dozens of genera and hundreds
of species. The various microsporidia are differentiated by their developmental life cycles,
ultrastructural features, and molecular taxonomy based on ribosomal RNA. The complex life
cycles of the organisms result in the production of
infectious spores (Fig. 229-3). Currently, at least
15 species of microsporidia, including the genera Encephalitozoon, Tubulinosema, Pleistophora,
Nosema, Vittaforma, Trachipleistophora, Anncaliia, Microsporidium, and Enterocytozoon, are
recognized as causes of human disease. Although
some microsporidia are probably prevalent
causes of self-limited or asymptomatic infections
in immunocompetent patients, little is known
about how microsporidiosis is acquired.
Microsporidiosis is most common among
patients with AIDS, less common among patients
with other types of immunocompromise, and
rare among immunocompetent hosts. In patients
with AIDS, intestinal infections with Enterocytozoon bieneusi and Encephalitozoon intestinalis
are recognized to contribute to chronic diarrhea
and wasting; these infections have been found
in 10–40% of patients with chronic diarrhea.
Both organisms have been found in the biliary
tracts of patients with cholecystitis. E. intestinalis may also disseminate to cause fever, diarrhea, sinusitis, cholangitis, and bronchiolitis. In
patients with AIDS, Encephalitozoon hellem has
caused superficial keratoconjunctivitis as well as
sinusitis, respiratory tract disease, and disseminated infection. Myositis due to Pleistophora
has been documented. Nosema, Vittaforma, and
Microsporidium have caused stromal keratitis
associated with trauma in immunocompetent
patients.
Microsporidia are small gram-positive organisms with mature spores measuring 0.5–2 μm ×
1–4 μm. Diagnosis of microsporidial infections
in tissue often requires electron microscopy,
although intracellular spores can be visualized by light microscopy with hematoxylin and
eosin, Giemsa, or tissue Gram’s stain. For the diagnosis of intestinal
microsporidiosis, modified trichrome or chromotrope 2R–based staining and Uvitex 2B or calcofluor fluorescent staining reveal spores in
smears of feces or duodenal aspirates. NAATs are useful for diagnosis
and speciation. Definitive therapies for microsporidial infections
remain to be established. For superficial keratoconjunctivitis due to
E. hellem, E. cuniculi, E. intestinalis, and E. bieneusi, topical therapy
with fumagillin suspension has shown promise (Chap. 222). For
enteric infections with E. intestinalis in HIV-infected patients, therapy
with albendazole may be efficacious (Chap. 222).
■ OTHER INTESTINAL PROTOZOA
Balantidiasis Balantidium coli is a large ciliated protozoal parasite
that can produce a spectrum of large-intestinal disease analogous to
amebiasis. The parasite is widely distributed in the world. Since it
infects pigs, cases in humans are more common where pigs are raised.
Infective cysts can be transmitted from person to person and through
water, but many cases are due to the ingestion of cysts derived from
porcine feces in association with slaughtering, with use of pig feces for
fertilizer, or with contamination of water supplies by pig feces.
Ingested cysts liberate trophozoites, which reside and replicate in
the large bowel. Many patients remain asymptomatic, but some have
persisting intermittent diarrhea, and a few develop more fulminant
dysentery. In symptomatic individuals, the pathology in the bowel—
both gross and microscopic—is similar to that seen in amebiasis, with
varying degrees of mucosal invasion, focal necrosis, and ulceration.
Balantidiasis, unlike amebiasis, only rarely spreads hematogenously to
other organs. The diagnosis is made by detection of the trophozoite
stage in stool or sampled colonic tissue. Tetracycline (500 mg four
times daily for 10 days) is an effective therapeutic agent.
Blastocystosis Blastocystis hominis remains an organism of uncertain taxonomy and pathogenicity. Some patients who pass B. hominis
in their stools are asymptomatic, whereas others have diarrhea and
associated intestinal symptoms. Diligent evaluation reveals other
potential bacterial, viral, or protozoal causes of diarrhea in some but
not all patients with symptoms. Because the pathogenicity of B. hominis
is uncertain and because therapy for Blastocystis infection is neither
specific nor uniformly effective, patients with prominent intestinal
symptoms should be fully evaluated for other infectious causes of diarrhea. If diarrheal symptoms associated with Blastocystis are prominent,
either metronidazole (750 mg thrice daily for 10 days) or TMP-SMX
(160 mg/800 mg twice daily for 7 days) can be used.
Dientamoebiasis Dientamoeba fragilis is unique among intestinal
protozoa in that it has a trophozoite stage but not a cyst stage. How trophozoites survive to transmit infection is not known. When symptoms
1768 PART 5 Infectious Diseases
develop in patients with D. fragilis infection, they are generally mild
and include intermittent diarrhea, abdominal pain, and anorexia. The
diagnosis is made by the detection of trophozoites in stool; the lability
of these forms accounts for the greater yield when fecal samples are
preserved immediately after collection. NAATs are more sensitive than
fecal microscopy. Paromomycin (25–35 mg/kg per day in three doses
for 7 days) or metronidazole (500–750 mg three times daily for 10
days) is appropriate for treatment.
TRICHOMONIASIS
Various species of trichomonads can be found in the mouth (in association with periodontitis) and occasionally in the gastrointestinal tract.
Trichomonas vaginalis—one of the most prevalent protozoal parasites
in the United States—is a pathogen of the genitourinary tract and a
major cause of symptomatic vaginitis (Chap. 136).
Life Cycle and Epidemiology T. vaginalis is a pear-shaped,
actively motile organism that measures about 10 × 7 μm, replicates
by binary fission, and inhabits the lower genital tract of females and
the urethra and prostate of males. In the United States, it accounts for
~3 million infections per year in women. While the organism can
survive for a few hours in moist environments and could be acquired
by direct contact, person-to-person venereal transmission accounts for
virtually all cases of trichomoniasis. Its prevalence is greatest among
persons with multiple sexual partners and among those with other
sexually transmitted diseases (Chap. 136).
Clinical Manifestations Many men infected with T. vaginalis are
asymptomatic, although some develop urethritis and a few have epididymitis or prostatitis. In contrast, infection in women, which has an
incubation period of 5–28 days, is usually symptomatic and manifests
with malodorous vaginal discharge (often yellow), vulvar erythema
and itching, dysuria or urinary frequency (in 30–50% of patients), and
dyspareunia. These manifestations, however, do not clearly distinguish
trichomoniasis from other types of infectious vaginitis.
Diagnosis Detection of motile trichomonads by microscopic
examination of wet mounts of vaginal or prostatic secretions has been
the conventional means of diagnosis. Although this approach provides
an immediate diagnosis, its sensitivity for the detection of T. vaginalis
is only ~50–60% in routine evaluations of vaginal secretions. Direct
immunofluorescent antibody staining is more sensitive (70–90%)
than wet-mount examinations. T. vaginalis can be recovered from the
urethra of both males and females and is detectable in males after prostatic massage. NAATs are FDA approved and are highly sensitive and
specific for urine and for endocervical and vaginal swabs from women.
TREATMENT
Trichomoniasis
Metronidazole (either a single 2-g dose or 500-mg doses twice
daily for 7 days) or tinidazole (a single 2-g dose) is effective. All
sexual partners must be treated concurrently to prevent reinfection, especially from asymptomatic males. In males with persistent
symptomatic urethritis after therapy for nongonococcal urethritis, metronidazole therapy should be considered for possible trichomoniasis. Alternatives to metronidazole for treatment during
pregnancy are not readily available. Reinfection often accounts for
apparent treatment failures, but strains of T. vaginalis exhibiting
high-level resistance to metronidazole have been encountered.
Treatment of these resistant infections with higher oral doses,
parenteral doses, or concurrent oral and vaginal doses of metronidazole or with tinidazole has been successful.
■ FURTHER READING
Buret AG et al: Update on Giardia: Highlights from the Seventh International Giardia and Cryptosporidim Conference. Parasite 27:49, 2020.
Carter BL et al: Health sequelae of human cryptosporidiosis in industrialized countries: A systematic review. Parasit Vectors 13:443, 2020.
Coffey CM et al: Evolving epidemiology of reported giardiasis cases in
the United States, 1995-2016. Clin Infect Dis 72:764, 2021.
Han B, Weiss LM: Therapeutic targets for the treatment of microsporidiosis in humans. Expert Opin Ther Targets 22:903, 2018.
Hemphill A et al: Comparative pathobiology of the intestinal protozoan parasites Giardia lamblia, Entamoeba histolytica and Cryptosporidium parvum. Pathogens 8:116, 2019.
Kissinger P: Trichomonas vaginalis: A review of epidemiologic, clinical and treatment issues. BMC Infect Dis 15:307, 2015.
Ramanan P, Pritt BS: Extraintestinal microsporidiosis. J Clin Microbiol
52:3839, 2014.
Van German TO, Muzny CA: Recent advances in the epidemiology,
diagnosis, and management of Trichomonas vaginalis infection.
F1000Res 8:1666, 2019.
Van Gestel RSFE et al: A clinical guideline on Dientamoeba fragilis
infections. Parasitology 146:1131, 2018.
Widmer G et al: Update on Cryptosporidium spp: Highlights from
the Seventh International Giardia and Cryptosporidim Conference.
Parasite 27:14, 2020.
Section 19 Helminthic Infections
230
The word helminth is derived from the Greek helmins (“parasitic
worm”). Helminthic worms are highly prevalent and, depending on
the species, may exist as free-living organisms or as parasites of plant
or animal hosts. The parasitic helminths have co-evolved with specific
mammalian and other host species. Accordingly, most helminthic
infections are restricted to nonhuman hosts, and only rarely do these
zoonotic helminths accidentally cause human infections.
Helminthic parasites of humans belong to two phyla: Nemathelminthes, which includes nematodes (roundworms), and Platyhelminthes, which includes cestodes (tapeworms) and trematodes
(flukes). Helminthic parasites of humans reside within the human
body and hence are the cause of true infections. In contrast, parasites
of other genera that reside only on mucocutaneous surfaces of humans
(e.g., the parasites causing myiasis and scabies) are considered to represent infestations rather than infections.
Helminthic parasites differ substantially from protozoan parasites in
several respects. First, protozoan parasites are unicellular organisms,
whereas helminthic parasites are multicellular worms that possess differentiated organ systems. Second, helminthic parasites have complex
life cycles that require sequential stages of development outside the
human host. Thus, most helminths do not complete their replication
within the human host; rather, they develop to a certain stage within
the mammalian host and, as part of their obligatory life cycle, must
mature further outside that host. During the “extra-human” stages of
their life cycle, helminths exist either as free-living organisms or as
parasites within another host species and thereafter mature into new
developmental stages capable of infecting humans. Thus, with only
two exceptions (Strongyloides stercoralis and Capillaria philippinensis,
which are capable of internal human reinfections), increases in the
number of adult helminths (i.e., the “worm burden”) within the human
Introduction to
Helminthic Infections
Peter F. Weller
1769CHAPTER 230 Introduction to Helminthic Infections
host require repeated exogenous reinfections. In the case of protozoan
parasites, a brief, even singular exposure (e.g., a single mosquito bite
transmitting malaria) may lead rapidly to intense parasite loads and
overwhelming infections; in contrast, for all but the two helminths
noted above, increases in worm burden require multiple and usually
ongoing exposures to infectious forms, such as ingestion of eggs of
intestinal helminths or waterborne exposures to infectious cercariae of
Schistosoma mansoni. This requirement is germane both to the consideration of helminthic infections in individuals and to ongoing global
efforts to interrupt and/or minimize the acquisition of helminthic
infections by humans.
Third, helminthic infections have a predilection toward stimulation
of host immune responses that elicit eosinophilia within human tissues and blood. The many protozoan infections characteristically do
not elicit eosinophilia in infected humans, with only three exceptions
(two intestinal protozoan parasites, Cystoisospora belli and Dientamoeba fragilis, and tissue-borne Sarcocystis species). The magnitude of
helminth-elicited eosinophilia tends to correlate with the extent of tissue
invasion by larvae or adult helminths. For example, in several helminthic infections, including acute schistosomiasis (Katayama syndrome),
paragonimiasis, and hookworm and Ascaris infections, eosinophilia is
most pronounced during the early phases of infection, when migrations of infecting larvae and progression of subsequent developmental
stages through the tissues are greatest. In established infections, local
eosinophilia is often present around helminths in tissues, but blood eosinophilia may be intermittent, mild, or absent. In helminthic infections
in which parasites are well contained within tissues (e.g., echinococcal
cysts) or confined within the lumen of the intestinal tract (e.g., adult
Ascaris or tapeworms), eosinophilia is usually absent.
■ NEMATODES
Nematodes are nonsegmented roundworms. Species of nematodes
are remarkably diverse and abundant in nature. Among the many
thousands of nematode species, few are parasites of humans. Most
nematodes are free-living, and these species have variably evolved to
survive in diverse ecologic niches, including saltwater, freshwater, or
soil. The well-studied organism Caenorhabditis elegans is a free-living
nematode. Nematodes can be either beneficial or deleterious parasites
of plants. Parasitic nematodes have co-evolved with specific mammalian hosts and have no capacity to live their full life cycles in other
hosts. Uncommonly, humans are exposed to infectious stages of nonhuman nematode parasites, and the resultant zoonotic nematode infections can elicit inflammatory and immune responses as larval forms
migrate and die in the unsuitable human host. Examples include pulmonary coin lesions due to mosquito-transmitted infections with the
dog heartworm Dirofilaria immitis; eosinophilic meningoencephalitis
due to ingested eggs of the raccoon ascarid Baylisascaris procyonis; and
eosinophilic meningitis due to ingestion of larvae of the rat lungworm
Angiostrongylus cantonensis.
Nematode parasites of humans include worms that reside in the
intestinal tract or localize in extraintestinal vascular or tissue sites.
Roundworms are bisexual, with separate male and female forms
(except for S. stercoralis, whose adult females are hermaphroditic in the
human intestinal tract). Depending on the species, fertilized females
release either larvae or eggs containing larvae. Nematodes have five
developmental stages: an adult stage and four sequential larval stages.
These parasites characteristically are surrounded by a durable outer
cuticular layer. Nematodes have a nervous system; a muscular system,
including muscle cells under the cuticle; and a developed intestinal
tract, including an oral cavity and an elongated gut that ends in an anal
pore. Adults may range in size from minute to >1 meter in length (with
Dracunculus medinensis, for example, at the long end of this spectrum).
Humans acquire infections with nematode parasites by various
routes, depending on the parasitic species. Ingestion of eggs passed in
human feces is a major global health problem with many of the intestinal
helminths (e.g., Ascaris lumbricoides). In other species, infecting larvae
penetrate skin exposed to fecally contaminated soil (e.g., S. stercoralis,
hookworms) or traverse the skin after the bite of infected insect vectors
(e.g., filariae). Some nematode infections are acquired by consumption
of specific animal-derived foods (e.g., trichinellosis from raw or undercooked pork or wild carnivorous mammals). As noted above, only two
nematodes, S. stercoralis and C. philippinensis, can internally reinfect
humans; thus, for all other nematodes, any increases in worm burden
must be due to continued exogenous reinfections.
■ CESTODES
Tapeworms are the cestode parasites of humans. Adult tapeworms are
elongated, segmented, hermaphroditic flatworms that reside in the
intestinal lumen or, in their larval forms, may live in extraintestinal
tissues. Tapeworms include a head (scolex) and a number of attached
segments (proglottids). The worms attach to the intestinal tract via their
scolices, which may possess suckers, hooks, or grooves. The scolex
is the site of formation of new proglottids. Tapeworms do not have
a functional gut tract; rather, each tapeworm segment passively and
actively obtains nutrients through its specialized surface tegument.
Mature proglottids possess both male and female sex organs, but
insemination usually occurs between adjacent proglottids. Fertilized
proglottids release eggs that are passed in the feces. When ingested by
an intermediate host, an egg releases an oncosphere that penetrates the
gut and develops further in tissues as a cysticercus. Humans acquire
infection by ingesting animal tissues that contain cysticerci, and the
resultant tapeworms develop and reside in the proximal small bowel
(e.g., Taenia solium, T. saginata). Alternatively, if humans ingest eggs of
these cestodes that have been passed in human or animal feces, oncospheres develop and can cause space-occupying extraintestinal cystic
lesions in tissues; examples include cysticercosis due to T. solium and
hydatid disease due to species of Echinococcus.
■ TREMATODES
Trematodes of medical importance include blood flukes, intestinal
flukes, and tissue flukes. Adult flukes are often leaf-shaped flatworms.
Oral and/or ventral suckers help adult flukes maintain their positions
in situ. Flukes have an oral cavity but no distal anal pore. Nutrients
are obtained both through their integument and by ingestion into the
blind intestinal tract. Flukes are hermaphroditic except for blood flukes
(schistosomes), which are bisexual. Eggs are passed in human feces
(Fasciola, Fasciolopsis, Clonorchis, Schistosoma japonicum, S. mansoni),
urine (Schistosoma haematobium), or sputum and feces (Paragonimus).
Expelled eggs release miracidia—usually in water—that infect specific snail species. Within snails, parasites multiply and cercariae are
released. Depending on the species, cercariae can penetrate the skin
(schistosomes) or can develop into metacercariae that can be ingested
with plants (e.g., watercress for Fasciola) or with fish (Clonorchis) or
crabs (Paragonimus).
■ CONCLUSION
Many of the so-called neglected tropical diseases are due to helminthic infections. The health impacts of many helminthic infections
are varied and are based on the frequent need for repeated exposures
to increase the worm burdens in infected humans. In global regions
where exposures to specific helminths occur even in childhood (e.g.,
fecally derived intestinal nematodes, mosquito-transmitted filariae,
or waterborne snail-transmitted schistosomes), the morbidities in
infected individuals can include nutritional, developmental, cognitive, and functional impairments. Ongoing global mass-treatment
programs are currently aimed at diminishing the local prevalences of
specific helminths and their consequent impacts on the health of local
populations.
1770 PART 5 Infectious Diseases
Nematodes are elongated, symmetric roundworms. Parasitic nematodes of medical significance may be broadly classified as either predominantly intestinal or tissue nematodes. The intestinal nematodes
are covered in Chap. 232. This chapter covers the tissue nematodes
that cause trichinellosis, visceral and ocular larva migrans, cutaneous
larva migrans, cerebral angiostrongyliasis, and gnathostomiasis. All of
these zoonotic infections result from incidental exposure to infectious
nematodes. The clinical symptoms of these infections are due largely
to invasive larval stages that (except in the case of Trichinella) do not
reach maturity in humans.
■ TRICHINELLOSIS
Trichinellosis develops after the ingestion of meat containing cysts of
Trichinella (e.g., pork or other meat from a carnivore). Although most
infections are mild and asymptomatic, heavy infections can cause
severe enteritis, periorbital edema, myositis, and (infrequently) death.
Life Cycle and Epidemiology Nine species of Trichinella and
13 genotypes are recognized as causes of infection in humans. Two
species are distributed worldwide: T. spiralis, which is found in a great
variety of carnivorous and omnivorous animals, and T. pseudospiralis,
which is found in mammals and birds. T. nativa is present in Arctic
and subarctic regions and infects bears, foxes, and walruses; T. nelsoni
is found in equatorial eastern Africa, where it is common among felid
predators and scavengers such as hyenas and bush pigs; and T. britovi
is found in Europe, western Africa, and western Asia among carnivores
but not among domestic swine. T. murrelli is
present in wild animals in North American and
Japan. T. papuae is found in Papua New Guinea,
Thailand, Taiwan, and Cambodia in domestic
and feral pigs and in saltwater crocodiles and
turtles. T. zimbabwensis is present in crocodiles
in Tanzania. T. patagoniensis is found in cougars
in South America.
After human consumption of trichinous
meat, encysted larvae are liberated by digestive
acid and proteases (Fig. 231-1). The larvae
invade the small-bowel mucosa and mature
into adult worms. After ~1 week, female worms
release newborn larvae that migrate via the
circulation to striated muscle. The larvae of all
species except T. pseudospiralis, T. papuae, and
T. zimbabwensis then encyst by inducing a radical transformation in the muscle cell architecture. Host immune responses may help to expel
intestinal adult worms but have few deleterious
effects on muscle-dwelling larvae.
Human trichinellosis classically has been
caused by the ingestion of infected pork products and thus can occur in almost any location
where the meat of domestic or wild swine is
eaten. Increasingly, human trichinellosis has
also been acquired from the meat of other
animals, including dogs (in parts of Asia and
Africa), horses (in Italy and France), and bears
and walruses (in northern regions). Although
cattle (being herbivores) are not natural hosts
of Trichinella, beef has been implicated in outbreaks when contaminated or adulterated with
231
trichinous pork. About 12 cases of trichinellosis are reported annually
in the United States, but most mild cases probably remain undiagnosed.
Recent U.S. and Canadian outbreaks have been attributable predominantly to consumption of wild game (especially bear and walrus meat).
Pathogenesis and Clinical Features Clinical symptoms of trichinellosis arise from the successive phases of parasite enteric invasion,
larval migration, and muscle encystment (Fig. 231-1). Most light infections (those with <10 larvae per gram of muscle) are asymptomatic,
whereas heavy infections (which can involve >50 larvae per gram of
muscle) can be life-threatening. An initial enteric phase due to release
of ingested muscle larvae may elicit diarrhea, abdominal pain, constipation, and nausea during the first weeks after infection.
Symptoms due to larval migration and muscle invasion begin to
appear in the second week after infection. The migrating Trichinella larvae provoke a marked local and systemic hypersensitivity reaction, with
fever and eosinophilia. Periorbital and facial edema is common, as are
hemorrhages in the subconjunctivae, retina, and nail beds (“splinter”
hemorrhages). A maculopapular rash, headache, cough, dyspnea, or
dysphagia sometimes develops. Myocarditis with tachyarrhythmias or
heart failure—and, less commonly, encephalitis or pneumonitis—may
develop and accounts for most deaths of patients with trichinellosis.
Upon onset of larval encystment in muscle 2–3 weeks after infection, symptoms of myositis with myalgias, muscle edema, and weakness develop, usually overlapping with the inflammatory reactions
to migrating larvae. The most commonly involved muscle groups
include the extraocular muscles; the biceps; and the muscles of the jaw,
neck, lower back, and diaphragm. Peaking ~3 weeks after infection,
symptoms subside only gradually during a prolonged convalescence.
Uncommon infections with T. pseudospiralis, whose larvae do not
encapsulate in muscles, elicit a prolonged polymyositis-like illness.
Laboratory Findings and Diagnosis Blood eosinophilia develops in >90% of patients with symptomatic trichinellosis and may
peak at a level of >50% 2–4 weeks after infection. Serum levels of
muscle enzymes, including creatine phosphokinase, are elevated in
most symptomatic patients. Patients should be questioned thoroughly
Trichinellosis and
Other Tissue Nematode
Infections
Peter F. Weller
Larvae are released
in the stomach and mature
into adults over 1–2 wks
in the small bowel,
causing:
Larvae migrate,
penetrate striated
muscle, reside in
"nurse-cells," and encyst,*
causing:
Muscle pain, fever,
periorbital edema,
eosinophilia, occasional
CNS or cardiac damage
Encysted larvae ingested
in undercooked pork,
boar, horse, or bear
Irritation and mild abdominal
cramping or even diarrhea
*T. papuae, T. zimbabwensis, and T. pseudospiralis do not encyst.
Similar cycle (as humans)
in swine or other carnivores
(rats, bears, foxes, dogs, or horses)
FIGURE 231-1 Life cycle of Trichinella spiralis (cosmopolitan); nelsoni (equatorial Africa); britovi (Europe,
western Africa, western Asia); nativa (Arctic); murrelli (North America); papuae (Papua New Guinea);
zimbabwensis (Tanzania); and pseudospiralis (cosmopolitan). CNS, central nervous system. (Reproduced with
permission from RL Guerrant et al [eds]: Tropical Infectious Diseases: Principles, Pathogens and Practice,
2nd ed, Elsevier, 2006.)
1771CHAPTER 231 Trichinellosis and Other Tissue Nematode Infections
about their consumption of pork or wild animal meat and about illness
in other individuals who ate the same meat. A presumptive clinical
diagnosis can be based on fevers, eosinophilia, periorbital edema, and
myalgias after a suspect meal. A rise in the titer of parasite-specific
antibody, which usually does not occur until after the third week of
infection, confirms the diagnosis. Alternatively, a definitive diagnosis
requires surgical biopsy of at least 1 g of involved muscle; the yields
are highest near tendon insertions. The fresh muscle tissue should
be compressed between glass slides and examined microscopically
(Fig. 231-2) because larvae may be missed by examination of routine
histopathologic sections alone.
TREATMENT
Trichinellosis
Most lightly infected patients recover uneventfully with bed rest,
antipyretics, and analgesics. Glucocorticoids like prednisone
(Table 231-1) are beneficial for severe myositis and myocarditis.
Mebendazole and albendazole are active against enteric stages of
the parasite, but their efficacy against encysted larvae has not been
conclusively demonstrated.
Prevention Larvae are usually killed by cooking pork until it is no
longer pink or by freezing it at −15°C for 3 weeks. However, Arctic
T. nativa larvae in walrus or bear meat are relatively resistant and may
remain viable despite freezing.
■ VISCERAL AND OCULAR LARVA MIGRANS
Visceral larva migrans is a syndrome caused by nematodes that are
normally parasitic for nonhuman host species. In humans, these
nematode larvae do not develop into adult worms but instead migrate
through host tissues and elicit eosinophilic inflammation. The most
common form of visceral larva migrans is toxocariasis due to larvae of
the canine ascarid Toxocara canis; the syndrome is due less commonly
to the feline ascarid T. cati and even less commonly to the pig ascarid
Ascaris suum. Rare cases with eosinophilic meningoencephalitis have
been caused by the raccoon ascarid Baylisascaris procyonis.
Life Cycle and Epidemiology The canine roundworm T. canis
is distributed among dogs worldwide. Ingestion of infective eggs by
dogs is followed by liberation of Toxocara larvae, which penetrate
the gut wall and migrate intravascularly into canine tissues, where
most remain in a developmentally arrested state. During pregnancy,
some larvae resume migration in bitches and infect puppies prenatally (through transplacental transmission) or after birth (through
suckling). Thus, in lactating bitches and puppies, larvae return to the
intestinal tract and develop into adult worms, which produce eggs that
are released in the feces. Eggs must undergo embryonation over several
weeks to become infectious. Humans acquire toxocariasis mainly by
eating soil contaminated by puppy feces that contains infective T. canis
eggs. Visceral larva migrans is most common among children who
habitually eat dirt.
Pathogenesis and Clinical Features Clinical disease most commonly afflicts preschool children. After humans ingest Toxocara eggs,
the larvae hatch and penetrate the intestinal mucosa, from which they
are carried by the circulation to a wide variety of organs and tissues. The
larvae invade the liver, lungs, central nervous system (CNS), and other
sites, provoking intense local eosinophilic granulomatous responses.
The degree of clinical illness depends on larval number and tissue
distribution, reinfection, and host immune responses. Most light infections are asymptomatic and may be evidenced only by blood eosinophilia. Characteristic symptoms of visceral larva migrans include fever,
malaise, anorexia and weight loss, cough, wheezing, and rashes. Hepatosplenomegaly is common. These features may be accompanied by
extraordinary peripheral eosinophilia at levels that may approach 90%.
Uncommonly, seizures or behavioral disorders develop. Rare deaths are
due to severe neurologic, pneumonic, or myocardial involvement.
The ocular form of the larva migrans syndrome occurs when
Toxocara larvae invade the eye. An eosinophilic granulomatous mass,
most commonly in the posterior pole of the retina, develops around
the entrapped larva. The retinal lesion can mimic retinoblastoma
in appearance, and mistaken diagnosis of the latter condition can
lead to unnecessary enucleation. The spectrum of eye involvement
also includes endophthalmitis, uveitis, and chorioretinitis. Unilateral
visual disturbances, strabismus, and eye pain are the most common
presenting symptoms. In contrast to visceral larva migrans, ocular
toxocariasis usually develops in older children or young adults with
no history of pica; these patients seldom have eosinophilia or visceral
manifestations.
Diagnosis In addition to eosinophilia, leukocytosis and hypergammaglobulinemia may be evident. Transient pulmonary infiltrates are
apparent on chest x-rays of about one-half of patients with symptoms
of pneumonitis. The clinical diagnosis can be confirmed by an enzymelinked immunosorbent assay for toxocaral antibodies. Stool examination for parasite eggs is worthless in toxocariasis, since the larvae do
not develop into egg-producing adults in humans.
FIGURE 231-2 Trichinella larva encysted in a characteristic hyalinized capsule
in striated muscle tissue. (Photographs provided by Dr. Mary Wu Chang with
permission of patient’s mother.)
TABLE 231-1 Therapy for Tissue Nematode Infections
INFECTION SEVERITY TREATMENT
Trichinellosis Mild Supportive
Moderate Albendazole (400 mg bid × 8–14 days)
or
Mebendazole (200–400 mg tid × 3 days,
then 500 mg tid × 10 days)
Severe Add glucocorticoids (e.g., prednisone,
1 mg/kg qd × 5 days)
Visceral larva
migrans
Mild to
moderate
Supportive
Severe Glucocorticoids (as above)
Ocular Not fully defined; albendazole (800 mg
bid for adults, 400 mg bid for children)
with glucocorticoids × 5–20 days has
been effective
Cutaneous larva
migrans
Ivermectin (single dose, 200 μg/kg) or
Albendazole (200 mg bid × 3 days)
Angiostrongyliasis Mild to
moderate
Supportive
Severe Glucocorticoids (as above)
Gnathostomiasis Ivermectin (200 μg/kg per day ×
2 days) or
Albendazole (400 mg bid × 21 days)
1772 PART 5 Infectious Diseases
Eosinophilic meningitis
2 weeks
3rd-stage larvae (consumed
in snail or slime) penetrate gut,
go to CNS (then lung in rat)
Larvae consumed by land
snail/slug (Achatina fulica)
viable in fresh water
Adult in pulmonary artery
produces fertile eggs; larvae
hatch, penetrate arterioles,
migrate up bronchi, and are
coughed up, swallowed, and
passed in feces
FIGURE 231-3 Life cycle of Angiostrongylus cantonensis (rat lung worm) found in Southeast Asia and the Pacific Basin as well as on Caribbean islands, in countries of
Central and South America, and in the southern United States. CNS, central nervous system. (Reproduced with permission from RL Guerrant et al [eds]: Tropical Infectious
Diseases: Principles, Pathogens and Practice, 2nd ed, Elsevier, 2006.)
TREATMENT
Visceral and Ocular Larva Migrans
The vast majority of Toxocara infections are self-limited and resolve
without specific therapy. In patients with severe myocardial, CNS,
or pulmonary involvement, glucocorticoids may be employed to
reduce inflammatory complications. Available anthelmintic drugs,
including mebendazole and albendazole, have not been shown
conclusively to alter the course of larva migrans. Control measures
include prohibiting dog excreta in public parks and playgrounds,
deworming dogs, and preventing pica in children. Treatment of
ocular disease is not fully defined, but the administration of
albendazole in conjunction with glucocorticoids has been effective
(Table 231-1).
■ CUTANEOUS LARVA MIGRANS
Cutaneous larva migrans (“creeping eruption”) is a serpiginous skin
eruption caused by burrowing larvae of animal hookworms, usually
the dog and cat hookworm Ancylostoma braziliense. The larvae hatch
from eggs passed in dog and cat feces and mature in the soil. Humans
become infected after skin contact with soil in areas frequented by dogs
and cats. Cutaneous larva migrans is prevalent among children and
travelers in regions with warm humid climates, including the southeastern United States.
After larvae penetrate the skin, erythematous lesions form along
the tortuous tracks of their migration through the dermal-epidermal
junction; the larvae advance several centimeters in a day. The intensely
pruritic lesions may occur anywhere on the body and can be numerous
if the patient has lain on the ground. Vesicles and bullae may form later.
The animal hookworm larvae do not mature in humans and, without
treatment, will die after an interval ranging from weeks to a couple of
months, with resolution of skin lesions. The diagnosis is made on clinical grounds. Skin biopsies only rarely detect diagnostic larvae. Symptoms can be alleviated by ivermectin or albendazole (Table 231-1).
■ ANGIOSTRONGYLIASIS
Angiostrongylus cantonensis, the rat lungworm, is the most common
cause of human eosinophilic meningitis (Fig. 231-3).
Life Cycle and Epidemiology This infection occurs principally
in Southeast Asia and the Pacific Basin but has spread to other areas
of the world, including the Caribbean islands, countries in Central and
South America, and the southern United States. A. cantonensis larvae
produced by adult worms in the rat lung migrate to the gastrointestinal
tract and are expelled with the feces. They develop into infective larvae
in land snails and slugs. Humans acquire the infection by ingesting raw
infected mollusks; vegetables contaminated by mollusk slime; or crabs,
freshwater shrimp, and certain marine fish that have themselves eaten
infected mollusks. The larvae then migrate to the brain.
Pathogenesis and Clinical Features The parasites eventually
die in the CNS, but not before initiating pathologic consequences that,
in heavy infections, can result in permanent neurologic sequelae or
death. Migrating larvae cause marked local eosinophilic inflammation
and hemorrhage, with subsequent necrosis and granuloma formation
around dying worms. Clinical symptoms develop 2–35 days after the
ingestion of larvae. Patients usually present with an insidious or abrupt
excruciating frontal, occipital, or bitemporal headache. Neck stiffness,
nausea and vomiting, and paresthesias are also common. Fever, cranial
and extraocular nerve palsies, seizures, paralysis, and lethargy are
uncommon.
Laboratory Findings Examination of cerebrospinal fluid (CSF) is
mandatory in suspected cases and usually reveals an elevated opening
pressure, a white blood cell count of 150–2000/μL, and an eosinophilic
pleocytosis of >20%. The protein concentration is usually elevated and
the glucose level normal. The larvae of A. cantonensis are only rarely
seen in CSF. Peripheral-blood eosinophilia may be mild. The diagnosis
is generally based on the clinical presentation of eosinophilic meningitis together with a compatible epidemiologic history.
TREATMENT
Angiostrongyliasis
Specific chemotherapy is not of benefit in angiostrongyliasis; larvicidal agents may exacerbate inflammatory brain lesions. Management consists of supportive measures, including the administration
of analgesics, sedatives, and—in severe cases—glucocorticoids
(Table 231-1). Repeated lumbar punctures with removal of CSF
can relieve symptoms. In most patients, cerebral angiostrongyliasis
has a self-limited course, and recovery is complete. The infection
may be prevented by adequately cooking snails, crabs, and prawns
and inspecting vegetables for mollusk infestation. Other parasitic
or fungal causes of eosinophilic meningitis in endemic areas may
1773CHAPTER 232 Intestinal Nematode Infections
More than a billion persons worldwide are infected with one or more
species of intestinal nematodes. Table 232-1 summarizes biologic
and clinical features of infections due to the major intestinal parasitic
nematodes. These parasites are most common in regions with poor
fecal sanitation, particularly in resource-poor countries in the tropics
and subtropics, but they have also been seen with increasing frequency
among immigrants and refugees to resource-rich countries. Although
nematode infections are not usually fatal, they contribute to malnutrition and diminished work capacity. It is interesting that these helminth infections may protect some individuals from allergic disease.
Humans may on occasion be infected with nematode parasites that
ordinarily infect animals; these zoonotic infections produce diseases
such as trichostrongyliasis, anisakiasis, capillariasis, and abdominal
angiostrongyliasis.
Intestinal nematodes are roundworms; they range in length from
1 mm to many centimeters when mature (Table 232-1). Their life cycles
are complex and highly varied; some species, including Strongyloides
stercoralis and Enterobius vermicularis, can be transmitted directly
from person to person, while others, such as Ascaris lumbricoides and
the hookworms, require a soil phase for development. Because most
helminth parasites do not self-replicate, the acquisition of a heavy
burden of adult worms requires repeated exposure to the parasite in
its infectious stage, whether larva or egg. Hence, clinical disease, as
opposed to asymptomatic (or subclinical) infection, generally develops only with prolonged exposure in an endemic area and is typically
related to infection intensity. In persons with marginal nutrition, intestinal helminth infections may impair growth and development. Eosinophilia and elevated serum IgE levels are features of many helminth
infections and, when unexplained, should always prompt a search
for intestinal helminths. Significant protective immunity to intestinal nematodes appears not to develop in humans, although the host
immune response to these infections has not been elucidated in detail.
■ ASCARIASIS
A. lumbricoides is the largest intestinal nematode parasite of humans,
reaching up to 40 cm in length. Most infected individuals have low worm
burdens and are asymptomatic. Clinical disease arises from larval migration in the lungs or effects of the adult worms in the intestines.
Life Cycle Adult worms live in the lumen of the small intestine.
Mature female Ascaris worms are extraordinarily fecund, each producing up to 240,000 eggs a day that pass with the feces. Ascarid eggs,
which are remarkably resistant to environmental stresses, become
infective after several weeks of maturation in the soil and can remain
infective for years. After infective eggs are swallowed, larvae hatched in
the intestine invade the mucosa, migrate through the circulation to the
lungs, break into the alveoli, ascend the bronchial tree, and return—
through swallowing—to the small intestine, where they develop into
adult worms. The time between initial infection and egg production is
typically between 2–3 months. Adult worms live for 1–2 years.
Epidemiology Ascaris is widely distributed in tropical and subtropical regions as well as in other humid areas in more temperate
regions of the world. Transmission typically occurs through fecally
contaminated soil and is due either to a lack of sanitary facilities or to
the use of human feces as fertilizer. With their propensity for hand-tomouth fecal carriage, younger children are most often affected. Infection outside endemic areas, though uncommon, can occur when eggs
on transported vegetables are ingested.
Clinical Features During the lung phase of larval migration,
~9–12 days after egg ingestion, patients may develop an irritating
232 Intestinal Nematode
Infections
Thomas B. Nutman, Peter F. Weller
include gnathostomiasis (see below), paragonimiasis (Chap. 234),
schistosomiasis (Chap. 234), neurocysticercosis (Chap. 235), and
coccidioidomycosis (Chap. 213).
■ GNATHOSTOMIASIS
Infection of human tissues with larvae of Gnathostoma spinigerum can
cause eosinophilic meningoencephalitis, migratory cutaneous swellings, or invasive masses of the eye and visceral organs.
Life Cycle and Epidemiology Human gnathostomiasis occurs
in many countries and is notably endemic in Southeast Asia and parts
of China and Japan. In nature, the mature adult worms parasitize the
gastrointestinal tract of dogs and cats. First-stage larvae hatch from
eggs passed into water and are ingested by Cyclops species (water fleas).
Infective third-stage larvae develop in the flesh of many animal species
(including fish, frogs, eels, snakes, chickens, and ducks) that have eaten
either infected Cyclops or another infected second intermediate host.
Humans typically acquire the infection by eating raw or undercooked
fish or poultry. Raw fish dishes, such as som fak in Thailand and
sashimi in Japan, account for many cases of human gnathostomiasis.
Some cases in Thailand result from the local practice of applying frog
or snake flesh as a poultice.
Pathogenesis and Clinical Features Clinical symptoms are due
to the aberrant migration of a single larva into cutaneous, visceral,
neural, or ocular tissues. After invasion, larval migration may cause
local inflammation, with pain, cough, or hematuria accompanied by
fever and eosinophilia. Painful, itchy, migratory swellings may develop
in the skin, particularly in the distal extremities or periorbital area.
Cutaneous swellings usually last ~1 week but often recur intermittently
over many years. Larval invasion of the eye can provoke a sight-threatening inflammatory response. Invasion of the CNS results in eosinophilic meningitis with myeloencephalitis, a serious complication
due to ascending larval migration along a large nerve tract. Patients
characteristically present with agonizing radicular pain and paresthesias in the trunk or a limb, which are followed shortly by paraplegia.
Cerebral involvement, with focal hemorrhages and tissue destruction,
is often fatal.
Diagnosis and Treatment Cutaneous migratory swellings with
marked peripheral eosinophilia, supported by an appropriate geographic and dietary history, generally constitute an adequate basis for
a clinical diagnosis of gnathostomiasis. However, patients may present
with ocular or cerebrospinal involvement without antecedent cutaneous swellings. In the latter case, eosinophilic pleocytosis is demonstrable (usually along with hemorrhagic or xanthochromic CSF), but
worms are almost never recovered from CSF. Surgical removal of the
parasite from subcutaneous or ocular tissue, though rarely feasible, is
both diagnostic and therapeutic. Albendazole or ivermectin may be
helpful (Table 231-1). At present, cerebrospinal involvement is managed with supportive measures and generally with a course of glucocorticoids. Gnathostomiasis can be prevented by adequate cooking of
fish and poultry in endemic areas.
■ FURTHER READING
Centers for Disease Control and Prevention: Surveillance for
trichinellosis—United States, 2015, Annual Summary. Atlanta, GA:
U.S. Department of Health and Human Services, CDC, 2017.
Lupi O et al: Mucocutaneous manifestations of helminth infections.
Nematodes. J Am Acad Dermatol 73:929, 2015.
Martins YC et al: Central nervous system manifestations of Angiostrongylus cantonensis infection. Acta Trop 141:46, 2015.
Rostami A et al: Meat sources of infection for outbreaks of human
trichinellosis. Food Microbiol 64:65, 2017.
Rostami A et al: Human toxocariasis—A look at a neglected disease
through an epidemiological “prism.” Infect Genet Evol 74:104002,
2019.
Sitcar AD et al: Raccoon roundworm infection associated with
central nervous system disease and ocular disease—six states,
2013–2015. Morbid Mortal Wkly Rep 65:930, 2016.
1774 PART 5 Infectious Diseases
TABLE 232-1 Major Human Intestinal Parasitic Nematodes
FEATURE
PARASITIC NEMATODE
ASCARIS LUMBRICOIDES
(ROUNDWORM)
NECATOR AMERICANUS,
ANCYLOSTOMA
DUODENALE,
ANCYLOSTOMA
CEYLANICUM (HOOKWORM)
STRONGYLOIDES
STERCORALIS
TRICHURIS
TRICHIURA
(WHIPWORM)
ENTEROBIUS
VERMICULARIS
(PINWORM)
Global prevalence in
humans (millions)
807 576 100 604 209
Endemic areas Worldwide Hot, humid regions Hot, humid regions Worldwide Worldwide
Infective stage Egg Filariform larva Filariform larva Egg Egg
Route of infection Oral Percutaneous Percutaneous or
autoinfective
Oral Oral
Gastrointestinal location
of worms
Jejunal lumen Jejunal mucosa Small-bowel mucosa Cecum, colonic
mucosa
Cecum, appendix
Adult worm size 15–40 cm 7–12 mm 2 mm 30–50 mm 8–13 mm (female)
Pulmonary passage of
larvae
Yes Yes Yes No No
Incubation perioda
(days) 60–75 40–100 17–28 70–90 35–45
Longevity 1 year N. americanus: 2–5 years
A. duodenale: 6–8 years
A. ceylanicum: 6–8 yearsb
Decades (owing to
autoinfection)
5 years 2 months
Fecundity (eggs/day/
worm)
240,000 N. americanus: 4000–10,000
A. duodenale: 10,000–25,000
A. ceylanicum: 5,000–15,000
5000–10,000 3000–7000 2000
Principal symptoms Rarely, biliary obstruction
or, in heavy infections,
gastrointestinal
obstruction
Iron-deficiency anemia in
heavy infection
Gastrointestinal
symptoms; malabsorption
or sepsis in hyperinfection
Gastrointestinal
symptoms or anemia
in heavy infection
Perianal pruritus
Diagnostic stage Eggs in stool Eggs in fresh stool, larvae in
old stool
Larvae in stool or
duodenal aspirate;
sputum in hyperinfection
Eggs in stool Eggs from perianal skin
on cellulose acetate tape
Treatment Mebendazole
Albendazole
Ivermectin
Mebendazole
Albendazole
Ivermectin
Albendazole
Mebendazole
Albendazole
Ivermectin
Mebendazole
Albendazole
a
Time from infection to egg production by mature female worm. b
Assumed but no evidence base in humans.
nonproductive cough and burning substernal discomfort that is aggravated by coughing or deep inspiration. Dyspnea and blood-tinged sputum are less common. Fever can occur. Eosinophilia develops during
this symptomatic phase and subsides slowly over weeks. Chest imaging
may reveal evidence of eosinophilic pneumonitis (Löffler’s syndrome),
with rounded infiltrates a few millimeters to several centimeters in
size. These infiltrates may be transient and intermittent, clearing after
several weeks. Where there is seasonal transmission of the parasite,
seasonal pneumonitis with eosinophilia may develop in previously
infected and sensitized hosts.
In established infections, adult worms in the small intestine usually cause no symptoms. In heavy infections, particularly in children,
a large bolus of entangled worms can cause pain and small-bowel
obstruction, sometimes complicated by perforation, intussusception,
or volvulus. Single worms may cause disease when they migrate into
aberrant sites. A large worm can enter and occlude the biliary tree,
causing biliary colic, cholecystitis, cholangitis, pancreatitis, or (rarely)
intrahepatic abscesses. Migration of an adult worm up the esophagus
can provoke coughing and oral expulsion of the worm. In highly
endemic areas, intestinal and biliary ascariasis can rival acute appendicitis and gallstones as causes of surgical acute abdomen.
Laboratory Findings Most cases of ascariasis can be diagnosed
by microscopic detection of characteristic Ascaris eggs (65 × 45 μm)
in fecal samples, although increasingly, polymerase chain reaction
(PCR) of DNA extracted from stool is being used in research and
some clinical settings. Occasionally, patients present after passing an
adult worm—identifiable by its large size and smooth cream-colored
surface—in the stool or, much less commonly, through the mouth
or nose. During the early transpulmonary migratory phase, when
eosinophilic pneumonitis occurs, larvae can be found in sputum or
gastric aspirates before diagnostic eggs appear in the stool. The eosinophilia that is prominent during this early stage usually decreases to
minimal levels in established infection. Adult worms may be visualized, occasionally serendipitously, on contrast studies of the gastrointestinal tract. A plain abdominal film may reveal masses of worms in
gas-filled loops of bowel in patients with intestinal obstruction. Pancreaticobiliary worms can be detected by ultrasound and endoscopic
retrograde cholangiopancreatography; the latter method also has been
used to extract biliary Ascaris worms.
TREATMENT
Ascariasis
Ascariasis should always be treated to prevent potentially serious
complications. Albendazole (400 mg once), mebendazole (100 mg
twice daily for 3 days or 500 mg once), or ivermectin (150–200 μg/
kg once) is effective. These medications are contraindicated in pregnancy, however. Mild diarrhea and abdominal pain are uncommon
side effects of these agents. Partial intestinal obstruction should be
managed with nasogastric suction, IV fluid administration, and
instillation of piperazine through the nasogastric tube, but complete
obstruction and its severe complications require immediate surgical
intervention.
■ HOOKWORM
Three species (Ancylostoma duodenale, Ancylostoma ceylanicum, and
Necator americanus) are responsible for most human hookworm infections. Most infected individuals are asymptomatic. Hookworm disease
1775CHAPTER 232 Intestinal Nematode Infections
develops from a combination of factors—a heavy worm burden, a
prolonged duration of infection, and an inadequate iron intake—and
results in iron-deficiency anemia and, on occasion, hypoproteinemia.
Life Cycle Adult hookworms, which are ~1 cm long, use buccal teeth
(Ancylostoma) or cutting plates (Necator) to attach to the small-bowel
mucosa and suck blood (0.2 mL/d per Ancylostoma adult) and interstitial fluid. The adult hookworms produce thousands of eggs daily. The
eggs are deposited with feces in soil, where rhabditiform larvae hatch
and develop over a 1-week period into infectious filariform larvae.
Infective larvae penetrate the skin and reach the lungs by way of the
bloodstream. There they invade alveoli and ascend the airways before
being swallowed and reaching the small intestine. The prepatent period
from skin invasion to appearance of eggs in the feces is ~6–8 weeks,
but it may be longer with Ancylostoma spp. Larvae of Ancylostoma spp.,
if swallowed, can survive and develop directly in the intestinal mucosa.
Adult hookworms may survive over a decade but usually live ~6–8 years
for A. duodenale and 2–5 years for N. americanus.
Epidemiology A. duodenale is prevalent in southern Europe,
North Africa, and northern Asia, and N. americanus is the predominant species in the Western Hemisphere and equatorial Africa.
A. ceylanicum is most prevalent in Southeast Asia. The species can
overlap geographically, particularly in Southeast Asia. Age prevalence
studies have shown a constant increase in hookworm prevalence over
time; older children have the greatest intensity of hookworm infection;
however, in rural areas where fields are fertilized with human feces,
older working adults also may be heavily infected.
Clinical Features Most hookworm infections are clinically asymptomatic. Infective larvae may provoke pruritic maculopapular dermatitis
(“ground itch”) at the site of skin penetration as well as serpiginous tracks
of subcutaneous migration (similar to those of cutaneous larva migrans;
Chap. 231) in previously sensitized hosts. Larvae migrating through the
lungs occasionally cause mild transient pneumonitis, but this condition
develops less frequently in hookworm infection than in ascariasis. In
the early intestinal phase, infected persons may develop epigastric pain
(often with postprandial accentuation), inflammatory diarrhea, or other
abdominal symptoms accompanied by eosinophilia. The major consequence of chronic hookworm infection is iron deficiency. Symptoms are
minimal if iron intake is adequate, but marginally nourished individuals
develop symptoms of progressive iron-deficiency anemia and hypoproteinemia, including weakness and shortness of breath.
Laboratory Findings The diagnosis is established by the finding of characteristic 40- by 60-μm oval hookworm eggs in the
feces. Stool-concentration procedures may be required to detect light
infections. Eggs of the three species are indistinguishable by light
microscopy, whereas PCR has provided a significant improvement
in species-specific diagnosis. In a stool sample that is not fresh, the
eggs may have hatched to release rhabditiform larvae, which need to
be differentiated from those of S. stercoralis. Hypochromic microcytic
anemia, occasionally with eosinophilia or hypoalbuminemia, is characteristic of hookworm disease.
TREATMENT
Hookworm Infection
Hookworm infection can be treated with several safe and highly
effective anthelmintic drugs, including albendazole (400 mg once)
and mebendazole (500 mg once). Mild iron-deficiency anemia can
often be treated with oral iron alone. Severe hookworm disease with
protein loss and malabsorption necessitates nutritional support and
oral iron replacement along with deworming. There is significant
concern that the benzimidazoles (mebendazole and albendazole)
are becoming much less effective against human hookworms.
Ancylostoma caninum and Ancylostoma braziliense A. caninum,
the canine hookworm, has been identified as a cause of human eosinophilic enteritis, especially in northeastern Australia. In this zoonotic
infection, adult hookworms attach to the small intestine (where they
may be visualized by endoscopy) and elicit abdominal pain and
intense local eosinophilia. Treatment with mebendazole (100 mg
twice daily for 3 days) or albendazole (400 mg once) or endoscopic
removal is effective. Both of these animal hookworm species can cause
cutaneous larva migrans (“creeping eruption”; Chap. 231).
■ STRONGYLOIDIASIS
S. stercoralis is distinguished by its ability—unique among helminths
(except for Capillaria; see below)—to replicate in the human host. This
capacity permits ongoing cycles of autoinfection as infective larvae are
internally produced. Infection with S. stercoralis can thus persist for
decades without further exposure of the host to exogenous infective
larvae. In immunocompromised hosts, large numbers of invasive
Strongyloides larvae can disseminate widely and can be fatal.
Life Cycle In addition to a parasitic cycle of development, Strongyloides can undergo a free-living cycle of development in the soil
(Fig. 232-1). This adaptability facilitates the parasite’s survival in the
absence of mammalian hosts. Rhabditiform larvae passed in feces can
transform into infectious filariform larvae either directly or after a
free-living phase of development. Humans acquire S. stercoralis when
filariform larvae in fecally contaminated soil penetrate the skin or
mucous membranes. The larvae then travel through the bloodstream
to the lungs, where they break into the alveolar spaces, ascend the
bronchial tree, are swallowed, and thereby reach the small intestine.
There the larvae mature into adult worms that penetrate the mucosa
of the proximal small bowel. The minute (2-mm-long) parasitic adult
female worms reproduce by parthenogenesis; adult males do not exist.
Eggs hatch in the intestinal mucosa, releasing rhabditiform larvae that
migrate to the lumen and pass with the feces into soil. Alternatively,
rhabditiform larvae in the bowel can develop directly into filariform
larvae that penetrate the colonic wall or perianal skin and enter the
circulation to repeat the migration that establishes ongoing internal
reinfection. This autoinfection cycle allows strongyloidiasis to persist
for decades.
Epidemiology S. stercoralis is spottily distributed in tropical areas
and other hot, humid regions and is particularly common in Southeast
Asia, sub-Saharan Africa, and Brazil. In the United States, the parasite
is endemic in parts of the Southeast and is found in immigrants, refugees, travelers, and military personnel who have lived in endemic areas.
Clinical Features In uncomplicated strongyloidiasis, many
patients are asymptomatic or have mild cutaneous and/or abdominal
symptoms. Recurrent urticaria, often involving the buttocks and wrists,
is the most common cutaneous manifestation. Migrating larvae can
elicit a pathognomonic serpiginous eruption, larva currens (“running
larva”). This pruritic, raised, erythematous lesion advances as rapidly
as 10 cm/h along the course of larval migration. Adult parasites burrow
into the duodenojejunal mucosa and can cause abdominal (usually
midepigastric) pain, which resembles peptic ulcer pain except that
it is aggravated by food ingestion. Nausea, diarrhea, gastrointestinal
bleeding, mild chronic colitis, and weight loss can occur. Small-bowel
obstruction may develop with early, heavy infection. Pulmonary
symptoms are rare in uncomplicated strongyloidiasis. Eosinophilia is
common, with levels fluctuating over time.
The ongoing autoinfection cycle of S. stercoralis is normally constrained by unknown factors of the host’s immune system. Abrogation
of host immunity, especially with glucocorticoid therapy and much
less commonly with other immunosuppressive medications, leads to
hyperinfection, with the generation of large numbers of filariform larvae. Colitis, enteritis, or malabsorption may develop. In disseminated
strongyloidiasis, larvae may invade not only gastrointestinal tissues and
the lungs but also the central nervous system, peritoneum, liver, and
kidneys. Moreover, bacteremia may develop because of the passage of
enteric flora through disrupted mucosal barriers. Gram-negative sepsis, pneumonia, or meningitis may complicate or dominate the clinical
course. Eosinophilia is often absent in severely infected patients. Disseminated strongyloidiasis, particularly in patients with unsuspected
1776 PART 5 Infectious Diseases
2-mm hermaphroditic
adult s
penetrate small-bowel
mucosa and release eggs,
which hatch to
rhabditiform larvae.
Larvae shed in stool
Lung or intestinal stage may cause:
Free-living
1-mm adults
in soil
Eggs in soil
Indirect development
(heterogonic)
(can multiply outside host
for several generations) in soil
Direct development
Rhabditiform larvae
in soil
Filariform
larvae (450 µm)
Eosinophilia and
intermittent
epigastric pain
Autoinfection:
Transform within the intestine
into filariform larvae, which
penetrate perianal skin
or bowel mucosa,
causing:
Pruritic larva currens
Eosinophilia
Hyperinfection:
With immunosuppression, larger
numbers of filariform larvae develop,
penetrate bowel, and disseminate,
causing:
Colitis, polymicrobial sepsis,
pneumonitis, or meningitis
Larvae migrate via
bloodstream or lymphatics
to lungs, ascend airway
to trachea and pharynx,
and are swallowed.
FIGURE 232-1 Life cycle of Strongyloides stercoralis. (Reproduced with permission from RL Guerrant et al [eds]: Tropical Infectious Diseases: Principles, Pathogens and
Practice, 2nd ed, Elsevier, 2006.)
infection who are given glucocorticoids, can be fatal. Strongyloidiasis
is a frequent complication of infection with human T-cell lymphotropic
virus type 1 (HTLV-1), but disseminated strongyloidiasis is not common among patients infected with HIV-1.
Diagnosis In uncomplicated strongyloidiasis, the finding of rhabditiform larvae in feces is diagnostic. Rhabditiform larvae are ~250 μm
long, with a short buccal cavity that distinguishes them from hookworm larvae. In uncomplicated infections, few larvae are passed
and single stool examinations detect only about one-third of cases.
Serial examinations and the use of the agar plate detection method
improve the sensitivity of stool diagnosis. Again, PCR has begun to
be used more widely and provides increased diagnostic specificity. In
uncomplicated strongyloidiasis (but not in hyperinfection), microscopy-based stool examinations may be repeatedly negative. Strongyloides
larvae may also be found by sampling of the duodenojejunal contents
by aspiration or biopsy. An enzyme-linked immunosorbent assay for
serum antibodies to antigens of Strongyloides is a sensitive method for
diagnosing uncomplicated infections. Such serologic testing should be
performed for patients whose geographic histories indicate potential
exposure, especially those who exhibit eosinophilia and/or are candidates for glucocorticoid treatment of other conditions. In disseminated
strongyloidiasis, filariform larvae should be sought in stool as well as
in samples obtained from sites of potential larval migration, including
sputum, bronchoalveolar lavage fluid, or surgical drainage fluid.
TREATMENT
Strongyloidiasis
Even in the asymptomatic state, strongyloidiasis must be treated
because of the potential for subsequent dissemination and fatal
hyperinfection. Ivermectin (200 μg/kg daily for 2 days) is consistently more effective than albendazole (400 mg daily for 3 days). For
disseminated strongyloidiasis, treatment with ivermectin should
be extended for at least 14 days or at least a week after parasites
have been eradicated. In potentially immunocompromised hosts,
the course of ivermectin should be repeated 2 weeks after initial
treatment. Ivermectin has been successfully given parenterally (subcutaneously or intramuscularly) in those unable to take ivermectin
orally.
■ TRICHURIASIS
Most infections with Trichuris trichiura are asymptomatic, but heavy
infections may cause gastrointestinal symptoms. Like the other
soil-transmitted helminths, whipworm is distributed globally in the
tropics and subtropics and is most common among poor children from
resource-poor regions of the world.
Life Cycle Adult Trichuris worms reside in the colon and cecum, the
anterior portions threaded into the superficial mucosa. Thousands of
eggs laid daily by adult female worms pass with the feces and mature in
the soil. After ingestion, infective eggs hatch in the duodenum, releasing
larvae that mature before migrating to the large bowel. The entire cycle
takes ~3 months, and adult worms may live for several years.
Clinical Features Tissue reactions to Trichuris are mild. Most infected
individuals have no symptoms or eosinophilia. Heavy infections may
result in anemia, abdominal pain, anorexia, and bloody or mucoid
diarrhea resembling inflammatory bowel disease. Rectal prolapse can
result from massive infections in children, who often suffer from malnourishment and other diarrheal illnesses. Moderately heavy Trichuris
burdens also contribute to growth retardation.
1777CHAPTER 232 Intestinal Nematode Infections
Diagnosis and Treatment The characteristic 50- by 20-μm lemonshaped Trichuris eggs are readily detected on stool examination. Adult
worms, which are 3–5 cm long, are occasionally seen on proctoscopy.
PCR is being used increasingly in settings where it is available. Mebendazole (500 mg once) or albendazole (400 mg daily for 3 doses) is
safe and modestly effective for treatment, with cure rates of 30−90%.
Ivermectin (200 μg/kg daily for 3 doses) is also safe but is not quite as
efficacious as the benzimidazoles.
■ ENTEROBIASIS (PINWORM)
E. vermicularis is more common in temperate countries than in the
tropics. In the United States, ~40 million persons are infected with
pinworms, with a disproportionate number of cases among children.
Life Cycle and Epidemiology Enterobius adult worms are ~1 cm
long and dwell in the cecum. Gravid female worms migrate nocturnally into the perianal region and release up to 2000 immature eggs
each. The eggs become infective within hours and are transmitted by
hand-to-mouth passage. From ingested eggs, larvae hatch and mature
into adults. This life cycle takes ~1 month, and adult worms survive for
~2 months. Self-infection results from perianal scratching and transport of infective eggs on the hands or under the nails to the mouth.
Because of the ease of person-to-person spread, pinworm infections are
common among family members.
Clinical Features Most pinworm infections are asymptomatic.
Perianal pruritus is the cardinal symptom. The itching, which is often
worse at night as a result of the nocturnal migration of the female
worms, may lead to excoriation and bacterial superinfection. Heavy
infections have been alleged to cause abdominal pain and weight loss.
On rare occasions, pinworms invade the female genital tract, causing
vulvovaginitis and pelvic or peritoneal granulomas. Eosinophilia is
uncommon.
Diagnosis Since pinworm eggs are not released in feces, the diagnosis cannot be made by conventional fecal ova and parasite tests. Instead,
eggs are detected by the application of clear cellulose acetate tape to the
perianal region in the morning. After the tape is transferred to a slide,
microscopic examination will detect pinworm eggs, which are oval,
measure 55 × 25 μm, and are flattened along one side.
TREATMENT
Enterobiasis
Infected children and adults should be treated with mebendazole
(100 mg once) or albendazole (400 mg once), with the same treatment repeated after 2 weeks. Treatment of household members
is advocated to eliminate asymptomatic reservoirs of potential
reinfection.
■ TRICHOSTRONGYLIASIS
Trichostrongylus species, which are normally parasites of herbivorous
animals, occasionally infect humans, particularly in Asia and Africa.
Humans acquire the infection by accidentally ingesting Trichostrongylus larvae on contaminated leafy vegetables. The larvae do not migrate
in humans but mature directly into adult worms in the small bowel.
These worms ingest far less blood than hookworms; most infected
persons are asymptomatic, but heavy infections may give rise to mild
anemia and eosinophilia. In stool examinations, Trichostrongylus eggs
resemble hookworm eggs but are larger (85 × 115 μm). Treatment consists of mebendazole or albendazole (Chap. 222).
■ ANISAKIASIS
Anisakiasis is a gastrointestinal infection caused by the accidental
ingestion in uncooked saltwater fish of nematode larvae belonging to the
family Anisakidae. The incidence of anisakiasis in the United States has
increased as a result of the growing popularity of raw fish dishes. Most
cases occur in Japan, the Netherlands, and Chile, where raw fish—
sashimi, pickled green herring, and ceviche, respectively—are national
culinary staples. Anisakid nematodes parasitize large sea mammals
such as whales, dolphins, and seals. As part of a complex parasitic life
cycle involving marine food chains, infectious larvae migrate to the
musculature of a variety of fish. Both Anisakis simplex and Pseudoterranova decipiens have been implicated in human anisakiasis, but an identical gastric syndrome may be caused by the red larvae of eustrongylid
parasites of fish-eating birds.
When humans consume infected raw fish, live larvae may be
coughed up within 48 h. Alternatively, larvae may immediately
penetrate the mucosa of the stomach. Within hours, violent upper
abdominal pain accompanied by nausea and occasionally vomiting
ensues, mimicking an acute abdomen. The diagnosis can be established by direct visualization on upper endoscopy, outlining of the
worm by contrast radiographic studies, or histopathologic examination of extracted tissue. Extraction of the burrowing larvae during
endoscopy is curative. In addition, larvae may pass to the small bowel,
where they penetrate the mucosa and provoke a vigorous eosinophilic
granulomatous response. Symptoms may appear 1–2 weeks after the
infective meal, with intermittent abdominal pain, diarrhea, nausea,
and fever resembling the manifestations of Crohn’s disease. Ingestion
of Anisakis-derived proteins through consumption of fish meat containing Anisakis parasites can elicit allergic gastrointestinal and even
anaphylactic responses.
The diagnosis may be suggested by barium or other radiographic
upper gastrointestinal studies and confirmed by curative surgical resection of a granuloma in which the worm is embedded. Anisakid eggs
are not found in the stool, since the larvae do not mature in humans.
Serologic tests have been developed but are not widely available.
Anisakid larvae in saltwater fish are killed by cooking to 60°C, freezing at –20°C for 3 days, or commercial blast freezing, but usually not by
salting, marinating, or cold smoking. No medical treatment is available;
surgical or endoscopic removal should be undertaken.
■ CAPILLARIASIS
Intestinal capillariasis is caused by ingestion of raw fish infected with
Capillaria philippinensis. Subsequent autoinfection can lead to a severe
wasting syndrome. The disease occurs in the Philippines and Thailand
and, on occasion, elsewhere in Asia. The natural cycle of C. philippinensis involves fish from fresh and brackish water. When humans eat
infected raw fish, the larvae mature in the intestine into adult worms,
which produce invasive larvae that cause intestinal inflammation
and villus loss. Capillariasis has an insidious onset with nonspecific
abdominal pain and watery diarrhea. If untreated, progressive autoinfection can lead to protein-losing enteropathy, severe malabsorption,
and ultimately death from cachexia, cardiac failure, or superinfection.
The diagnosis is established by identification of the characteristic
peanut-shaped (20- × 40-μm) eggs on stool examination. Severely ill
patients require hospitalization and supportive therapy in addition
to prolonged anthelmintic treatment with albendazole (200 mg twice
daily for 10 days; Chap. 222).
■ ABDOMINAL ANGIOSTRONGYLIASIS
Abdominal angiostrongyliasis is found in Latin America and Africa.
The zoonotic parasite Angiostrongylus costaricensis causes eosinophilic
ileocolitis after the ingestion of contaminated vegetation. A. costaricensis normally parasitizes the cotton rat and other rodents, with slugs and
snails serving as intermediate hosts. Humans become infected by accidentally ingesting infective larvae in mollusk slime deposited on fruits
and vegetables; children are at highest risk. The larvae penetrate the
gut wall and migrate to the mesenteric artery, where they develop into
adult worms. Eggs deposited in the gut wall provoke an intense eosinophilic granulomatous reaction, and adult worms may cause mesenteric
arteritis, thrombosis, or frank bowel infarction. Symptoms may mimic
those of appendicitis, including abdominal pain and tenderness, fever,
vomiting, and a palpable mass in the right iliac fossa. Leukocytosis and
eosinophilia are prominent. CT with contrast medium typically shows
inflamed bowel, often with concomitant obstruction, but a definitive
diagnosis is usually made surgically with partial bowel resection.
Pathologic study reveals a thickened bowel wall with eosinophilic
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