3606 PART 14 Poisoning, Drug Overdose, and Envenomation
(e.g., diphenhydramine, hydroxyzine). If bronchospasm is severe,
an inhaled bronchodilator (e.g., albuterol) can be used. In rare
cases, parenteral epinephrine may be needed. The use of activated
charcoal is not recommended. Protracted nausea and vomiting
may be controlled with antiemetics (e.g., ondansetron, prochlorperazine). Hypotension should be treated with IV fluids. It is
important to inform the patient that the symptoms are related to
eating improperly refrigerated fish and are not due to a fish allergy.
■ CIGUATERA
Epidemiology and Pathogenesis Ciguatera poisoning is the
most common nonbacterial food poisoning associated with fish in the
United States and accounts for approximately half of all cases. Florida
and Hawaii account for 90% of reported U.S. cases, although, with
transportation of imported fish worldwide, all clinicians need to be
aware of ciguatera. The poisoning almost exclusively involves carnivorous, bottom-dwelling reef fish native to the Indian Ocean, the South
Pacific, and the Caribbean Sea. More than 500 different fish species
have been implicated in ciguatera poisoning, but the most common are
barracuda, snapper, moray eel, grouper, sea bass, and Spanish mackerel.
Global estimates of incidence vary widely from 20,000–500,000 cases
per year; it is suspected that a large majority of cases go unreported.
Ciguatoxins are produced primarily by the bottom-dwelling, photosynthetic marine dinoflagellate Gambierdiscus toxicus. These lipophilic
toxins bioaccumulate in the marine food chain when large carnivorous
fish consume the grazing fish that feed on these dinoflagellates. Ciguatoxins are heat stable and unaffected by freezing, drying, cooking, or
gastric acid. The toxins do not affect the odor, taste, or appearance of
the fish, making identification and prevention difficult. Ciguatoxins are
potent activators of neuronal sodium channels but may also have other
effects such as antagonism of voltage-gated potassium channels. Toxins
are found in the highest concentrations in the fish’s skin, head, and
viscera; therefore, consumption of these portions should be avoided.
Clinical Manifestations Symptoms can develop within 15–30
min of ingestion but more commonly in 2–6 h. Most victims develop
symptoms within 12 h of ingestion, and virtually all are afflicted within
24 h. Numerous ciguatoxins have been identified, and their relative
abundance in different species of fish and geographic regions likely
explains the wide array of reported symptoms (Table 460-3). Early
symptoms include nausea, vomiting, diarrhea, abdominal cramps,
headache, and diaphoresis. Neurologic manifestations include vertigo,
dysesthesia, paresthesia, visual disturbance, dysgeusia, and reversal of
hot and cold temperature discrimination. Some victims describe a sensation of loose teeth. Bradycardia, hypotension, and orthostasis have
also been reported. Gastrointestinal symptoms generally resolve after
24−48 h but neurologic manifestations may persist for days to weeks.
More severe reactions tend to occur on repeat exposure. Persons who
have ingested parrotfish (scaritoxin) may develop classic ciguatera
poisoning as well as a “second-phase” syndrome (after a delay of 5–10
days) of disequilibrium with ataxia, dysmetria, and resting or kinetic
tremor. This syndrome may persist for 2–6 weeks.
Diagnosis Ciguatera poisoning is a clinical diagnosis. The toxin can
be detected by liquid chromatography and tandem mass spectrometry,
and fish suspected of contamination can be tested using a ciguatoxinspecific enzyme immunoassay, but these techniques are generally not
available in most health care institutions. The differential diagnosis of
ciguatera includes paralytic shellfish poisoning, eosinophilic meningitis, type E botulism, organophosphate insecticide poisoning, tetrodotoxin poisoning, and psychogenic hyperventilation.
TREATMENT
Ciguatera Poisoning
Therapy is supportive and based on symptoms. Volume losses from
vomiting and diarrhea should be treated with crystalloids and electrolyte repletion. Hypotension may rarely be unresponsive to fluids
and require vasopressors. Symptomatic bradyarrhythmias generally
respond well to atropine (0.5 mg IV, up to 2 mg). Problematic
orthostasis can be treated with direct alpha-adrenergic agonists
(e.g., phenylephrine). IV infusion of mannitol may be beneficial in
moderate or severe cases in fluid-replete patients; however, the efficacy of this therapy has not been definitively proven. An initial IV
dose of mannitol at 1 g/kg may be given over 45–60 min. If symptoms are alleviated, a second dose may be given within 3–4 h and a
third dose the next day. Care must be taken to avoid dehydration.
The mechanism of the drug’s benefit against ciguatera poisoning is
unclear but may be due to decreased sodium conductance across
neuronal cell membranes. Hyperosmotic water-drawing action is
another proposed mechanism but no changes in neuronal cell
edema have been observed in vitro. Amitriptyline (25 mg orally
twice a day) reportedly alleviates pruritus and dysesthesias and
may decrease rates of subsequent development of chronic nerve
symptoms. Gabapentin and pregabalin have shown some efficacy in
the treatment of long-term nerve pain in case reports, but evidence
from controlled trials is lacking.
During recovery from ciguatera poisoning, the victim should
exclude the following from the diet for 6 months: fish (fresh or
preserved), fish sauces, shellfish, shellfish sauces, alcoholic beverages, nuts, and nut oils. Consumption of fish in ciguatera-endemic
regions should be avoided.
■ PARALYTIC SHELLFISH POISONING
Paralytic shellfish poisoning is induced by ingestion of filter-feeding
organisms, including clams, oysters, scallops, mussels, chitons, limpets,
starfish, and sand crabs. The most common agent is saxitoxin, produced by dinoflagellates in the genera Alexandrium, Gonyaulax, and
Pyrodinium. These unicellular phytoplankton form the foundation of
the food chain for many filter-feeding organisms and the toxin accumulates in their tissues. In the United States, paralytic shellfish poisoning is acquired primarily from seafood harvested in the Northeast,
the Pacific Northwest, and Alaska. During algal blooms (“red tides”)
in the summer months, these planktonic species can release massive
amounts of toxic metabolites into the water and cause mortality in bird
and marine populations. The paralytic shellfish toxins are water soluble
as well as heat and acid stable; ordinary cooking or freezing does not
destroy them. Contaminated seafood looks, smells, and tastes normal.
Saxitoxin appears to block sodium conductance, inhibiting neuromuscular transmission at the axonal and muscle membrane levels. A toxin
concentration of >75 μg/100 g of foodstuff is considered hazardous
to humans. During an algal bloom, the concentration of saxitoxin in
shellfish can exceed 9000 μg/100 g. A mouse bioassay that identifies
saxitoxin in suspected shellfish is currently in use. Saxitoxin can be
detected in body fluids by high-performance liquid chromatography,
but this method is generally not available in the clinical setting.
TABLE 460-3 Representative Symptoms and Signs of Ciguatera
Poisoning
SYSTEM SYMPTOMS/SIGNS
Gastrointestinal Abdominal pain, nausea, vomiting, diarrhea
Neurologic Paresthesias, pruritus, tongue and throat numbness or
burning, sensation of “carbonation” during swallowing,
odontalgia or dental dysesthesias, dysphagia, tremor,
fasciculations, athetosis, meningismus, aphonia, ataxia,
vertigo, pain and weakness in the lower extremities,
visual blurring, transient blindness, hyporeflexia,
seizures, coma
Dermatologic Conjunctivitis, maculopapular rash, skin vesiculations,
dermographism
Cardiovascular Bradycardia, heart block, hypotension, central
respiratory failurea
Other Chills, dysuria, dyspnea, dyspareunia, fatigue, nasal
congestion and dryness, insomnia, hypersalivation,
diaphoresis, headache, arthralgias, myalgias
a
Tachycardia and hypertension may occur after potentially severe transient
bradycardia and hypotension. Death is rare.
3607 Disorders Caused by Venomous Snakebites and Marine Animal Exposures CHAPTER 460
Intraoral and perioral paresthesia can occur within minutes to a few
hours after ingestion of contaminated shellfish and can progress rapidly to involve the neck and distal extremities. Other neurologic symptoms can include headache, vertigo, ataxia, diffuse muscle weakness,
hyperreflexia, and cranial neuropathies such as dysarthria, dysphagia,
dysphonia, and transient vision loss. Gastrointestinal symptoms can
include nausea, vomiting, diarrhea, and abdominal pain. Flaccid paralysis and respiratory insufficiency may follow 2–12 h after ingestion. In
the absence of hypoxia, the victim often remains alert but paralyzed.
Up to 12% of patients may die.
TREATMENT
Paralytic Shellfish Poisoning
Treatment is supportive and based on symptoms. If the victim
seeks medical attention within the first few hours after ingestion,
activated charcoal (50–100 g) can be administered in the absence
of vomiting. Gastric lavage and cathartics have been attempted
but there is no evidence of benefit and most authors recommend
against their use.
The most serious concern is respiratory paralysis. The victim
should be closely observed for respiratory distress for at least 24 h in
a hospital. With prompt recognition of respiratory failure and establishment of ventilatory support, anoxic myocardial and brain injury
may be prevented. If the patient survives for 18 h, the prognosis is
good for a complete recovery.
■ AMNESIC SHELLFISH POISONING
Amnesic shellfish poisoning occurs when humans consume shellfish
containing domoic acid. Marine diatoms of the genera Nitzschia and
Pseudonitzchia produce the toxin, which can bioaccumulate in filter
feeders during algal blooms. Clams, mussels, oysters, anchovies, and
Dungeness crabs have all been found to cause amnesic shellfish poisoning. Domoic acid is an excitotoxic amino acid capable of binding to
kainate and AMPA-type glutamate receptors in the central nervous system. Uncontrolled calcium influx into neurons stimulated by domoic
acid binding causes neurodegeneration and apoptosis. The toxin is heat
stable and is not affected by cooking or freezing. Shellfish can be tested
for domoic acid by mouse bioassay and high-performance liquid chromatography (HPLC). The regulatory limit for domoic acid in shellfish
is 20 parts per million. An enzyme-linked immunoassay has been
developed to detect domoic acid in human body fluids but is generally
not available in clinical laboratories.
Most victims will report symptoms within 5 h of ingesting contaminated shellfish but delayed onset of up to 40 h has been reported. Symptoms include nausea, vomiting, diarrhea, abdominal cramps, and a
variety of neurologic manifestations, such as severe headache, memory
loss, seizures, hemiparesis, ophthalmoplegia, grimacing, purposeless
chewing, agitation, emotional lability, and coma. Cardiac dysrhythmias,
hypotension, and pulmonary edema have also been reported. Postmortem examination of brain tissue has shown neuronal necrosis or cell loss
and astrocytosis, most prominently in the hippocampus and amygdala.
Several months after the primary intoxication, victims may still display
chronic residual memory deficits and motor or sensory neuropathy.
TREATMENT
Amnesic Shellfish Poisoning
Therapy is supportive and based on symptoms. IV fluids and antiemetics may be used for severe nausea, vomiting, and diarrhea.
Domoic acid neurotoxicity is primarily seizure mediated; anticonvulsive therapy using GABA agonists (e.g., benzodiazepines,
propofol, or barbiturates) should be instituted early. However, some
patients without clinically evident seizure activity have developed
neurologic sequelae.
■ DIARRHETIC SHELLFISH POISONING
Diarrhetic shellfish poisoning occurs with consumption of shellfish
containing the lipophilic compound okadaic acid. This toxin inhibits
serine and threonine protein phosphatases, with consequent protein
accumulation and continued secretion of fluid by intestinal cells leading to diarrhea. Shellfish acquire these toxins by feeding on dinoflagellates, particularly of the genera Dinophysis and Prorocentrum.
Symptoms include diarrhea, nausea, vomiting, abdominal pain, and
chills. Onset typically occurs between 30 min and 12 h after ingestion
of contaminated shellfish. The illness is usually self-limited; most
patients recover in 3–4 days and only a few require hospitalization.
Treatment is supportive and focused on hydration. Toxins can be
detected in food samples by a mouse bioassay, an immunoassay, and
fluorometric HPLC.
Acknowledgment
Kirsten B. Hornbeak and Robert L. Norris contributed to this chapter in
the prior edition and material from that chapter has been retained here.
We would like to dedicate this chapter to the late Dr. Paul S. Auerbach,
who was a contributing author for the previous seven editions of Harrison’s
Principles of Internal Medicine. Dr. Auerbach had a tremendous impact
on the field of emergency medicine and founded the subspecialty of wilderness medicine. Dr. Auerbach was a wonderful teacher, mentor, and
friend, and will be deeply missed.
■ FURTHER READING
Blohm E et al: Marine envenomations, in Goldfrank’s Toxicologic
Emergencies, 11th ed. LS Nelson et al (eds). New York, McGraw-Hill
Education, 2019, pp 1567-1580.
Bush SP et al: Comparison of F(ab’)2 versus Fab antivenom for pit
viper envenomation: A prospective, blinded, multicenter, randomized clinical trial. Clin Toxicol 53:37, 2015.
Cannon R et al: Acute hypersensitivity reactions associated with
administration of crotalidae polyvalent immune Fab antivenom. Ann
Emerg Med 51:407, 2008.
Fil LJ et al: Food Poisoning, in Goldfrank’s Toxicologic Emergencies,
11th ed. LS Nelson et al (eds). New York, McGraw-Hill Education,
2019, pp 592-605.
French LK et al: Marine vertebrates, cnidarians, and mollusks, in
Critical Care Toxicology: diagnosis and management of the critically
poisoned patient, 2nd ed. J Brent et al (eds). New York, Springer, 2017,
pp 2045-2074.
Green S: Ciguatera, in Critical Care Toxicology: Diagnosis and Management of the Critically Poisoned Patient, 2nd ed. J Brent et al (eds). New
York, Springer, 2017, pp 2033-2043.
Hornbeak KB, Auerbach PS: Marine envenomation. Emerg Med
Clin North Am 35:321, 2017.
Kang AM, Fisher ES: Thromboelastography with platelet studies
(TEG® with PlateletMapping®) after rattlesnake envenomation in
the southwestern United States demonstrates inhibition of ADPinduced platelet activation as well as clot lysis. J Med Toxicol 16:24,
2020.
Lavonas EJ et al: Unified treatment algorithm for the management
of crotaline snakebite in the United States: results of an evidenceinformed consensus workshop. BMC Emerg Med 11:2, 2011.
Longbottom J et al: Vulnerability to snakebite envenoming: A global
mapping of hotspots. Lancet 392:673, 2018.
Ruha A et al: Native (US) venomous snakes and lizards, in Goldfrank’s
Toxicologic Emergencies, 11th ed. LS Nelson et al (eds). New York,
McGraw-Hill Education, 2019, pp 1617-1626.
Suguitan MA et al: Scombroid, in Critical Care Toxicology: Diagnosis
and Management of the Critically Poisoned Patient, 2nd ed. J Brent
et al (eds). New York, Springer, 2017, pp 2075-2083.
World Health Organization: Snakebite envenoming−A strategy for prevention and control. Available from https://www.who.
int/snakebites/resources/9789241515641/en/. Accessed May 11,
2020.
3608 PART 14 Poisoning, Drug Overdose, and Envenomation
Ectoparasites include arthropods and creatures from other phyla that
infest the skin or hair of animals; the host animals provide them with
sustenance and shelter. The ectoparasites may remain superficially on
the skin or hair, attached by mouthparts and specialized claws. Other
ectoparasites may penetrate the skin and reside in the epidermis, dermis, or subcutis. Ectoparasites may inflict direct mechanical injury, consume blood or nutrients, induce hypersensitivity reactions, inoculate
toxins, transmit pathogens, create openings in the skin for secondary
bacterial infection, and incite fear or disgust. Human beings are the sole
or obligate hosts for only a few kinds of ectoparasites but serve as facultative, dead-end, or paratenic (accidental) hosts for many others. Of
the organisms discussed in this chapter, only scabies mites (the hominis
variety) and human-infesting lice are obligate parasites of humans.
Arthropods that are capable of ectoparasitism or that can otherwise
cause injury include insects (such as lice, fleas, bed bugs, wasps, ants,
bees, and diverse kinds of flies), arachnids (spiders, scorpions, mites,
and ticks), and myriapods (millipedes and centipedes). Several arthropods can cause uncomfortable reactions when they or their setae and
exudates contact skin, mucous membranes, and ocular tissues.
Certain nematodes (helminths), such as the hookworms (Chap. 231),
are ectoparasitic in that they penetrate and migrate through the skin.
Infrequently encountered ectoparasites in other phyla include the pentastomes (armillifers or tongue worms) and leeches.
Arthropods may cause injury when they attempt to take a blood meal
or as they defend themselves by biting, stinging, or exuding venoms.
Papular urticaria and other lesions caused by arthropod bites and stings
are so diverse and variable (depending upon the host’s health status and
prior exposure to the arthropod’s saliva, venom, or other exudates) that
it is difficult to identify the precise causative organism without a bona
fide specimen and taxonomic expertise. Specimens of the presumably
offending arthropod should, whenever possible, be sampled (ideally by
medical personnel) directly (when taken from the patient) or indirectly
by the use of traps or other monitoring devices in the patient’s home
or workplace. Samples sent to laboratorians for evaluation should be
properly fixed, preserved, and packaged. Information on the patient’s
travel history, occupation and avocation, and exposure to animals—pets
and pests—often helps the clinician and parasitologist resolve the cause.
■ SCABIES
The human itch mite, Sarcoptes scabiei var. hominis, is an obligate
human ectoparasite and a common cause of itchy dermatosis, affecting
~250 million persons worldwide. Gravid female mites (~0.3 mm in
length) burrow superficially within the stratum corneum, depositing
several eggs per day. Six-legged larvae mature to eight-legged nymphs
and then to adults. Gravid adult females emerge to the surface of the
skin about 8 days later and then (re)invade the skin of the same or
another host. Newly fertilized female mites are transferred from person
to person mainly by direct skin-to-skin contact; transfer is facilitated
by crowding, poor hygiene, and close physical contact with other
persons. Generally, scabies mites die within a day or so in the absence
of a suitable host. Transmission via sharing of contaminated bedding or
clothing occurs less frequently than is often thought. In the United States,
scabies may account for up to 5% of visits to dermatologists. Outbreaks
are known to occur in preschools, hospitals, nursing homes, prisons,
and other institutional residences.
The itching and rash associated with scabies derive from a sensitization reaction to mites and their secretions/excretions. A person’s
initial infestation typically remains asymptomatic for up to 6 weeks
before the onset of intense pruritus, but a reinfestation produces a
hypersensitivity reaction without delay. Burrows become surrounded
by inflammatory infiltrates composed of eosinophils, lymphocytes, and
461 Ectoparasite Infestations
and Arthropod Injuries
Richard J. Pollack, Scott A. Norton
histiocytes. Infested individuals often feel generalized pruritus, not just
in the most heavily involved areas. Hyperinfestation with thousands of
mites, a condition known as crusted scabies (formerly termed Norwegian scabies), may result from glucocorticoid use, immunodeficiency
(including that due to HIV/AIDS), and neurologic or psychiatric illnesses that limit the itch and/or the scratch response.
Pruritus typically intensifies at night and after hot showers. Classic
burrows are often difficult to find because they are few in number and
may be obscured by excoriations. Burrows appear as dark wavy lines
in the upper epidermis and are 3–15 mm long. Scabietic lesions are
most common on the volar wrists and along the digital web spaces.
In males, the penis and scrotum almost invariably become involved.
Small papules and vesicles, often accompanied by eczematous plaques,
pustules, or nodules, appear symmetrically at those sites and within
intertriginous areas, around the navel and belt line, in the axillae, and
on the buttocks and upper thighs. Except in infants, the face, scalp,
neck, palms, and soles are usually spared. Crusted scabies often resembles psoriasis: both are characterized by widespread thick keratotic
crusts, scaly plaques, and dystrophic nails. Characteristic burrows are
not seen in crusted scabies, and patients usually do not itch, although
their infestations are highly contagious and have been responsible for
outbreaks of common scabies in hospitals.
Scabies should be considered in patients with pruritus and symmetric superficial, excoriated, papulovesicular skin lesions in characteristic locations, particularly if there is a history of direct and
prolonged contact with an infested person. Burrows should be sought
and unroofed with a sterile needle or scalpel blade, and the scrapings
should be examined microscopically for mites, eggs, and fecal pellets.
Examination of biopsied skin samples (including those obtained by
superficial cyanoacrylate biopsy) or scrapings, dermatoscopic imaging
of papulovesicular lesions, and microscopic inspection of clear cellophane tape lifted from lesions also may be diagnostic. In the absence
of identifiable mites or eggs, a clinical diagnosis is based on a history
of pruritus, a physical examination, and an epidemiologic link. Unrelated skin diseases are frequently misdiagnosed as scabies, particularly
in presumed “outbreak” situations. Sarcoptes mites of other mammals
may cause transient irritation, but they do not reside or reproduce in
human hosts. In some aboriginal communities, household dogs may
serve as reservoirs for human scabies mites.
TREATMENT
Scabies
The four scabicides approved by the U.S. Food and Drug Administration (FDA)—permethrin, crotamiton, spinosad, and lindane—
are topical and available solely by prescription. Permethrin cream
(5%) is less toxic than 1% lindane preparations and is effective
against lindane-resistant infestations. Scabicides are applied thinly
but thoroughly from the jawline down after bathing, with careful
application to interdigital spaces, the navel, and under the nails,
and are removed 6–14 h later with soap and water. Treatment of
crusted scabies is difficult and may require preapplication of a keratolytic agent such as 6% salicylic acid and then of scabicides to the
skin’s entire surface, including the scalp, face, and ears. Repeated
treatments or the sequential use of several agents may be necessary.
Ivermectin, which is approved by the FDA for the treatment of two
nematodal diseases, has not been approved for the treatment of scabies; however, a single oral dose (200 μg/kg) is effective in otherwise
healthy persons. Patients with crusted scabies require three to seven
doses of ivermectin over 8–30 days, along with topical permethrin
and possibly a keratolytic compound.
Within 1 day of effective treatment, scabies infestations become
noncommunicable, but the pruritic hypersensitivity dermatitis
induced by dead mites and their detritus frequently persists for
weeks. Unnecessary retreatment with topical agents may provoke
contact dermatitis, especially from repeated applications of permethrin cream. Topical emollients, menthol and methyl salicylate
products, calamine lotion, and oral antihistamines relieve itching
3609Ectoparasite Infestations and Arthropod Injuries CHAPTER 461
during treatment. Topical glucocorticoids may calm pruritus that
lingers after effective treatment. To prevent reinfestations, bedding
and clothing should be washed and dried on high heat or heatpressed, and other environmental surfaces or fomites should be
cleaned. Close contacts of confirmed cases, even if asymptomatic,
should be treated simultaneously.
Scabies infestations often lead to secondary bacterial infections,
usually with Staphylococcus aureus or Streptococcus pyogenes (or
both). Consequences of these superinfections include impetigo,
cellulitis, invasive bacterial infections, poststreptococcal glomerulonephritis, and possibly acute rheumatic fever.
■ CHIGGERS AND OTHER BITING MITES
Chiggers are the larvae of trombiculid (harvest) mites that normally
feed on mice and other small vertebrates in grassy or brush-covered
sites in tropical, subtropical, and (less frequently) temperate areas
during warm months. They reside on low vegetation and attach themselves to passing vertebrate hosts. While feeding, larvae secrete saliva
with proteolytic enzymes to create a tube-like invagination in the host’s
skin; this stylostome allows the mite to imbibe tissue fluids. The saliva
is highly antigenic and causes small (usually <1 cm in diameter) but
exceptionally pruritic papular, urticarial, or pustulovesicular lesions. In
persons previously sensitized to salivary antigens, the papules develop
within hours of attachment. While attached, mites appear as minute
(~0.5-mm diameter) red dots on the skin. Generally, lesions have a
hemorrhagic base and are slightly elevated, resembling vasculitic papules. Scratching invariably destroys the body of a mite, but itching and
burning often persist for weeks. The rash is common on the ankles and
in areas where circumferentially tight clothing obstructs the further
wanderings of the mites. Repellents are useful for preventing chigger
bites. Chiggers (Leptotrombidium species) serve as vectors for Orientia
tsutsugamushi, the agent of scrub typhus in the eastern half of Asia
and the Indomalayan and Australasian regions. Endemic foci of scrub
typhus were recently identified in southern Chile and in East Africa, far
outside the traditional endemic region.
Many kinds of mites associated with peridomestic birds and rodents
are particularly bothersome when they invade homes and bite people.
In North America, the northern fowl mite, chicken mite, tropical rat
mite, and house mouse mite normally feed on poultry, other birds,
and small mammals. After their natural hosts leave the nest or die, the
mites disperse and may invade homes. Although the mites are rarely
seen because of their small size, their bites can be painful and pruritic.
House mouse mites (Liponyssoides sanguineus) serve as vectors for the
agent of rickettsialpox, Rickettsia akari, an uncommon disease characterized by mild fevers, an eschar at the bite site, and a papulovesicular
eruption. Rickettsialpox (Chap. 187) has been recognized mainly in
large northern temperate cities. Once confirmed as the cause of a skin
disorder, rodent- and bird-associated mites are best eliminated by
exclusion of their animal hosts, removal of the nests, and cleaning and
treatment of the nesting area with appropriate acaricides.
Pyemotes and other mites that infest grain, straw, cheese, hay, oak
leaf galls, or other products occasionally produce similar episodes of
rash and discomfort and may produce a unique dermatologic “comet
sign” lesion—a paisley-shaped urticarial plaque (Fig. 461-1).
Diagnosis of mite-induced dermatitides (including those caused by
chiggers) relies on confirmation of the mite’s identity or elicitation of a
history of exposure to the mite’s source. Because the mites do not reside
on humans, treatment of the patient with acaricides (e.g., permethrin)
is discouraged. Oral antihistamines or topical steroids may reduce
mite-induced pruritus temporarily.
The mites that cause house dust–related allergic conditions neither
bite nor infest humans.
■ TICK BITES AND TICK PARALYSIS
Ticks attach superficially to skin and usually feed painlessly; blood
is their only food. Their salivary secretions are biologically active
(intended to prevent blood coagulation while the tick feeds) and can
produce local reactions, induce fevers, and cause paralysis in addition
to transmitting diverse pathogens. The two main families of ticks are
the hard (ixodid) ticks and soft (argasid) ticks. Because no ticks are
obligate parasites on humans, all tick-borne diseases (bacterial, viral,
and protozoal) are zoonoses.
Generally, soft ticks feed quickly, attaching for <1 h, and then drop
off. Because of this rapid feeding behavior, the ticks are not carried
widely by animal or bird hosts. Soft tick–associated infections usually
have fairly focal distributions. When a soft tick finishes the blood meal
on a human and drops off, red macules may develop at the bite site.
Some species in Africa, the western United States, and Mexico produce
painful hemorrhagic lesions.
Hard ticks are much more common than are soft ticks, and
they transmit most of the tick-borne infections that are familiar to
physicians and patients. Hard ticks attach to the host and feed for
several days to >1 week, with the exact duration depending upon
the tick’s species and stage of development. At the site of hard-tick
bites, small areas of induration, often purpuric, develop and may be
surrounded by an erythematous rim. A necrotic eschar, called a tâche
noire (“black spot”), occasionally develops. Chronic nodules (persistent tick-bite granulomas) can be several centimeters in diameter
and may linger for months after the feeding tick has been removed.
These granulomas can be treated with injected intralesional glucocorticoids or by simple local excision. Tick-induced fever, unassociated with transmission of any pathogen, is often accompanied by
headache, nausea, and malaise but usually resolves ≤36 h after the
tick is removed. Salivary antigens of certain ticks, particularly the
Lone Star tick, Amblyomma americanum, may induce antibodies to
galactose-α-1,3-galactose (alpha-gal) that result in mammalian meat
allergy–alpha-gal syndrome.
Tick paralysis, an acute ascending flaccid paralysis that resembles
Guillain-Barré syndrome, is believed to be caused by one or more toxins in tick saliva that block neuromuscular transmission and decrease
nerve conduction. This rare complication has followed the bites of >60
species of ticks. It is reported worldwide, but most cases arise in the
Rocky Mountain region, in the northwestern United States and southeastern Canada, and on the east coast of Australia. In North America, dog
and wood ticks (Dermacentor species) are most commonly involved.
Weakness begins symmetrically in the lower extremities ≤6 days after
the tick’s attachment, ascends symmetrically during several days, and
may culminate in complete paralysis of the extremities and cranial
nerves. Deep tendon reflexes are diminished or absent, but sensory
examination and findings on lumbar puncture are typically normal.
Diagnosis depends on finding the tick, which is often hidden beneath
scalp hair. Removal of the tick generally leads to improvement within
a few hours and complete recovery after several days, although the
patient’s condition may continue to deteriorate for a full day. Failure
to remove the tick may lead to dysarthria, dysphagia, and ultimately
death from aspiration or respiratory paralysis. An antiserum to the
saliva of Ixodes holocyclus, the usual cause of tick paralysis in Australia,
effectively reverses paralysis caused by these ticks.
Removal of hard ticks during the first 36 h of attachment generally prevents transmission of the agents of Lyme disease, babesiosis,
anaplasmosis, and ehrlichiosis, although tick-borne viruses may be
transmitted more quickly. Ticks should be removed by traction with
fine-tipped forceps placed firmly around the tick’s mouthparts where
they enter the skin. Careful handling (to avoid rupture of ticks) and
use of gloves may avert accidental contamination with pathogens
contained in tick fluids. Use of occlusive dressings, heat, or various
substances (in an attempt to induce the tick to detach) merely delays
tick removal. Afterward, the site of attachment should be disinfected.
Tick mouthparts sometimes remain in the skin but generally are shed
spontaneously within days without the need for surgical removal. Current guidelines from the Centers for Disease Control and Prevention
suggest that, rather than awaiting the onset of erythema migrans, the
results of tick testing, or seroconversion to antigens diagnostic for
Lyme disease, physicians may appropriately administer prophylaxis—a
single oral dose of doxycycline (200 mg) within 72 h of tick removal—
to adult patients with bites thought to be associated with Ixodes scapularis
(deer ticks) in Lyme disease–endemic areas. Whereas prophylactic
3610 PART 14 Poisoning, Drug Overdose, and Envenomation
antibiotic treatment may have value in preventing Lyme disease, it is
not recommended as a means to prevent other tick-borne infections.
The Asian longhorned tick (Haemaphysalis longicornis) is a newly
invasive species in the United States, first detected in the northeastern
states in 2017. Although it carries several pathogens to domestic animals, wildlife, and humans in its natural range (northeastern Asia), it
has not yet been implicated in disease transmission in the United States.
■ LOUSE INFESTATION (PEDICULIASIS AND PTHIRIASIS)
Three kinds of biting lice are obligate blood-feeding ectoparasites
of human beings. These include the human head and body lice that
represent distinct genetic clades of Pediculus humanus, and the pubic
(“crab”) lice (Pthirus pubis). Nymphs and adults of these lice feed at
least once a day, ingesting human blood exclusively, and they partition
ecologically on the host. Head lice infest mainly the hair of the scalp,
body lice the clothing, and pubic lice mainly the hair of the pubis. The
saliva of lice produces a pruritic morbilliform or urticarial rash in some
sensitized persons. Female head and pubic lice cement their eggs (nits)
firmly to hair, whereas female body lice cement their eggs to clothing,
particularly to threads along clothing seams. After ~10 days of development within the egg, a nymph emerges. Empty eggs may remain affixed
for months or years thereafter.
Body lice are acquired by direct contact with an infested person
or that individual’s recently used clothing or bedding. These lice
venture for just minutes to the skin to feed, but otherwise sequester on
clothing. They generally succumb in ≤2 days if separated from their
host. Body lice tend to be limited to a small proportion of indigent
persons or others who have relevant exposure and lack the wherewithal or desire to change or appropriately launder their clothing
and bedding. Body lice, as well as the pathogens they transmit, may
become increasingly prevalent after societal upheaval and disasters.
These lice are vectors for the agents of louse-borne (epidemic) typhus
(Chap. 187), louse-borne relapsing fever (Chap. 185), and trench
fever (Chap. 172). Chronic infestations result in a postinflammatory
hyperpigmentation and thickening of the skin known as vagabond’s
disease.
Head lice are acquired mainly by direct head-to-head contact rather
than via fomites such as shared headgear, bed linens, and grooming
implements. The prevalence of head lice varies widely as a function of
age, geography, and cultural habits. In North America, the prevalence
is greatest (~1%) among 6- to 10-year-old children and is considerably
lower among persons of other ages. Infestations can be far more prevalent elsewhere. Generally, an infested person hosts 10 or fewer head
lice. Chronically infested persons tend to be asymptomatic, and some
may host >100 lice. Pruritus, due mainly to hypersensitivity to the
louse’s saliva, usually is transient and mild and is most evident around
the posterior hairline. Head lice removed from a person succumb to
desiccation and starvation within ~1 day. Head lice are generally considered unimportant as natural vectors for any pathogens.
FIGURE 461-1 Comet signs in individuals with known or suspected mite-bite reactions, likely due to Pyemotes species. Note central punctum at bite site, surrounded by
edematous erythema. Linear or serpiginous “comet tails” emanate from the central site. Pyemotes-induced comet tails generally do not follow typical patterns of ascending
lymphatic drainage.
3611Ectoparasite Infestations and Arthropod Injuries CHAPTER 461
The crab or pubic louse is transmitted mainly by sexual contact.
These lice occur predominantly on pubic hair and less frequently on
axillary or facial hair, including the eyelashes. Children and adults
may acquire pubic lice by sexual or close nonsexual contact. Intensely
pruritic, bluish macules ~3 mm in diameter (maculae ceruleae) develop
at the site of bites. Blepharitis commonly accompanies infestations of
the eyelashes.
Pediculiasis is often suspected upon the detection of presumed nits
firmly cemented to hairs or in clothing or on the basis of pruritus.
Often, objects presumed to be louse eggs are, instead, pseudo-nits
composed of debris and hair-associated fungi. Hatched and dead
eggs remain firmly affixed to scalp hair for months. Such relicts are
frequently misconstrued to be signs of an active louse infestation.
Confirmation of a louse infestation, therefore, should rely on the discovery of a live louse.
TREATMENT
Louse Infestation
Body lice usually are eliminated by bathing and by changing to
laundered clothes. Application of topical pediculicides from head to
foot may be necessary for hirsute patients. Clothes and bedding are
effectively deloused by heating in a clothes dryer at ≥55°C (≥131°F)
for 30 min or by heat-pressing. Emergency mass delousing of persons and clothing may be warranted during periods of civil strife
and after natural disasters to reduce the risk of pathogen transmission by body lice.
Head lice and their eggs may be removed with a fine-toothed
louse or nit comb, but this effort can be difficult and timeconsuming and often fails to eradicate the lice. Treatment of newly
identified, active infestations traditionally relies on a 10-min topical application of ~1% permethrin or pyrethrins, with a second
application ~10 days later. Lice persisting after this treatment may
be resistant to pyrethroids. Chronic infestations may be treated for
≤12 h with 0.5% malathion. Lindane is applied for just 4 min but
seems less effective and may pose a greater risk of adverse reactions,
particularly when misused. Resistance of head lice to permethrin,
malathion, and lindane is well documented. Newer FDA-approved
topical pediculicides contain benzyl alcohol, dimethicone, spinosad,
and ivermectin. Although children infested by head lice—or those
who simply have remnant nits from a prior infestation—are frequently isolated or excluded from school, this practice increasingly
is considered to be unjustified, ineffective, and counterproductive.
Pubic louse infestations are treated with topical pediculicides,
except for eyelid infestations (pthiriasis palpebrum), which generally respond to a coating of petrolatum applied for 3–4 days.
■ MYIASIS (FLY INFESTATION)
Myiasis refers to infestations by fly larvae (maggots) that invade living
or necrotic tissues or body cavities and produce different clinical syndromes, depending on the species of fly.
In forested parts of Central and South America, larvae of the human
botfly (Dermatobia hominis) produce furuncular (boil-like) dermal
and subcutaneous nodules ≤3 cm in diameter. A gravid adult female
botfly captures a mosquito or another bloodsucking insect and deposits her eggs on its abdomen. When the carrier insect attacks a human or
another mammalian host (often cattle) several days later, the warmth
and moisture of the host’s skin stimulate the eggs to hatch. The emerging larvae, ~1 mm long, promptly penetrate intact skin. After 6–12 weeks
of development, mature larvae emerge from the skin and drop to the
ground to pupate and then become adults.
The African tumbu fly (Cordylobia anthropophaga) deposits its
eggs on damp sand, leaf litter, or drying laundry, particularly items
contaminated by urine or sweat. Larvae hatch from eggs upon contact
with a host’s body and penetrate the skin, producing boil-like lesions
from which mature larvae emerge ~9–10 days later. Furuncular myiasis
is suggested by uncomfortable lesions with a central breathing pore
that emit bubbles when submerged in water. A sensation of movement
under the patient’s skin may cause severe emotional distress.
Larvae that cause furuncular myiasis may be induced to emerge if
the air pore is coated with petrolatum or another occlusive substance.
Removal may be facilitated by injection of a local anesthetic (or sterile
injectable saline) into the subjacent tissue to uplift the larva through
the breathing pore. Surgical excision is sometimes necessary because
upward-pointing spines of some species hold the larvae firmly in place.
Other fly larvae cause nonfuruncular myiasis. Larvae of the horse
botfly (Gasterophilus intestinalis) emerge from eggs, usually deposited on the hairs of a horse’s front legs. Direct contact with a person’s
bare hands or legs may result in the larvae’s hatching from the eggs
and invading skin. After penetrating human skin, these larvae rarely
mature but instead may migrate for weeks in the dermis. The resulting
pruritic and serpiginous eruption resembles cutaneous larva migrans
caused by canine or feline hookworms (Chap. 231). Larvae of rabbit
and rodent botflies (Cuterebra species) occasionally cause cutaneous
or tracheopulmonary myiasis.
Certain flies are attracted to blood and pus, laying their eggs on
open or draining sores. Newly hatched larvae enter wounds or diseased
skin. Larvae of several types of green bottle flies (Lucilia species) usually remain superficial and confined to necrotic tissue. Specially raised,
sterile “surgical maggots” are sometimes used deliberately for wound
debridement. Larvae of screwworm flies (Cochliomyia) and flesh flies
(Wohlfahrtia species) invade viable tissues more deeply and produce
large suppurating lesions. Larvae that infest wounds also may enter
body cavities such as the mouth, nose, ears, sinuses, anus, vagina, and
lower urinary tract, particularly in unconscious or otherwise debilitated patients. The consequences range from harmless colonization to
destruction of the nose, meningitis, and deafness. Treatment involves
removal of maggots and debridement of tissue.
Larvae of the sheep botfly, Oestrus ovis, and other flies responsible
for furuncular and wound myiasis also may cause ophthalmomyiasis. Sequelae include nodules in the eyelid, retinal detachment, and
destruction of the globe. Most instances in which maggots are found in
human feces result from deposition of eggs or larvae by flies on recently
passed stools, not from an intestinal maggot infestation.
■ PENTASTOMIASIS
Pentastomids (tongue worms), an obscure type of crustacean, inhabit
the respiratory passages of reptiles and carnivorous mammals. Human
infestation by Linguatula serrata is common in the Middle East and
results from the consumption of encysted larval stages in raw liver or
lymph nodes of sheep and goats, which are true intermediate hosts for
the tongue worms. In areas where raw sheep and goat liver are served,
larvae migrate to the nasopharynx and produce an acute self-limiting
syndrome—known as halzoun in Lebanon and marrara in Sudan—
characterized by rapid onset (within <12 h) of pain and itching of the
throat and ears, coughing, hoarseness, dysphagia, and dyspnea. Severe
edema may cause obstruction that requires tracheostomy. In addition,
ocular invasion has been described. Diagnostic larvae measuring ≤10 mm
in length appear in copious nasal discharge or vomitus.
Another type of tongue worm, Armillifer armillatus, infects people
who consume its eggs in contaminated food or drink or after handling
the definitive host, the African python. Larvae encyst in various organs,
usually the liver or peritoneum, but rarely cause symptoms. Cysts
may require surgical removal as they enlarge during worm molting,
but they usually are encountered as an incidental finding at autopsy.
Parasite-induced lesions may be misinterpreted as a malignancy, with
the correct diagnosis confirmed histopathologically. Cutaneous larva
migrans–type syndromes of other pentastomes have been reported
from Southeast Asia and Central America.
■ LEECH INFESTATIONS
Medically important leeches are annelid worms that attach to their
hosts with chitinous cutting jaws and draw blood through muscular
suckers. Medicinal leeches (Europe: Hirudo medicinalis and other
Hirudo species; Asia: Hirudinaria manillensis; North America: Macrobdella
3612 PART 14 Poisoning, Drug Overdose, and Envenomation
decora) are still used occasionally for medical purposes to reduce
venous congestion in surgical flaps or replanted body parts. This practice has been complicated by intractable bleeding, wound infections,
myonecrosis, and sepsis due to Aeromonas hydrophila, which colonizes
the gullets of commercially available leeches.
Ubiquitous aquatic leeches that parasitize fish, frogs, and turtles
readily attach to human skin—most often the nasal mucosa—and
avidly suck blood. Attachment is usually painless, and the leeches will
detach themselves when satiated with a blood meal. Hirudin, a powerful anticoagulant secreted by the leech, causes continued bleeding
after the leech has detached. Healing of a leech-bite wound is slow,
and secondary bacterial infections are not uncommon. Several kinds
of aquatic leeches in Africa, Asia, and southern Europe can enter the
mouth, nose, and genitourinary tract and attach to mucosal surfaces
at sites as deep as the esophagus and trachea. Leeches may detach on
exposure to gargled saline or may be removed by forceps or medical
suction.
Arboreal land leeches, which live amid rain forest vegetation, are
attracted by heat and can drop from a leaf onto one’s skin. Externally
attached leeches generally drop off after they have engorged, but
removal is hastened by gentle scraping aside of the anterior and posterior suckers the leech uses for attachment and feeding. Some authorities dispute the wisdom of removing leeches with alcohol, salt, vinegar,
insect repellent, a flame or heated instrument, or applications of other
noxious substances.
■ SPIDER BITES
Of the >30,000 recognized species of spiders, only ~100 defend themselves aggressively and have fangs sufficiently long to penetrate human
skin. The venom that some spiders use to immobilize and digest their
prey can cause necrosis of the skin and systemic toxicity. Whereas the
bites of most spiders may be painful but not harmful, envenomations
by recluse or fiddleback spiders (Loxosceles species) and widow spiders
(Latrodectus species) may be life-threatening. Identification of the
offending spider is important because specific treatments exist for bites
of widow spiders. Except when the patient actually observes a spider
immediately associated with the bite or fleeing from the site, painful
noduloulcerative and other lesions reported as spider-bite reactions are
most often due to other injuries or to infections with bacteria, particularly methicillin-resistant S. aureus (MRSA).
Recluse Spider Bites and Necrotic Arachnidism Brown
recluse spiders (Loxosceles reclusa) live mainly in the southcentral
United States and have close relatives in Central and South America,
Africa, the Mediterranean basin, and the Middle East. Recluse spiders are not aggressive toward humans and bite only if threatened or
pressed against the skin. They generally dwell beneath rocks and logs
or in caves and animal burrows. They invade homes and seek dark and
undisturbed hiding spots in closets, garages, crawl spaces, and attics;
under furniture and rubbish in storage rooms; and in folds of clothing. Despite their impressive abundance in some homes, these spiders
rarely bite humans. Bites tend to occur while the victim is donning
clothing in which the spider has hidden itself and are sustained primarily on the hands, arms, neck, and lower abdomen.
Whereas a bite by a brown recluse spider may cause minor injury
with edema and erythema, envenomation can cause severe necrosis
of skin and subcutaneous tissue and, more rarely, systemic hemolysis. Initially, the bite is painless or may produce a stinging sensation.
Within a few hours, the site becomes painful and pruritic, with central
induration surrounded by a pale ischemic zone that itself is encircled
by a zone of erythema. In most cases, the lesion resolves without
treatment in just a few days. In severe cases, the erythema spreads,
and the center of the lesion becomes hemorrhagic or necrotic with an
overlying bulla. A black eschar forms and sloughs several weeks later,
leaving an ulcer that eventually may create a depressed scar. Healing
usually takes place in ≤3 months. Local complications include injury
to nerves and secondary bacterial infection. Fever, chills, weakness,
headache, nausea, vomiting, myalgia, arthralgia, morbilliform eruption, and leukocytosis may develop ≤72 h after the bite. Reports of
deaths attributed to bites of North American brown recluse spiders
have not been verified.
The Mediterranean recluse spider (Loxosceles rufescens) is a widely
invasive species in urban areas of both the Old and New Worlds. The
dorsal surfaces of L. rufescens and L. reclusa are adorned with a
fiddle-shaped pattern. L. rufescens is warier than L. reclusa, is less likely
to bite, and rarely causes necrosis. Misidentification of this spider may
create spurious reports of L. reclusa activity outside the known range
of that species.
TREATMENT
Recluse Spider Bites
Initial management includes rest, ice, compression, and elevation
(RICE). Analgesics, antihistamines, antibiotics, and tetanus prophylaxis should be administered if indicated. Early debridement
or surgical excision of the wound without closure delays healing.
Routine use of antibiotics or dapsone lacks utility. Patients should
be monitored closely for signs of hemolysis, renal failure, and other
systemic complications.
Widow Spider Bites The black widow spider, common in the
southeastern United States, measures ≤1 cm in body length and 5 cm
in leg span and is shiny black with a red hourglass marking on the ventral abdomen. Other dangerous Latrodectus species occur elsewhere in
temperate and subtropical parts of the world. The bites of the female
widow spiders are notorious for their potent neurotoxins.
Widow spiders spin their webs under stones, logs, plants, or rock
piles and in dark spaces in barns, garages, and outhouses. Bites are
most common in the summer and early autumn and occur when a web
is disturbed or a spider is trapped or provoked. The initial bite is perceived as a sharp pinprick or may go unnoticed. Fang-puncture marks
are uncommon. The venom that is injected does not produce local
necrosis, and some persons experience no other symptoms.
α-Latrotoxin, the most active component of the venom, binds irreversibly to presynaptic nerve terminals and causes release and eventual
depletion of acetylcholine, norepinephrine, and other neurotransmitters from those terminals. Painful cramps may spread within 60 min
from the bite site to large muscles of the extremities and trunk. Extreme
rigidity of the abdominal muscles and excruciating pain may suggest
peritonitis, but the abdomen is not tender on palpation and surgery is
not warranted. The pain begins to subside during the first 12 h but may
recur during several days or weeks before resolving spontaneously. A
wide range of other sequelae may include salivation, diaphoresis, vomiting, hypertension, tachycardia, labored breathing, anxiety, headache,
weakness, fasciculations, paresthesia, hyperreflexia, urinary retention,
uterine contractions, and premature labor. Rhabdomyolysis and renal
failure have been reported, and respiratory arrest, cerebral hemorrhage,
or cardiac failure may end fatally, especially in very young, elderly, or
debilitated persons.
TREATMENT
Widow Spider Bites
Treatment consists of RICE and tetanus prophylaxis. Hypertension
that does not respond to analgesics and antispasmodics (e.g., benzodiazepines or methocarbamol) requires specific antihypertensive
medication. The efficacy and safety of antivenin (i.e., antivenom)
made from equine immunoglobulins are controversial for bites of
the black widow and the closely related Australian redback spider
because of concerns about potential anaphylaxis or serum sickness.
Antivenins made from monoclonal antibodies are in development.
Tarantulas and Other Spiders Tarantulas are large hairy spiders
of which 30 species are found in the United States, mainly in the Southwest.
Several species of tarantulas that have become popular household pets
are usually imported from Central or South America. Tarantulas bite
persons only when threatened and usually cause no more harm than a
3613Ectoparasite Infestations and Arthropod Injuries CHAPTER 461
bee sting, but on occasion, the venom causes deep pain and swelling.
Several species of tarantulas are covered with urticating hairs that are
brushed off in the thousands when a threatened spider rubs its hind
legs across its dorsal abdomen. These hairs can penetrate human skin
and produce pruritic papules that may persist for weeks. Failure to wear
gloves or to wash the hands after handling the Chilean Rose tarantula, a
popular pet spider, has resulted in transfer of hairs to the eye with subsequent devastating ocular inflammation. Treatment of bites includes
local washing and elevation of the bitten area, tetanus prophylaxis, and
analgesic administration. Antihistamines and topical or systemic glucocorticoids are given for exposure to urticating hairs.
Atrax robustus, a funnel-web spider of Australia, and Phoneutria
species, the South American banana spiders, are among the most
dangerous spiders in the world because of their aggressive behavior
and potent neurotoxins. Envenomation by A. robustus causes a rapidly
progressive neuromotor syndrome that can be fatal within 2 h. The bite
of a banana spider causes severe local pain followed by profound systemic symptoms and respiratory paralysis that can lead to death within
2–6 h. Specific antivenins for use after bites by each of these spiders are
available. Yellow sac spiders (Cheiracanthium species) are common in
homes worldwide. Their bites, though painful, generally lead to only
minor erythema, edema, and pruritus.
■ SCORPION STINGS
Scorpions are arachnids that feed on arthropods and other small
animals. They paralyze their prey and defend themselves by injecting venom from a stinger on the tip of the tail. Painful but relatively
harmless scorpion stings need to be distinguished from the potentially
lethal envenomations that are produced by ~30 of the ~1000 known
species and that cause >5000 deaths worldwide each year. Scorpions
are nocturnal and remain hidden during the day in crevices or burrows
or under wood, loose bark, or rocks. They occasionally enter houses
and tents and may hide in shoes, clothing, or bedding. Scorpions sting
humans only when threatened.
Of the 40 or so scorpion species in the United States, only bark
scorpions (Centruroides sculpturatus/C. exilicauda) in the Southwest
produce venom that is potentially lethal to humans. This venom
contains neurotoxins that cause sodium channels to remain open.
Such envenomations usually are associated with little swelling, but
prominent pain, paresthesia, and hyperesthesia can be accentuated by
tapping on the affected area (the tap test). These symptoms soon spread
to other locations; dysfunction of cranial nerves and hyperexcitability
of skeletal muscles develop within hours. Patients present with restlessness, blurred vision, abnormal eye movements, profuse salivation,
lacrimation, rhinorrhea, slurred speech, difficulty in handling secretions, diaphoresis, nausea, and vomiting. Muscle twitching, jerking,
and shaking may be mistaken for a seizure. Complications include
tachycardia, arrhythmias, hypertension, hyperthermia, rhabdomyolysis, and acidosis. Symptoms progress to maximal severity in ~5 h and
subside within a day or two, although pain and paresthesia can last for
weeks. Fatal respiratory arrest is most common among young children
and the elderly.
Envenomations by Leiurus quinquestriatus in the Middle East and
North Africa, by Mesobuthus tamulus in India, by Androctonus species
along the Mediterranean littoral and in North Africa and the Middle
East, and by Tityus serrulatus in Brazil cause massive release of endogenous catecholamines with hypertensive crises, arrhythmias, pulmonary
edema, and myocardial damage. Acute pancreatitis occurs with stings
of Tityus trinitatis in Trinidad, and central nervous toxicity complicates
stings of Parabuthus and Buthotus scorpions of South Africa.
In Iran and adjacent countries, Hemiscorpius lepturus causes the
most scorpion envenomations. Its stings are relatively asymptomatic at
first, but its cytotoxic venom causes pain, hemolysis, and tissue necrosis after the first day. Systemic complications include hemoglobinuria
and subsequent acute kidney injury.
Stings of most other species cause immediate sharp local pain
followed by edema, ecchymosis, and a burning sensation. Symptoms
typically resolve within a few hours, and skin does not slough. Allergic
reactions to the venom sometimes develop.
TREATMENT
Scorpion Stings
Identification of the offending scorpion helps to determine the
course of treatment. Stings of nonlethal species require at most
ice packs, analgesics, or antihistamines. Because most victims
experience only local discomfort, they can be managed at home
with instructions to return to the emergency department if signs
of cranial-nerve or neuromuscular dysfunction develop. Aggressive
supportive care and judicious use of antivenom can reduce or eliminate deaths from more severe envenomations. Keeping the patient
calm and applying pressure dressings and cold packs to the sting
site are measures that decrease the absorption of venom. A continuous IV infusion of midazolam controls the agitation, flailing, and
involuntary muscle movements produced by scorpion stings. Close
monitoring during treatment with this drug and other sedatives or
narcotics is necessary for persons with neuromuscular symptoms
because of the risk of respiratory arrest. Hypertension and pulmonary edema respond to nifedipine, nitroprusside, hydralazine,
or prazosin. Dangerous bradydysrhythmia can be controlled with
atropine.
Commercially prepared antivenins are available in several countries for some of the most dangerous scorpion species. An FDAapproved C. sculpturatus IgG F(ab’)2
antivenin in horse serum is
available. IV administration of antivenin rapidly reverses cranial-nerve
dysfunction and muscular symptoms.
■ HYMENOPTERA STINGS
Bees, wasps, hornets, yellow jackets, and ants (all of the insect order
Hymenoptera) sting in defense or to subdue their prey. Their venoms
contain a wide array of amines, peptides, and enzymes that cause local
and systemic reactions. Although the toxic effect of multiple stings can
be fatal to a human, nearly all of the ≥100 deaths due to hymenopteran
stings in the United States each year result from type 1, immediate-type
allergic reactions.
Bee and Wasp Stings The stinger of the honeybee (Apis mellifera)
is unique in being barbed. The stinging apparatus and attached
venom sac tear loose from the honeybee’s body, and muscular contractions of the venom sac continue to infuse venom into the skin. Other
kinds of bees, ants, and wasps have smooth stinging mechanisms and
can sting numerous times in succession. Generally, a person sustains
just one sting from a bee or social wasp unless a nest was disturbed.
Africanized honeybees (now present in South and Central America
and the southern and western United States) respond to minimal
intrusions more aggressively. The sting of an Africanized bee contains
less venom than that of its non-Africanized relatives, but victims tend
to sustain far more stings and thus receive a far greater overall volume
of venom. Most patients who report having sustained a “bee sting” are
more likely to have encountered stinging wasps instead.
The venoms of different kinds of hymenopterans are biochemically and immunologically distinct. Direct toxic effects are mediated
by mixtures of low-molecular-weight compounds such as serotonin,
histamine, acetylcholine, and several kinins. Polypeptide toxins in
honeybee venom include mellitin, which damages cell membranes;
mast cell–degranulating protein, which causes histamine release; the
neurotoxin apamin; and the anti-inflammatory compound adolapin.
Enzymes in venom include hyaluronidase and phospholipases. There
appears to be little cross-sensitization between the venoms of honeybees and wasps.
Uncomplicated hymenopteran stings cause immediate pain, a
wheal-and-flare reaction, and local edema, all of which usually subside
in a few hours. Multiple stings can lead to vomiting, diarrhea, generalized edema, dyspnea, hypotension, and non-anaphylactic circulatory
collapse. Rhabdomyolysis and intravascular hemolysis may cause
renal failure. Death from the direct (nonallergic) effects of venom has
followed stings of several hundred honeybees. Stings to the tongue or
mouth may induce life-threatening edema of the upper airways.
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