Herpes Zoster in Childhood

Abstract

Herpes zoster is caused by reactivation of latent varicella-zoster virus that resides in a dorsal root ganglion. Herpes zoster can develop at any time after a primary infection or varicella vaccination. The incidence among children is approximately 110 per 100,000 person-years. Clinically, herpes zoster is characterized by a painful, unilateral vesicular eruption in a restricted dermatomal distribution. In young children, herpes zoster has a predilection for areas supplied by the cervical and sacral dermatomes. Herpes zoster tends to be milder in children than that in adults. Also, vaccine-associated herpes zoster is milder than herpes zoster after wild-type varicella. The diagnosis of herpes zoster is mainly made clinically, based on a distinct clinical appearance. The most common complications are secondary bacterial infection, depigmentation, and scarring. Chickenpox may develop in susceptible individuals exposed to herpes zoster. Oral acyclovir should be considered for uncomplicated herpes zoster in immunocompetent children. Intravenous acyclovir is the treatment of choice for immunocompromised children who are at risk for disseminated disease. The medication should be administered ideally within 72 hours of rash onset.

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Leung, A. and Barankin, B. (2015) Herpes Zoster in Childhood. Open Journal of Pediatrics, 5, 39-44. doi: 10.4236/ojped.2015.51008.

1. Introduction

Herpes zoster, also known as shingles, is caused by reactivation of endogenous latent varicella-zoster virus that resides in a sensory dorsal root ganglion usually after primary infection with varicella-zoster virus (i.e., varicella or chickenpox) [1] . Herpes zoster can develop at any time after a primary infection or varicella vaccination [1] . The activated virus travels back down the corresponding cutaneous nerve to the adjacent skin, causing a painful, unilateral vesicular eruption in a restricted dermatomal distribution.

2. Epidemiology

Herpes zoster occurs more commonly after varicella infection than after varicella vaccination [2] . Herpes zoster usually occurs in persons with relative cell-mediated immunologic compromise such as elderly individuals or patients with an immunosuppressive illness or receiving immunosuppressive therapy [3] . The cumulative lifetime incidence among the general population is approximately 10% to 30%, with the risk increasing sharply after 50 years of age [4] -[6] . In the study by Insigna et al, the overall age- and sex-adjusted incidence of herpes zoster was 320 per 100,000 person-years in the United States from 2000 to 2001 [7] . The rate was higher among females (390 per 100,000 person-years) than among males (260 per 100,000 person-years).The incidence among children aged 0 to 14 years was 110 per 100,000 person-years [7] . Kawai et al performed a systematic review of 63 studies from 22 countries on the incidence of herpes zoster [4] . The authors found the incidence rate of herpes zoster ranged between 300 to 500 per 100,000 person-years in the general population in North America, Europe, and Asia-Pacific, based on studies using prospective surveillance, electronic medical record data or administrative data with medical record review. The incidence is twice in whites when compared to blacks [8] . Immunocompromised individuals have a 20 to 100 times greater risk than immunocompetent individuals of the same age [9] [10] .

In general, herpes zoster is uncommon in individuals younger than 10 years of age and rare in infants [3] [5] . The younger a child is when he/she has varicella, the greater the likelihood that herpes zoster will develop in childhood or early adulthood [6] . In this regard, infantile herpes zoster is more commonly associated with intrauterine varicella-zoster virus infection than postnatal infection. In approximately 2% of children exposed to varicella-zoster virus in utero, subclinical varicella develops, and therefore they are at risk for herpes zoster after birth [3] . Enders et al prospectively followed 1373 women who had varicella during the first 36 weeks of gestation [11] . Herpes zoster in infancy or early childhood was reported in 10 children who were asymptomatic at birth. The observed risk of herpes zoster after maternal varicella between 13 and 24 weeks and between 25 and 36 weeks was 4/477 (0.8%) and 6/345 (1.7%), respectively. Eight of these children had herpes zoster during the first year of life.

At times, herpes zoster may result from varicella vaccination as the vaccine strain of varicella-zoster virus may become latent and later reactivate to cause herpes zoster [3] [12] [13] . In one study, the incidence of herpes zoster among varicella vaccine recipients is about 14 cases per 100,000 person-years, compared with 20 to 63 cases per 100,000 person-years after natural varicella infection [14] . In another study, the incidence of laboratory-confirmed herpes zoster was 48 cases per 100,000 person-years in vaccinated children (wild type and vaccine-strain) and 230 cases per 100,000 person-years in unvaccinated children (wild type only) [15] . Several studies have shown that the incidence of herpes zoster in both healthy and immunocompromised children who received varicella vaccine is less than that experienced by healthy and immunocompromised children who experienced natural varicella infection, respectively [12] [15] -[17] . The lower incidence may be related to a lower rate of reactivation of the attenuated vaccine strain of varicella-zoster virus and the lower rate of rash following vaccination compared with wild-type varicella [12] .

3. Pathogenesis

A primary infection with either wild-type or vaccine-type varicella-zoster virus is a prerequisite for herpes zoster [3] . Activation of latent varicella-zoster virus in a partially immune host results in herpes zoster. Defects in immunity, especially cell-mediated immunity, resulting from an immunosuppressive illness or immunosuppressive therapy are important factors in the pathogenesis. Predisposing factors include increasing age, fatigue, and emotional stress. In children, asthma is a risk factor for herpes zoster [18] .

The vaccine-type virus strain is known to establish a latent infection in the dorsal root ganglia [14] . The virus reaches the sensory ganglia through sensory nerves at the injection site. The relative risk of herpes zoster developing in a vaccine recipient is higher in individuals who had a vaccine-associated rash or breakthrough infection [14] . In the majority of cases, the zoster lesions occur on the same side as the vaccine injection site [3] . Varicella vaccine is composed of a mixture of varicella zoster virus strains. Viruses sampled from herpes zoster vesicles are single clones, suggesting that a single strain is selected between the time of inoculation and development of the rash [19] .

4. Clinical Manifestations

The onset of disease may be heralded by pain within the dermatome and precedes the lesions by 48 to 72 hours [1] [12] . The pain is due to acute neuritis and is related to viral replication, inflammation, and cytokine production leading to neuronal destruction and increased sensitivity of pain receptors [20] . At times, there may be paresthesia, burning, or itching in the affected area [12] . An area of erythema might follow and precede the development of a group of vesicles in the distribution of the dermatome that corresponds to the infected dorsal root ganglion (Figure 1) [12] . Usually 1 or, less commonly, 2 or 3 adjacent dermatomes are affected [5] [20] . In young children, herpes zoster has a predilection for areas supplied by the cervical and sacral dermatomes [21] . In adults, the lesions are more common in the lower thoracic and upper lumbar dermatomes and may involve the trigeminal nerve [12] . In both children and adults, the lesions usually do not cross the midline [12] . Vesicles may coalesce to form bullous lesions [1] . The vesicular and bullous lesions may become pustular or occasionally hemorrhagic and ultimately crust in 7 to 10 days [20] . There may be regional lymphadenopathy [12] .

Herpes zoster may involve the eyelids when the ophthalmic branch of the trigeminal nerve is affected. Appearance of skin lesions at the side of the nose represents involvement of the nasociliary branch of ophthalmic nerve (Hutchinson’s sign) and predicts a higher likelihood of ocular involvement [11] [22] .

Herpes zoster tends to be milder in children than in adults [2] [3] [4] . Also, vaccine-associated herpes zoster is milder than herpes zoster after wild-type varicella [2] [3] .

In individuals with immunodeficiency, the lesions may involve multiple contiguous, non-contiguous, bilateral,

Figure 1. Multiple grouped papules and vesicles on an erythematous base, present unilaterally on the right flank in a dermatomal distribution.

or unusual dermatomes [4] [12] . The lesions may disseminate to other organs such as the liver, kidneys, lungs, and central nervous system. Also, the illness is more severe and prolonged.

5. Complications

The most common complications are secondary bacterial infection, post-inflammatory depigmentation, and scarring [12] . Necrotizing fasciitis is a potential complication if there is secondary bacterial infection [12] . Herpes zoster ophthalmicus may lead to severe eye pain, conjunctivitis, lid ulceration, retinal necrosis, ophthalmoparesis/plegia, sclerokeratitis, anterior uveitis, and optic neuritis [23] . Postherpetic neuralgia, which represents a continuum of pain that does not resolve following the acute episode of herpes zoster, is uncommon in children [1] [2] [5] . Other rare complications include Ramsay Hunt syndrome, Guillain-Barré syndrome, pneumonia, aseptic meningitis, encephalitis, meningoencephalitis, ventriculitis, transverse myelitis, granulomatous cerebral angiitis, cranial nerve paresis/palsies, and peripheral nerve paresis/palsies [17] [20] [24] [25] . Inflammatory skin lesions following herpes zoster may occur within the same dermatome (Wolf’s isotopic phenomenon) [12] .

Complications are uncommon in vaccine-induced herpes zoster in healthy children. In contrast, in immunocompromised patients, complications are more common and severe.

6. Diagnosis

The diagnosis of herpes zoster is mainly made clinically, based on the distinctive clinical appearance and symptomatology. Laboratory tests usually are not necessary. A Tzanck smear, performed by scraping the base of the lesion, can demonstrate giant cells [1] . The diagnosis can be confirmed if necessary by the demonstration of specific viral antigens in skin scrapings or vesicles using direct fluorescent (FDA) assay. Viral DNA analysis of the lesion by polymerase chain reaction (PCR) can be used to distinguish between wild-type and vaccine-type viruses (genotyping) [14] .

7. Differential Diagnosis

Herpes zoster should be differentiated from zosteriform herpes simplex. In zosteriform herpes simplex, there is no painful prodrome, small vesicles of almost uniform size, less number of grouped vesicles, and more likely to recur. Other differential diagnoses include zosteriform lichen planus, drug eruption, insect bites, folliculitis, hand-foot-mouth disease, contact dermatitis, atopic dermatitis, phytophotodermatitis, and dermatitis herpetiformis.

8. Prognosis

Recurrence is uncommon in the immunocompetent individual. Approximately 5% of immunocompetent patients have a second episode of herpes zoster [5] . Three or more episodes are rare [5] [20] .

9. Management

Affected patients are contagious because the virus can be transmitted by direct contact with herpes zoster lesions and, less commonly, by airborne spread from aerosolization of virus from skin lesions [11] [14] . Affected children should be kept out of school or day care until crusting appears and contact with pregnant women in particular is to be avoided [1] . Chickenpox may develop in susceptible individuals exposed to herpes zoster [1] . General preventive measures include good personal hygiene, with particular emphasis on hand washing, proper clothing, and covering exposed lesions with bandages. Fingernails should be trimmed to reduce injury from scratching. If secondary bacterial infection occurs, topical or systemic antibiotic therapy is indicated.

The goals of antiviral therapy are to reduce viral shedding, hasten healing of cutaneous lesions, prevent new lesion formation, reduce the pain associated with acute neuritis and possibly decrease complications from the disease [11] [20] . Oral acyclovir (20 mg/kg/dose, maximum 800 mg/dose) five times per day for 5 to 7 days should be considered for uncomplicated herpes zoster in immunocompetent children [5] . Intravenous acyclovir (10 mg/kg or 500 mg/m2 every 8 hours) for 7 to 10 days is the treatment of choice for immunocompromised children who are at risk for disseminated disease [1] [5] . The medication should be administered ideally within 72 hours of rash onset [20] . Relapse of herpes zoster can be treated with a second course of acyclovir with similar dosing and duration as for a primary episode.

10. Prevention

It is known that vaccine-associated herpes zoster is milder than herpes zoster after wild type-varicella [26] . As such, there is a need for prevention of varicella-zoster virus infection though universal childhood immunization [26] [27] . The Advisory Committee for Immunization Practices of the Centers for Disease Control and Prevention and the American Academy of Pediatrics recommend a routine two-dose varicella vaccination program for children, with the first dose administered at 12 to 18 months and the second dose at 4 to 6 years of age [2] . The Advisory Committee on Immunization Practices further recommends two doses of varicella vaccine, 4 to 8 weeks apart, for all susceptible adolescents and adults and a catch-up second dose for everyone who receives one dose of varicella vaccine previously [28] .

NOTES

*Corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.

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