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Neonatal herpes
Neonatal herpes
Neonatal herpes
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Neonatal herpes simplex
Other namesNeonatal herpes
A cutaneo-mucous form of herpes simplex in a neonate
SpecialtyPediatrics Edit this on Wikidata
Usual onsetCongenital
CausesHerpes simplex virus infection
Frequency1 in 10,000 births[1]

Neonatal herpes simplex, or simply neonatal herpes, is a herpes infection in a newborn baby, caused by the herpes simplex virus (HSV). It occurs mostly as a result of vertical transmission of the HSV from an affected mother to her baby.[2] Types include skin, eye, and mouth herpes (SEM), disseminated herpes (DIS), and central nervous system herpes (CNS).[3] Depending on the type, symptoms vary from a fever to small blisters, irritability, low body temperature, lethargy, breathing difficulty, and a large abdomen due to ascites or large liver.[3] There may be red streaming eyes or no symptoms.[3]

The cause is HSV 1 and 2.[2] It can infect the unborn baby, but more often passes to the baby during childbirth.[4] Onset is typically in the first six weeks after birth.[3] The baby is at greater risk of being affected if the mother contracts HSV in later pregnancy.[2] In such scenarios a prolonged rupture of membranes or childbirth trauma may increase the risk further.[2]

Globally, it is estimated to affect one in 10,000 births.[1] Around 1 in every 3,500 babies in the United States contract the infection.[5]

Signs and symptoms

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Neonatal herpes manifests itself in three forms: skin, eye, and mouth herpes (SEM, sometimes referred to as "localized"); disseminated herpes (DIS); and central nervous system herpes (CNS).[6]

  • SEM herpes is characterized by external lesions but no internal organ involvement. Lesions are likely to appear on trauma sites such as the attachment site of fetal scalp electrodes, forceps, or vacuum extractors that are used during delivery; in the margin of the eyes; in the nasopharynx; and in areas associated with trauma or surgery (including circumcision).[7]
  • DIS herpes affects internal organs, particularly the liver.[citation needed]
  • CNS herpes is an infection of the nervous system and the brain that can lead to encephalitis. Infants with CNS herpes present with seizures, tremors, lethargy, and irritability. They feed poorly, have unstable temperatures, and their fontanelle (soft spot of the skull) may bulge.[8]

CNS herpes is associated with higher morbidity, while DIS herpes has a higher mortality rate. These categories are not mutually exclusive and there is often overlap of two or more types. SEM herpes has the best prognosis of the three, however if left untreated it may progress to disseminated or CNS herpes with attendant increases in mortality and morbidity.[citation needed]

Death from neonatal HSV disease in the U.S. is currently decreasing; the current death rate is about 25%, down from as high as 85% in untreated cases just a few decades ago. Other complications from neonatal herpes include prematurity, with approximately 50% of cases having a gestation of 38 weeks or less, and concurrent sepsis in approximately one-quarter of cases that further clouds speedy diagnosis.[citation needed]

Cause

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The cause is HSV 1 and 2.[2] It can infect the unborn baby, but more often passes to the baby during childbirth.[4] Onset is typically in the first six weeks after birth.[3] The baby is at greater risk of being affected if the mother contracts HSV in later pregnancy.[2] In such scenarios a prolonged rupture of membranes may increase the risk further.[2] Sites of injury such as forceps or scalp electrodes may provide a portal of entry for HSV.[4]

Risk factors

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Maternal risk factors for neonatal HSV-1 include: White non-Hispanic race,[9] young maternal age (<25), primary infection in third trimester,[10] first pregnancy, HSV (1&2) seronegativity,[8][11] a discordant partner,[12] gestation <38 weeks,[10] and receptive oral sex in the third trimester.[13]

Neonatal HSV-2 maternal risk factors: Black race,[14] young maternal age (<21),[8][10] a discordant partner, primary or non-primary first episode infection in the third trimester,[15] four or more lifetime sexual partners,[14] lower level of education,[14] history of previous STD, history of pregnancy wastage, first viable pregnancy, and gestation <38 weeks.[8][10]

Transmission

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The majority of cases (85%) occur during birth when the baby comes in contact with infected genital secretions in the birth canal, most common with mothers that have newly been exposed to the virus (mothers that had the virus before pregnancy have a lower risk of transmission). An estimated 5% are infected in utero, and approximately 10% of cases are acquired postnatally. Detection and prevention is difficult because transmission is asymptomatic in 60–98% of cases.[16]

Post-natal transmission incidences can happen from a source other than the mother, such as an Orthodox Jewish mohel with herpetic gingivostomatitis who performs oral suction on a circumcision wound without using a prophylactic barrier to prevent contact between the baby's penis and the mohel's mouth.[17][18][19]

Diagnosis

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Diagnosis is by blood tests and culture.[6] Swabs are generally taken from the mouth, nose, throat, eyes, and anus, for HSV culture an PCR.[4] Fluid from any blisters can be swabbed too.[4] Liver enzymes may be the first sign to be noted when suspecting neonatal HSV.[4] Other tests include a lumbar puncture and medical imaging of the brain; MRI, CT scan, ultrasound.[3] An assessment of the eyes may reveal eye disease.[3]

Differential diagnosis

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Other skin conditions that may appear similar include erythema toxicum neonatorum, transient neonatal pustular melanosis, infantile acne, miliaria, infantile acropustulosis, and sucking blisters.[3] CNS disease may appear like bacterial or other viral meningitis's.[3] Conjunctivitis due to bacterial infection or other viruses can look like neonatal herpes eye disease.[3] Bacterial sepsis, viral hepatitis, and other infections including cytomegalovirus, toxoplasmosis, syphilis, rubella may mimic the disseminated type.[3]

Treatment

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Reductions in morbidity and mortality are due to the use of antiviral treatments such as vidarabine and acyclovir.[20][21][22][23] However, morbidity and mortality still remain high due to diagnosis of DIS and CNS herpes coming too late for effective antiviral administration; early diagnosis is difficult in the 20–40% of infected neonates that have no visible lesions.[24] A recent large-scale retrospective study found disseminated NHSV patients least likely to get timely treatment, contributing to the high morbidity/mortality in that group.[25]

Harrison's Principles of Internal Medicine recommends that pregnant women with active genital herpes lesions at the time of labor be delivered by caesarean section. Women whose herpes is not active can be managed with acyclovir.[26] The current practice is to deliver women with primary or first episode non-primary infection via caesarean section, and those with recurrent infection vaginally (even in the presence of lesions) because of the low risk (1–3%) of vertical transmission associated with recurrent herpes.[citation needed]

Epidemiology

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Neonatal HSV rates in the U.S. are estimated to be between 1 in 3,000 and 1 in 20,000 live births. Approximately 22% of pregnant women in the U.S. have had previous exposure to HSV-2, and an additional 2% acquire the virus during pregnancy, mirroring the HSV-2 infection rate in the general population.[27] The risk of transmission to the newborn is 30–57% in cases where the mother acquired a primary infection in the third trimester of pregnancy. Risk of transmission by a mother with existing antibodies for both HSV-1 and HSV-2 has a much lower (1–3%) transmission rate. This in part is due to the transfer of a significant titer of protective maternal antibodies to the fetus from about the seventh month of pregnancy.[8][28] However, shedding of HSV-1 from both primary genital infection and reactivations is associated with higher transmission from mother to infant.[8]

HSV-1 neonatal herpes is extremely rare in developing countries because development of HSV-1 specific antibodies usually occurs in childhood or adolescence, precluding a later genital HSV-1 infection. HSV-2 infections are much more common in these countries. In industrialized nations, the adolescent HSV-1 seroprevalence has been dropping steadily for the last 5 decades. The resulting increase in the number of young women becoming sexually active while HSV-1 seronegative has contributed to increased HSV-1 genital herpes rates, and as a result, increased HSV-1 neonatal herpes in developed nations. A study in the United States from 2003 to 2014 using large administrative databases showed increasing trends in incidence of neonatal HSV from 7.9 to 10 cases per 100,000 live births and mortality of 6.5%. Babies of decreased gestational age and those of African American race had higher incidences of neonatal HSV. Another study from Canada showed similar results, with an incidence of 5.9 per 100,000 live births and a case fatality of 15.5%.[29] A three-year study in Canada (2000–2003) revealed a neonatal HSV incidence of 5.9 per 100,000 live births and a case fatality rate of 15.5%. HSV-1 was the cause of 62.5% of cases of neonatal herpes of known type, and 98.3% of transmission was asymptomatic.[16] Asymptomatic genital HSV-1 has been shown to be more infectious to the neonate, and is more likely to produce neonatal herpes than HSV-2.[8][30] However, with prompt application of antiviral therapy, the prognosis of neonatal HSV-1 infection is better than that for HSV-2.[citation needed]

References

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Neonatal herpes

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from Grokipedia
Neonatal herpes simplex is a severe viral in newborns caused by types 1 or 2 (HSV-1 or HSV-2), most commonly acquired perinatally from maternal genital during . The infection manifests in three primary forms: localized to , eyes, and mouth (SEM disease); (CNS) involvement; or disseminated multi-organ disease, with the latter two carrying the highest morbidity and mortality risks even with treatment. In the United States, incidence remains stable at approximately 1 case per 10,000 to 20,000 live births, predominantly HSV-2, despite increasing maternal seroprevalence, likely due to reduced transmission from shedding via improved diagnostics and interventions. Untreated, mortality approaches 60% overall, but high-dose intravenous acyclovir (60 mg/kg/day for 14-21 days, depending on disease type) has reduced disseminated disease fatality to 29-41% and CNS disease to 4-6%, though neurodevelopmental sequelae persist in over half of survivors. Prevention strategies include cesarean delivery for mothers with active genital lesions at term and suppressive antiviral therapy for those with recurrent HSV near delivery, which can decrease transmission risk by up to 75% in high-risk cases.

Etiology and Transmission

Causative Agents

Neonatal herpes is caused by types 1 (HSV-1) and 2 (HSV-2), enveloped double-stranded DNA viruses in the Alphaherpesvirinae subfamily. Traditionally, HSV-2 has predominated due to its prevalence in genital infections, accounting for the majority of cases, though HSV-1 has historically comprised 15–30%. Recent surveillance data show HSV-1 rising in neonatal infections, with approximately 52% of UK cases attributed to HSV-1 and 48% to HSV-2 as of 2024. HSV virions feature a linear dsDNA of about 152 kilobase pairs within an icosahedral (diameter ~100–110 nm), surrounded by tegument proteins and a containing at least 12 glycoproteins critical for receptor binding (e.g., gB, gC, gD) and membrane fusion. These structural elements enable efficient host cell , primarily targeting epithelial cells and neurons. The productive replication cycle initiates with glycoprotein-mediated attachment to host receptors (e.g., nectins for HSV-1, for both), followed by or direct fusion, retrograde of the to the nucleus, and DNA release through nuclear pores. Viral genes are expressed in cascades—immediate-early (transactivators like ICP0), early ( for replication via rolling-circle mechanism, yielding concatemers cleaved during packaging), and late (structural proteins)—with assembly in the nucleus, primary envelopment, de-envelopment at the nuclear membrane, and final envelopment in the before egress, completing a cycle in 12–24 hours under optimal conditions. HSV establishes latency primarily in sensory ganglia, maintaining the genome as an extrachromosomal with silenced lytic genes via epigenetic modifications (e.g., ) and interference, allowing periodic reactivation triggered by stress or . This latency-reactivation dynamic underlies persistent infection but manifests differently in neonates due to host factors. Neonates exhibit heightened susceptibility owing to an immature , including underdeveloped T-cell responses, reduced function, and limited type I signaling, which fail to contain initial replication and permit viremic dissemination to visceral organs and the —outcomes rare in adults, where robust innate and adaptive barriers localize infection to mucocutaneous sites. This results in dissemination rates up to 25–30% of neonatal cases, contrasting with adult HSV infections that seldom progress systemically in immunocompetent hosts.

Modes of Transmission

Neonatal herpes simplex virus (HSV) infection occurs predominantly through vertical transmission from mother to infant, with intrapartum acquisition accounting for approximately 85% of cases via exposure to virus in maternal genital tract secretions during vaginal delivery. This pathway involves direct contact between the neonate's skin, mucous membranes, or eyes and HSV shed from the maternal cervix or vulvovagina, with viral entry facilitated by microtrauma or intact mucosal absorption; cesarean delivery substantially reduces this risk by avoiding such contact. Transmission rates vary significantly by maternal infection status: primary first-episode infections near term carry risks of 30-60% due to high viral loads and absence of neonatal-protective antibodies, whereas recurrent infections transmit at rates below 2-3%, even with asymptomatic shedding, owing to maternal type-specific immunity that limits viral replication and shedding duration. Asymptomatic genital shedding, detected in 10-20% of HSV-seropositive women on any given day via PCR, underlies most intrapartum transmissions in recurrent cases but yields low overall rates (<3%) because of reduced viral titers. Intrauterine transmission, responsible for about 5% of neonatal HSV cases, arises via transplacental hematogenous spread or ascending from the lower genital tract after membrane rupture, often earlier in and associated with disseminated fetal . This mode is rare, estimated at 1 in 300,000 deliveries in the United States, and typically involves HSV-2 crossing the during primary maternal , leading to fetal exposure without intrapartum contact. Postnatal transmission comprises roughly 10% of cases and occurs after delivery through horizontal spread from infected individuals, including maternal or caregiver orolabial HSV via kissing or direct contact, or rarely via breastfeeding if active breast lesions are present. HSV-1 predominates in this mode, often from community sources rather than maternal genital HSV-2, with risks elevated in settings of poor hygiene or multiple caregivers harboring asymptomatic oral shedding.

Risk Factors

Primary maternal (HSV) infection occurring proximate to delivery confers the highest transmission risk to the neonate, with rates estimated at 30-50%, attributable to insufficient time for development and transplacental transfer of protective maternal antibodies. In contrast, recurrent maternal infections pose a markedly lower risk, typically under 2-3%, as preexisting type-specific antibodies mitigate viral dissemination despite potential shedding. Isolation of HSV from the maternal genital tract at delivery further amplifies this odds by over 300-fold, independent of infection recency. HSV-1 genital infections in the mother appear to carry a higher per-exposure transmission probability to the neonate than HSV-2, based on observed disparities in acquisition rates during intrapartum exposure. Intrapartum invasive procedures, such as fetal scalp electrode application for monitoring, elevate transmission risk by breaching the neonatal scalp barrier and facilitating direct viral inoculation, with multiple case series documenting resultant HSV dissemination. Neonatal prematurity, especially at gestations under 38 weeks, compounds vulnerability through immature innate immunity and diminished placental antibody transfer efficiency, particularly when maternal timing limits humoral protection. Absence of maternal HSV-specific neutralizing antibodies at birth remains a critical determinant, as evidenced by higher incidence in seronegative mothers' offspring during primary exposures.

Clinical Manifestations

Signs and Symptoms by Presentation Type

Neonatal herpes simplex virus (HSV) infection is classified into three main presentation types based on clinical involvement: skin, eye, and mouth (SEM) disease; central nervous system (CNS) disease; and disseminated disease. These forms account for varying proportions of cases, with SEM disease comprising 40-50%, CNS disease around 30%, and disseminated disease the remainder. Distinctions arise from the virus's tropism and dissemination extent, with HSV-2 predominating in SEM and perinatal cases overall. Skin, Eye, and Mouth (SEM) Disease
SEM disease is characterized by localized vesicular lesions on the skin, conjunctivitis or keratitis in the eyes, and stomatitis in the mouth. More than 80% of affected neonates present with skin vesicles, typically appearing as clustered, fluid-filled blisters that may crust over, while 20% involve isolated ocular or oral sites without cutaneous findings. Symptoms include and localized discomfort, with the lowest mortality among types but a risk of progression to CNS or disseminated forms if untreated. HSV-2 is more commonly associated with this presentation due to its in genital infections. Central Nervous System (CNS) Disease
CNS involvement manifests as with neurological signs such as seizures (focal or generalized), , , poor feeding, tremors, and temperature instability. Initial symptoms can be nonspecific, including fever and fussiness, and up to 30% of cases lack concurrent skin lesions, complicating early recognition. Ocular features like may accompany neurological deficits, reflecting viral spread to neural tissues. Untreated, this form carries a 50% , with survivors often facing neurologic sequelae. Disseminated Disease
Disseminated neonatal HSV features systemic affecting multiple organs, including severe with liver involvement, , and mimicking bacterial . Clinical signs include shock, , respiratory distress, and multi-organ failure, with vesicles present in many but not all cases. Without antiviral therapy, mortality exceeds 80%, underscoring the aggressive nature of unchecked in neonates.

Timing of Onset

Neonatal herpes simplex virus (HSV) infections acquired intrauterine, representing about 5 percent of cases, typically manifest with signs evident at or shortly after birth, including cutaneous scarring, , , or other congenital anomalies resulting from transplacental transmission or ascending infection. In these rare instances, symptoms align with fetal exposure during , distinguishing them from later-onset forms through immediate postnatal detection. Intrapartum transmission, accounting for 85 to 90 percent of neonatal HSV cases via exposure to maternal genital secretions during delivery, generally leads to symptom onset between 5 and 14 days postpartum, corresponding to the virus's typical of 2 to 12 days. This timeline facilitates inference of perinatal acquisition when vesicles, systemic illness, or neurological signs emerge in this window absent prenatal indicators. Postnatal infections, comprising roughly 10 percent and often stemming from nonsexual contacts such as orolabial shedding from family members, exhibit delayed onset typically beyond 2 to 4 weeks, extending into several weeks or months depending on exposure timing and . Population-based surveillance data from over 500 U.S. cases reveal that 87 percent present within the first two weeks of life, with over half manifesting by day 7, though up to 6 weeks may elapse in cases involving initial shedding or atypical progression, underscoring the need for extended vigilance.

Diagnosis

Diagnostic Approaches

(PCR) assays for (HSV) DNA represent the gold standard for diagnosing neonatal HSV , offering superior sensitivity and rapidity compared to traditional methods. Specimens typically include surface swabs from skin vesicles, conjunctivae, mouth, nasopharynx, anus, and ; or plasma for disseminated ; and () for () involvement. PCR on surface swabs demonstrates sensitivity exceeding 95% in neonates with lesions, significantly outperforming , which, while 100% specific, has lower sensitivity (often <70%) and requires 2–7 days for results. For , HSV PCR sensitivity varies from 70% to 98% in CNS cases, with near-100% specificity, though false negatives may occur early in or due to low viral loads, necessitating repeat testing if clinical suspicion persists. Viral culture from lesion swabs or tissues provides confirmatory isolation of HSV but is increasingly supplanted by PCR due to slower turnaround (up to 7 days) and reduced yield, particularly from non-lesional sites. Serologic assays for HSV-specific IgM or IgG are unreliable in neonates, as maternal IgG antibodies cross the placenta and persist for months, masking infant-specific responses; thus, they are not recommended for acute diagnosis. The Tzanck smear, a cytologic test on lesion scrapings revealing multinucleated giant cells, enables rapid bedside assessment (within hours) but exhibits low specificity (due to mimics like varicella) and sensitivity (<50% in some series), limiting its role to supportive rather than definitive evidence. The 2024 Red Book guidelines advocate comprehensive PCR-based evaluation of at-risk neonates, including , CSF, and surface sites, to facilitate early detection across disease manifestations (skin-eye-mucosa, CNS, or disseminated). Imaging such as cranial ultrasound or MRI may adjunctively assess CNS complications like but does not confirm HSV etiology, relying instead on correlated PCR positivity.

Differential Diagnosis

Neonatal herpes simplex virus (HSV) infection must be differentiated from other causes of neonatal illness presenting with nonspecific systemic symptoms, vesicular or pustular skin lesions, or (CNS) involvement, as early misdiagnosis can delay . Conditions such as bacterial often mimic disseminated HSV through overlapping features like fever, lethargy, poor feeding, and organ dysfunction, but lack characteristic clustered vesicles; group B Streptococcus or predominates in early-onset cases without skin findings. Enteroviral infections, particularly or , can resemble HSV in producing or disseminated disease with irritability, seizures, and occasionally a maculopapular or vesicular , though enteroviral rashes are typically nonclustered and seasonal (summer-fall peaks). similarly presents with sepsis-like illness or but more frequently involves abnormalities and respiratory symptoms without prominent skin lesions. Other differentials include , which features annular or targetoid rashes potentially confused with HSV vesicles, especially in cases with maternal autoantibodies, but distinguished by and cardiac involvement; and bacterial skin infections like , presenting with honey-crusted bullae rather than clear, umbilicated vesicles. TORCH infections such as (CMV) may overlap in congenital presentations with or , but CMV typically shows and periventricular calcifications absent in HSV. Varicella-zoster virus can produce vesicular lesions, yet these are larger, variably distributed, and often accompanied by maternal or household exposure history. Empirical errors arise from presuming all neonatal vesicles indicate HSV, overlooking that bacterial or enteroviral accounts for most culture-negative cases, with HSV comprising only about 1-2% of evaluated neonates in some cohorts. , such as organic acidemias, may simulate CNS disease with acidosis and lethargy but feature metabolic derangements without vesicles. Distinctions rely on lesion morphology, exposure history, and syndromic patterns to guide urgent .

Treatment and Management

Antiviral Therapy

The standard antiviral therapy for neonatal herpes simplex virus (HSV) infection is high-dose intravenous acyclovir at 20 mg/kg per dose administered every 8 hours (total 60 mg/kg/day), with duration tailored to disease presentation: 21 days for (CNS) or disseminated involvement, and 14 days for skin, eye, and (SEM) disease alone. This regimen assumes normal renal function, with dose adjustments and monitoring for renal toxicity via serum creatinine levels, as acyclovir is renally excreted. Institution of high-dose intravenous acyclovir has substantially reduced mortality rates compared to historical untreated or lower-dose benchmarks; for disseminated disease, mortality declined from approximately 57% to 31%, while CNS disease mortality fell to around 6%. These improvements stem from prospective studies demonstrating viral clearance and benefits, though untreated disseminated cases historically approached 85% mortality prior to acyclovir's widespread adoption. Following completion of , suppressive oral acyclovir at 300 mg/m² per day divided into three doses for 6 months is recommended, particularly for CNS-involved cases, to mitigate recurrent skin lesions and enhance neurodevelopmental outcomes. A multicenter randomized trial of 55 infants with HSV CNS disease showed that this regimen improved IQ scores and reduced skin recurrences by over 50% at 12 months post-therapy compared to , with no significant adverse effects observed. Acyclovir resistance in neonatal HSV remains rare, occurring in fewer than 1% of primary infections based on surveillance data, typically arising from mutations and confirmed via phenotypic susceptibility testing or PCR monitoring of . Routine use of alternatives like foscarnet is not indicated; however, for confirmed resistance—manifested by poor clinical response despite adequate dosing—intravenous foscarnet (60 mg/kg every 8 hours) serves as second-line , with case series reporting survival in resistant cases but requiring close and renal monitoring due to its profile.

Supportive Interventions

Supportive interventions in neonatal (HSV) infection target organ-specific complications arising from disseminated or (CNS) involvement, emphasizing stabilization of vital functions alongside antiviral therapy. In cases of disseminated disease, which affects approximately 25% of infected neonates and often leads to multiorgan failure, is employed for respiratory distress or failure due to or hepatic involvement, while intravenous fluids and vasopressors address hypovolemic or . Management of coagulopathy, such as (DIC), involves or platelets as needed to mitigate bleeding risks from liver dysfunction. For CNS disease, occurring in about 30% of cases and characterized by or seizures, anticonvulsants like or are administered to control acute seizures, with continuous (EEG) monitoring to guide therapy and prevent . and balance must be meticulously maintained to avoid , often requiring restricted fluids in the presence of raised . Ophthalmologic evaluation is critical for neonates with skin, eye, and mouth (SEM) disease or in disseminated/CNS forms, involving slit-lamp examination and funduscopy to detect or early; supportive measures include topical lubricants to protect the and frequent monitoring to preserve vision, as untreated ocular involvement can lead to scarring or blindness in up to 20% of affected eyes without prompt intervention. Multidisciplinary care in a (NICU), integrating , infectious disease, , and specialists, facilitates comprehensive monitoring and has been associated with improved short-term stability by addressing complications proactively, though long-term morbidity reduction depends on early viral control. Nutritional support via is provided during acute phases to sustain growth amid hepatic or gastrointestinal compromise.

Prevention Strategies

Intrapartum and Maternal Measures

Elective cesarean section is recommended for pregnant women with active genital herpes simplex virus (HSV) lesions or prodromal symptoms at the onset of labor to minimize neonatal exposure to infected secretions during vaginal delivery. This intervention reduces transmission risk substantially, with cohort studies showing neonatal HSV infection rates dropping from approximately 7.7% in vaginal deliveries to 1.2% in cesarean deliveries among mothers shedding virus at delivery, representing an 84% relative risk reduction when performed before membrane rupture. The American College of Obstetricians and Gynecologists (ACOG) guidelines emphasize that this benefit diminishes if prolonged rupture of membranes occurs prior to cesarean, as ascending infection can still transmit virus. For women with a history of recurrent genital HSV, suppressive antiviral therapy with acyclovir (400 mg orally three times daily) or valacyclovir (500 mg orally twice daily) initiated at 36 weeks of gestation decreases and the frequency of clinical recurrences at delivery by up to 75-90% in randomized trials. This approach also lowers the cesarean delivery rate from about 25% to 10-15% by preventing outbreaks, though it does not fully eliminate transmission risk, as cases of neonatal HSV have occurred despite suppression. Safety data from registries indicate no increased risk of congenital anomalies with third-trimester use, supporting its routine application in recurrent cases but not for primary infections acquired early in . Routine universal serologic screening for maternal HSV is not recommended by ACOG or the Centers for Disease Control and Prevention (CDC), as type-specific antibody testing identifies 20-40% seroprevalence of HSV-2 in reproductive-age women but fails to detect incident primary infections near term, which account for most transmissions due to higher viral loads. Targeted history-taking for prior outbreaks guides management more effectively than broad screening, which modeling studies show lacks cost-effectiveness and may lead to unnecessary interventions without reducing overall neonatal cases. Evidence from decision analyses suggests potential benefits in high-prevalence settings, but current guidelines prioritize symptomatic evaluation to avoid overdiagnosis of shedders.

Postnatal Precautions

In hospital settings, contact precautions are recommended for neonates born to mothers with active (HSV) lesions at delivery or for any neonate developing mucocutaneous lesions, including gowning, gloving, and hand hygiene until lesions have crusted over. Healthcare staff with active orolabial or skin HSV lesions should cover lesions completely, perform meticulous hand hygiene, and avoid direct contact with neonates if lesions cannot be adequately covered; surgical masks may be considered for orolabial lesions to minimize droplet transmission risk. Mothers with known HSV infection should avoid direct skin-to-skin contact with the neonate if active lesions are present, practicing strict hand prior to any handling or feeding. is generally safe for HSV-positive mothers provided there are no lesions on the s or nipples and any lesions elsewhere on the body are fully covered to prevent indirect transmission; if lesions appear on the breast, direct from the affected side should cease, with milk expressed and discarded until healing is confirmed, while continuing from the unaffected breast if applicable. At home, families of newborns should be educated on rigorous practices, including frequent handwashing by all caregivers before touching the , and avoiding close contact such as kissing from individuals with active oral or skin HSV lesions, which accounts for the majority of rare postnatal transmissions estimated at less than 10% of neonatal cases. These measures address documented vectors like household members with shedding or unrecognized lesions, though empirical data indicate low overall postnatal acquisition risk with adherence.

Epidemiology

Global and Regional Incidence

Neonatal herpes simplex virus (HSV) infection has a global incidence estimated at approximately 10 cases per 100,000 live births, equating to around 14,000 cases annually worldwide. This figure encompasses infections from both HSV-1 and HSV-2, with the majority resulting from intrapartum transmission, though postnatal and intrauterine routes contribute variably by region. Estimates derive from systematic reviews aggregating surveillance data, , and modeling, revealing underreporting in many areas due to diagnostic challenges and varying case definitions. In the United States, incidence rates are higher than the global average, with recent analyses estimating 15.7 cases per 100,000 hospital births in 2019, based on national inpatient data identifying 561 cases. Broader pediatric references, including the Red Book, approximate the rate at 1 in 2,000 live births, reflecting an increase over prior decades and incorporating both confirmed and probable cases influenced by improved detection. HSV-2 predominates in intrapartum cases (accounting for 50-70%), while HSV-1 is more common in postnatal infections linked to oral shedding. Regionally, rates vary significantly with adult HSV seroprevalence patterns and transmission dynamics. In and , incidences range from 6 to 33 per 100,000 births, with the reporting 6.9 per 100,000 live births during 2019-2021, often lower than continental averages due to surveillance differences. In contrast, lower rates prevail in (1.7 per 100,000) and (2.6 per 100,000), attributed to early-life acquisition of HSV-1 and HSV-2 conferring maternal antibodies that mitigate neonatal transmission risk, despite higher overall adult seroprevalence. HSV-1 drives a larger proportion of postnatal cases in developed regions like , where oral-genital shifts increase genital HSV-1 prevalence, whereas HSV-2 remains tied to sexual transmission patterns in areas with sustained high endemicity. In the United States, the incidence of neonatal herpes simplex virus (HSV) infection has risen notably since the early , with estimates reaching 15.7 cases per 100,000 hospital births in 2019, representing a potential doubling or tripling compared to prior benchmarks around 5 to 7 per 100,000 in earlier datasets like the 2006 Kids' Inpatient Database. This upward trend correlates with epidemiological shifts in maternal HSV-1 infections, as declining childhood acquisition of oral HSV-1 (from 48% seroprevalence in persons aged 14-19 in the to 27% by 2015-2016) leaves more adults susceptible to genital HSV-1 transmission via oral-genital contact, elevating primary maternal infections near term—a key with transmission rates of 30% to 50% versus 1% to 3% for recurrent episodes. Diagnostic and management practices contribute substantially to apparent increases, as expanded guidelines recommend empiric acyclovir for all infants undergoing evaluation for possible HSV (e.g., those with maternal history or nonspecific symptoms), prompting broader testing and surface cultures that identify subclinical or cases previously overlooked, thereby inflating reported incidence without a proportional rise in true . Delays in such are linked to higher mortality (up to 60% untreated), driving protocol adherence that captures milder presentations. Key determinants include evolving sexual behaviors, such as increased lifetime partners and oral-genital practices, which facilitate primary HSV-1 genital acquisition in HSV-naive women, alongside delayed childbearing that may paradoxically heighten vulnerability if it coincides with peak susceptibility windows before seroconversion. HSV-1 predominates over HSV-2 in recent neonatal cases due to its higher per-exposure transmissibility during primary maternal shedding. Advocacy efforts in 2025, including pushes by groups like Herpes Cure Advocacy to the Council of State and Territorial Epidemiologists, seek to designate neonatal HSV as nationally reportable to enable precise tracking beyond the current patchwork (reportable in only seven states as of 2023), addressing underreporting that obscures causal drivers.

Prognosis and Outcomes

Mortality and Morbidity Rates

Prior to the advent of antiviral therapy, neonatal (HSV) infection carried high mortality rates, with approximately 85% of cases involving disseminated disease resulting in death and 50% of (CNS) disease cases proving fatal within the first year of life. In the era of high-dose acyclovir treatment (typically 60 mg/kg/day intravenously for 14-21 days), overall mortality has declined substantially, ranging from 6% to 30% across disease classifications, though disseminated disease retains the highest risk at around 30%, CNS disease at 4%, and skin, eye, and mouth (SEM) disease at 0%. Morbidity among survivors remains significant, particularly in CNS disease, where up to 50% experience neurodevelopmental impairments such as seizures or cognitive deficits attributable to acute or neuronal damage. In disseminated cases, short-term complications include multi-organ failure affecting the liver, lungs, and adrenals, contributing to persistent high morbidity even with treatment. SEM disease, while rarely lethal, involves immediate ocular morbidity in 10-20% of cases, manifesting as or that can lead to vision impairment if not addressed promptly with topical antivirals. Initiation of antiviral therapy within 48 hours of symptom onset causally reduces mortality risk by approximately half compared to delayed treatment, as evidenced by registry data linking earlier intervention to decreased viral dissemination and tissue necrosis. This underscores the critical role of rapid diagnosis via PCR confirmation of HSV in cerebrospinal fluid, blood, or vesicular swabs to enable timely acyclovir administration.

Long-term Sequelae

Survivors of neonatal (HSV) infection, particularly those with (CNS) involvement, face substantial risks of persistent neurologic and developmental deficits despite antiviral treatment. Longitudinal studies indicate that 56-69% of infants with neonatal herpes encephalitis experience long-term neurologic sequelae, including seizures, psychomotor retardation, and learning disabilities. These outcomes stem from viral invasion of the developing , leading to , , and potential latency that disrupts neuronal function over time. Epilepsy develops in a significant proportion of CNS disease survivors, with disorders reported in up to 14-30% of followed cases in small cohorts, often linked to recurrent skin lesions or HSV type 2 infection. Other neurologic impairments include and focal deficits, contributing to overall morbidity rates exceeding 50% in untreated or severe cases. Behavioral and psychiatric issues, such as attention deficits and mood disturbances, may also emerge, potentially tied to chronic viral persistence in the CNS. Cognitive impairments are particularly insidious, manifesting as IQ deficits, speech delays, and even in infants with mild or infections. A 2025 mouse model demonstrated that low-dose, subclinical neonatal HSV exposure results in lifelong CNS viral persistence and cognitive decline, with deficits in and learning observable in adulthood, suggesting underrecognized human risks beyond overt . Human neuropsychologic assessments corroborate broader impacts on and , though limited cohort sizes hinder precise prevalence estimates. Empirical gaps persist due to incidence and challenges in long-term tracking, but emerging animal data underscore a potentially underappreciated lifelong CNS burden, emphasizing the need for vigilant neurodevelopmental monitoring in all exposed neonates.

Historical Context and Controversies

Discovery and Treatment Evolution

Neonatal herpes simplex virus (HSV) infections were first reported in the mid-1930s through histopathological descriptions of disseminated disease in fatal newborn cases, highlighting widespread organ involvement including the liver, adrenals, and . Prior to antiviral therapies, untreated disseminated or (CNS) disease carried mortality rates of 85% or higher, with survivors often experiencing severe neurological impairment due to delayed reliant on , which took days to confirm. Systematic virologic studies in the and early delineated the natural history, establishing intrapartum transmission as predominant and skin lesions as an early site, though progression to disseminated or CNS forms occurred in up to 70% of cases without intervention. The introduction of intravenous vidarabine in the late 1970s marked the first effective antiviral, reducing mortality in disseminated disease from approximately 57% to lower rates, but its toxicity and cumbersome administration limited adoption. Acyclovir, approved for HSV infections in 1982, revolutionized management following multicenter randomized controlled in the and early demonstrating its superior and profile over vidarabine; a blinded of 100 neonates showed equivalent overall survival but better outcomes in acyclovir-treated CNS disease cases, with fewer adverse events. High-dose acyclovir (60 mg/kg/day) became standard by the early 2000s, further lowering mortality to 6% for CNS disease and 29% for disseminated forms in treated cohorts. Diagnostic advances in the 1990s included (PCR) assays for HSV DNA detection in and , enabling same-day confirmation with sensitivity exceeding 95% compared to culture's 50-70%, thus reducing treatment delays from empiric starts. Key epidemiological insights from 1990s studies, such as a 1991 New England Journal of Medicine analysis of over 40,000 deliveries, linked fetal use to a sixfold increased transmission risk via cutaneous during asymptomatic maternal shedding, prompting procedural cautions. By the , suppressive oral acyclovir post-acute (300 mg/m²/day for 6 months) improved neurodevelopmental outcomes in CNS-involved survivors, as evidenced by a randomized showing reduced recurrences and better Bayley scores at age 12 months. The ' 2024 Red Book updates expanded empirical acyclovir initiation and comprehensive evaluation (including PCR on blood, CSF, and surface swabs) to all neonates born after maternal HSV history or suspicious lesions, reflecting heightened vigilance amid stable but persistent incidence.

Debates on Transmission Risks and Cultural Practices

A significant centers on postnatal transmission of type 1 (HSV-1) through metzitzah b'peh, a practice in some Orthodox Jewish communities involving direct oral suction of blood from the circumcision wound by the . Between 2006 and 2011 in , 11 laboratory-confirmed cases of neonatal HSV-1 infection occurred in male infants following this ritual, with an estimated infection rate of 24.4 per 100,000 circumcisions involving direct orogenital contact—3.4 times higher than circumcisions without it. Health authorities, including the CDC and New York City Department of Health, have documented severe outcomes, including hospitalizations and at least two infant deaths linked to such transmissions since 2000, attributing them to HSV-1 carriage in the mohel's oropharynx. Proponents of the unaltered ritual emphasize religious and low absolute , arguing that alternatives like glass tubes dilute spiritual efficacy without eliminating all transmission potential from other postnatal contacts. Critics, prioritizing of avoidable iatrogenic , advocate for mandatory , mohel testing, or bans on direct suction, citing causal chains from oral HSV shedding to neonatal dissemination via mucosal contact. Policy responses vary: New York City requires parental consent forms disclosing risks, but enforcement challenges persist due to community resistance and underreporting in insular groups, highlighting tensions between cultural autonomy and grounded in verifiable morbidity data. Circumcision itself shows protective effects against HSV-2 acquisition in males, with randomized controlled trials in reporting 28-34% reductions in incidence among heterosexual men, potentially via reduced viral entry sites on the . A of such trials confirms statistically significant albeit modest overall risk reduction ( 0.88 for prevalent ). However, these benefits pertain to medical or indirect-suction procedures; debates underscore how metzitzah b'peh introduces orthogonal postnatal risks that outweigh indirect preventive gains, as HSV-1 neonatal cases from rituals differ mechanistically from maternal genital HSV-2 transmission. Antenatal HSV screening policies provoke contention over balancing transmission prevention against diagnostic limitations and economic burdens. The U.S. Preventive Services recommends against routine serologic screening in pregnant women, citing insufficient evidence of reduced neonatal herpes incidence despite identifying subclinical cases, compounded by false negatives from testing before or asymptomatic shedding. Cost-effectiveness analyses indicate universal screening with suppressive therapy yields minimal QALY gains relative to costs—e.g., $8.6 million for 16.8 fewer cases in one model—favoring targeted approaches for symptomatic women or those with infected partners. Some analyses question overemphasis on screening amid behavioral drivers of maternal seroprevalence, such as multiple lifetime partners correlating with HSV-2 acquisition ( up to 50% in high-risk groups), advocating primary behavioral interventions over resource-intensive testing with imperfect sensitivity.

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