There are two main sources of maternal CMV infection: sexual activity and contact with young children. However, the latter is considered the most important one as the high circulation rate of CMV in infants and children of preschool age puts seronegative pregnant women caring for young children at high risk for CMV infection [6]. Transmission occurs through direct contact with infectious bodily fluids such as saliva and urine; children who excrete CMV may spread infection to a parent and to other adults in the household [6]. CMV educational and hygienic measures have the potential to prevent primary maternal infection. A recent study provides evidence that a primary prevention strategy based on the identification and provision of adequate information to seronegative susceptible pregnant women at risk for primary infection is highly effective in reducing the rate of maternal primary CMV infection and, ultimately, congenital CMV infection. Specifically, women are invited to frequently wash their hands after exposure to young children’s bodily fluids as well as surfaces touched by children (toys, high chair, stroller, etc.), to avoid kissing children on the mouth/cheeks, and not to share utensils, food, drinks, washcloths, etc. The use of gloves and avoidance of sleeping in the same bed were not suggested.

Recent onset of sexual activity (last 2 years) in young women increases the risk for congenital CMV infection in their offspring; this finding suggests that recent sexual exposure to CMV may have occurred in the months or years before conception and also during pregnancy. The risk for congenital CMV infection remains elevated even when primary maternal infection occurs months before conception so it is preferable to wait at least 6 months after primary CMV infection before pregnancy. Another important aspect to underline is the relation between sexually transmitted infections during pregnancy (such as gonorrhea, chlamydia, genital warts, syphilis, and trichomoniasis) and primary CMV infection that could enhance the transmission of CMV from mother to fetus. In addition, because of the possibility of CMV transmission through sexual intercourse, pregnant women should be urged to adopt safe sexual practices if they are not engaged in a mutually faithful monogamous relationship.

Numerous reports have analyzed how to prevent primary maternal infection, and they have shown that CMV educational and hygienic measures have this prevention potential. In the first time, woman seronegative should be informed about CMV and prevention measures and hygiene recommendations to be adopted [8].

Future prospectives are based on development of an effective vaccine for prevention of CMV infection that could be of high epidemiological impact in this regard.

The first step in the prenatal diagnosis of congenital CMV infection is determination of maternal primary and secondary infection by serological testing (Fig. 20.2).

In women with a proven or highly suspected, recent primary CMV infection, the second step is to propose the diagnosis of fetal infection by noninvasive (ultrasound examination) and invasive (amniocentesis) prenatal tests [9].

Congenital CMV occurs transplacentally and may result in symptomatic or asymptomatic infection in the neonate.

Diagnosis in the neonate is made by viral detection in body fluids via PCR, culture, or antigen testing (pp65 antigen) within the first 3 weeks of life. The finding of CMV antibodies or viral DNA after this point makes congenital versus postnatally acquired infection (from cervical secretions, breastfeeding, or blood products) difficult to distinguish. Antibody titers cannot reliably make the diagnosis as maternal CMV IgG crosses the placenta, and neonates mount weak IgM responses. The preferred specimens are saliva and urine as newborns shed high levels of the virus from these fluids. Thus far, urine has been considered the gold standard [15].

However, difficulties in urine collection documented in some studies have led to a suggestion that saliva analysis may represent an easier, more practical, and less expensive approach, so some propose that saliva PCR should be considered the investigation of choice, although it is susceptible to contamination by maternal milk [10].

After the evidence of the infection of fetuses, the main issue is to predict which of them will be symptomatic at birth or later in life. A symptomatic infection was defined as the presence of an abnormal ultrasound and/or magnetic resonance imaging findings and/or histopathological findings of disseminated infection for fetuses terminated or dead in utero or as the presence of clinical symptoms up to 6 months of age for delivered newborns [23]. A lot of studies have shown that a single test or examination cannot predict the collective events that might lead to permanent damage. Although the role of ultrasound examination in predicting the presence of symptoms at birth has been emphasized by some authors, this has been questioned by other groups who find an ultrasound sensitivity of only 21 % in predicting symptomatic newborns.

New approaches have been proposed based on CMV DNA quantification in amniotic fluid or combined assessment of ultrasound findings and prognostic markers evaluated in the fetal blood.

Approximately 10 % of the infants born with congenital CMV infection have signs and symptoms at birth. Only half of these symptomatic infants have disseminated multiorgan involvement named cytomegalic inclusion disease (CID). Other infants have mild or subclinical manifestations of the disease [24]. In the typical form of CID, many organs are involved, mainly the reticuloendothelial system and the CNS. The main clinical abnormalities observed are hepatomegaly, splenomegaly, microcephaly, jaundice, petechiae, hypotonia/lethargy, or seizures. Elevated alanine aminotransferase, conjugated hyperbilirubinemia, and thrombocytopenia are the main laboratory abnormalities. Other manifestations occasionally present in symptomatic newborns include pneumonitis, dental defects, ocular defects (chorioretinitis, strabismus and optic atrophy, cataracts, microphthalmos, necrosis, calcifications, blindness, anterior chamber and optic disk malformations, and papillary membrane vestiges), and hearing loss, intrauterine growth retardation (IUGR), and prematurity (Fig. 20.3). Overall, in this symptomatic subgroup of congenitally infected infants, the mortality rate is around 15–30 %. Death is often due to multiorgan involvement with severe hepatic dysfunction, bleeding, disseminated intravascular coagulation, and secondary bacterial infection. In this condition, death mainly occurs in the first weeks of life. Around 90 % of the symptomatic infected newborns who survive will develop some degree of disability including psychomotor retardation usually associated with microcephaly and other neurological impairments, SNHL, visual impairment, and expressive language delays [25].

At the other extreme of the spectrum of CMV congenital infection are the asymptomatic forms of the disease. Without any systematic screening policy at birth, these infected newborns are most frequently left undiagnosed. Approximately 15 % of asymptomatic children will develop some degree of hearing loss following congenital CMV infection. Globally, CMV causes around 10 % of congenital SNHL, his deficit may be present at birth or develop later in childhood usually during the first year of life, with a great variability in the severity range. Development of new diagnostic tools such as dried blood spots (DNA detection in Guthrie cards) helps to retrospectively attribute SNHL to congenital CMV infection [26].

The possibility to treat CMV infection is limited due to toxicity of drugs available. After ultrasound detection of fetus abnormalities and confirmation of the primary CMV infection in the mother and fetus (by amniocentesis), the only “therapeutic” option available to avoid the birth of a severely damaged infant is to terminate pregnancy [27, 28]. Many studies have been done to investigate how it is possible to prevent and treat fetal infection.

In particular, several studies have been developed to analyze the possibility to administrate human immunoglobulins with a double role: prophylactic and therapeutic. Before analyzing which are the actual approach with immunoglobulin, it’s important to explain the function of maternal immune system to protect the fetus. An important aspect to be analyzed is the role of maternal immune system to prevent virus transfer across the decidual-placental interface. Recent report suggests that CMV utilizes the fetal Fc receptor for its passage across the placenta. Physiologically, these receptors are used to transport maternal IgG from the intervillous space to the syncytiotrophoblast. In this way, IgG antibodies seem to have a protective role with regard to vertical transmission rates [4]. Due to their mechanism of action, CMV-specific immunoglobulins could be useful for the prevention of congenital CMV infection following primary CMV infection. In the absence of maternal CMV-specific antibodies, the administration of human cytomegalovirus immunoglobulins is thought to prevent the transmission of CMV from the mother with no specific immunity against CMV to the fetus. These immunoglobulins, known as hyperimmune globulins (HIG), are drawn only from selected donors with high-titer IgG antibodies after CMV infection. Therefore immunoglobulins could reduce the viral load and could thus decrease the probability of severe fetal disabilities. Besides infection of the fetus, active CMV infection of the pregnant women can also lead to impairment of placental function – which may be followed by spontaneous abortion (mainly at the beginning of pregnancy) or restriction of fetal growth [20]. In fact, it seems that the partial reduction in placental size after treatment with HIG provides further evidence that treatment with HIG could resolve fetal disease by neutralizing virus and reducing placental inflammation and insufficiency. The placenta is likely to be one site of action of HIG, and many of the manifestations of congenital CMV infection at birth, including intrauterine growth restriction or neurological damage, may be due to placental insufficiency. CMV modifies maternal immunity through an inflammatory process leading to abortion or immune-mediated disease, most commonly in the brain resulting from neurotoxicity of overexpressed cytokines [29]. Since an efficacious vaccine for CMV disease is still lacking, immunoglobulins are used to treat a large number of transplant patients. Currently, the only approved indication for cytomegalovirus hyperimmune globulins (CMV-HIG) in Europe is for patients who have undergone solid organ transplantation to prevent CMV reactivation and reinfection [30]. Although CMV-HIG are not approved for the prevention or therapy of congenital CMV infections, some authors have used this therapeutic option as so-called “off-label” mode, and results are very questionable, mainly because of the lack of serious large randomized controlled studies (Tables 20.1 and 20.2).

Some studies on HIG administration suggest that there is a possible association between the treatment and both birth weight and duration of pregnancy; CMV may also cause low birth weight due to placental dysfunction with intrauterine hypoxia and malnutrition, even in asymptomatic infants [31]. Multiple doses of HIG seem to improve features of placenta and are correlated with both increasing birth weight and longer gestation, but only for infants born asymptomatic.

Finally, a recent randomized placebo-controlled trial of virus-specific hyperimmune globulin [32] has showed no significant reduction in the rate of transmission of CMV infection among women receiving hyperimmune globulin as compared with women receiving placebo. Moreover, from the cost-effectiveness point of view, results of that trial (related to reduction of vertical infection) are less than the threshold identified as the optimum for a screening program and treatment of primary maternal infection in pregnancy (CHIP study 2014).

Another therapeutic option recently proposed (always “off label”) is standard intravenous immunoglobulins (IVIG), obtained from unselected donor pools, including a varying proportion of donors previously exposed to CMV that seems to be a less expensive alternative to HIG [33].

Such experience has started since 2010 at the Infectious Disease Unit of Pescara General Hospital, Italy, and it is based on the monthly infusion of IVIG (0.5 g/kg of body weight). CMV IgG and IgM antibodies and IgG avidity indexes are assayed both before and after each IVIG infusion. Preliminary evaluation demonstrates that infusion of IVIG in woman with primary CMV infection significantly increases CMV IgG titers and avidity indexes on blood samples. Moreover, several study have suggested a possible efficacy of HIG administered either to the mother or the foetus in cases of proven foetal infection, in reducing the frequency and severity of foetal and newborn sequelae.

Finally, in a very recent study by Leruez-Ville et al. [34], experimental use of valacyclovir for pregnant women infected by CMV has been proposed. It is a multicenter open-label phase 2 study with one arm. The aim of this study was to evaluate the efficacy of oral valacyclovir, 8 g daily, for pregnant women carrying a symptomatic cytomegalovirus-infected fetus, defined by the presence of measurable extracerebral or mild cerebral ultrasound symptoms. Although results of this study indicate that high-dosage valacyclovir given in pregnancy is effective for improving the outcome of moderately symptomatic infected fetuses, it is not a randomized controlled trial. Other trials might be made in the future to improve the knowledge about new emerging and more potent anti-cytomegalovirus drugs that have not currently been tested in pregnancy.

Infection occurs worldwide and the percentage of seropositive persons ranges from 5 % to 90 % [35]. These extreme variations are due to the different level of both exposure to the main sources of infection and hygienic standards between geographic areas. The sources of infection are ubiquitous.

Symptomatic infections usually cause a mononucleosis-like illness with low-grade fever, malaise, headache, and cervical lymphadenopathy. Other manifestations such as encephalitis, myocarditis, hepatitis, and pneumonia can rarely complicate acute disease. Primary infection in pregnant women, when is transmitted transplacentally, can cause congenital toxoplasmosis. Congenital toxoplasmosis can then lead to a wide array of manifestations, ranging from mild chorioretinitis, which can present many years after birth, to miscarriage, mental retardation, microcephaly, hydrocephalus, and seizures.

Prenatal care must include education about the prevention of toxoplasmosis infection in seronegative pregnant women, who – along with their primary care physicians and obstetricians – need to be informed about the risk factors for toxoplasmosis in order to lower the risk of congenital infection.