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Journal of
eISSN: 2373-4396

Cardiology & Current Research

Case Report Volume 4 Issue 1

Congenital Cytomegalovirus (Cmv) Infection and Ascending Aorta Dilation

Tapas Mondal

Department of Pediatrics, McMaster University, Canada

Correspondence: Tapas Mondal, Associate Professor Pediatrics, division of Cardiology, McMaster University, 1200 Main Street West, room number 3A54 , L8N3Z5 Hamilton, Ontario, Canada, Tel 9055212100, Fax 9055211703

Received: November 14, 2015 | Published: November 23, 2015

Citation: Khan R, Ranganathan M, Mondal T (2015) Congenital Cytomegalovirus (Cmv) Infection and Ascending Aorta Dilation. J Cardiol Curr Res 4(1): 00130. DOI: 10.15406/jccr.2015.04.00130

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Abstract

Cytomegalovirus is the most frequent congenital infection worldwide and is diverse in its clinical manifestations. We report here a newborn baby who had congenital cytomegalovirus infection and was also found to have aortic root dilatation on echocardiography. We have noted 2 babies diagnosed with congenital CMV with incidental finding ascending aorta dilation, which completely resolved after adequate Ganciclovir treatment in one baby. Vertically transmitted HIV disease is known to cause arteriopathy and mild nonprogressive aortic root dilation in children between 2-9 years of age, associated with increased serum HIV levels and lower CD4 counts [1]. Ascending aorta dilation was a coincidental finding in these two newborns with congenital CMV disease, appearing at the time of birth and resolving by the end of 6 weeks Gangciclovir treatment, We hypothesize that there is an association between Congenital CMV infection and dilatation of the ascending aorta.

Keywords: Ascending aorta dilatation; Cytomegalovirus; Congenital CMV infection and ascending aorta dilation

Abbreviations

CMV: Cytomegalovirus; HIV: Human Immunodeficiency Virus; VDRL: Venereal Disease Research Laboratories; IUGR: Intrauterine Growth Retardation; PCR: Polymerase Chain Reaction; NICU: Neonatal Intensive Care Unit; IVIG: Intravenous Immunoglobulin; PDA: Patent Ductusarteriosus; LV: Left Ventricle; LVEDD: Left Ventricular End Diastolic Dimension

Introduction

We present a case report on two neonates with congenital CMV and aortic dilation reversible after treatment with Gangciclovir Aortic dilation was a coincidental finding in these two newborns with multisystem involvement congenital CMV disease, appearing at the time of birth and resolving by the end of 6 weeks treatment period after standard dosing of Valganciclovir, as seen in both our cases. We hypothesize that there is an association between Congenital CMV infection and dilation of the ascending aorta. Further research needs to be done to validate this association and the possible etiology as well as propose guidelines for long-term echocardiographic follow-up in survivors of congenital CMV disease. This is a novel report as we discovered after an extensive literature review, that the association between congenital CMV and aortic root dilation has not been previously published.

Case Presentation

Case 1

Baby boy A was born at 38 weeks gestational age to a 20 year old gravid mom. Pregnancy was uneventful. Mom was HIV negative, VDRL negative, HBsAg negative, Rubella immune and group B streptococcus positive. There was spontaneous onset of labour with rupture of membranes. He was delivered vaginally with Apgar scores of 4, 4 and 6 at 1, 5 and 10 minutes respectively. He had no respiratory effort and was intubated. Birth weight was 3.16 kg (50th percentile) and head circumference was 35 cm (75th percentile). His size was appropriate for gestational age. Physical examination revealed jaundice, generalized petechiae and large hepatosplenomegaly. He was immediately started on intravenous antibiotics following a full septic workup. Laboratory investigations revealed a platelet count of 46,000, Urine culture was positive for Cytomegalovirus. Chest X-Ray/Abdomen X-Ray revealed small right sided pleural effusion, hepatomegaly 7.8 cm and splenomegaly 8.8 cm. Ultrasound of the head revealed calcification in the basal ganglia bilaterally and a 9*9*7 mm cyst in the left temporal lobe adjacent to the temporal horn of the left lateral ventricle. Ophthalmology exam revealed bilateral retinal hemorrhages, but no chorioretinitis. Placental pathology showed features of chronic villitis with presence of plasma cells. Immunostaining in placental tissue was positive for CMV in 4 cells, but negative for Ebsteinbarr virus/ parvovirus/herpes virus 1 and 2 and toxoplasma. With findings suggestive of Congenital CMV infection, baby boy A was started on intravenous Gancyclovir. He was extubated on day 3 of life to low flow oxygen initially and then to room air. Antibiotics were discontinued after 48 hrs of negative blood cultures. He was noted to have a murmur on physical exam. Echocardiogram revealed dilated ascending aorta with normal measurements of aortic valve annulus, aortic sinus and sinotubular junction. The supravalvular aorta was dilated (Z score 3.64, absolute measurement of 1.2 cm), with maximum dilation seen at the level of the ascending aorta (Z score 6). It was a normal aortic valve, baby had good biventricular function with no LV dilation. There was no flow acceleration across the trileaflet aortic valve. The baby had normal hemoglobin and was not tachycardiac or febrile at the time of the Echocardiogram (Figure 1). A follow up echocardiogram done at 6 months of age revealed partial resolution of the dilation of the supravalvular aorta 1.37 cm (Z score 2.72), ascending aorta 1.16 cm (Z score 2.29).

Figure 1: Echocardiogram.

Case 2

Baby Girl B was born at 30 weeks gestational age to a 32 year old Gravida 4 mother. It was an uneventful pregnancy with maternal HIV, VDRL, Hepatitis B negative, Rubella Immune and Group B streptococcus not done due to early gestational age. Mum noted reduced fetal movements and non stress test was atypical with minimal beat to beat variability, suggesting significant fetal distress with no ultrasound evidence of hydrops. Baby was delivered by emergency Cesarean section after 2 adequate doses of antenatal Steroids. Baby had no initial respiratory efforts required stimulation and PPV for 5 minutes at 100% oxygen which was rapidly weaned off toroomair. Apgar scores were 7,8. At 1 minute and 5 minute respectively. She was noted to have symmetric IUGR with both weight and head circumference less than 3rd centile (weight 1060 grams and occipito frontal circumference 25 cm).

Post natal events: Baby developed conjugated hyper bilirubinemia and neonatal hepatitis. Shehad persistant thrombocytopenia unresponsive to platelet transfusion (with generalised petechia baby received IVIG and daily platelet transfusions. Baby had normal hematocrit and hemoglobin levels, didnot require transfusions and remained hemodynamically stable. Urine CMV was positive at birth and placental histology and PCR was consistent with CMV infection. Parents refused lumbar puncture and CSF evaluation. Initial transfontanelle ultrasound showed bilateral grade 3 intraventricular hemorrhages with cystic changes suggestive of intrauterine bleed, no intracranial calcifications were seen. Baby had RDS (Respiratory distress syndrome) treated with CPAP till day 7 of life. She was found to have a moderate sized patent ductus arteriosus (PDA). Initial Echocardiogram the heart was structurally and functionally normal with minimal LV dilation. She was treated with indomethacin as per our NICU protocol for PDA closure, subsequent Echocardiogram showed closure of PDA, dilated ascending aorta (7.8 mm) with z score of 4.6, the ascending aorta was dilated upto the isthmus which measured 5.3 mm ( z score 2.9), there was no evidence to suggest LV volume overload with normal LVEDD. There was no flow acceleration across the normal trileaflet aortic valve. Baby was started on IV Gangciclovir on day 4 of life for 2 weeks followed by oral Valganciclovir for additional 4 weeks after consultation with our infectious disease team. Repeat Echocardiogram towards the end of the treatment regimen was completely normal with resolution of aortic dilation.

Discussion

Aortic root dilatation has been associated with: Bicuspid Aortic valve, 22q11.2 deletion [2], Marfan’s syndrome [3], Ehler-Danlos syndrome [4], Turner syndrome [5], Noonan’s syndrome [6], Post repair of Tetralogy of Fallot [7], Syphilis, Ankylosing spondylitis [8], Hypertension and advanced age [9]. Cytomegalovirus is a beta herpes virus with a double stranded DNA. CMV is the most frequent congenital infection worldwide and is diverse in its clinical manifestations. Congenital CMV infection occurs in approximately 0.2 to 2.5% of all live births [10]. 10% of infants born with Congenital CMV infection show signs and symptoms at birth [11], the remaining 90% remain asymptomatic. The clinical features most commonly seen include petechiae/purpura, hepatosplenomegaly, jaundice, blueberry muffin spots, small for gestational age, microcephaly and periventricular calcifications [10]. Other manifestations include seizures, intracranial hemorrhage, hydrocephalus, hypotonia, chorioretinitis, poor suck, high arched palate, sensorineural hearing loss, inguinal hernia, clubfoot, pneumonia, hepatitis and osteitis [10]. There are no reports of cardiac structural abnormalities with Congenital CMV infection. The patients presented in our report have significant aortic root dilatation as evident by a Z score of 6.4. Repeat echocardiogram done at 6 months of age showed significant resolution of the Aortic root dilatation post therapy. This is not associated with changes in the LVEDD (left ventricular end diastolic diameter) suggesting volume overload caused by anemia or stress. In children with sickle cell anemia, increased left ventricular and aortic root dimensions have been reported to correlate well with hemoglobin levels [12]. Examination and laboratory workup have ruled out other common causes of Aortic root and ascending aorta dilatation. Possible postulated causes for aortic root dilation in newborn clinically unwell with CMV disease include the following:

  1. Stress modulated growth [13-15].
  2. Direct infection of the ascending aorta.
  3. Systemic cytokine or lymphokine mediated alteration of the aortic root and ascending aorta
  4. Central immune dysregulation as seen in other forms of immune mediated arteritis like ankylosing spondylitis and Takayasu’s arteritis and Kawasaki’s disease [16-18] (List modified from Lai et al. [1]).

Aortic dilation was a coincidental finding in two newborns with multisystem involvement congenital CMV disease, appearing at the time of birth and resolving by the end of 6 weeks treatment period, as seen in both our cases. We hypothesize that there is an association between Congenital CMV infection and dilation of the ascending aorta. Further research needs to be done to validate this association and the possible etiology as well as propose guidelines for long-term echocardiographic follow-up in survivors of congenital CMV disease.

Acknowledgement

Dr. Rubeena Khan and Meenatchi Ranganathan compiled the report, Dr. Tapas Mondal provided access to the clinical information, provided expert advice and edited the report.

References

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