Healthcare | Free Full-Text | Vein of Galen Aneurysmal Malformation: A Case Report
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2. Case Report
A term male infant presented for review at a tertiary neonatal centre at 18 h of age. He had been delivered cephalically at home to a 29-year-old primigravida mother following an uncomplicated pregnancy. The maternal blood group was O negative, with anti-D given appropriately. Ultrasounds at 12 and 20 weeks were normal. Group B streptococcus testing was not performed. Delivery followed spontaneous onset of labour at 40 weeks, with clear liquor and no prolonged rupture of membranes. A midwife attended the planned delivery at home. Apgar scores were 4, 5, and 8 at 1, 5, and 10 min of age, respectively. Intermittent positive pressure ventilation was given for three minutes after delivery. Birth weight was 3760 g (57th percentile), length was 54 cm (88th percentile), and head circumference was 38.2 cm (98th percentile).
On examination at 18 h of age, the infant was mottled and had subcostal and intercostal recession. Pre-ductal oxygen saturation was 88%, with a respiratory rate of 70 breaths per minute. He was afebrile and normotensive, with a normal cardiovascular examination. Breath sounds were audible bilaterally. The abdominal examination was unremarkable. The tone was normal, and the infant was not encephalopathic.
Full blood count, electrolytes, and inflammatory markers were normal on admission. Capillary blood gas showed metabolic acidosis (pH 7.24, pCO2 40, HCO3− 16.1 mmol/L, base excess −10.3, lactate 3.4 mmol/L). Chest X-ray showed cardiomegaly with no focal collapse or consolidation (Figure 1). The echocardiogram was normal, apart from a 2.9 mm patent ductus arteriosus with bidirectional flow and mild suprasystemic pulmonary hypertension.
Differential diagnoses were sepsis, perinatal asphyxia, respiratory distress syndrome, and transient tachypnoea of the newborn. Initial management included continuous positive airway pressure (CPAP), oxygen to maintain pre-ductal SaO2 ≥ 95%, antibiotics (benzylpenicillin and gentamicin), and maintenance of intravenous fluids.
The patient’s oxygen requirement resolved within 48 h, but he had ongoing work of breathing requiring CPAP and persistent metabolic acidosis. He developed coagulopathy (INR 3.3, APTT 66 s, PT 37 s), renal impairment (urea 6.8 mmol/L, creatinine 99 µmol/L), and hyponatraemia (Na 126 mmol/L), and became oliguric and oedematous. Blood cultures were negative, but the umbilical swab grew Group B streptococcus. Additional management included intravenous vitamin K, fresh frozen plasma, and a sideline of concentrated sodium chloride. The working diagnosis was perinatal asphyxia given the acidosis and multi-organ dysfunction.
On day 5 of life, the patient deteriorated with severe respiratory distress, poor perfusion, minimal responsiveness, oliguria, and hyponatraemia (Na 117 mmol/L). Examination revealed worsening generalized oedema, ascites, and hepatomegaly. This was attributed to congestive heart failure. Chest X-ray showed worsening cardiomegaly. The patient was managed with intubation and ventilation, fluid restriction, frusemide, bicarbonate correction, and the addition of cefotaxime.
Following the stabilisation of the patient, a cranial ultrasound was performed, which showed a large anechoic structure mainly to the left of the midline posteriorly, with marked internal vascularity and prominent flow in keeping with the vein of Galen aneurysmal malformation (VGAM). The dilated median prosencephalic vein measured 36 × 26 × 29 mm (Figure 2). Clinical examination at this stage revealed cranial bruit, which was missed on admission.
The patient was transferred to a tertiary paediatric hospital for paediatric neurosurgery and intervention radiology assessment, as this service was not available at our hospital. Following the transfer, a brain MRI was performed (Figure 3), and the patient underwent a coiling procedure to embolise the arterial feeders of the VGAM. In total, four coiling procedures were performed over a period of six weeks. Following the second of these, the patient was found to have hydrocephalus and underwent insertion of an external ventricular drain, which was removed after several weeks. Before discharge, an MRI of the brain demonstrated a reduction in the size of the VGAM and arterial collaterals, but also showed ongoing hydrocephalus and small bilateral infarcts in the corona radiata.
The patient was discharged at seven weeks of age. The discharge head circumference was 40.5 cm (63rd percentile). At three months of age, the head circumference was 43.7 cm (90th percentile), and the weight was 5.7 kg (20th percentile). Development was appropriate for the patient’s age, although gross and fine motor scores were in the lower average range. MRI showed a mild progressive increase in the size of the VGAM, along with multiple collaterals and mild progressive dilatation of the ventricles. The patient may require multiple further embolisation procedures, and his prognosis remains uncertain.
3. Discussion
Vein of Galen malformation (VGAM) is a rare type of abnormality that affects the blood vessels within the brain. It develops as a direct arteriovenous fistula between the choroidal or quadrigeminal arteries and an overlying single median venous sac [6]. The venous sac most probably represents the persistence of the embryonic median prosencephalic vein of Markowski, not the vein of Galen, per se [6]. These malformations are rare, representing less than 1% of all intracranial arteriovenous malformations [7].
Antenatally, the diagnosis of VGM is well documented via colour Doppler ultrasonography [7,8] and foetal magnetic resonance (MR) [9].
The most common presentation of VGAM is neonatal high-output cardiac failure, as observed in our patient [10]. Less severe forms of the disease may present later in infancy and childhood, typically with hydrocephalus and macrocephaly, developmental delay, headaches, and/or seizures [11]. In neonates presenting with high-output cardiac failure, persistent pulmonary hypertension is common, and patients often develop multi-organ dysfunction, including myocardial ischaemia, which may worsen cardiac dysfunction. Persistent venous congestion may lead to cerebral atrophy and irreversible brain damage [11].
Most heart failure in the neonatal period is cardiac in origin, most commonly caused by congenital cardiac lesions, and less commonly arrhythmias, myocardial ischaemia, myocarditis, or cardiomyopathy. However, high-output cardiac failure represents another important cause. This is usually due to systemic arteriovenous shunts, including liver lesions (such as rapid involuting congenital haemangioma) and cerebral VGAM.
Foetuses prenatally diagnosed with VGAM have poor outcomes when cardiac or cerebral anomalies are present [12,13]. Conversely, those with isolated VGAM tend to have more favourable outcomes [14].
Management of VGAM should consist of aggressive intensive care management of cardiac failure and fluid status, as well as management of multi-organ dysfunction [2]. The treatment of choice for VGAM now consists of an endovascular approach to selectively occlude feeder vessels with coils or liquid embolic agents, aiming to reduce or eliminate the arteriovenous shunt [11,15]. This is typically achieved via the femoral transarterial route. Several procedures are often required to achieve a significant reduction in shunting [15]. Retrospective studies of patients treated with the endovascular approach report that between 56% and 85% of children are neurologically normal (follow-up period ranging from 6 months to 4 years) [2,14,15]. However, several of these studies included older infants and children in addition to neonates; these reported poorer outcomes in the neonatal group [14,15].
Lasjaunias and colleagues have developed a scale, the “Bicêtre neonatal evaluation score”, which evaluates the gross neurological status and non-neurological manifestations in neonates with VGAM and suggests an approach to treatment based on the patient’s score [14]. Using this system, our patient scored 8 out of 21, which falls into the emergency endovascular intervention category. Other considerations in the decision to treat our patient included the structurally normal appearance of the rest of the brain on MRI and near-normal bedside amplitude-integrated electroencephalogram (aEEG) monitoring.
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