AgrawalAmit_Giant


 

 

 

 

 
122         Agrawal et al          Giant high occipital encephalocele 

 

 

 

 

 

 

 

Giant high occipital encephalocele 

Amit Agrawal1, Umamaheshwara Reddy V.2, Kishor V. Hegde2,  

Suneetha P.2, Divya Siddharth Kolikipudi2 

Narayana Medical College Hospital, Chinthareddypalem, Nellore, Andhra Pradesh (India) 
1Department of Neurosurgery; 2Department of Radiology  

 
Abstract: Encephaloceles are rare embryological mesenchymal developmental 

anomalies resulting from inappropriate ossification in skull through with herniation of 

intracranial contents of the sac. Encephaloceles are classified based on location of the 

osseous defect and contents of sac. Convexity encephalocele with osseous defect in 

occipital bone is called occipital encephalocele. Giant occipital encephaloceles can be 

sometimes larger than the size of baby skull itself and they pose a great surgical challenge. 

Occipital encephaloceles (OE) are further classified as high OE when defect is only in 

occipital bone above the foramen magnum, low OE when involving occipital bone and 

foramen magnum and occipito-cervical when there involvement of occipital bone, 

foramen magnum and posterior upper neural arches. Chiari III malformation can be 

associated with high or low occipital encephaloceles. Pre-operatively, it is essential to 

know the size of the sac, contents of the sac, relation to the adjacent structures, presence 

or absence of venous sinuses/vascular structures and osseous defect size. Sometimes it 

becomes imperative to perform both CT and MRI for the necessary information. Volume 

rendered CT images can depict the relation of osseous defect to foramen magnum and 

provide information about upper neural arches which is necessary in classifying these 

lesions. 

Key words: Giant encephalocele, high occipital encephalocele, occipital encephalocele, 

meningocele, cephalocele, posterior encephalocele 

 
Introduction 

Encephaloceles are rare embryological 

mesenchymal developmental anomalies 

resulting from inappropriate ossification 

defect in skull through with herniation of 

intracranial contents. (1-4) Nomenclature is 

mainly based on location and the contents of 

the herniated sac. When meninges alone are 

the content they are meningoceles, when brain 

tissue along with meninges is the content of 

herniation it is called meningoencephalocele 

or encephalocele and occasionally they may 

include a ventricle then they are called as 

hydroencephaloceles. (3, 4) Dural sinuses as 



 

 

 

 

 
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contents of encephalocele are also seen 

infrequently. (3, 4) Atretic encephaloceles 

contain fibrous tissue within the sac and 

sometimes intracranial communication may 

not be present. (5) Encephaloceles cause severe 

morbidity and mortality if untreated. Occipital 

encephalocele (OE) is posterior encephalocele 

which is a result of herniation of intracranial 

contents through occipital bone defect with or 

without associated foramen magnum and 

upper cervical vertebral defects. (1, 2, 6-8) 

Giant occipital encephaloceles (GOE) because 

of their size they are a neurosurgical challenge. 

(1) Herein we report a 40 day old female child 

who presented to us with giant high occipital 

encephalocele and imaging played a decisive 

role in providing preoperative information. 

Case report 

A 40 days old female child was brought to 

pediatric outpatient department with 

complaints of swelling over back of head since 

birth.  The mother due to her poor socio-

economic status did not have regular antenatal 

checkups and antenatal ultrasound. Baby was 

delivered through caesarian section, as there 

was delay in head fixation after onset of labor 

pains. Baby cried immediately after birth. 

Large occipital swelling was noticed at birth 

and APGAR score was 10. There was no h/o 

similar births in family. On examination, there 

was a single large gray colored round shaped 8 

x 8 cm swelling at occipital region of head. Skin 

over the swelling was normal. All the scalp 

veins were dilated.  The swelling was 

compressible & baby cried on compression of 

the swelling. Transillumination test was 

positive with dark areas showing reduced 

transillumination.  Child did not have any 

other associated abnormalities. Routine 

investigations were normal except for 

persistent elevation of serum potassium levels 

(Serum potassium- 6.2 meq/L, Na-136 meq/L, 

Cl: 94 meq/L, Urea 14.8 mg/dl and creatinine: 

0.56 mg/dl.). CT scan was advised which 

showed high occipital bony defect with 

herniation of meninges and posterior fossa 

contents (Figures 1, 2). Surface rendered and 

volume rendered images showed detail of 

giant occipital encephalocele, size of osseous 

defect, and relation to foramen magnum. 

(Figure 3). MRI showed details of total 

herniation of cerebellum, occipital horn of 

lateral ventricle and part of mid brain (Figures 

4, 5). There was no associated chiari 

malformation. Diagnosis of high occipital 

encephalocele was made. The child underwent 

complete surgical excision and repair of the 

meningocoele and doing well at follow up. 
 

 
Figure 1 - Axial CT scan images brain window (A) 

and soft tissue windowing (B) showing larger 

posterior fossa defect, with herniation of brain tissue 

and meninges 



 

 

 

 

 
124         Agrawal et al          Giant high occipital encephalocele 

 

 

 

 

 

 

 

 
Figure 2 - Saggital reconstructed CT scan images 

showing herniation of posterior fossa structures 

through the defect 
 

 
Figure 3 - Surface rendered images (A) showing the 

cyst size, volume rendered images of skull (B) 

showing the size of  osseous defect (white arrows) in 

relation to foramen magnum (arrow heads) 
 

 
Figure 4 - T1 (A, B) and T2 weighted axial images 

(C) of MRI showing dysmorphic cerebellar tissue, 

fourth ventriclular contents and meninges herniated 

through the defect, also note stretching of tectum 
 

 
Figure 5 - T1 (A) and T2 (B, C) weighted axial 

images showing the herniation of posterior fossa 

structures and beaking of the tectum 

Discussion 

Encephaloceles are identified and classified 

based on the location of the osseous skull 

defect. When defect is located in 

frontoethmoidal, nasofrontal, nasoethmoidal, 

naso-orbital, interfrontal regions it is called as 

sincipital encephalocele. (3) Convexity 

encephaloceles have osseous defect located in 

parietal, occipital, occipital-cervical regions 

and finally basal encephaloceles have defect in 

the skull base. (3) Incidence of encephaloceles 

is 0.8 - 3.0 per 10,000 live births and varies 

based on geological location and race. (3, 6) 

However with improvement of antenatal 

detection of these lesions, incidence has 

decreased significantly in recent times. (4)  

Associated anomalies (microcephaly, chiari III 

malformation, craniosynostosis, and 

syringomelia and neural tube defects are seen 

in approximately 20% of children. (3, 4) 

Anterior encephaloceles are more common 

than posterior ones in Asian continent. (3) OE 

are further classified as high OE when defect is 

only in occipital bone above the foramen 

magnum, low OE when involving occipital 

bone and foramen magnum and occipito-

cervical when there involvement of occipital 

bone, foramen magnum and posterior upper 

neural arches. Chiari III malformation can be 

associated with high or low occipital 

encephaloceles. (9) The size of occipital OE 

may vary from small to giant masses. (1, 6) 

Giant encephaloceles can be some times larger 

than size of baby skull and because of their 

enormous size pose a great surgical challenge. 

(1) OE are normally covered by healthy skin or 

abnormal skin, sometimes only a thin 



 

 

 

 

 
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meningeal membrane may be covering the 

OE. (10) Contents within the herniated sac are 

variable. (1, 6) Ultrasound and doppler are 

cheap readily available tools for knowing 

contents of sac; however MRI may be required 

to know contents of sac in detail. CT is mainly 

used to assess the size of the osseous defect. (3, 

4) Conservative approach for encephalocele is 

not advised as many complications such as 

infection, trauma, and hydrocephalus can 

worsen the clinical scenario. (3, 6, 8) Amount 

of viable brain tissue, size of the OE, skin 

covering and associated congenital anomalies 

should be considered in planning surgery. 

Repair of OE without active CSF leak or 

overlying skin necrosis should be an elective 

procedure and be done without delay. 

Anaesthetic support is extremely important 

while operating OE, endotracheal intubation is 

real challenge in these patients and it should be 

done in right or left lateral position based on 

individual anaesthetist expertise. (11, 12) In 

general dysplastic brain tissue and meninges 

should be excised preserving the vascular 

structures. Attempts should be made to 

preserve normal brain parenchyma and 

ventricles by expansion cranioplasty and 

ventricular reduction. Reconstructive 

surgeries like skin flap rotation should be 

performed when there is inadequate skin for 

primary closure. (1-3, 6) Great importance 

should be given for two-layered watertight 

closure. (6) Osteogenic properties of dura can 

reduce the bony defect obviating the need for 

cranioplasty. Titanium mesh closure of defect 

can also be tried. (3) Surgical outcome is 

generally good independent of size depending 

upon amount of neural tissue. Even giant OE 

with less neural tissue have excellent 

prognosis. (1, 4, 6, 8) However in giant OE due 

to the removal of abundant CSF volume, 

electrolyte imbalances can occur which should 

be corrected peri-operatively. Amount of 

normal viable brain tissue after surgery also is 

important in assessing the prognosis. 

Conclusion 

Giant high occipital encephaloceles are 

rare congenital lesions. Diagnosis can be made 

soon after birth by clinical examination and 

because of their enormous size they pose a 

great surgical challenge. Elective surgical 

repair can be performed as early as possible. 

Pre-operatively it is essential to know the size 

of the sac, contents of the sac, relation to the 

adjacent structures, presence or absence of 

venous sinuses/vascular structures and 

osseous defect size. Sometimes it becomes 

imperative to perform both CT and MRI for 

the necessary information. Volume rendered 

CT images can depict relation of osseous 

defect to foramen magnum and information 

about upper neural arches which is necessary 

in classifying these lesions. 
 

Correspondence 

Dr. Amit Agrawal 

Professor of Neurosurgery 

Department of Neurosurgery 

Narayana Medical College Hospital 

Chinthareddypalem 

Nellore-524003 

Andhra Pradesh (India) 

Email: dramitagrawal@gmail.com 

dramit_in@yahoo.com 

Mobile: +91-8096410032 



 

 

 

 

 
126         Agrawal et al          Giant high occipital encephalocele 

 

 

 

 

 

 

 

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