Vol.:(0123456789)1 3

https://doi.org/10.1007/s00381-021-05395-2

CASE REPORT

Suprasellar arachnoid cyst due to ectopic choroid plexus: case report

Jason Labuschagne1,2  · Denis Mutyaba1,2 · Tanyia Pillay3,4 · Peter Swart5,6

Received: 15 September 2021 / Accepted: 11 October 2021 
© The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2021

Abstract
Arachnoid cysts (ACs) are malformations that account for about 1% of all intracranial lesions. The aetiology and progres-
sion of these lesions have been debated, with one possible explanation being the production of cerebro-spinal fluid (CSF) by 
ectopic choroid plexus (CP). To our knowledge, only seven cases of ACs incorporating CP have been reported, and we believe 
this to be the first reported case of a suprasellar AC containing ectopic CP. A 1-year-old boy presented with developmental 
delay and macrocephaly. MRI scan revealed hydrocephalus due to a suprasellar AC. An endoscopic ventriculocisternostomy 
was undertaken. Intra-operatively, intra-cystic, pink frond-like tissue resembling choroid plexus was identified. Histologi-
cally, the cyst wall was composed of fibrous tissue, with layered arachnoid cells, while the frond-like tissue was composed 
of papillary structures in keeping with normal choroid plexus tissue. We postulate that the rest of the ectopic CP may have 
been trapped within the double layered arachnoid fold of the diencephalic leaf of Liliequist’s membrane which may drive 
the formation and development of certain suprasellar ACs.

Keywords Arachnoid cyst · Suprasellar · Ectopic choroid plexus · Ventriculostomy

Introduction

Arachnoid cysts (ACs) are malformations that account 
for about 1% of all intracranial lesions. The aetiology and 
progression of these lesions have been debated, with the 
production of cerebro-spinal fluid (CSF) by ectopic choroid 
plexus (CP) proposed as a possible mechanism. This is, to 
our knowledge, the first reported case of a suprasellar arach-
noid cyst containing ectopic CP. Herein, we present our case 

and review the literature to discuss the pathophysiological 
mechanisms that are thought to lead to this rare occurrence.

Case report

A 1-year-old boy presented with delayed neurological 
development and macrocephaly. There was no history of 
preceding trauma or infection. Visual testing was normal. 
Endocrine evaluation revealed hypothyroidism. MRI scan 
revealed hydrocephalus due to a suprasellar mass. The mass 
was in keeping with a suprasellar AC, measuring 3.45 (AP) 
by 3 cm (TV) by 3 cm (CC). The cyst extended into the base 
of the sella turcica. T1 and T2 MRI sequences (Fig. 1) were 
in keeping with that of CSF signal. The anterior wall of the 
cyst demonstrated a “nodule” of hypodense, non-enhancing 
tissue on both T1 and T2 sequences. Given the presence of 
hydrocephalus and endocrine abnormalities, an endoscopic 
ventriculocisternostomy was proposed and undertaken. 
Intra-operatively, the cyst roof was bulging through the fora-
men of Monroe. Following fenestration of the roof of the 
cyst, intra-cystic, pink frond-like tissue resembling CP was 
identified. The floor of the cyst was then widely fenestrated, 
caudal to which an incomplete/perforated mesencephalic 
leaf of Liliequist’s membrane could be identified along 

 * Jason Labuschagne 
 Jason.labuschagne@icloud.com

1 Department of Neurosurgery, University 
of the Witwatersrand, Johannesburg, South Africa

2 Department of Paediatric Neurosurgery, Nelson 
Mandela Children’s Hospital, 6 Jubilee Rd, 
Parktown, Johannesburg 2193, South Africa

3 Department of Radiology, Nelson Mandela Children’s 
Hospital, Johannesburg, South Africa

4 Department of Radiology, University of the Witwatersrand, 
Johannesburg, South Africa

5 Division of Anatomical Pathology, National Health 
Laboratory Service, Johannesburg, South Africa

6 Division of Anatomical Pathology, University 
of the Witwatersrand, Johannesburg, South Africa

/ Published online: 19 October 2021

Child's Nervous System (2022) 38:1381–1384

http://orcid.org/0000-0002-6567-0131
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with neurovascular structures coursing through the prepon-
tine cistern (see Fig. 2). The cyst wall and ectopic tissue 
were biopsied. Histologically the cyst wall was composed of 
fibrous tissue, with layered arachnoid cells, while the frond-
like tissue was composed of papillary structures lined by 
exuberant cuboidal epithelium, in keeping with normal CP 
tissue. (See Figs. 3 and 4) The child had an uneventful post-
operative course. Follow-up MRI revealed resolution of his 
hydrocephalus with partial collapse of the cyst. The child 
displayed significant improvement in his neurodevelopment. 
His endocrine function however did not improve.

Discussion

The majority of ACs are primary lesions, of congenital ori-
gin as a result of anomalous splitting and duplication of the 
endomenix during the early stages of embryonal develop-
ment of the arachnoid pathways [3, 15]. Histological find-
ings in these lesions demonstrate splitting or duplication of 
the arachnoid membrane into an inner and outer leaflet at the 
edge of the cyst cavity [5, 28].

Secondary, or acquired, ACs are less common, and occur 
[3, 25] as a result of trauma, surgery, infection, or intracra-
nial haemorrhage [16, 20, 25]. Suprasellar ACs in particular 
have been associated with trauma in infancy [14]. Fox and 
Al-Mefty [7] were the first to propose that ACs may develop 
in the suprasellar area due to the occlusion of the normal 
perforations in Liliequist’s membrane, “by adhesions after 
subarachnoid haemorrhage, infection and other causes of 
inflammation”. Choi and Kim [3] speculate that trauma may 
rather induce an abnormal splitting or duplication of the 
immature endomenix in infancy, given that the subarach-
noid space is not yet fully developed, with areas still “closed 
without cerebrospinal fluid”.

The mechanism by which ACs expand is poorly under-
stood [15], with several postulates, including osmotic gradi-
ents caused by higher protein or sodium content in the cyst, 
[23] one way valve mechanisms, [11, 13, 29] direct secretion 
of fluid by arachnoidal cells lining the cyst wall [8], or by 
fluid production by ectopic CP [3, 12].

To our knowledge, only seven cases of ACs incorporating 
CP have been reported [12, 26, 27]. In Schummann et al.’s 
[26] review of these cases, however, they noted that four of 

Fig. 1  Left: T1 MRI sequence 
demonstrating a large supra-
sellar cyst. Arrow: small nodule 
of hypodense tissue within the 
cyst. Right: T2-weighted MRI 
sequence. Arrow: hypodense 
tissue within the suprasellar cyst

Fig. 2  Left: Endoscopic view from within lateral ventricle revealing 
roof of arachnoid cyst. Middle: following fenestration of both the roof 
and floor of the cyst. Asterisk: contents of prepontine cistern. Arrow-
head: incomplete mesencephalic leaf of Lilliquist’s membrane. Small 

arrow: basilar tip behind the posterior wall of the cyst. Large arrow: 
septostomy in the floor of the cyst. Right: visualization of contents of 
cysts. Arrow: large tuft of normal appearing choroid plexus. Asterisk: 
posterior clinoid process. Arrowhead: floor of suprasellar cyst

1382 Child's Nervous System (2022) 38:1381–1384



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these described cysts were possibly lined with epithelium of 
ependymal origin, thus making the present case the fourth 
reported case of an AC arising due to entrapped CP, and the 
first case description of a suprasellar AC containing ectopic 
CP.

As postulated by Schummann et al., [26] two scenarios 
exist to explain this unique situation: either the ectopic CP 
is incorporated into an already developing AC, or the CSF 
production from the ectopic CP becomes entrapped between 
two layers of arachnoid which then induces membrane split-
ting and cyst growth.

The diencephalic leaf of Liliequist’s membrane has been 
shown by Zhang [30] to be a double layered fold of arach-
noid mater, which can allow for the formation of a truly 
intra-arachnoid diverticulum [17]. We postulate that the rest 

of the ectopic CP may have been trapped within this intra-
arachnoidal diverticulum and, following CSF production by 
the ectopic tissue, formed a truly intra-arachnoid cyst. This 
morphology would be in keeping with a suprasellar type 1 
AC according to the classification of Andre et al. [1]. The 
position of the basilar artery bifurcation behind the posterior 
wall of the cyst and the clinical presentation of hydrocepha-
lus are typical for the type 1 suprasellar AC [1, 21].

The presence of CP in an extra-ventricular location is 
thought to occur as a result of an abnormality in embryonic 
development from either anomalous migration of CP tissue 
or metaplasia from ependymal rests [2], and has been used 
to explain the occurrence of extra-ventricular CP cysts [9], 
choroid papillomas [2, 18, 24], and ACs [26].

In the current case, given the hydrocephalus and neuro-
developmental delay, surgery would generally be indicated. 
In asymptomatic cases, however, or cases in which there is 
only endocrine dysfunction or isolated gaze disturbances, 
several authors [4, 10] have suggested a conservative 
approach as many of these cysts will not evolve and may 
even resolve spontaneously [6, 19, 22]. We postulate that 
given the presence of CSF producing CP within the cyst, 
progression is likely and that as suggested by Shuman et al. 
[26] in cases of reclosure of a fenestrated cyst, ectopic CP 
tissue would predispose to a faster recurrence.

Conclusions

The mechanism by which ACs expand is poorly understood, 
and fluid production by ectopic CP should be considered as 
an aetiological factor. We suggest that during the endoscopic 
treatment of suprasellar ACs, a careful inspection of the cyst 
cavity is performed as even small pieces of ectopic choroi-
dal tissue may drive the progression or rapid recurrence of 
suprasellar ACs.

Declarations 

Ethics approval The Human Research Ethics Committee of the Univer-
sity of the Witwatersrand approved the presentation of the case report.

Conflicts of interest The authors declare no competing interests.

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Fig. 4  High-power view (H&E 200 ×), demonstrating arachnoid villi 
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	Suprasellar arachnoid cyst due to ectopic choroid plexus: case report
	Abstract
	Introduction
	Case report
	Discussion
	Conclusions
	References