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Abstract
Background. Extradural spinal cord compression in children may be the 
result of infection/inflammation or neoplasia. It is vital to differentiate 
between the two as there is considerable difference in the management 
of these entities. 
Objective. The aim of this paper is to determine whether there are sig-
nificant differences between TB spondylitis and neoplasia causing extra-
dural compression of the cord with regard to the anatomical distribution 
and compartmentalisation. 
Materials and methods. A group of 16 children between the ages of 4 
months and 14.2 years who had magnetic resonance (MR) evaluation of 
the spine consecutively were analysed retrospectively. 
Results. A wide variety of neoplasms demonstrated an anatomical site 
and compartment on MRI that is ‘characteristic’ of TB spondylitis. 
Conclusion. Anatomical distribution alone does not assist in narrowing 
the differential diagnosis. There is still need for biopsy in children with 
extradural compression by a mass.

Introduction
Extradural spinal cord compression may be the result of infection, 
inflammation or neoplasia. Masses may arise from the thoracic and 
abdominal cavities, from the vertebral column (and discs) as well as both 
sympathetic and exiting nerves. Categorisation of lesions according to 
the level involved (cervical, thoracic, lumbar, sacral) and according to 
the compartments involved, in combination or singly (extraspinal, ver-
tebral, intraspinal extradural, intradural extramedullary and intradural 
intramedullary), is routinely performed with the aim of narrowing the 
differential diagnosis.1 In particular, in the developing world (and with 
the advent of HIV in the developed world), it is necessary to distinguish 
TB spondylitis from neoplastic causes, to avoid biopsy.2 TB spondylitis 
is treated medically in most cases2 while neoplastic lesions require any 
combination of surgery, chemotherapy and radiotherapy to alleviate the 
cord compression. Using signal characteristics on magnetic resonance 
imaging (MRI) to distinguish infective lesions from neoplasia does not 

usually resolve the differential diagnosis, with the majority of lesions 
(infective and neoplastic) demonstrating low or intermediate signal on 
T1 and high signal on T2 with abscess formation in TB spondylitis2,3 
and cyst formation in some neoplasms (Ewing’s sarcoma, neuroblas-
toma).4,5 Rim enhancement of the soft-tissue mass is a feature that most 
strongly supports a diagnosis of TB spondylitis2,3 but this is also seen 
in pyogenic spondylitis5 and may occur when enhancing neoplasms 
show cystic degeneration.5 Involvement of a disc in conjunction with a 
vertebral body is considered a strong pointer to an infective spondyli-
tis2 but has been shown with metastatic disease3 and other neoplasms. 
Subligamentous spread is seen in TB spondylitis demonstrating exten-
sion above and below the level of involvement but this extension is also 
seen with neuroblastoma5 and lymphoma involving the spinal canal. 
The aim of this paper is to determine whether there are significant 
differences between TB spondylitis and neoplasia causing extradural 
compression of the cord with regard to the anatomical distribution and 
compartmentalisation without considering the signal characteristics or 
contrast enhancement.

Aim
The aim was to determine if the demonstration of anatomical distribu-
tion/compartmentalisation on magnetic resonance imaging (MRI) can 
differentiate TB spondylitis from neoplasia in extradural cord compres-
sion in children.

Materials and methods
A subgroup of patients who had a diagnosis of extradural spinal cord 
compression was extracted from a database of MRI scans performed 
of the spine in children at one institution over one year. Incomplete or 
inadequate studies, inadequate clinical notes and patients imaged for 
trauma or congenital anomalies (such as tethered cord/dysraphism) 
were excluded. A paediatric radiologist and a registrar, both blinded to 
the final diagnoses, reviewed images. Features recorded included verte-
bral level involved (cervical, thoracic, lumbosacral), uni- or multifocal 
involvement, involvement over numerous vertebral levels and the com-
partments involved in combination (extraspinal, vertebral, intraspinal 
extradural). The final diagnoses reached through biopsy, trial of therapy 
and associated clinical findings were used to categorise the patients after 
the blinded CT review into a ‘TB spondylitis group’ and a ‘neoplastic 
group’. Only the anatomical distribution and compartment information 
was then used to determine differences between the two groups.

Results
From a total of 67 patients who had undergone MRI of the spine, 16 
had a diagnosis of extradural spinal pathology (24%) and were included 
in the study. There were 9 males and 7 females and ages ranged from 

Is anatomical distribution helpful for  
differentiating TB spondylitis from neoplastic 

causes of extradural spinal cord compression in 
children? A pilot study

Reena George, MD, MMed Rad, FRCR (UK)
Savvas Andronikou, MB BCh, FCRad, FRCR, PhD

Hassan Lameen, MB ChB
Ayanda Mapukata, MB ChB

Salomine Theron, MB ChB, MMed Rad, FCRad
Jaco du Plessis, MB ChB

Deapartment of Radiology, Tygerberg Hospital and Stellenbosch University, 
Tygerberg 

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81         SA JOURNAL OF RADIOLOGY • December 2007

4 months to 14 years and 2 months (average 97 months/8 years and 1 
month). Final diagnosis comprised 8 cases of neoplastic disease, 6 cases 
of infection and 2 cases of inflammation. The two cases of non-specific 
inflammation were excluded for the purposes of this study. Neoplastic 
lesions included neurofibromas (2), ganglioneuroma (1), lymphoma 
(1), pulmonary blastoma (1) (Fig. 1), Ewing‘s sarcoma (1) (Fig. 2a & 
b), infantile fibromatosis (1) (Fig. 3a & b) and haemangioma (1) (Fig. 
4). Table I compares the 2 groups. The site was primarily thoracic for 
both groups and cervical location was uncommon for TB. Both groups 
involved multiple vertebral levels in contiguity (TB 6/6, neoplasm 7/8) 
but TB was often multifocal (6/6) whereas no neoplastic process was 
seen multifocally. Both TB and neoplasia involved the extraspinal com-
partment regularly (TB 4/6, neoplasia 6/8) and TB always involved the 
vertebral body (6/6) while neoplasia only involved the vertebral body in 
half the cases (4/8).

Discussion
It is reported and taught that an effective and commonly used approach 
to interpretation of disease involving the spine is to categorise the dis-
ease as extradural, intradural extramedullary or intradural intramedul-
lary.1 This is best achieved using axial and sagittal MRI sequences.1 The 
intent is to narrow the differential diagnosis in the hope of reaching an 
imaging diagnosis, thereby avoiding biopsy in addition to planning sur-
gery/management in the case of neoplasia. The pattern of bone and disc 
involvement is insufficient grounds for differentiating TB spondylitis 

from metastatic disease in adults3 and this is also sometimes the case 
with paediatric imaging. Multiple destructive vertebral bone lesions in 
children other than TB spondylitis include: (i) malignancies, particularly 
neuroblastoma metastases, lymphoma and Ewing’s sarcoma; (ii) benign 
bone tumours such as aneurysmal bone cysts; and (iii) infections includ-
ing pyogenic, Brucella, fungal and echinococcal lesions.2 By far the most 
common diagnosis in the developing world is infective spondylitis.2 
Although computed tomography (CT) and MRI features of TB spondy-
litis have been reported in adults and children there is significant overlap 
with neoplastic disease.2,3

Fig 1. A 4-month-old boy with pulmonary blastoma - coronal T1-weighted 
post-gadolinium-enhanced image shows the mass extending into the spinal 
canal with a large extradural component.

Fig. 2. An 11-year-old girl with Ewing’s sarcoma of the sacrum. Axial (a), and 
sagittal (b) T1-weighted gadolinium-enhanced images. Extradural extension 
of the iso-intense mass through the neural foramen.

a

b

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Neoplasms 
Extradural neoplasms in children are usually an extension of neoplasms 
in the paravertebral soft tissues or anterior vertebral column, most com-
monly neuroblastoma.6

Neuroblastoma, ganglioneuroblastoma and ganglioneuroma arise 
wherever there is sympathetic tissue.5 MRI is the preferred modality for 
demonstrating intraspinal extension of the primary tumour through the 
neural foramina – dumbbell neuroblastoma.5,6 This occurs in 10% of 
abdominal and 28% of thoracic neuroblastomas.5 Neuroblastoma may 
also result in vertebral body metastases, which can also result in cord 
compression.

Lymphoma may involve the paravertebral lymph nodes and cause 
adjacent vertebral invasion, may show malignant vertebral infiltration 
with or without intra- and para-spinal involvement, may involve the 
epidural space in isolation and may present as an intramedullary mass. 
Spinal cord compression as the presenting feature is rare however (0.1-
3.3%). It is less frequent in childhood than in adulthood and usually 
affects the cervical region. When spinal localisation is the sole mani-
festation of lymphoma, the imaging characteristics are not sufficient to 
make a diagnosis and it is reported that this can only be made by means 
of biopsy.7

Eosinophilic granuloma lesions affect the vertebral body primarily 
but may extend into the adjacent epidural space to compress the thecal 
sac.6

Ewing sarcoma (primitive neuroectodermal tumour) often origi-
nates in the paravertebral soft tissue and extends through the neural 
foramina, but may also infiltrate other surrounding structures.4

Spinal tumours form part of the spectrum of both neurofibroma-
tosis I and II and occur in a large number of patients in all segments of 
the spine. These are often intraforaminal (57%) and are surrounded by 
soft-tissue tumour.8,9

Infection 
A common location for infection in the paediatric spine is the anterior 
vertebral column; this may involve the vertebral body in isolation, the 
vertebral body and intervening disc, or the disc alone.6 Infection may 
extend into the epidural space causing compression of the thecal sac.6

The imaging features characteristic of TB spondylitis in addition to 

Fig. 3. A one-and-a-half-year-old boy with infantile fibromatosis. Axial (a) 
and coronal (b) T2-weighted studies show a hyperintense mass with extra-
dural extension via the neural foramina.

a

b

Table I. Comparison of TB spondylitis with neoplasia for anatomical distribution
	 	 	 	 	 	 	 TB	spondylitis	(6)	 	 Neoplasia	(8)
Age        109.8 months  87.5 months 
Male       2   6
Female       4   2
Cervical       1   3
Thoracic       5   4
Lumbar       1   3
Sacral       1   2
Multiple vertebral segments (contiguous)    6   7
Multifocal involvement (distant)    3   0
Extraspinal with intraspinal extradural    4   6
Vertebral with intraspinal extradural    6   4

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vertebral body involvement include involvement of multiple vertebral 
segments (contiguously or far apart), presence of a pre/paravertebral 
mass/abscess; rim enhancement of the abscess; involvement of the disc; 
and subligamentous spread above and below the level of bone destruc-
tion (Figs 5, 6a & b).2,3 The thoracolumbar region is reported to be the 
commonest involved.2,3 One author reports that bony fragments (low 
signal on all sequences) only occur with TB,3 but the other characteris-
tics listed above may be mimicked by neoplastic disease (Table II).

Conclusion
A small number of patients were evaluated in this paper, but even with 
this small sample a wide variety of neoplasms demonstrated features 

Fig. 5. A 12-year-old boy with TB spondylitis. Sagittal T2-weighted image 
shows contiguous vertebral body and disc destruction with a large anterior 
mass and a posterior extradural component compressing the spinal cord.

Fig. 4. A 10-year-old boy with capillary haemangioma of the vertebral body. 
Sagittal T1-weighted image shows a mottled pattern of increased intensity 
with a large extradural component.

Table II. Neoplastic mimickers of characteristic features of TB spondylitis
TB	spondylitis	characteristic	 	 	 	 	 Neoplastic	mimicker
Pre/paravertebral abscess     Ewing's cystic degeneration4 
Rim enhancement of abscess     Cystic neuroblastoma/Ewing's5,4
Extension beyond level of bone destruction   Neuroblastoma5
Multifocal       Neurofibromatosis,8 neuroblastoma5 
Disc involvement      Metastases3

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Fig. 6. A 10-year-old boy with TB spondylitis. (a) Sagittal T1 post-gadolinium and (b) coronal T2-weighted images show multiple contiguous vertebral bodies which 
have abnormal signal and enhancement as well as disc destruction. There is a predominantly anterior ring-enhancing soft-tissue mass but the smaller posterior 
extradural component causes spinal cord compression.

on MRI with regard to their anatomical site and compartment that are 
characteristic of TB spondylitis. It is not likely that anatomical distribu-
tion alone will assist in narrowing the differential diagnosis and obviate 
the need for biopsy in children with extradural compression by a mass. 
More research into new MRI sequences and use of tissue characterisa-
tion as well as gadolinium enhancement patterns are necessary to reach 
this goal, as current signal and enhancement characteristics for TB 
spondylitis and neoplasia also overlap.

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and the role of gadolinium. Pediatr Radiol 2002; 32: 798-805.
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