ORIGINAL ARTICLE ORIGINAL ARTICLE

28         SA JOURNAL OF RADIOLOGY • June 2010

ORIGINAL ARTICLE

Abstract
Objective. The objective of the study was to determine whether 
computed tomography (CT) of the brain is necessary in all head trauma 
patients with clinically suspected depressed skull fractures, Glasgow 
Coma Scale (GCS) scores of 13 and above, and no focal neurological 
deficits.
Design. A retrospective descriptive analysis was undertaken of patients 
of all ages who presented at the trauma unit of the Pelonomi Hospital 
Complex in Bloemfontein with GCS of 13 to 15, depressed skull fracture, 
no clinical focal neurological deficit, and who also underwent CT of the 
brain. Data were obtained from patients' files, and radiological reports 
and were analysed by the Department of Statistics, University of the 
Free State.
Results. One hundred and thirty-one patients were included in the 
study, of whom 56 (42.7%) were found to have substantial intracranial 
pathology as determined by CT. Twenty-four (18.3%) of these patients 
had a GCS of 13, of whom 6 (25%) had normal CT scans and 18 (75%) 
intracranial pathology. Twenty-eight (21.37%) of the 56 patients with 
intracranial pathology had a GCS of 14, of whom 11 (39.3%) had normal 
CT scans and 17 (60.7%) intracranial pathology. A GCS of 15 was 
determined in 79 (60.3%) of the 131 patients, of whom 58 (73.4%) had 
normal CT scans and 21 (26.6%) intracranial pathology.
Conclusion. Based on our findings, CT imaging of the brain in patients 
with a clinically suspected depressed skull fracture despite any clinical 
neurological deficit and a GCS of 13 or more is warranted in our setting. 
The likelihood of injury on CT correlated inversely with the GCS.

Introduction
The Glasgow Coma Scale (GCS), introduced by Teasdale and Jenner 
in 1974, was devised to provide a uniform approach to the clinical 
assessment of patients with acute head trauma. The scale measures levels 
of arousal and awareness and attempts to assign numeric values (1 to 5 ) 
to eye opening, the best motor response and the best verbal response. As 
a predictor of outcome, scores of 13 to 15 are considered to correspond 
with mild injury, 9 to 12 with moderate injury and 8 or lower with severe 
injury.1-3

Since the advent of computed tomography (CT) scans in the early 
1970s, the demand from emergency room physicians for CT scans 

for minor head injury patients is a routine practice, although most of 
these investigations are normal and fewer than 1% of patients require 
neurosurgery.4,5 It is not known how many CT scans are done in South 
Africa but, according to one estimate in the USA, even a 10% reduction 
in the number of CT scans in patients with minor head injuries would 
save more than $20 million per year.6 

Over the past decade, numerous studies have investigated and 
attempted to regulate the utility of head CT in patients with minor head 
injury, such as the New Orleans criteria, the Canadian CT head rule 
and the National Institute for Health and Clinical Excellence (NICE) 
head injury guidelines. These studies use lists of clinical findings, 
any of which call for CT after minor head injury,7 and have given 
rise to a good deal of controversy.8 The aim of our study was to carry 
out a retrospective analysis of CT scans performed in the Radiology 
Department at Pelonomi Hospital in Bloemfontein. Only patients with 
clinically diagnosed depressed skull fracture with a GCS of 13 - 15 were 
included in this study and where the presence of brain pathology on CT, 
if any, was documented. The diagnosis of a depressed skull fracture was 
made by clinical examination of the patient's head and a skull X-ray to 
confirm the clinical observation. By undertaking this study, we hoped 
to provide more reliable guidelines permitting general practitioners, 
specialists and radiologists to be more selective in using CT scans, 
without compromising the care of patients with minor head injuries.

Methods
A retrospective descriptive analysis was conducted at the Pelonomi 
Hospital Complex and trauma unit in Bloemfontein. Data from 1 
January 2008 - 1 January 2009 were collected. The trauma protocol at 
our institution requires all patients with depressed skull fractures to 
undergo an acute CT brain scan, irrespective of their GCS scores. A 
CT examination of the brain without intravenous iodinated contrast 
was required for the study. All patients with a history of head trauma 
and depressed skull fracture on clinical examination, a GCS score of 
13 - 15/15 and no focal neurological signs referred to the Department 
of Radiology for an acute CT of the brain, were eligible for the study. 
The CT scans of patients of all age and racial groups who fulfilled the 
inclusion criteria were assessed.

All CT scans were performed on a GE high-speed ZXT single-slice 
helical CT scanner. Two radiology registrars evaluated the scans; results 
were verified by a specialist radiologist.

Information was also collected from patient records, and all 
intracranial pathology was noted. Data were captured on a form and 
transferred to a Microsoft Excel spreadsheet for statistical analysis of 
normal and abnormal findings. Approval to conduct the investigation 
was granted by the Ethics Committee of the Faculty of Health Sciences, 
University of the Free State.

Is computed tomography of the brain necessary 
in patients with clinically suspected depressed 

skull fracture and no focal neurological deficit?

J A Rabie, MB ChB
S Otto, MB ChB, MMed (Diagnost Radiol)

A J le Roux, MB ChB
Department of Diagnostic Radiology, Faculty of Health Sciences, University 

of the Free State, Bloemfontein



ORIGINAL ARTICLEORIGINAL ARTICLE

29         SA JOURNAL OF RADIOLOGY • June 2010

Results
Data were collected from 131 patients' records during the study period. 
All these patients had a clinically diagnosed depressed skull fracture and 
no focal neurological deficit. The GCS of the patients varied between 
13/15 and 15/15. A CT brain scan was performed on all the patients 
as requested at the time of presentation. One hundred and fourteen 
(87.0%) of the patients were male. Patients' ages ranged from 1 - 76 years. 
Fifty-six (42.7%) of the CT brain scans showed abnormalities.

The distribution of patients with regard to GCS score and the 
number of abnormalities found per GCS level are shown in Table I.

Seven different groups of intracranial pathology were encountered. 
A number was allocated to each pathology group for statistical 
analysis, as shown in Table II. Three types of pathology predominated, 
i.e. intracerebral contusion/haemorrhage, brain oedema and 
pneumocranium, which were observed in more than 15% of patients 
overall. The other pathologies (subarachnoid, subdural and extradural 
haemorrhage, and base of skull fractures) occurred at a remarkably 
lower rate. Twenty-four (42.9%) of the abnormal CT scans revealed 
a single pathology, while multiple pathologies were observed in the 
remainder.

Discussion
Similar to previously published reports,9-11 a considerable number of 
abnormal CT scans following a depressed skull fracture with no clinical 
focal neurological deficit were found. Although most of the injuries 
were minor and possibly did not require any intervention, a CT of the 

brain was still warranted on the basis of the intracranial pathology 
retrospectively identified in these patients. Furthermore, these CT 
scans could provide a baseline for comparison of subsequent pathology 
related to the initial injury in the event of later complications and patient 
follow-ups.

A depressed skull fracture was significantly associated with 
intracranial pathology, as observed by the presence of CT scan 
abnormality in 42.3% of patients. As shown in Table I, a clear association 
between incidence of intracranial pathology and GCS score was revealed, 
showing an increase in the rate of pathology as the GCS score decreases. 
Seventy-five percent of patients with a GCS score of 13 had abnormal CT 
scans, as opposed to 26.6% of those patients with a GCS score of 15.

However, despite a GCS of 15/15, intracranial pathology was 
nonetheless demonstrated. The majority (19.8%) of these were 
intracerebral contusions and haemorrhages. As this study was a 
retrospective assessment of CT scans performed on patients fulfilling 
the inclusion criteria, further management of these patients with regard 
to observation, treatment and/or surgical intervention was beyond the 
scope of this investigation.

Some clinicians believe that it is necessary to identify patients with 
minor brain injuries. However, several problems with this approach 
exist. Firstly, a patient with a normal CT of the brain may have abnormal 
MRI scans.12,13 Secondly, an abnormal CT does not predict neurological 
outcome.14-16 Previous studies have shown that patients with minor brain 
injury requiring no surgery or medical intervention had an average stay 
of 1.7 days in hospital, which questions the necessity for admission.17

Some physicians16 also warn of the risk of early epidural haematomas. 
However, only 17 (12.9%) of our patients presented with epidural 
haematomas. In a paediatric study, one-third of patients were diagnosed 
with epidural hematomas within 24 - 48 hours after sustaining head 
injury. All of these patients presented with normal mental status.17 
Patients with minor CT abnormalities and normal mental status were 
found to have a very low risk for deterioration.17 As a result, some centres 
now have a non-operative approach to asymptomatic haematomas.16,17

Regarding the results presented in Tables I and II, we are convinced 
that CT of the brain in patients with depressed skull fractures, GCS of 
13 - 15 and no focal neurological signs, is indeed necessary, owing to the 
high percentage of abnormalities found in this study group.

The rate of abnormal CT findings for patients with a GCS score 
of 13/15, clinical depressed skull fracture and no focal neurological 
signs was much higher than expected. Owing to intracranial pathology 
observed in 42.7% of CT scans performed on patients with minor head 
injuries, it can be concluded that CT of the brain will be required in our 

Table II. Pathology groups observed on CT scan

No. Pathology

No. of patients 
(%)

(N=131)

1 Cerebral oedema 23 (17.6)

2
Subarachnoid 
haemorrhage 8 (6.1)

3 Subdural haemorrhage 9 (6.9)
4 Pneumocranium 22 (16.8)

5
Intracerebral contusion/
haemorrhage 26 (19.8)

6 Base of skull fracture 1 (0.8)
7 Extradural haemorrhage 7 (5.3)

Table I. Number of patients and abnormal CT scan findings per GCS level

GCS 
score

No. of patients (%) 
(N=131)

CT scan findings

Normal
No. of patients (%)

Abnormal
No. of patients (%)

13 24 (18.3) 6 (25.0) 18 (75.0)
14 28 (21.4) 11 (39.3) 17 (60.7)
15 79 (60.3) 58 (73.4) 21 (26.6)

Total 131 (100) 75 (57.3) 56 (42.7)



ORIGINAL ARTICLE ORIGINAL ARTICLE

30         SA JOURNAL OF RADIOLOGY • June 2010

setting for all patients with depressed skull fractures and GCS scores of 
13 - 15/15 without clinical neurological deficit.

Acknowledgements
We thank Daleen Struwig (medical writer, Faculty of Health Sciences, 
UFS) for technical and editorial preparation of the manuscript for 
publication, and Professor Gina Joubert, Department of Biostatistics, 
Faculty of Health Sciences, UFS, for statistical analysis of the data.

  1.  Grossmann RI, Yousem DM. Neuroradiology: The Requisites. 2nd ed. Philadelphia: Mosby, 2003: 243-245.
  2. Herndon RM. Handbook of Neurologic Rating Scales. New York: Demos Vermande, 1997: 187-208.
  3.  Haydel MJ, Preston CA, Mills TJ, Luber S, Blaudeau E, De Blieux PM. Indication for computer tomography 

in patients with minor head injury. New Engl J Med 2000; 343: 100-105.
  4.  Peters MC. Does every minor head injury need a CT scan? Emergency Medicine News 2003; 25: 28-30.
  5.  Smits M, Dippel DW, de Haan GG, et al. Minor head injury: guidelines for the use of CT – a multicentre 

validation study. Radiology 2007; 245: 831-838.
  6.  Saboori M, Ahmadi J, Farajzadegan Z. Indications for brain CT scan in patients with minor head injury. 

Clin Neurol Neurosurg 2007; 109: 399-405.
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Criteria in patients with minor head injury. JAMA 2005; 294: 1511-1518.

  8.  Holmes JF, Baier ME, Derlet RW. Failure of the Miller criteria to predict significant intracranial injury in 
patients with a Glasgow Coma Scale score of 14 after minor head trauma. Acad Emerg Med 1997; 4: 788-
792.

  9. Stein SC, Ross SE. Mild head injury: a plea for routine early CT scanning. J Trauma 1992; 33; 11-13.
10.  Harad FT, Kerstein MD. Inadequacy of bedside clinical indicators in identifying significant intracranial 

injury in trauma patients. J Trauma 1992; 32: 359-363.
11.  Shackford SR, Wald SL, Ross SE, et al. The clinical utility of computed tomography scanning and 

neurologic examination in the management of patients with minor head injuries. J Trauma 1992; 33: 385-
394.

12.  Levin HS, Williams DH, Eisenberg HM, High WM Jr, Guinto FC Jr. Serial MRI and neurobehavioural 
findings after mild to moderate closed head injury. J Neurol Neurosurg Psychiatr 1992; 55: 255-262.

13.  Eide PK, Tysnes OB. Early and late outcome in head injury patients with radiological evidence of brain 
damage. Acta Neurol Scand 1992; 86: 194-198.

14.  Lee ST, Lui TN. Early seizures after mild closed head injury. J Neurosurg 1992; 76: 435-439.
15.  Mendelow AD, Teasdale G, Jennett B, Bryden J, Hessett C, Murray G. Risks of intracranial haematoma in 

head injured adults. BMJ 1983; 287: 1173-1176.
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Emerg Med 1996; 27: 290-294.
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Neurosurg 1989; 70: 392-396. 

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