Romanian Neurosurgery  |  Volume XXXI  |  Number 1 |  2017  |  January - March 

 
Article 

 
 Commonly available CT characteristics and 

prediction of outcome in traumatic brain injury 

patients  

Anil Kumar, Umamaheswara Reddy V., Vasuki Pratyusha, Ashok Munivenkatappa, Ranabir Pal, Kishore V. Hegde, 

Ranjan Jena, Satish Kumar S., Amit Agrawal 
INDIA 

 

 

 

DOI: 10.1515/romneu-2017-0016 
 



 
 
 
 
 

Romanian Neurosurgery (2017) XXXI 1: 101 – 110 | 101 

 

 
 
 
 
 
 

DOI: 10.1515/romneu-2017-0016   

Commonly available CT characteristics and prediction of 
outcome in traumatic brain injury patients 

Anil Kumar1, Umamaheswara Reddy V.2, Vasuki Pratyusha3, 
Ashok Munivenkatappa4, Ranabir Pal5, Kishore V. Hegde6, 
Ranjan Jena7, Satish Kumar S.8, Amit Agrawal9 

1Resident of Neurosurgery, Department of Neurosurgery, Narayana Medical College Hospital, 
Chinthareddypalem, Nellore, Andhra Pradesh, INDIA 
2Assistant Professor of Radiology, Department of Radiology, Narayana Medical College 
Hospital, Chinthareddypalem, Nellore, Andhra Pradesh, INDIA 
3Department of Biostatistics and Epidemiology, National Institute of Mental Health and 
Neurosciences, Bangalore, INDIA 
4MBBS, PhD: Scientist C, VRDL project, National Institute of Epidemiology, ICMR, Chennai – 
77, Tamil Nadu, INDIA 
5Department of Community Medicine, Andaman and Nicobar Islands Institute of Medical 
Sciences, Port Blair – 744104, INDIA 
6Professor of Radiology, Department of Radiology, Narayana Medical College Hospital, 
Chinthareddypalem, Nellore, Andhra Pradesh, INDIA 
7Assistant Professor of Neurosurgery, Department of Neurosurgery, Narayana Medical College 
Hospital, Chinthareddypalem, Nellore, Andhra Pradesh, INDIA 
8Associate Professor of Emergency Medicine, Department of Emergency Medicine, Narayana 
Medical College Hospital, Chinthareddypalem, Nellore, Andhra Pradesh, INDIA 
9Professor of Neurosurgery, Department of Neurosurgery, Narayana Medical College Hospital, 
Chinthareddypalem, Nellore, Andhra Pradesh, INDIA 

 
Abstract: Background: Acute Computerized Tomography (CT) characteristics are used 
widely and most accepted for prediction of outcome among Traumatic Brain Injury 
(TBI). The commonly available and simple combinations of existing and unexplored 
CT parameters may be more useful in prediction of outcome. The present study 
explores commonly available CT characteristics by possible combinations based on 
anatomical basics. Methods: Abnormal CT sign was considered with any cranial lesion. 
Based on anatomical locations of cortical lobes, nine possibilities were made that 
include individual and combinations of mentioned lobes. The laterality was either right 
or left or bilateral. The outcome was favourable or unfavourable based on discharge 
Glasgow Outcome Scale (GOS). Binary logistic regression was used to predict outcome. 



 
 
 
 
 
102 | Kumar et al - Commonly available CT characteristics 

 

 
 
 
 
 
 

Results: 452 patients were recruited in the present study. There was significant risk of 
unfavourable outcome among patients with location of Sub Dural Haemorrhage (SDH) 
in Parietal + Temporal region (OR=10,p<0.001); Cerebral Contusion in Temporal 
region (OR=3,p=0.03), Frontal + Temporal region(OR=16,P=0.001), Frontal + Parietal 
+ Temporal region (OR=18.7,p<0.001). Patients with four abnormal CT signs had 
worst outcome. Presence of SDH on right side (OR=4.5,p<0.001) and bilateral Cerebral 
Contusion (OR=4.5,p=0.003) was at the risk of unfavourable outcome. Conclusion: The 
present study based on anatomical classification has shown that location and laterality 
of lesion can significantly predict TBI outcome.  
Key words: CT characteristics, locations, laterality, cortical regions, prediction, 
outcome 

 
Introduction 

Computerized Tomography (CT) 
examination remains the investigation of 
choice in the acute phase of Traumatic Brain 
Injury (TBI). CT characteristics not only 
widely accepted for descriptive purposes, but 
also increasingly being used as major 
predictor of outcome in TBI. Following TBI 
the pathological findings on CT scan that is 
represented by scoring system is oriented in 
predicting prognification of outcome (2, 4, 
12, 13). Various studies and the international 
guidelines on prognosis include the CT 
scoring system as a major outcome 
predictor13. Several predicting models in 
terms of scoring had been developed for TBI 
prognostication. Few models are validated 
and few are not accurately validated (12). The 
current available CT scoring systems based on 
abnormal CT characteristics do not provide 
details that are best suited for prediction. 
Possibly there are other very simple 
combinations of CT parameters that may be 
more appropriate for this specific purpose 
that has not been investigated in detail. The 
aim of the present study is to examine the 

possible available CT characteristics with 
simple combinations based on anatomical 
location and distribution.       

Methods 
Inclusion and exclusion criteria 

Inclusion criteria for the study were 
patients with history of TBI and having 
abnormal CT signs. Any age group and both 
the genders were considered, very 
importantly willing to participate in study. 
The study was approved by Institute Ethical 
Committee; the purpose of the study was 
explained in patients own language and 
willing patient/relative written consent was 
taken before enrolling into the study.          
Abnormal CT signs 

Patient’s emergency CT scan showing any 
cranial abnormality was considered as 
abnormal CT signs. Abnormal cranial CT 
signs were Intra Cerebral Haemorrhage 
(ICH), Cerebral contusion, Sub Arachnoid 
Haemorrhage (SAH), Extra Dural 
Haemorrhage (EDH), Sub Dural 
Haemorrhage (SDH) and Skull Fracture 
(Figures 1-4). 



 
 
 
 
 

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Figure 1 - CT scan brain plain showing left parieto-

occiptal extradural hematoma with scalp swelling and 
right frontal polar contusion 

 
Figure 2 - CT scan brain plain showing left fronto-
temporo-parietal acute subdural hematoma with 

mass effect and midline shift 

 
Figure 3 - CT scan brain plain showing left temporal 
contusion with mass effect and perilesional oedema 

 

 
Figure 4 - CT scan brain plain showing right 
temporal thin acute subdural hematoma and 

coalescing contusion causing formation of 
intracerebral hematoma with peri-lesional oedema 

and mass effect 



 
 
 
 
 
104 | Kumar et al - Commonly available CT characteristics 

 

 
 
 
 
 
 

Location 
Based on location of abnormal CT signs 

on different lobes of brain it was categorized 
into nine groups. That includes Frontal, 
Temporal, Parietal, Occipital, Frontal + 
Temporal, Frontal + Parietal, Parietal + 
Temporal, Temporal + Occipital, Frontal + 
Parietal + Temporal. Further each patient 
either having EDH or SDH or ICH or 
Cerebral Contusion or Skull Fracture, 
abnormal CT signs were grouped into one 
with either of one mentioned, two with 
combination of two abnormal signs, three 
combinations of three abnormal signs and 
four with combination of four abnormal 
signs. 
Laterality 

The laterality of abnormal CT signs was 
categorized into Left hemisphere, Right 
hemisphere and bilateral hemisphere.  
Outcome  

The discharge outcome was evaluated 
using Glasgow Outcome Scale (GOS). The 
scale was categorized into favourable that 
includes Good and Moderate recovery and 
unfavourable that includes persistent state, 
severe disability and death.  
Statistical analysis 

The collected data was analyzed using 
SPSS software IBM SPSS Version 22. 
Percentages were calculated for categorical 
data, and mean, standard deviation was 
calculated for continuous data.  
Logistic regression model 

Binary logistic regression was used to 
identify the possible risk factors responsible 
for discharge outcome favourable or 
unfavourable (dependent variables). The 

variables that included in logistic regression 
model are; EDH, SDH, Cerebral Contusion, 
ICH, Skull Fracture, SAH, location and 
laterality of abnormal CT signs. Significance 
level was considered with p value of ≤0.05.  

Results 
During study period 452 patients were 

explored with mean age of 39.39 ± 15.08 
years. Victims from male gender were four 
times (79%) higher than female group (21%). 
Patients with favourable and unfavourable 
outcome were 84% and 16% respectively. 
Location of abnormal CT signs 

Distribution of EDH, SDH, ICH, CC and 
Skull Fracture at nine different location 
mentioned elsewhere are detailed in Table 1. 
Location of EDH at Temporal region is 1.2 
times at the risk; Occipital region at 6 times at 
the risk; Frontal + Parietal region at 2 times at 
the risk of unfavourable outcome, however 
none were significant.  SDH at Parietal + 
Temporal region was significantly (p<0.001) 
10 times at the risk of unfavourable outcome. 
Presence of Cerebral Contusion was at 
Temporal region was 3 times at the risk 
(p=0.03); Frontal + Temporal region was 16 
times (P=0.001) at the risk; Frontal + Parietal 
+ Temporal region was 18.7 times (p<0.001) 
at the risk of unfavourable outcome. For 
details refer Table 2. 

Majority of patients had one abnormal CT 
sign that is 271(60%), followed by two 
146(32%), three 31(7%) and four (1%) 
abnormal findings. Patients with one, two 
and three abnormal CT findings were at lesser 
risk of unfavourable outcome with reference 
to four abnormal CT findings (Table 2).   

    



 
 
 
 
 

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Laterality of abnormal CT signs 
Distribution of abnormal CT signs (EDH, 

SDH, Cerebral Contusion, SAH) either on left 
or right or bilateral hemispheres are shown in 
table 3. Majority of patients has abnormal CT 
signs (EDH, SDH, Cerebral Contusion, SAH) 
on right side 215 (48%), followed by left side 
151 (33%) and bilateral 86 (19%). SDH on 

right side is significantly (p<0.001) 4.5 times 
at the risk of unfavourable outcome. Bilateral 
Cerebral Contusion is significantly (p=0.003) 
4.5 times at the risk of unfavourable outcome. 
Presence of bilateral abnormal CT sign is 
significantly (p=0.005) 2.4 times at the risk of 
unfavourable outcome. 

 
Table I 

Distribution of abnormal CT findings in different anatomical lobes of brain 
 
Location  

Abnormal CT signs n (%)
Extra Dural 
Haemorrhage  

Sub Dural 
Haemorrhage 

Intra Cranial 
Haemorrhage 

Cerebral 
Contusion 

Skull 
Fracture 

None  348 (77) 292 (65) 446 (98.8) 174 (38.5) 326 (72) 
Frontal 27 (6) 40 (9) 2 (0.4) 113 (25) 50 (11)  
Temporal 30 (7) 18 (4) 2 (0.4) 79 (17.5) 60 (13) 
Parietal 16 (3.5) 7 (1.5) 0 27 (6) 3 (0.7) 
Occipital 7 (1.5) 6 (1) 1 (0.2) 1 (0.2) 5 (1) 
Frontal + 
Temporal 

1 (0.2) 0 0 12 (2.7) 2 (0.4) 

Frontal + 
Parietal 

14 (3) 6 (1) 1 (0.2) 9 (2) 0 

Parietal + 
Temporal 

1 (0.2) 19 (4) 0 20 (4) 7 (0.3) 

Temporal 
+ Occipital 

7 (1.5) 64 (14) 0 1 (0.2) 7 (0.3) 

Frontal + 
Parietal + 
Temporal 

0 0 0 16 (3.5) 0 

Total 452 (100) 452 (100) 452 (100) 452 (100) 452 (100) 
 

Table II 
Outcome prediction based on location of CT characteristics 

Abnormal CT sign Location Significance Odds 
ratio 

95% CI
Lower Upper  

Extra Dural Haemorrhage* 
Temporal 0.83 1.2 0.22 6.50 
Occipital  0.06 6 0.88 40.43 
Frontal + Parietal 0.36 2 0.41 10.96 



 
 
 
 
 
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Sub Dural Haemorrhage* 
Frontal 0.47 1.6 0.40 6.85 
Parietal 0.40 2.3 0.31 17.38 
Frontal + Temporal 0.11 5.4 0.64 44.93 
Parietal + Temporal <0.001 10.2 4.25 23.89 
Cerebral Contusion* 
Frontal 0.11 2.1 0.84 5.28 
Temporal 0.03 3 1.10 8.58 
Parietal 0.21 2.6 0.56 12.30 
Frontal + Temporal 0.001 16.2 3.29 80.29 
Frontal + Parietal 0.76 1.5 0.11 18.38 
Parietal + Temporal 0.24 2.5 0.54 11.42 
Frontal + Parietal + Temporal <0.001 18.7 4.86 71.87 
Skull Fracture* 
Frontal + Temporal 0.53 2.9 0.10 79.45 
Parietal + Temporal 0.39 5 0.13 186.39 
Number of abnormal CT signs$ 
One  0.10 0.18 0.02 1.37 
Two@ 0.10 0.18 0.02 1.39 
Three@  0.13 0.19 0.02 1.70 

* reference is no abnormal CT sign; $reference is presence of four abnormal CT sign; @ combination of either 
Extra Dural Haemorrhage or Sub Dural Haemorrhage or Intra Cranial Haemorrhage or Cerebral Contusion or 

Skull Fracture 
 

Table III 
Distribution of abnormal CT findings based on laterality 

 
Laterality 

Abnormal CT signs n (%) 
Extra Dural 
Haemorrhage 

Sub Dural 
Haemorrhage 

Cerebral 
Contusion 

Sub Arachnoid 
Haemorrhage 

None  350 (77.4) 272 (60) 181 (40) 404 (89.3) 
Left 
hemisphere 

47 (10.4) 68 (15) 95 (21) 16 (3.5) 

Right 
hemisphere 

51 (11.2) 104 (23) 127 (28.2) 23 (5) 

Bilateral 
hemisphere 

4 (1) 8 (2) 49 (11) 9 (2.2) 

Total 452 (100) 452 (100) 452 (100) 452 (100) 
 
 
 



 
 
 
 
 

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Table IV 

Outcome prediction based on distribution of CT characteristics 
Laterality of abnormal CT signs Significance Odds 

ratio 
95% CI

Lower Upper  
Extra Dural Haemorrhage* 
Bilateral 0.59 2.1 0.13 34.01 
Sub Dural Haemorrhage* 
Left 0.32 1.5 0.64 3.66 
Right <0.001 4.5 2.20 9.16 
Bilateral 0.85 1.2 0.14 10.55 
Cerebral Contusion* 
Left 0.28 1.6 0.68 3.72 
Right 0.30 1.5 0.70 3.10 
Bilateral 0.003 4 1.60 9.31 
Sub Arachnoid Haemorrhage*
Left 0.94 1.1 0.21 5.16 
Bilateral 0.37 2.1 0.39 11.83 
Laterality of abnormal CT signs@ 
Left 0.70 0.88 0.47 1.64 
Bilateral  0.005 2.4 1.29 4.38 

P<0.05; *reference is no abnormal CT sign; @reference is right side 
 

Discussion 
The present study summarize that there is 

significant risk of unfavourable outcome 
among patients with SDH in Parietal + 
Temporal region; Cerebral Contusion in 
Temporal, Frontal + Temporal, & Frontal + 
Parietal + Temporal regions and also Patients 
presenting SDH on right sided and bilateral 
Cerebral Contusion. Patients with ≤ three 
abnormal CT signs are having favourable 
outcome as compared with four abnormal CT 
signs. Presence of bilateral abnormal CT sign 
is significantly having unfavourable outcome 
as compared with right side.  

 Among brain injury patients, early 
diagnosis and aggressive management is very 

crucial to prevent further complications of 
ongoing injury process. Identification of 
anatomical site of injury is essential for taking 
appropriate measures to reduce morbidity 
and mortality (1). In acute settings imaging 
helps in accurate localization of any cerebral 
damage. During first 24 hours of injury 
conventional CT scan is considered to be 
imaging modality of choice because of its 
availability, lesser imaging time, able to 
perform on disturbed patients and cost 
effective (2). CT scan is superior in detecting 
any bony damage and bleeding in brain 
parenchymal or meninges or spaces (3). CT 
characteristics not only provide details of 
devastating site but also provide base for 



 
 
 
 
 
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interpreting outcome (4).      
Brain injury is affected by multiple factors 

and heterogeneous in manifestation because 
of which identifying variables specific for 
outcome prediction is challenging. In present 
armamentarium individual or combination of 
CT characteristics scoring system has 
remained vital entity in prognostication of 
TBI patients. The scoring systems have 
incorporated CT characteristics like cisterns, 
midline shift, volume of mass lesions, blood 
in brain spaces, and density of lesion (5, 6). 
Many studies have detailed and verified these 
scoring systems in predicting outcome. The 
scoring systems are not without limitations. 
Prediction of TBI outcome may be better with 
individual or combination of location and/or 
laterality of abnormal CT signs (4, 8, 9, 10).   

The locations of abnormal imaging 
characteristic either focal or diffuse are also 
important in predicting outcome (10). But 
localization of imaging characteristic in 
specific brain lobes (either single or 
combination) may also be useful in outcome 
prediction, because brain lesions in different 
anatomical areas are heterogeneous in 
manifestation (10). A study on paediatric TBI 
predicted outcome based on location of brain 
lesions. In the study the brain were 
distinguished into three zones: zone A 
(cortical structures); zone B (basal ganglia, 
corpus callosum, internal capsule, and 
thalamus); and zone C (brainstem). The 
Magnetic Resonance Imaging (MRI) Fluid-
attenuated inversion recovery (FLAIR) 
hyperintense lesions in mentioned zones were 
correlated with GOS. The study reported that 
Patients with lesion in all three zones were 4.4 

times at the risk of unfavourable as compared 
to lesions only in zone A or both in zone A & 
B (10). In the present study only cortical areas 
are evaluated based on standard anatomical 
demarcation that is frontal, parietal, temporal 
and occipital lobes. Our study reports that the 
patients with abnormal CT signs in one or 
two or three lobes were having favourable 
outcome with reference to abnormal CT signs 
in four brain lobes. The injury to brain in 
multiple areas predicts worst outcome as 
reported from our study and literature.    

The type of CT characteristics that include 
SDH, EDH, SAH, ICH and Intra Ventricular 
Haemorrhage (IVH) plays a significant role in 
prediction of outcome (7, 8). The anatomical 
locations of mentioned CT characteristic also 
have significance in outcome prediction (8, 
9). A study from China correlated daily living 
activities (as assessed by Barthel index) with 
location of brain lesions among TBI patients. 
The study reveals that cerebral contusion in 
temporal, parietal, frontal and occipital lobes 
among moderate to severe TBI patients were 
showing significant difference with outcome. 
The current study reports that cerebral 
contusion in temporal, frontal + temporal, & 
frontal + parietal + temporal region and SDH 
in parietal + temporal region are at the risk of 
unfavourable outcome.  

Laterality of brain injury has significant 
role in prediction of outcome (11). A study 
evaluated occupational profile of unilateral 
TBI patients. The study reported that patients 
with left hemispheric TBI manifest with 
poorer functional independence, ability, 
participation and the quality of performance 
of everyday activities. The study suggested 



 
 
 
 
 

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that patients with left hemispheric brain 
lesion need intensive treatment for better 
improvement (11). The current study 
reported that patients with bilateral abnormal 
CT signs have unfavourable outcome as 
compared with right sided lesions. The 
abnormal CT characteristics like SDH on 
right sided and cerebral contusion on bilateral 
distribution were having worst outcome.  

Limitation; Posterior fossa abnormality is 
not incorporated in the present study, as 
posterior fossa has significant effect on 
outcome (10). Our study is restricted only to 
cortical areas, but sub cortical and brain stem 
regions are also affected in brain injury as 
evidenced in literature (10). In the study 
unfavourable outcome number is lesser than 
one forth of favourable outcome. The present 
study had not grouped severity of injury, 
grouping was important because mild injury 
may not have significance with location of 
brain lesions and outcome (8). ICH and 
cerebral contusion is taken as two different 
entities. In spite of these limitations our study 
provides clue that very commonly available 
CT findings provide higher prediction value 
for TBI outcome.   

Conclusion 
The study endow that anatomical 

distributions of CT findings have potential 
inference in predicting of TBI outcome. 
Further studies should include these variables 
with appropriate anatomical distribution into 
existing scoring system and look for any 
higher predictive values in interpreting TBI 
outcome. 
 

Correspondence 
Dr Amit  Agrawal 
Professor of Neurosurgery 
Department of Neurosurgery 
Narayana Medical College Hospital 
Chinthareddypalem 
Nellore-524003 
Andhra Pradesh (India) 
Email- dramitagrawal@gmail.com 
Mobile- +91-8096410032 

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