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354          V. Pasca et al          Intraoperative ultrasonography in low-grade gliomas 

 
 
 

The role of the intraoperative ultrasonography in low-grade 
gliomas. Case report 

V. Pasca1, Şt.I. Florian1,2, Andreea Magyoros1 

1Cluj County Emergency Hospital, Neurosurgical Department  
2University of Medicine and Pharmacy “Iuliu Hatieganu” Cluj-Napoca 

 

Abstract 
Objective: Use of intraoperative 

ultrasound for localizing tumors and 
determining the extent of resection. 

Materials and methods: We report two 
patients diagnosed with brain tumors that 
underwent intraoperative ultrasonoghraphy 
in localizing and defining the borders of 
tumors and assessing the extent of their 
resection. 

Discussions: Intraoperative ultrasound 
brain scanning is extremely useful to detect 
the cerebral lesion, the relationships with 
the nearby structures, the estimation of 
vascularization, the grade of resection and 
other associated lesions. The tumor image 
is different from the normal anatomical 
CNS structures, and some features like soft 
or hard tissue, cystic or necrotic areas can 
be visualized.  

Conclusion: Cerebral intraoperative 
ultrasound is a benefit for the surgical act, 
thus being the neurosurgeon’s “deep-seated 
eye”. 

Keywords: low - grade glioma, 
ultrasonography mode B, doppler 

Backround 
Medical practice requires a correlation of 

clinical aspects, imaging and treatment 
methods in order to have a successful 

outcome. In the neurosurgical field, 
approaching the intracranial lesion is more 
challenging than in other surgical specialties 
because the cranial vault can not be 
“squeezed” as the neurosurgeon would like 
to do it. In corticalized brain tumors the 
approach is easy. The maximum usage of 
ultrasound takes place during gliomas and 
metastases operations because of their 
subcortical deep-seated localization, where 
the need to pinpoint the tumor site is 
important so that a major brain damage to 
be avoided. CT scan and MR imaging are 
utilized to diagnose brain lesions. 
Intraoperatively, the MRI and ultrasound 
scanning are the tools used to localize the 
lesions. Intraop. MRI is of a higher 
sensitivity and can be correlated with the 
preop. MR images but, it’s still expensive, 
needing a special equipment and a quite 
long examination time. The real-time B-
mode and Doppler sonography is easy, fast, 
reproducible, inexpensive and relatively 
simple equipment (1,5). One of the 
limitations of the intraoperative 
ultrasonography is that it is difficult to 
correlate with the preoperative 
examinations (CT, MRI ), because the 
slices are different and the quality of the 
image somehow is poorer. However, some 
lesions are highly visible in ultrasound 
without requiring contrast enhancement. 



 
 
 

Romanian Neurosurgery (2010) XVII 3: 354 – 358          355 

 
 
 

This study, supported by two clinical case 
presentations, highlights both the 
usefulness of the intraoperative ultrasound 
for lesion site and the quality of the 
echographic images. 

Material and methods 
Case one  
(Figure 1 A, B, C, D) 
Patient BC, a 36 years old male, 

admitted with headaches, vomiting, right 
omonime hemianopsy. The native and 
contrast enhanced cerebral CT scan 
revealed a hypodense lesion in the left 
occipital lobe with slight post contrast 
enhancement. T1 weighted MRI images 
showed a decreased signal intensity lesion 
with distortion of the nearby structures and 
low contrast enhancement. On T2-
weighted images the lesion is of low signal 
intensity and with ill-defined tumor 
margins. Intraoperative ultrasound was 
performed for tumor location and its 
relationships with the surrounding 
anatomical structures. The sonographic 
image was of a homogenous, 
hyperechogenic lesion, poor delineated 
with the aspect of an amphora with the 
neck oriented upwards. The cortical sulcus 
for the optimal approach to the tumor was 
also visualized and the Doppler mode 
unveiled a low-grade tumor vascularization. 
Macroscopically, a grey, friable, poorly 
defined, poorly vascularized and infiltrative 
tumor was removed. After ablation, the 
ultrasound was used to asses the extent of 
resection at the end of surgery. There was a 
clear boundary between the tumor and the 
cerebral edema and no signs of hemorrhage 
or ischemic lesions after surgery. 

 

 
Figure1 A Preoperative B mode ultrasonography 

 
Figure 1 B B mode ultrasonography: for the tumor 

and reper 

 
Figure 1 C Postoperative ultrasonography 



 
 
 
356          V. Pasca et al          Intraoperative ultrasonography in low-grade gliomas 

 
 
 

 
Figure 1 D MRI cerebral 

 
Figure 2 A Preoperative ultrasonography 

 
Figure 2 B Postoperative ultrasonography 

highlighting zone resection and the tumoral rest 

 
Figure 2 C Doppler ultrasonography 

 
Figure 2 D MRI cerebral 

 
Case two 
(Figure 2 A, B, C, D) 
Female patient, MA, 29 years old 

admitted in our department with partial 
seizures, dromomania, moderate 
intracranial hypertension syndrome, 
without papillary stasis at the 



 
 
 

Romanian Neurosurgery (2010) XVII 3: 354 – 358          357 

 
 
 

ophthalmoscope examination. On the CT 
scan a hypointense lesion in the left 
temporal lobe with poor enhancement after 
contrast administration and displacement of 
the neighboring structures was detected. 
The MRI T1-weighted images showed the 
left temporal lobe lesion, hypointense, 
poorly defined margins, with little contrast 
enhancement and with the corresponding 
mass effect. In T2-weighted imaging, the 
lesion has a moderate signal intensity and 
cerebral edema around the tumor mass. 
During surgery, the echographic imaging 
helped in localizing and defining the 
margins of the tumor. The tumor echo-
image was hyperdense, homogenous with 
no well defined borders, poorly 
vascularized and with a moderate mass 
effect. After evaluating the cortical sulci 
above the tumor and the depth of the 
tumor, an ash-grey colored, friable, low-
grade vascularized and poorly defined mass 
lesion was removed. Postoperatively, the 
resection control was done with the real-
time B mode ultrasound. 

Discussions 
Astrocytomas are intraaxial, infiltrating 

brain tumors with a poor blood supply. 
According to the WHO grading system 
there are three types: WHO grade I 
corresponds to pilocytic astrocytoma, WHO 
grade II corresponds to low-grade (diffuse) 
astrocytoma, WHO grade III corresponds 
to anaplastic astrocytoma. 

Grade II astrocytoma appears as a poorly 
defined, homogeneous, infiltrating, low 
blood supply, usually unilocular lesion. 
Astrocytomas of the CNS arise in the 
subcortical areas and the regional effects 
include compression, invasion, and 
destruction of the brain parenchyma, 
leading to cortical surface flattening and 

altered cortical vascularization. 
Sonographically, the lesion is hyperechoic, 
homogenous with ill-defined margins and 
perilesional edema which is seen as less 
echo-intense than the tumor. The mass 
effect on the surrounding CNS structures 
is evident and the cortical sulci are left in 
place, the tumor extending along the 
arcuate fibers (7, 8 and 9). On the Doppler 
mode the tumor vascularization is poor and 
the blood supply to the surrounding brain 
is affected according to the tumor 
localization. There are no intratumoral 
cysts or necroses which are seen as hypo or 
anechogenic areas.  

As Keles et al. stated,(6) the main 
advantage is that the intraoperative 
ultrasound is a real time examination 
performed on certain anatomical features of 
each operative field. As it requires a certain 
pressure on the cortex during ultrasound 
examination, the brain structures and the 
image of the lesion are slightly modified 
from that of CT or MRI investigations but, 
with all those the relationship between 
them remains the same. Brain CT and MRI 
studies are useful to pinpoint brain injuries 
and their effect on nearby structures, giving 
an overview of the intracranial content and 
details of lesion. The drawback is that they 
are not “live” examinations. 

Intraoperative cerebral ultrasonograghy 
uses ultrasonic waves to highlight the 
injury. Images are formed by analyzing the 
reflected waves from interfaces situated at 
different distances from the transducer (5). 
Using distinct physical principles the echo 
images are different according to one of the 
three modes used in ultrasonography. 
Intraoperative cerebral echography is a 
complementary examination for detecting 
the mass lesion in order to obtain the most 
easy and safe surgical approach (2,4). After 



 
 
 
358          V. Pasca et al          Intraoperative ultrasonography in low-grade gliomas 

 
 
 

tumor excision, the cerebral sonography is 
useful in assessing the extent of the 
resection, the anatomical relationship and 
the existence of some of the surgery 
produced injuries like hemorrhage, cerebral 
ischemia. Ultrasound B-mode Doppler 
sonography enables the estimation of 
tumoral and perilesional vascularization and 
the pulsed Doppler specifies if the vessels 
are of arterial or venous type. Signs like 
cortical blood supply, flattening of the 
cortical sulci, changing in the consistency of 
brain parenchyma at light palpation are 
indirect marks of a tumoral mass, and they 
are only clues in the whole surgical 
planning. B-mode real-time linear 
sonographic scanning can be used to 
identify and localize the margins of the 
lesion, the degree of the vascularization, the 
relationship to the surrounding 
neurovascular structures and cortical 
grooves, the type of the mass ( cystic, 
parenchymatous or mixt), size and the 
depth of the lesion(3).  

Conclusion 
Real-time B-mode intraoperative 

ultrasound is a complementary, convenient 
and user-friendly method for identifying, 
localizing, characterizing the pathological 
aspects, assessing the extent of tumor 
resection, pointing the relationships with 
surface and deep cerebral structures and, 
recognizing surgical complications at the 
time of tumor removal (hemorrhage, 

ischaemia, edema). The intraoperative 
ultrasound scanning is a useful medical 
tool, which doesn’t exclude the CT and 
MRI examinations, and needs a good 
understanding of ultrasonography and 
anatomy. It is considered as the 
neurosurgeon’s “deep-seated” eye. 

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