Material and Method: The authors reviewed the histopathological results of 383 brain tumors, including IOFS and permanent histological diagnosis. The cases were classified into three diagnostic compatibilities (i) Perfect fit; the diagnosis of IOFS was identical to the permanent diagnosis, (ii) Partial compatibility; IOFS diagnosis was not incorrect but was too broad to be considered full compatibility, (iii) Conflict; IOFS diagnosis is completely different from the permanent diagnosis. The permanent diagnosis was used as a primary criterion and was compared to IOFS diagnosis and recurrence rate using different statistical methods.
Results: 84% of the patients underwent craniotomy and tumor resection, while 15% only underwent tumor biopsy. Approximately, 53.8 % of the cases revealed perfect matching in the diagnosis between IOFSs and permanent sections, while 16.2% of the cases revealed complete mismatching in the diagnosis between the sections. The remaining 30% of the cases showed partial compatibility in the diagnosis between the two diagnostic methods. There was no significant difference in recurrence rate among all cases of different diagnostic compatibility (p=0.54).
Conclusion: There is a diagnostic discrepancy between IOFSs and permanent sections. However, cases that revealed no consensus in the diagnoses showed no negative effect on the patient outcome. Further studies should be conducted to explore the reasons of this conflict in the two diagnostic methods.
Intraoperative frozen section (IOFS) diagnosis of brain tumors plays an important role in assessing the adequacy of the specimen, determining the surgical treatment plan, improving surgical procedures, and facilitating postoperative follow-up. In certain cases, when unexpected lesions cannot be identified by radiological imaging, the surgeon can determine the best procedure and endpoint of the operation [2,3]. This can reduce the incidence of surgical complications and avoid unnecessary second surgical procedures. The key criteria and indications for requesting an intraoperative diagnosis by the surgeon are as follows: (a) intraoperative surgery would be affected by the diagnosis, (b) an unexpected lesion appears during surgery that is different from what was clinically suspected, (c) the primary goal is to obtain a biopsy diagnosis, and (d) the necessity to assess the margins if a total resection is planned [4-6]. The distinction between primary tumor, lymphoma, metastatic tumor, or unusual lesions are considered the main reasons for requesting intraoperative diagnosis of brain tumors. Sometimes, the tumor is not accessible by surgery, and thus a stereotactic biopsy with IOFS is recommended. The assessment of brain tumors through IOFS is commonly used in clinical practice to verify the origin and type of tumor; however, the final diagnosis should be reported later after the permanent section [4,6].
Several studies have discussed the diagnostic accuracy of IOFS in assessing brain tumor type and grading, and inconsistencies were found between IOFS diagnosis and permanent diagnosis. Nevertheless, permanent paraffinembedded examination remains the gold standard in diagnosing brain tumors. In Saudi Arabia, no publications have discussed the diagnostic accuracy between IOFS and permanent tissue diagnosis of brain tumors. In this study, we aimed to assess the compatibility between the results of frozen sections and permanent sections in patients diagnosed with brain tumors. We also discussed the reasons attributed to the lack of diagnostic accuracy between the two diagnostic methods.
Histopathological Confirmation
The histopathological report of IOFS and permanent
paraffin-embedded section of each patient with a brain
tumor was examined. The diagnostic compatibility between the two diagnostic methods was determined on the basis
of tumor type and grading. The cases were classified into
three degrees of diagnostic compatibility as follows: 1)
the diagnosis of IOFS was identical to the final diagnosis
(perfect fit); 2) the diagnosis of IOFS was not incorrect but
was too broad to be considered fully compatible (partial
compatibility); and 3) the diagnosis of IOFS were incorrect
and differs from the final diagnosis (conflict).
Statistical Analysis
Statistical analysis was performed using SPSS software
(version 20). To describe the data, we used means,
frequencies, and percentages. To assess the diagnostic
compatibility of different methods, we used the linear
model, ANOVA and peoples Chi-square test. The number
and types of discrepancies were identified.
Table I: Descriptive distribution of the data in this study.
Diagnostic Compatibility Between IOFS and Permanent
Sections
The diagnostic compatibility between IOFS and permanent
section showed comprehensive variability, as 53.8%
(n=206) of the cases showed perfect match between IOFS
and permanent section diagnosis, while 16.2% (n=62)
of the cases showed complete mismatch. Furthermore,
30% (n=115) of the cases showed partial compatibility
between the two diagnostic methods (Table I; Figure 2).
For example, the cases diagnosed as glioblastoma with
IOFS were also diagnosed as glioblastoma with permanent
section; however, these cases represented 13% perfect
compatibility among all investigated brain tumors (Table
II). In a few cases, glioblastomas were misdiagnosed with
IOFS as low-grade gliomas, necrotic cells, or glioneuronal
tumors (Table III).
Table III: List of brain tumors with their misdiagnosis with intraoperative frozen sections (IOFS).
Diagnostic Compatibility of Low-Grade and High-
Grade Gliomas
Approximately 9% of the cases diagnosed as low-grade
gliomas with IOFS were diagnosed as high-grade gliomas
with permanent sections, and one case was found to be
a meningioma (Table II). Conversely, 17% of the cases
diagnosed as high-grade gliomas with IOFS were diagnosed
on permanent sections as either low-grade gliomas or a different histological subtype such as medulloblastoma or
metastasis. Furthermore, 19% of the cases diagnosed with
infiltrating glioma with IOFS showed partial compatibility
on permanent sections. The final diagnosis was grade II,
such as cases of oligodendrogliomas (Table II).
Diagnostic Compatibility Between Atypical, Reactive,
and Necrotic Cells
From the 22 cases diagnosed as atypical glial cells with
IOFS, two of them were permanently diagnosed as mature
teratoma and hemangioblastoma. The remaining 20
cases of atypical glial cells were compatible with the same
glioma histogenesis, regardless of the grading. These cases
were considered partially compatible. The cases that were
showing reactive cells in IOFS (n=6, 9.6%) were diagnosed
differently from permanent sections (Table II). These
cases included teratoma, hemangioblastoma, germinoma,
ganglioglioma, pilocytic astrocytoma, and pituitary
adenoma. Cases for which IOFS revealed necrotic cells
were diagnostically deferred at the time of surgery. Their
permanent sections revealed malignant tumors except one
case (pilocytic astrocytoma in the brainstem), which was
rediagnosed as diffuse midline glioma.
Relationship Between Recurrence Status and Diagnostic
Compatibility
There was no statistically significant relationship between
the recurrence rates and the diagnostic compatibilities
of different brain tumors (p=0.54) (Table IV). Cases that
showed conflicts in diagnostic compatibility showed no
significant differences in recurrence rates compared to
cases with perfect diagnosis matches. This clarifies that
conflict in the diagnostic compatibility between IOFS,
and permanent histological sections may not affect tumor
recurrence rate.
The IOFS analysis was first introduced in 1891 by a pathologist at Johns Hopkins Hospital, and is currently used worldwide. The application of this method became much easier through improvements in cryostat devices [7]. IOFS is mainly useful for solid and stretchy tumors such as meningiomas, schwannoma, and most metastases in which cell smears are difficult to prepare [8,9]. It also provides good architectural detail of the lesion, and better reveals histological patterns and cell morphology [10,11]. IOFS is commonly used to verify the competence, and origin of brain tumors [4,6].
There are two methods to assess the diagnostic compatibility between IOFS and permanent sections. The first method is to determine whether the IOFS diagnosis matches the permanent diagnosis, e.g., glioblastoma diagnosed with IOFS is also diagnosed as glioblastoma with permanent section. The second method is to determine whether the permanent diagnosis is histologically close to the IOFS diagnosis, e.g., glioblastoma diagnosed on permanent section is observed as atypical glial cells in frozen sections. In our current study, both methods were used; however, we focused more on the first method as it represents the foundation of the general diagnostic accuracy of brain tumors.
The compatibility between IOFS and permanent section in clinical practice always shows diagnostic diversity. In our study, 53% of the lesions diagnosed on permanent histological sections matched the IOFS diagnosis, while 16% showed complete mismatching (Figure 2). This variation is considered clinically significant as it reveals that IOFS itself should not be solely used as a definitive diagnostic method. Most of the discordances between IOFS and permanent histological sections were observed in highgrade gliomas. This might be attributed to the difficulty in the microscopic interpretation, and the lack of experience. It is sometimes quite hard to identify the cytoplasmic processes in the frozen section, which makes it difficult to differentiate glial background from other types of tumors, particularly metastasis. For example, glioblastomas may be misdiagnosed as low-grade gliomas during the IOFS. This is because the peripheral edges of glioblastoma may contain reactive or atypical glial cells without necrosis or endothelial proliferation. Furthermore, the distinction between high-grade gliomas and metastasis is also difficult unless the malignant glial cells with gliotic background are clearly seen. In diffusely astrocytic cases, missing IOFS diagnosis of astrocytomas could be due to the thickness of the sections and technical problems with staining, which disrupts the cellular morphology. The difficulties in diagnosing hemangioblastoma with IOFS were because most hemangioblastomas are bloody and vascular, which may mask the cellular features of the tumors. Cases that showed reactive or necrotic cells with IOFS revealed different diagnostic results on permanent sections. For example, most of the cases diagnosed as necrotic cells with IOFS had a permanent section diagnosis of glioblastoma, while IOFS diagnosis of reactive cells had a permanent section diagnosis of teratoma, germinoma, ganglioglioma, pilocytic astrocytoma, or pituitary adenoma. These findings depend on the biopsy location, and the size of the necrotic component in the tumor.
The diagnostic accuracy in our study was 53%. In other studies, the diagnostic accuracy was 92.4% in Talan- Hraniloviæ et al. [12], and 95% in Roessler et al. [13] with 89% complete concordance among 4,172 patients. The most accurate IOFS diagnoses in Roesslers study were made in cases of meningioma (97.9%), metastasis (96.3%), and glioblastoma (95.7%) [13]. Although the high-grade gliomas showed high discordance between IOFS and permanent histological section, the diagnostic compatibility was still acceptable. Plesec et al., had almost 3% discordancy among 2,156 cases. Approximately 80% of these cases were spindle cell lesions, astrocytoma versus oligodendroglioma, lymphoma, reactive versus neoplastic process, and tumor overgrading [14]. We also have found that 97% of meningioma cases showed perfect matching between the IOFS and permanent section diagnoses. One case turned out to be a schwannoma.
Several reasons might be attributed to this mismatching. Theoretically, the reasons can either be related to the quality of surgical procedure or the quality beyond the laboratory diagnostic techniques. If the neurosurgeon takes the biopsy from the necrotic part of the tumor or from the surrounding reactive area, the tissue may be fragmented, nonviable, or nondiagnostic. An experienced neurosurgeon should navigate the tumor using a brain imaging navigator before taking the biopsy. However, multiple punch biopsies are recommended in cases where the necrotic parts are deeply seated in the tumour center. Freezing processes may also mask the tissue diagnosis. Calcification, autolysis, improper hematoxylin and eosin staining, or inappropriate usage of hemostatic agents all can contribute to incorrect diagnosis.
As we mentioned before, one of the common reasons for diagnostic disagreements between IOFS, and permanent paraffin-embedded section is the microscopic interpretation. Most pathologists who see the brain tumors during IOFS are non-neuropathologists with limited experience in the brain. Pathologists, who see brain tumors during IOFS, must have enough knowledge to correlate between brain imaging and histology. This would help pathologists minimize the differential diagnoses, and approximate the diagnostic probabilities with neurosurgeons. This problem is more common in developing countries where health care systems have shortage of neuropathologists. A fully certified neuropathologist with a minimum two-year training in neuropathology will have better diagnostic outcome than a non-neuropathologist.
CONFLICT of INTEREST
The authors declare no conflicts of interest.
AUTHORSHIP CONTRIBUTIONS
Concept: MK, Design: MK, Data collection or processing:
YM, AB, RS, AL, TS, AS, Analysis or Interpretation: MK,
SB, SH, Literature search: MK, SB, RS, Writing: MK, SB,
YM, RS, AS, Approval: MK,SB, AL.
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