Results
• As P<0.05
• As P<0.05
• As P<0.05
In this study, the 280 data of female patients diagnosed with uterine cancer
(including endometrial and other types of sarcoma) were extracted from the
hospital's archival files
and analyzed.
Demographical Information of Patients
Data analysis showed that there was no
significant relationship between age, gravid and parity between the two groups (P>0.05).
However,
it was found that the difference in the frequency of grades I, II and III in the two
groups was
statistically significant (P=0.008). Also, in relation to the type of pathology,
there were three
types of endometrioid, serous, clear cell, and carcinoma sarcoma, and the difference
in frequency
between the two groups was statistically significant (P<0.001, Table- 1 ).
Pathological Information of Patients
The results showed that the frequency of Myometer,
LVSI, cervix, serous, tube, intra-abdominal, lymph node and omentum was different
between the two
groups, so these differences were statistical significant (P<0.05). Based on
this, it was found
that their frequency was higher in the group without OI. Also, in terms of
complaints, which were
divided into different categories, a comparison was made between the two groups,
which was
statistical statistically (P50%)
myometrial invasion (OR=2.06, 95% CI: 1.04_3.9, P=0.96), non-deep (<50%)
myometrial invasion
(OR=0.3, 95% CI: 0.13_0.65, P=0.23), omentum involvement (OR=21.36, 95% CI:
5.50_82.94, P=0.03),
P.P.C (OR=10.96, 95% CI=3.38_35.46, P=0.015), full myometrial invasion (OR=5.2, 95%
CI=1.51_17.99,
P=0.28), cervical stromal involvement (OR=2.14, 95% CI=1.04_4.40, P=0.75),
parametrial invasion
(OR=2.7, 95% CI=1.06_7.22, P=0.36), uterine serosa extension (OR=5.6, 95%
CI=2.16_14.60, P=0.63),
fallopian tube involvement (OR=6.14, 95% CI= 2.53_14.90, P=0.48), lymph node
involvement (OR=2.71,
95% CI=1.10_6.68, P=0.77), and serous carcinoma (OR=5.6, 95% CI=2.36_13.60, P=0.006)
showed
significant differences (Table- 3 ).
ROC Curve Analysis
In Figure- 1 , ROC curve analysis
was analyzed for the diagnostic value of demographic variables in patients. Based on
this, the
results showed that only the variable and grade was significant (P=0.013). It was
also determined
the sensitivity and specificity for age (sensitivity: 62.26%, specificity: 50%),
gravid
(sensitivity: 81.32%, specificity: 57.14%), parity (sensitivity: 47.08%,
specificity: 60.71%), and
grade (sensitivity: 74.32%, Specificity: 53.57%) was calculated.
In Figure- 2 , ROC curve analysis was analyzed for
the
diagnostic value of pathology variables in patients. The results showed that all
four variables of
cervix, serous, tube and intra-abdominal were significant (P<0.05). Also,
sensitivity and
specificity for cervix (sensitivity: 81.32%, specificity: 57.14%), serous
(sensitivity: 93.77%,
specificity: 50%), tube (sensitivity: 93.77%, specificity: 43.46%), and
intra-abdominal
(sensitivity: 96 .89%, Specificity: 28.57%) was calculated.
Conclusion
Overall, this study underscores the significant risk factors for OI in EC, which
include deep and
non-deep myometrial invasion, omentum involvement, ascites, full stromal cervical
involvement,
parametrial invasion, uterine serosa extension, fallopian tube involvement, lymph
node
involvement, and serous carcinoma. P.P.C, omentum involvement, and serous carcinoma
are powerful
predictors.
Identifying these risk factors is crucial for developing effective treatment
strategies,
especially for preserving fertility in young women. Future research should focus on
larger,
prospective studies and the development of genetic tools to enhance diagnostic
precision and
treatment outcomes.
Discussion
Figure 1 . Roc curve analysis related
demographic variables. A: parity, B: Age, C: grade and D: gravid.
Figure 2 . Roc curve analysis related
pathological variables. A: cervix, B: serous, C: tube, and D:
inta-abdominal.
The main objective of present study was to identify the factors that cause OI in EC
and mitigate
this complication by addressing modifiable factors. Identifying these risk factors
is critical
to developing effective treatment strategies and improving patient management. The
results
showed that the frequency of Myometer, LVSI, cervix, serous, tube, intra-abdominal,
lymph node
and omentum was different between the two groups, so these differences were
statistical
significant (P<0.05).
Based on this, it was found that their frequency was higher in the group without OI.
Also, in
terms of complaints, which were divided into different categories, a comparison was
made between
the two groups, which was statistical statistically (P50%) myometrial invasion, non-deep (<50%) myometrial invasion, omentum
involvement,
P.P.C, full myometrial invasion, cervical stromal involvement, parametrial invasion,
uterine
serosa extension, fallopian tube involvement, lymph node involvement, and serous
carcinoma
showed significant differences In addition, our study confirms that myometrial
invasion is a
significant factor associated with OI. Both deep (>50%) and non-deep (≤50%)
myometrial
invasion were significantly associated with outcome, with deep invasion representing
a higher
risk. This is consistent with previous clinical studies demonstrating an association
between
deep myometrial invasion and OI in patients with EC [ 18 ][ 19 ][ 20 ] [ 14 ][ 21 ][ 22 ],.
High histologic grade (G2-G3) and lymphatic space
invasion (LVSI) were also identified as valuable indicators for assessing OM,
consistent with
our findings and previous studies [ 23 ][ 24 ].
This finding is consistent with a 2022 study that identified age as a variable
influencing OI in
EC patients [ 25 ]. It is essential to consider
age-related
differences when developing treatment strategies for EC patients. In a similar study
conducted
by Matoba et al., they reported that in the analysis, pathological findings
indicating that
Lymphatic space invasion (LSI), cervical stromal involvement (CSI) peritoneal
dissemination, and
ovarian swelling (OvS) were cause progression of disease. Additionally, type 2
histologic type,
LSI, CSI, and OvS were significantly more common in cases with OM in stage I and II
without
adnexal pathological factors. In multivariate analysis, LSI, CSI, and OvS emerged as
significant
risk factors for OI [ 23 ].
Type II EC cancer (e.g., serous or clear cell carcinoma) is more likely to
metastasize to the
ovaries compared to Type I (endometrioid) EC [
23 ][ 26 ]. In a 2023 study of 1240
patients with EC, Qian Li and
Xin Zhang concluded that deep myometrial invasion, lymph node metastasis, and higher
CA125
levels may be independent high-risk factors for OI in patients with EC. OI has a
higher
influence on the prognosis in patients with low-risk EC [
27 ]. OI in EC patients significantly impacts prognosis. It is associated
with poorer
outcomes and lower overall survival rates. The presence of OI often necessitates
more aggressive
treatment strategies and can affect decisions regarding fertility preservation
[ 20 ][
27 ][ 28 ].
One large multicenter retrospective study conducted by Ignatov et al. [ 20 ] in 2329 patients with EC, the 5-year overall
survival rate was
significantly lower in patients with OI (51.9%) than those without (84.6%). They
found that OI
in EC patients is associated with poorer prognosis and reduced survival rates
compared to those
without OI [ 20 ]. EC is still the most common
cancer of
the female reproductive system and is responsible for around 20% of deaths worldwide
[ 29 ]. The high invasiveness and metastatic
capacity of this
cancer, especially to the ovaries, requires comprehensive treatment strategies,
including
primary hysterectomy, bilateral salpingo-oophorectomy, and pelvic and para-aortic
lymphadenectomy.
This standard treatment protocol is critical even for young patients with low-risk,
early-stage
EC, where oophorectomy is performed as part of the surgery to reduce the risk of
metastasis.
Despite the solid findings, this study faced some issues, including a limited number
of eligible
patients and a retrospective case-control design. Inconsistent pathology reports of
precursor
lesions such as endometrial hyperplasia or concurrent ovarian endometriosis could
have
influenced the final diagnosis. Therefore, future research should focus on
developing novel
genetic tools to accurately classify patients with complex symptoms and strive for a
more
accurate research database.
Introduction
Endometrial cancer (EC) is a cancer that occurs in women. [ 1 ][ 2 ]. According to the
statistics published in the past decades, the prevalence of EC in the world is
increasing. Accordingly, in 2020, about 4.5% of women’s cancers are EC. Also,
EC-related deaths in the world are reported to be 97,000 [ 3 ]. Despite the expansion of knowledge and progress in the
treatment of patients, the death rate of patients is still high [ 4 ][ 5 ].
When the diagnosis of EC in patients is delayed and the disease is detected in
advanced stages, the survival rate of patients decreases significantly. Metastasis
is an important issue that health workers are facing today in connection with EC
patients. During EC progression, malignant cells metastasize to various organs. One
of the most important organs is actually the ovary. Ovarian involvement (OI) has
been observed in many EC patients. Despite infertility in the patient, this conflict
also reduces their survival [ 6 ][ 7 ][
8 ][ 9 ][ 10 ].
Recently, it has been shown that there are many risk factors related to EC metastasis
in patients. Each of these risk factors, based on their nature, has a different
effect on EC metastasis in ovarian metastasis [
11 ][ 12 ][ 13 ]. These risk factors are acquired and inherited. Some study
conducted asses risk factors in EC, But the important point is that the risk factors
are different in each region based on the conditions of the patients [ 14 ][ 15 ][ 16 ].
Understanding the risk factors associated with OI is clinically significant for
preserving fertility and other complications and improving prognosis. This issue
impacts treatment decisions, outcomes, prognosis, and patient management. Some
studies have been conducted to investigate this matter. However, many risk factors
related to OI have not been identified. The current research focuses on assessing
the risk factors associated with OI in patients with EC.
Coi Statement
The authors declare that they have no conflict of interest.
Acknowledgement
We wish thank you of all our colleague in Isfahan university of medical science.
Materials And Methods
Study Design
This retrospective study was conducted to determine the risk factors of OI following
EC in female patients with a definitive diagnosis of uterine cancer admitted to Imam
Khomeini Hospital in Tehran over the preceding 15 years, between 2010 and 2024. The
diagnosis of EC in patients was confirmed based on the results of tests and also
based on pathology results. This was while the patients were checked under the
supervision of the relevant specialist.
Inclusion and Exclusion Criteria
In this study, 280 female patients diagnosed with uterine cancer (including
endometrial and non-endometrial adenocarcinoma) were included for analysis. Patient
data were extracted from the hospital’s archival records. Patients with a history of
pre-existing ovarian diseases, infertility, prior use of hormonal medications such
as oral contraceptive pills (OCPs), or pelvic infections preceding uterine cancer
diagnosis were excluded.
Data Collection
Through a retrospective review of hospital records, comprehensive patient data were
collected encompassing demographic features (age, gravidity, parity) and
lesion-specific details (pathological grading, uterine cancer subtypes, myometrial
invasion, cervical, lymph node, non-endometrioid histology, and vascular lymphatic
space invasion). Patients were stratified into two groups based on evidence from
imaging reports and biopsy findings: those with OI involvement and those without.
Subsequently, these two groups’ baseline parameters were compared to discern factors
associated with OI development.
Ethical Considerations
Patients' private information remained utterly confidential. Their diagnostic and
treatment paths were not disturbed, and no extra cost was imposed on the patient.
Any exploitation of patients' information was done with their permission and the
approval of the center's research assistant (IR.TUMS.IKHC.REC.1402.299).
Method for Calculating Sample Size
Based on the study by Ashrafganjoei et al. [ 17 ],
which reported a prevalence of OI at 1.11%, and considering a confidence level of
95% and a precision level of 5%, the minimum required sample size for the study was
determined to be equivalent to 152 cases.
N=P ˟ (1 - P) ˟ Z1-α/2 2/d2
P=0.111, α=0.05, Z1-α/2= 1.96, d=0.05
N=152
Statistical Analysis
The results were reported as mean ± standard deviation (mean ± SD) for quantitative
variables and percentages for categorical variables. The data distribution was not
normal, so the Mann-Whitney test was used. Mann-Whitney was applied to compare
quantitative variables, while chi-square test was used for qualitative variables.
Multiple logistic regression analysis was conducted to identify risk factors related
to OI. A significance level of 0.05 or lower was considered statistically
significant. Statistical analysis was carried out using SPSS version 23 software
(IBM Corp., Armonk, NY., USA).
Text is read by the "Ask this paper" AI Q&A widget below.
Extraction quality varies by source — PMC NXML preserves structure
cleanly, OA-HTML may include some navigation residue, and OA-PDF can
have broken hyphenation. The publisher copy
(via DOI)
is the canonical version.