Endometrial cancer (EC) is the most common gynecological tumor worldwide and patients suffering of this malignancy are usually faced with high cancer-specific survival rates due to an early-staged diagnosis after the surgical treatment.
Historically classified as type I (i.e., low-grade, hormone-dependant, young patients, good prognosis) or type II (i.e., high-grade, hormone-independent, older patients, poor prognosis), the EC was posteriorly stratified in four molecular subtypes based on The Cancer Genome Atlas (TCGA).
In these settings, we sought to re-explore the association of well-known prognostic factors with recurrence in presumed early-stage low-risk EC patients using our 15-year single-surgeon experience from Northeast Brazil. Furthermore, we add special attention to explore rate of adjuvant therapy in this cohort of patients from our private surgical practice.
A retrospective cohort study was carried out on patients who underwent surgical treatment for EC at the level of our private clinic, from September 2003 to August 2017. Using a prospectively maintained database by Bezerra ALR, we selected patients underwent simple hysterectomy plus bilateral salpingo-oophorectomy due to EC, histologically confirmed by a preoperative endometrial sampling. We limited our study to adults (≥18 years) with presumed early-stage low-risk disease (i.e., FIGO I, endometrioid histology, grade 1 or 2, and limited myometrial invasion), and excluded those cases in whom the main medical records were not available, those with non-endometrioid histology at the final pathology and also cases with follow-up losses. The study protocol was reviewed by our ethics research committee (CAAE: 88368818.3.0000.5569, acceptance protocol No.: 040861/2018; April 25, 2018).
We re-explore well-known clinicopathological prognostic factors such as age, lymph node dissection, histological grade, myometrial invasion (MMI; <50% vs. ≥50%), cervical stroma involvement, lymph node metastasis, peritoneal cytology, lymphovascular invasion (LVI) and pathological stage. Lymph nodes dissection was performed at the surgeon's discretion in patients with clinically suspicious nodal involvement or just as a sampling dissection. The post-operative pathological exams were also reviewed in order to fit the pathological stage to the current version (AJCC/TNM, 2018). During the period of this study, the adjuvant therapies were conducted as most of guidelines available recommended. Follow-up scheduling included physical exam every 3 to 6 months for 2 years, every 6 to 12 months for the next 3 years, and then, annually. Imaging exams such as pelvic/abdominal ultrasound or CT-scans and tumor markers such as serum CA 125 were performed every 6-12 months or when clinically required.
Continuous variables were summarized as medians (interquartile range) and categorical variables as frequencies (percent). We explored overall (OS) and disease-free survivals (DFS) rates by Kaplan-Meier estimates from the date of surgery to the corresponding event, and the prognostic value of clinicopathological factors for DFS was assessed by univariate analyses. The association of clinicopathological factors with recurrence was assessed using the log-rank test as an univariate analysis. Statistical analyses were performed using the STATISTICA Data Analysis Software System, Version 8.0 (Statsoft, Inc., Tulsa, OK, U.S.), considering a significant two-tailed p-value of 0.05.
Over a 15-year of our private surgical practice, 141 patients who underwent surgical treatment for clinically early-stage endometrioid carcinomas were selected to study and 105 of them fit the criteria for this analysis. Patients excluded from this review involved those with a diagnosis other than endometrioid adenocarcinoma in the hysterectomy specimens (n=6), lost from follow-up (n=19) and missing or unclear data at the medical records (n=11). Patients in this sample underwent total hysterectomy plus bilateral salpingo-oophorectomy without any lymph nodes dissection (n=11, 10.5%) or with a pelvic sampling dissection (n=94, 89.5%), and the preoperative staging was based on magnetic resonance imaging in 68.6% (n=72/105) of patients. Their baseline characteristics are summarized in
| Prognostic factors | n (%) or median (Q25 - Q75) |
|---|---|
| Age (years) | 59 (53 - 68) |
| <60 | 55 (52.4) |
| ≥60 | 50 (47.6) |
| Final histological grade G1 | 67 (63.8) |
| G2 | 34 (32.4) |
| G3 | 4 (3.8) |
| Myometrial invasion <50% | 74 (70.5) |
| ≥50% | 31 (29.5) |
| Lymphovascular invasion Present | 6 (5.7) |
| Absent | 22 (21) |
| Not Reported | 77 (73.3) |
| Cervical involvement Present | 8 (7.6) |
| Absent | 97 (92.4) |
| Lymphnode metastasis Present | 5 (4.8) |
| Absent | 89 (84.8) |
| Not Assessed | 11 (10.4) |
| Pelvic washing Positive | 2 (1.9) |
| Negative | 95 (90.5) |
| Not Assessed | 8 (7.6) |
| Pathological stage I | 92 (87.6) |
| II | 6 (5.7) |
| III | 7 (6.7) |
Figure 1 Kaplan-Meier survival estimates for disease-free (red line) and overall (blue line) survivals. The 3-year survivals were 88.1% and 97.7%, respectively.
Adjuvant therapies ware applied in 43 (40.1%) of patients as pelvic radiotherapy (n=31, 29.5%) or chemoradiation (n=12, 11.4%).
Our univariate analysis confirmed histological grade 3 (3y-DFS of 89.9% vs. 33.3%, p=0.004), MMI ≥50% (3y-DFS of 95.2% vs. 71.3%, p=0.003), lymph node metastasis (3y-DFS of 88.3% vs. 60%; p=0.028) and more advanced pathological stages (3y-DFS of 91.2% vs. 56.3; p<0.001) as significantly associated to recurrences. An overview of this univariate analysis is shown in
| Variable (categorized as in parenthesis ) | 3y-DFS | p-value |
|---|---|---|
| 91% vs. 84.5% | 0.313 | |
| Grade (G1/2 vs. G3) | 89.9% vs. 33.3% | 0.004 |
| Myometrial invasion (<50% vs. ≥50%) | 95.2% vs. 71.3% | 0.003 |
| Cervical involvement (Absent vs. Present) | 90.1% vs. 56.4% | 0.128 |
| Lymphovascular invasion (Absent vs. Present) | 80% vs, 66.7% | 0.547 |
| Pelvic washing (Negative vs. Positive) | 87.8% vs. 0% | 0.760 |
| Lymph node metastasis (Absent vs. Present) | 88.3% vs. 68% | 0.028 |
| Pathological staging (I vs. II or III) | 91.2% vs. 56.3% | 0.005 |
The present study confirmed the association of classical prognostic factors such as high histological grade, deeper MMI, lymph node metastasis and more advanced pathological stages with disease recurrence in this cohort of patients with clinically early-stage lowrisk EC. As previously reported in a cohort of our patients from the public health system,
The prognosis for patients with EC is markedly affected by the extension of the disease at the time of diagnosis and clinicopathological prognostic factors that may impact on survival.
Despite promising, the interpretation of data in the cohorts exploring both the feasibility and prognostic ability of ProMisE may have suffered of some bias related to multimodal approaches based on classical prognostic models
High rates of adjuvant therapy have been reported in retrospective series of EC patients
Our study was intrinsically limited by its retrospective design and the long period analyzed. Unfortunately, we were also not able to provide a stratification of risk based on the ESMO/ESGO/ESTRO 2016 guideline
We confirmed the association of classical prognostic factors such as high histological grade, deeper MMI, lymph node metastasis and more advanced pathological stages with disease recurrence in this cohort of patients from Northeast Brazil. Further efforts are needed to avoid overtreatment in patients with low risk of relapses.
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Journal: Brazilian Journal of Oncology
DOI: 10.1055/s-00059887
e-issn: 2526-8732
Publisher: Thieme Revinter Publicações Ltda.
Publisher address: Rua do Matoso 170, Rio de Janeiro, RJ, CEP 20270-135, Brazil
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