Summary
OBJECTIVEThe purpose of the study was to compare FIGO 2009 and 2018 uterine cervical carcinoma staging systems in terms of patient distribution and efficacy in predicting treatment outcome in patients treated with surgery and adjuvant radiotherapy (RT)+/?concomitant chemotherapy (CT).
METHODS
The records of 184 uterine cervical cancer patients treated with post-operative RT/RCT from 2007 to
2017 were retrospectively reviewed. Surgical procedure was in the form of Wertheim surgery in 96 patients
(52%) and pelvic lymph node dissection was performed in 32 patients (17.5%). One hundred and
sixty-six patients (87.5%) received both external RT and intracavitary brachytherapy, and 23 (12.5%)
patients were treated only with external RT.
RESULTS
The median follow-up time was 61.5 months (range, 8-132 moths). One hundred and fifty-one (82%) patients
were alive, and 144 (94%) of these were free of disease at the time of this analysis. The median time
for locoregional failure and distant metastasis were 25 months (range, 8-88 months) and 38 months (range,
12-118 months). Stage migration was recorded in 130 patients (70.7%) in our series when the International
Federation of Gynecology and Obstetrics (FIGO) 2018 staging system was used. The most remarkable
stage migration was detected for Stage I patients. A total of 119 (64.6%) patients with Stage I showed stage
migration. Five-year locoregional control, disease-free survival, disease-specific survival, and overall survival
rates were 91%, 88%, 91%, and 83%, respectively.
CONCLUSION
The updated FIGO staging system for invasive cervical cancer incorporates imaging and pathological findings.
Our results suggest us that the major improvement of 2018 staging system for uterine cervical carcinoma
is that it produced better discrimination in terms of survival outcome in patients with lymph node
metastases both pelvic and para-aortic.
Introduction
In cancer treatment, staging is an essential tool for comparison of therapeutic outcomes, classification of prognostic factors, and deciding treatment. The International Federation of Gynecology and Obstetrics (FIGO) staging has played a central role all over the world providing easier comparisons of treatment results and aiding to make diagnosis and planning treatment for gynecologic malignancies. In 1970, FIGO introduced the first staging system for cervical uterine cancer.[1] Until now, the FIGO staging was based mainly on clinical examination with the addition of certain procedures that were allowed by FIGO to change the staging. In 2018, this has been revised by the FIGO Gynecologic Oncology Committee to allow radiological and pathological findings, where available, to assign the stage. The revised staging was presented at the FIGO XXII World Congress of Gynecology and Obstetrics.[2] Table 1 summarizes the changes in uterine cervical cancer (UCC).;){kind=link}
Table 1: Changes in cervical cancer staging system in new FIGO 2018
Staging according to the previous systems was inadequate; with 20-40% of Stage IB-IIIB cancers understaged and up to 64% of Stage IIIB cancers overstaged.[3-5] They did not include assessment of lymph node metastases (LNM), an important determinant for prognosis and treatment planning. Moreover, radical trachelectomy, an emerging fertility-preserving technique in which the uterine corpus is anastomosed to the vagina to treat many women diagnosed during their reproductive years, was not a consideration with these previous staging systems.[6] The revisions introduced in the 2018 FIGO staging system are intended to address the gap between the staging formalism and routine clinical practice and to explicitly acknowledge the role that advanced imaging has come to play in the care of women with cervical uterine cancer.[7] In addition, new staging system clearly reflects the importance of LNM as a major prognostic factor in UCC.
After the change of staging system, all authorities expected to see a significant advance to stratify patients with different prognosis. In the perspective of new changes in staging system, we compared FIGO 2009 and 2018 staging systems in patients with operated UCC receiving adjuvant radiotherapy+/?chemotherapy (RT+/-CT) in our RT center.
Methods
We evaluated the medical files of UCC patients treated at the Ege University, Department of Radiation Oncology between January 2008 and December 2017. All patients underwent surgery before RT. The surgical procedure was usually total abdominal hysterectomy with bilateral salpingo-oophorectomy (TAH-BSO) in addition to pelvic and/or para-aortic lymph node dissection (LND), and partial or total omentectomy with peritoneal washing cytology. Patients with metastatic disease and patients receiving definitive RT were excluded from this analysis. All patients were staged according to both 2009 and 2018 staging systems.Post-operative RT+CT was applied in patients with LNM, positive and/or close surgical margin, bulky tumor (>4 cm), and parametrial involvement, whereas post-operative RT was applied to patients with suboptimal surgery and/or with lymphovascular space involvement. Weekly concomitant cisplatin with the dose of 40 mg/m2 was administered to patients received concomitant CT with RT. RT consisted of external RT and intracavitary brachytherapy. External RT was applied with 6-18 MV linear accelerators to all patients. External RT was applied with 1.8 Gy daily fractions with a median total dose of 45 Gy (45-59.4 Gy). Brachytherapy was applied with high-dose rate afterloader microSelectron device to 0.5 cm depth from mucosal surface. Brachytherapy dose and fractionation were 3×600 cGy.
Patients were followed with physical and gynecological examination, pap smear, and laboratory tests at 3-month intervals for the first 2 years, at 6-month intervals for 3 years, and annually thereafter. For survival endpoints - locoregional control (LRC), progressionfree survival (PFS), disease-specific survival (DSS), and overall survival (OS)-time interval was defined as the time from surgery to the date of first relapse, diseasespecific death, or any death.
Statistical analysis was performed using SPSS version 21.0 (SPSS, Chicago, Illinois). The Kaplan-Meier method was performed for OS, and PFS rates and the survival curves were compared by non-parametric survival analysis (log-rank test). All time-related events (failure or death) were calculated from the diagnosis to last follow-up or death. P<0.05 was considered statistically significant.
Results
The medical records of 184 eligible patients with histologically confirmed UCC were evaluated. The median age was 49 years (range, 18-80 years). The most commonly seen histopathologic diagnosis was squamous cell carcinoma (SCC) in 129 (70%) patients. Other subtypes were as follows: Adenocarcinoma (17%), adenosquamous (9%), clear cell (3%), and undifferentiated (1%). Surgical procedure was in the form of Wertheim surgery in 96 patients (52%) and TAH-BSO only in 26 patients (14%). Pelvic LND was performed only in 32 patients (17.5%), and pelvic lymph node (LN) sampling was performed in 30 patients (16.5%). The median and mean number of LNs dissected were 18 and 19, respectively. One hundred and sixty-six patients (87.5%) received both external RT and intracavitary brachytherapy, and 23 (12.5%) patients were treated only with external RT. The median external pelvic RT dose was 45 Gy (range, 45-59.4 Gy), and median para-aortic dose was 45 Gy. One hundred and six (57.6%) patients received concomitant weekly cisplatin with median 3 courses. Patient and treatment characteristics are listed in Table 2.;){kind=link}
Table 2: Patient and disease characteristics
The median follow-up time was 61.5 months (range, 8-132 moths). One hundred and fifty-one (82%) patients were alive, and 144 (94%) of these were free of disease at the time of this analysis. One hundred and sixty-four patients were in the routine follow-up until the time of death or the last follow-up visit. The other 20 (11%) patients, who were lost to follow-up, were received from general citizenship information systems and/or phone calls. Forty patients were alive with disease at their last follow-up records: 10 with pelvic wall, 9 with vaginal cuff, 13 with distant metastasis, and 8 with both lymphatic and distant metastasis. The median time for locoregional failure and distant metastasis were 25 months (range, 8-88 months) and 38 months (range, 12-118 months).
Stage migration was recorded in 130 patients (70.7%) in data when FIGO 2018 staging system was used. There was not seen any stage change for the patients with Stage IIIB and IVA in compatible with staging systems. The most remarkable stage migration was detected for Stage I patients. A total of 119 (64.6%) patients with Stage I showed stage migration. About 47.8% of this migration was seen within Stage I itself according to new FIGO 2018 staging system. The remaining 31 patients (16.8%) with Stage I disease were upstaged to Stage IIIC disease. In addition, 11 patients (6%) with Stage II were upstaged to Stage IIIC with new staging system (Table 3). We compared the stage migration in terms of histopathology (SCC vs. non-SCC). However, we could not find any difference between the stage migration and the histopathology of patients (p>0.05).
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Table 3: The patient data restaged with new FIGO 2018 staging system
Five-year LRC, PFS, DSS, and OS rates were 91%, 88%, 91%, and 83%, respectively. In Table 4, OS and disease-free survival (DFS) rates according to both FIGO 2009 and FIGO 2018 were shown. The first thing should be said that all the treatment outcomes were observed excellent with both staging system. The remarkable point in this table was that the survival rates of both Stages I and II were increased due to the fact that the patients with LNM were staged as IIIC. As a result of this, treatment outcomes of both Stages I and II were detected higher in FIGO 2018.
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FIGO 2018 divided Stage IB into three subgroups according to tumor size.[2] Overall and PF survival curves were similar for Stage IB2 and IB3 in new FIGO 2018 staging system. Stage IBI had better OS curve than the others in both staging systems (Fig. 1). On the other hand, PFS curve of Stage IBI was not better than the others (Fig. 1). It could be argued that as followup time became longer, patients with Stage IB3 disease would show decreased treatment outcomes.
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LN metastasis has been a new parameter in UCC staging with FIGO 2018 due to known worse treatment outcome of it.[2] Small tumors with LNM upstaged to Stage IIIC.
In this current study, pelvic +/- para-aortic lymphatic dissection was performed in 159 (86.4%) patients and para-aortic lymphatic dissection was added to pelvic lymphatic dissection in 76 (41.3%) patients. The detecting way of LNM has not made any change in new staging system. In other words, lymphatic metastasis could be shown by pathologically or by radiologically. In our series, we had only three radiologic Stage IIIC patients. We detected pelvic LNM in 40 (21.7%) and para-aortic LNM in 6 (3.3%) patients. Totally, 46 (25%) patients had LNM, 43 of them were pathologically detected, in our data.
We compared the OS and PFS rates in terms of both pelvic (Stage IIIC1) and para-aortic LN metastasis (Stage IIIC2). Five-year OS and PFS rates were 75.1% and 61.7% for the patients with pelvic LNM (Stage IIIC1). We could not show statistically significant difference for OS rates for pelvic LNM (75.1% vs. 85.9%, p=0.183). On the other hand, PFS rates were affected unfavorably with pelvic LNM (61.7% vs. 83.6%, p=0.004) (Fig. 2). Five-year OS and PFS rates were 44.4% and 50.0% for the patients with para-aortic LNM (Stage IIIC2). Both OS (44.4% vs. 84.4%, p=0.006) and PFS (50.0% vs. 84.1%, p=0.001) rates were significantly affected by para-aortic LNM (Fig. 3).
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Fig 2: Kaplan-Meier survival curves according to pelvic lymphatic involvement.
Fig 3: Kaplan-Meier survival curves according to para-aortic lymphatic involvement.
We grouped patients according to stage migration as: (1) Within Stage I, (2) Stage II upstaged to stage IIIC, and (3) Stage I upstaged to Stage IIIC. The Kaplan-Meier plot for stage migration showed discriminative survival curves for upstaging to Stage IIIC disease. In accordance with literature, the patients had stage migration within Stage I had significantly better OS and PFS rates than the others, with 5-year OS and PFS rates of 87.7% and 96.5%, respectively. The worse treatment results were detected the patients with Stage II upstaged to Stage IIIC disease in terms of both OS and PFS rates, with 5-year OS and PFS rates of 62.3% and 60.6%, respectively (Fig. 4).
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Fig 4: Kaplan-Meier survival curves according to stage migration.
Discussion
Globally, cervical cancer continues to be one of the most common cancers among females, being the fourth most common after breast, colorectal, and lung cancer. In 2012, it was estimated that there were approximately 527.600 new cases of cervical cancer with 265.700 deaths annually.[8] In low- and middle-income countries, it is more common, being the second most common cancer in incidence among women and the third most common in terms of mortality.[9] Recent developments in imaging technology, radiotherapeutic approaches, biological target therapy, and increased use of minimally invasive surgery have drastically changed the paradigm for the management of women with cervical cancer. Until now, the FIGO staging system was based primarily on clinical examination with limited additional diagnostic procedures allowed by the FIGO staging system.[7,10]There is only one recent report which could be found in literature regarding new FIGO 2018 staging system. [11] This report aimed to validate the revised FIGO 2018 staging system for cervical cancer, with a particular focus on Stage IB and Stage III disease. Based on this validation analysis of Matsuo et al. using the National Cancer Institute's Surveillance, Epidemiology, and End Results (SEER) program between 1988 and 2014, the revised FIGO staging system for cervical cancer is useful to distinguish survival groups. Applying the new system, Stage IB1 and Stage IB2 disease have distinct characteristics and outcomes. It has been shown that Stage IB1 disease is more likely to be low grade and has adenocarcinoma histology, whereas Stage IB2 distasisease is more likely to be high grade and has squamous histology.[11] We could not show any relation between histopathological tumor type and FIGO staging in our cohort. In addition, they concluded that patients with Stage IB2 disease have a nearly 2-fold increased risk of cervical cancer death compared to those with Stage IB1 disease. Similar with this, we detected that Stage IBI had better OS curve than the others in both staging system. On the other hand, we could not show statistically significant difference in terms of treatment outcomes between new IB staging groups. By the help of focusing new predictive molecular and/or genetic biomarkers, we might present new factors for distinguishing Stage IB disease rather than tumor size.
Another major change in the FIGO 2009 staging system is the inclusion of LN status into Stage III disease.[2] Patients who have documented pelvic and/ or para-aortic LN metastasis are specifically staged as Stage IIIC. Under the revised system, radiographic and/or histological findings are allowed to assign Stage IIIC disease. Stage IIIC1 is designated when only pelvic LN metastasis is detected, while Stage IIIC2 is designated when para-aortic LN metastasis is documented by either method. In the validation analysis of Matsuo et al.,[11] they evaluated 11.733 women with Stage III UCC. They found that Stage IIIC1 disease was also more likely to have adenocarcinoma or adenosquamous histology and to be higher grade but have smaller tumor size (all, p<0.001). However, we could not show any statistically significant difference between Stage IIIC disease and histology. In Stage III disease, survival of women with Stage IIIC1 disease is greater for those patients with Stage IIIA or Stage IIIB disease. The analysis showed 5-year cancer-specific survival rates of 46.0% for Stage IIIA disease, 42.6% for Stage IIIB disease, and 62.1% for Stage IIIC1 disease in the trial of Matsuo et al.[11] Interestingly, this current study did not have patient with Stage IIIA. In addition, we had only one patient Stage IIIB disease. Therefore, we could not compare the treatment results for the patient with these Stage III disease subgroups. In our trial, we found that 5-year OS and PFS rates were 75.1% and 61.7% for the patients with Stage IIIC1 disease. It is important not to miss that Stage IIIC1 disease reflects a heterogeneous group of tumors with a wide range of survivals based on local tumor factors. Patients with metastatic para-aortic LNs are managed with concurrent CRT, and these patients would be staged as Stage IIIC2 in the new FIGO 2018 system. Kidd et al.[12] demonstrated >35% DSS for patients with Stage IIIC2 disease. In this current data, 5-year OS and PFS rates were 44.4% and 50.0% for the patients with Stage IIIC2 disease. Some patients with supraclavicular only LN metastasis have been shown to achieve long-term DFS. With help of this knowledge, Zighelboim et al.[13] indicated that some patients who receive external beam RT and CT for limited oligometastatic disease may also have a prolonged DFS.
The FIGO classification system combines the most basic parameters of gynecologic malignancies to stratify patients according to extent of disease, to decide the better treatment modality, and to develop a common language for the future testing of cancer treatment strategies. [1] FIGO 2018 staging system examines both clinical and radiological findings, as well. Although the patient number is low compared to large multi-institutional series, the uniform risk-adapted treatment in our patients gives us valuable information about the ability of old and new staging systems for discriminating the survival outcomes (Fig. 5). Our data showed that there were no major differences between FIGO 2009 and 2018 staging systems in terms of OS and PFS rates when comparisons were made as Stage I and II in FIGO 2009 versus 2018. Major difference was seen for the patients with Stage I and II disease upstaged to Stage III disease in terms of both OS and PFS. The worse treatment outcomes were detected for the patients with Stage II disease upstaged to Stage IIIC disease. Based on this result, it might be argued that not only LNM both also primary tumor involvement should be kept on mind while deciding treatment approach. The survival curves between stages were separated clearly with the use of FIGO 2018 (Fig. 5).
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A strength of this study is that this is likely the first single institutional study to examine the comparison of the two staging system for operated UCC. Out of this current study, there is only one population-based study, done by Matsuo et al.,[11] using SEER data. Our results are important in terms of including homogenous patient data and using modern treatment techniques. On the other hand, limitation of this study includes that this is a retrospective study, and there may be missing confounding surgical pathological and follow- up evaluations.
Conclusion
The updated FIGO staging system for invasive operated UCC incorporates imaging and pathological findings. Our results suggest us that the major improvement of 2018 staging system for UCC is that it produced better discrimination in terms of survival outcome in patients with LNM both pelvic and para-aortic. In addition, the hope is that these revisions will improve the accuracy of staging and this will be reflected a more refined understanding of prognostic groups, which will facilitate better treatment for women with invasive UCC.Peer-review: Externally peer-reviewed.
Conflict of Interest: All authors declared no conflict of interest.
Ethics Committee Approval: The study was approved by the Ege University Faculty of Medicine Clinical Research Ethics Committee (No: 18-10.2T/36, Date: 01/11/2018).
Financial Support: None declared.
Authorship contributions: Concept - F.S., B.B., S.A., Z.Ö.; Design - F.S., B.B., S.A., Z.Ö.; Supervision - F.S., B.B., S.A., Z.Ö.; Funding - F.S., B.B., S.A., Z.Ö.; Materials - F.S., B.B., S.A., Z.Ö.; Data collection and/or processing - F.S., B.B., S.A., Z.Ö.; Data analysis and/or interpretation- F.S., B.B., S.A., Z.Ö.; Literature search - F.S., B.B., S.A., Z.Ö.; Writing - F.S., B.B., S.A., Z.Ö.; Critical review - F.S., B.B., S.A., Z.Ö.
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