Introduction
Cervical cancer (CC) ranks as the fourth most frequently diagnosed cancer and the fourth leading cause of cancer-related mortality [
1]. Over the past decade, CC mortality has seen a gradual increase in transitioning countries such as China, primarily due to inadequate human papillomavirus (HPV) vaccination and screening strategies [
2,
3]. While both surgery and radiotherapy are viable options for clinical early-stage cervical cancer (ESCC), surgery is more commonly employed in developing countries. However, a subset of patients experiences relapse after several years, with a limited survival time post-recurrence, often not surpassing 12 months [
4]. Postoperative risk factors have been traditionally categorized as high and intermediate risk; however, the specific impact of each on prognosis remains underexplored.
Many large-scale clinical trials have predominantly utilized the older The International Federation of Gynecology and Obstetrics (FIGO) stage (2009 edition) or subsequent staging standards. FIGO has introduced a new staging system in 2018. However, the extent to which this updated staging system can guide clinical practice and accurately predict prognosis has not been thoroughly investigated. Moreover, there is a paucity of research data concerning the prognosis of patients initially diagnosed with ESCC who undergo surgery when lymph node metastasis (LNM) is identified postoperatively and during adjuvant therapy. This study aims to analyze recurrence-related factors in patients with ESCC following hysterectomy and adjuvant radiotherapy, also seeking to validate the revised 2018 FIGO staging system for CC.
Materials and methods
Study design and patients
This retrospective study, conducted at Zhongshan Hospital affiliated with Fudan University, screened patients diagnosed with ESCC (e.g., I B1, I B2, II A1, and II A2) by the FIGO 2009 staging system between January 2012 and December 2019. Patients underwent radical hysterectomy, lymphadenectomy, and adjuvant radiotherapy or chemoradiothrapy. Retrospective restaging was performed based on surgical pathological characteristics using the FIGO 2018 staging system. All patients received postoperative adjuvant radiotherapy at the Department of Radiation Oncology. The study received approval from the Ethics Committee of Zhongshan Hospital, affiliated with Fudan University, and obtained written informed consent from each patient (B2021-814R).
Inclusion criteria: All adult patients who underwent radical hysterectomy and pelvic lymph node (LN) dissection, employing surgical or laparoscopic approaches, were included. Surgical stages ranged from I B1–I B3, II A1–A2, II B to III C1-2, without evidence of distant metastasis on preoperative imaging (magnetic resonance imaging [MRI] and/or computed tomography [CT] and/or positron emission tomography [PET]/CT). Exclusion criteria encompassed patients with malfunctioning vital organs (heart, liver, bone marrow, and kidney), a medical history of additional malignant tumors, or prior radiotherapy or chemotherapy. Patients with intermediate risk factors (IRFs), as per Sedlis criteria based on GOG92, necessitated adjuvant radiation [
5]. Patients with adenocarcinoma were referred to the KGOG Study [
6], and those with two or more risk factors will received adjuvant radiotherapy. High-risk factors (HRFs) included parametrial, LN, or vaginal cut margin involvement, mandating concurrent chemoradiotherapy (CCRT) based on GOG109 results [
7].
Gynecological surgical methods
All eligible patients underwent radical hysterectomy combined with pelvic LN dissection ± para-aortic LN biopsy/dissection using either a surgical or laparoscopic approach. The laparoscopic approach was discontinued at our center following the publication of the Laparoscopic Approach to Cervical Cancer (LACC) results in 2018 ((
8‐
9)). Radical hysterectomy involved the removal of the uterus, parametrium, paravaginal tissues, upper third of the vagina, and uterosacral ligament. The ureter was dissected from its entry into the broad ligament to its reach to the bladder and laterally from its attachment to the cardinal ligament.
Adjuvant radiotherapy
Adjuvant radiotherapy generally employed intensity-modulated radiotherapy or three-dimensional conformal radiotherapy (6-MV photon beam). Based on the Radiation Therapy Oncology Group target delineation guidelines, the clinical target volume (CTV) primarily included common, external, and internal iliac LN regions, presacral LN region, and the upper 3.0 cm of the vagina and paravaginal soft tissue lateral to the vagina [
10]. The planning target volume (PTV) was defined by expanding an edge of 0.5–1.0 cm to the CTV. The prescribed dose was 45.0–50.4 Gy/1.8 Gy, five times per week. The minimum and maximum acceptable PTV dose were 95% and 110% of the prescribed dose (median 45 Gy), respectively. Most patients received a radiation field of the pelvic cavity. Patients with a positive vaginal margin received intracavitary brachytherapy with a dose at point A of 30 Gy ± 10%, 5–6 Gy per fraction, once or twice a week for 4–6 fractions in total. Patients with common iliac or para-aortic lymph node metastases received para-aortic extension fields (simultaneously integrated or sequential). All treatments commenced 2–4 weeks following surgery and were completed within 6–8 weeks. The limits of the organ-at-risk were as follows: The maximum dose of the spinal cord was less than 45 Gy. small intestine V
40 < 30%,V
30 < 40%; the average dose of bilateral femoral head < 30 Gy; bladder V
45 < 40%;rectumV
40 < 40%; left and right kidney V
20 < 33%.
Adjuvant chemotherapy regimen
The decision between CCRT or radiotherapy was determined by the treatment team, considering patients’ risk factors, performance scores, and comorbid conditions. Patients with HRFs received cisplatin-based combination chemotherapy once a week (30–40 mg/m2) for 5 weeks. The decision to administer synchronous chemotherapy to patients with IRFs was collaboratively taken following discussions among the doctor, patient, and their families. A subset of patients received postoperative adjuvant chemotherapy with paclitaxel (135–175 mg/m2) combined with cisplatin (60–75 mg/m2) or carboplatin (area under the curve [AUC] = 5) every 3 weeks following radiotherapy for 4–6 cycles. The treatment team considered factors such as patients’ age, HRFs, performance scores, and comorbid conditions for making this decision. Due to the side effects of bone marrow suppression, most patients completed 5 weeks of synchronous chemotherapy, whereas patients at high risk received 4 cycles of postoperative adjuvant chemotherapy.
Follow-up plan
Patients underwent regular follow-ups with a frequency of every 3 months during the first 2 years, every 6 months in 3–5, and annually after 5 years. The follow-ups included medical examinations, outpatient colposcopy, ultrasonography, CT scans, MRI, PET/CT, and serum tumor biomarker detection (usually adopted in combination rather than all). Recurrence is defined as evidence of tumor relapse or metastasis detected in any medical examination after a minimum of 3 months following the completion of the operation, including local recurrence (within the radiation field, e.g., pelvic cavity or irradiated para-aortic extension fields) and distant metastasis (LNM outside the radiation field area, lung metastasis, bone metastasis, and other organ metastasis). Survival calculations were performed post-surgery.
Statistical analysis
IBM SPSS (version 22.0, Chicago, USA) and R software (Version 4.1.2) were utilized for statistical analyses. Descriptive statistics summarized the frequency of clinical-pathological factors (e.g., age, FIGO Stage, parametrial invasion (PI), surgical margin, number of LNM, depth of stromal invasion, tumor diameter (TD), lymphovascular space invasion (LVSI), and histological type). The Pearson χ2 test or Fisher’s exact test determined the difference in 5-year recurrence-free survival (RFS) rates between subgroups. The Cox proportional hazards model was employed to establish the relationship between each clinical/demographic factor and RFS. Factors identified by univariable analyses (p < 0.1) (FIGO stage, PI, surgical margin, TD, number of of LN+) were subjected to multivariable analyses to identify significant independent factors. The R software was used to draw a nomogram, assessing the value of prognosis-related factors in predicting outcomes. The accuracy of the prediction model was evaluated using an internal calibration curve. Survival curves and the number of at-risk patients were generated and calculated using R software. The Kaplan–Meier method estimated the median overall survival (OS), and the log-rank test compared the association of OS and RFS with relevant clinicopathological factors between subgroups. The significance level was set at 0.001 due to multiple testing, adhering to the Bonferroni adjustment. All p-values were two-sided, and a p-value less than 0.05 was considered statistically significant.
Discussion
This study encompasses a comprehensive data collection of 310 ESCC cases from real-world scenarios after hysterectomy followed by adjuvant radiotherapy or chemoradiotherapy in a single-institution cohort. The data is more authentic and heterogeneous, aligning more closely with actual clinical practice. While the 2009 FIGO staging is simpler for surgical physicians, its prognostic significance is deemed insufficient. In this study, 126 patients with ESCC were reclassified to stage III C1 or III C2 post-surgery due to LNM based on the 2018 FIGO staging criteria. They exhibited a poorer 5-year RFS than those whose disease staging had not changed (65.9% vs. 88.6%), even after receiving CCRT. Similar findings in another study indicated a reduction in the 5-year RFS rate from 88 to 57% in the LNM group [
11], confirming the efficacy of the the 2018 staging system in guiding the prognosis of patients with LN positivity.
The KROG1303 study constructed a nomogram incorporating parameters such as age, number of pelvic LNMs, PI, LVSI, and the use of CCRT to predict 5-year OS. The risk of death increased with the number of pelvic LNMs [
12]. Another multicenter retrospective study, including 249 IB to II A patients, identified the number of LNMs as the best prognostic variable related to LN status, and patients with LNM > 3 had a high risk of recurrence even with postoperative chemoradiotherapy [
13]. Our findings are consistent with these results, with multivariate analysis indicating that the number of positive LNs was an independent factor affecting recurrence and an independent prognostic factor of RFS. Patients with 3 or more positive LNs had a higher RR than those with 1–2 LNs (45.5% vs. 22.0%). However, besides the number of LNMs, factors such as the location, distribution, proportion, and size of LNMs may also be relevant to prognosis, warranting further research and exploration.
Despite the recommendation for postoperative CCRT for all patients with LNM in this study, the follow-up data revealed that patients with LNM still exhibited the worst prognosis. This suggests that LNM may differ from other HRFs such as positive vaginal margins and PI, whose risks might be mitigated by brachytherapy. LNM is viewed as a systemic disease with microscopic tumor spread, and systemic treatment may be more effective than local treatment for patients with LNM. This hypothesis requires further investigation.
LNM is a crucial factor in treatment decisions and prognosis prediction. Preoperative evaluation of LNM is therefore pivotal in clinical practice. After the revision of staging in 2018, patients with stage III C are more likely to receive CCRT-based treatment. Determining LNM accurately before surgery is challenging, and literature indicates the importance of PET/CT in identifying low-risk patients [
14]. While PET/CT is not covered by medical insurance in China and poses financial challenges for some patients, the data and findings highlight the significance of performing PET/CT in patients with ESCC preparing for surgery, not only those undergoing definitive radiotherapy.
Despite tumor size being considered an IRF, our research findings reveal that tumor size is an independent factor affecting recurrence, as crucial as the classic HRFs of PI and LNM. This contrasts with the traditional view that smaller tumors are less dangerous in terms of recurrence and metastasis. A study supporting our findings demonstrated that, for patients with stage III C1, the prognosis closely correlated with the extent of tumor invasion, with a wider scope of invasion leading to a worse prognosis. Another study showed that the 5-year survival rates of T1, T2, and T3 were 74.8%, 54.7%, and 39.4%, respectively, among patients with stage III C1 [
15]. In our study, we observed that in the LNM-positive subgroup, patients with TD > 4 cm and deeper PI had a poorer prognosis. These findings cast doubt on the rationality of dividing postoperative recurrence risk factors into HRF and IRF categories. Currently, the NCCN guidelines recommend that patients with ESGC with IRFs should undergo radiotherapy ± chemotherapy. The evidence level of concurrent radiotherapy and chemotherapy for moderate risk factors is category II B from a single cohort. Our findings indicate that for patients with large TD, the recurrence probability is very high, and CCRT should be strongly recommended for such patients in clinical practice.
No statistical difference was found between the IB1 and IB2 groups in terms of RFS or OS in this study, possibly due to the small sample size. In contrast, another study comparing the old system with the 2018 FIGO new staging system in a validation study demonstrated that the 5-year disease-free survival of the old I B1 (5 mm to 4 cm) was 90.0%, whereas that of the new I B2 (2–4 cm) was 78.6%. This new classification was deemed more effective in guiding the prognosis of patients [
16]. It is worth noting that our study covers all pathological classifications, which could significantly impact statistical results. For instance, a patient diagnosed with gastric-type endocervical adenocarcinoma with stage I B1 experienced rapid disease progression and recurrence 29.8 months following surgery. The survival time of this patient could significantly affect that of the whole IB1 group due to the small sample size. In conclusion, we were unable to complete the validation of the effect of dividing old I B1 into I B1 and I B2 stages according to the boundary value of 2 cm in diameter in the 2018 FIGO stage in this study.
Despite the robustness of our study, several limitations need to be acknowledged. The retrospective design and the modest number of patients might compromise statistical accuracy. The absence of a significant difference between the IB1 and IB2 groups in terms of RFS or OS may be attributed to the small number of cases, emphasizing the need for caution in the interpretation of these results. The inclusion of all pathological classifications in our study could significantly impact statistical outcomes. Furthermore, the lack of detailed classification regarding the characteristics of the location, number, and size of metastatic lymph nodes could potentially influence prognostic assessments and should be addressed in future research. Additionally, the study did not include data on the status of HPV infection, which is recognized as a significant risk factor for recurrence in patients undergoing conization for high-grade cervical lesions [
17]. Future studies should consider incorporating this crucial aspect for a more comprehensive analysis. Moreover, the suspension of laparoscopic surgery since November 2018 in our hospital raises questions, although new research results seem to be inconsistent with LACC trial in low-risk patients [
18]. Thus, high-level evidence from phase III studies are urgently required on how to select between these two approaches.
Conclusion
The challenges posed by the recurrence and metastasis of EGCC persist as clinical complexities, and ongoing debates surround the primary determinants of prognosis. In this retrospective study, we meticulously examined 310 patients diagnosed with ESCC, aiming to understand the pivotal factors influencing recurrence. Our findings reveal that the RR in patients with clinical ESCC post-hysterectomy, followed by adjuvant radiotherapy, is associated with specific factors—namely, the number of positive LNs, TD exceeding 4 cm, and PI. Of utmost significance is the imperative to direct heightened attention toward LNM and TDs. Patients manifesting these factors may necessitate more aggressive intervention strategies and tailored treatment approaches.
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