Abstract
Aim: To compare the advantage of image-guided brachytherapy (IGBT) over conventional two-dimensional brachytherapy (2DBT) in patients with advanced cervical squamous cell carcinoma. Patients and Methods: This study included 253 patients with stage IB2-IVA diseases treated with two schemes of brachytherapy. One hundred and thirty-six patients received 2DBT, whereas 117 patients received IGBT. Tumor stage, age, and tumor diameter were matched between the two groups. Local relapse-free survival, overall survival, and cumulative incidences of gastrointestinal and genitourinary complications were compared between the two groups. Results: The overall and local relapse-free survival rates were similar between the two groups. The cumulative rate of grade 2 and higher gastrointestinal complication was 21.3% for the 2DBT group, and 8.5% for the IGBT group (p=0.007), whereas that of grade 2 and higher genitourinary injury was 11.8% for the 2DBT group, and 1.7% for the IGBT group (p=0.002). Conclusion: In patients with advanced cervical squamous cell carcinoma, IGBT achieves a higher therapeutic ratio compared to 2DBT technique by minimizing the late toxicities.
Cervical cancer remains one of the leading causes of cancer-related deaths in women worldwide (1). In patients with intact uterus, the use of image-guided brachytherapy (IGBT) has grown considerably because of the introduction of an adaptive target concept and a dose volume assessment balancing constraints for clinical target volume (CTV) and organ at risk (OAR) (2-10). A series of single institutional studies demonstrated an increased therapeutic ratio when compared to conventional two-dimensional brachytherapy (2DBT) (2, 5). Although current findings suggest a favorable impact of IGBT on outcomes, so far, no randomized trial has been conducted to validate its benefits over 2DBT probably due to ethical concerns.
In definitive chemoradiotherapy (CRT) for locally advanced cervical cancer, in which brachytherapy is an essential component of radiotherapy, the net impact of advanced technique using IGBT on final outcome has been reported by a prospective international study on magnetic resonance imaging (MRI) based brachytherapy in cervical cancer (EMBRACE) (9). The results showed that IGBT leads to excellent local control and pelvic control (91% and 87% at 3 years) and overall survival (74% at 3 years) with limited severe morbidity (9). However, IGBT is a more time-consuming process requiring individualized contouring and planning. It also requires additional resources such as real-time images and availability of 3D treatment planning systems. The additional costs of setting up IGBT are more than the normal costs of the conventional brachytherapy procedure (11). In some developing countries, not all cancer patients requiring brachytherapy are able to receive adequate treatment (12). Furthermore, patients who can undergo routine IGBT might be restricted in some institutes where patient load was huge. Therefore, this retrospective study was conducted to examine the hypothesis that IGBT may potentially gain more therapeutic effect. All the studied patients were treated with the similar technique and dosage of external-beam radiotherapy (EBRT) using intensity-modulated radiation therapy (IMRT) and concurrent chemotherapy. The result will be helpful to institutions where the cost-effectiveness of modern technique is a concern, particularly where resources are limited.
Patients and Methods
Patients. This retrospective cohort study included patients with stage IB2-IVA cervical squamous cell carcinoma, according to the International Federation of Gynecology and Obstetrics (FIGO) staging system, treated with curative CRT in two treatment periods between January 2007 and December 2016. In 2018, staging has been revised by the FIGO Gynecologic Oncology Committee to allow imaging and pathological findings to assign the stage (13). Therefore, both old and new FIGO stages were applied. To minimize the bias in this comparative study, patients with a histological type of adenocarcinoma or adenosquamous carcinoma were excluded because they have inferior outcomes compared with those with squamous cell carcinoma when primarily treated with CRT (14, 15). All patients received comprehensive pretreatment workup, including computed tomography (CT), and completed an allocated CRT course. Figure 1 presents the flowchart of patient selection and study design.
The patients in the first period received IMRT plus 2DBT and were labeled 2DBT group, whereas patients after 2012 were irradiated with IMRT plus IGBT, referred to as IGBT group. A total of 253 cases were included in this comparative study, and sample size for 2DBT and IGBT group was 136 and 117, respectively. Tumor stage, age, and tumor diameter were matched between the two groups, while were treated by the same radiation oncology team. Patient characteristics are summarized in Table I. The study was approved by the institutional review board [CMUH107-REC3-19].
External beam radiotherapy. All patients underwent CT-based planning with custom immobilization. Both groups were initially irradiated with an IMRT technique with a prescribed dose to the whole pelvis of 45 Gy in 25 fractions (16). Following the IMRT, bilateral parametrial disease was boosted to 50.4 to 54.0 Gy via anterior and posterior parallel fields with central shielding. In patients with radiologically metastatic pelvic lymph nodes, the involved nodes were further irradiated with IMRT to a cumulative dose of 60 to 64 Gy. The CTV of the initial IMRT included the gross disease, cervix, parametrium, uterus, superior half of the vagina, cardinal ligament, presacral region, and regional lymph nodes (common, internal, and external iliac) as similar with consensus guidelines on CTV delineation (17, 18). Uniform planning margins were added to account for organ motion and setup uncertainty. We applied a 15-mm planning margin around the cervix, a 10-mm margin around the uterus and the vagina, and an 8-mm margin around the remainder of the CTV according to previous studies (19). Target planning constraints were standardized and previously described (16).
Image-guided radiotherapy using kilo-voltage imaging, and cone beam CT to minimize geometrical uncertainties for daily treatment setup was not routinely employed. This technique was implemented by individual choice, and the proportion of the use for 2DBT and IGBT groups was 19% and 21%, respectively.
Brachytherapy. Following 45 Gy to the pelvis, high-dose rate intracavitary brachytherapy was performed using an Ir-192 remote after-loading technique after adequate tumor regression and concurrently with pelvic irradiation or parametrial boosting. In the 2DBT group, the standard prescribed dose for each 2DBT was 6.0 Gy to Point A for 4 sessions. The Point A dose was reduced to 5.0 Gy for those with higher reference doses to the rectum or bladder, or those aged over 70 years. The total prescribed Point A doses (external beam + brachytherapy) ranged from 65.6 to 75 Gy (median, 69 Gy). The details of the 2DBT have been reported previously (20).
In IGBT group, gross tumor volume (GTV) and high-risk CTV (HR-CTV) were contoured on pelvic MRI that was done prior to the first secession of IGBT. Using image registration technique, the MRI-based target volumes were then fused with applicator-based simulation CT on the first IGBT. Planning volumes were according to the GEC-ESTRO guidelines (21). Thereafter, individual dose optimization of the subsequent application was based on the transferred MRI target volume and OAR structures delineated on CT. A dose-volume histogram was calculated according to CT-based HR-CTV and OAR. The brachytherapy was performed by commercial treatment planning system (Varian GammaMedplus ix, Palo Alto, CA, USA). Intracavitary applicators with Henschke T&O applicator consisting of tandem and ovoids (Mick Radio-Nuclear Instruments, Inc., Mount Vernon, NY, USA) were used for insertion. Dose volume adaptation was performed with the aim of dose of cumulative equivalent dose in 2 Gy per fraction (EQD2) of HR-CTV-D90 >80 Gy. The mean HR-CTV was 34.5±15.5 ml (range=14.0-150.4), and the mean cumulative EQD2 of HR-CTV-D90 was 87.6±7.9 Gy10 (range=71.9-110.1). The mean cumulative EQD2 of doses for the most exposed 2cc (D2cc) for rectum, bladder, and sigmoid colon were 60.9±6.4 Gy3, 67.1±8.6 Gy3, and 64.8±6.9 Gy3, respectively.
Chemotherapy. Chemotherapy consisted of cisplatin delivered weekly at a dose of 40 mg/m2 intravenously, with a total maximal dose of up to 60 mg. The first cycle of cisplatin was initiated at the first radiotherapy (RT) treatment. In accordance with the duration of RT, the treatment plan included a total of five to eight cycles of cisplatin (16).
Follow-up. After completion of radiotherapy, patients received regular follow-up every 2 months for the first year, and every 3 months afterward. A pelvic examination was performed during each follow-up; in addition, tumor markers (squamous cell carcinoma antigen and carcinoembryonic antigen) were checked. A CT scan was carried out every 6 months for the first 2 years and routine urine and stool examinations were done every 6 to 12 months. Patients who had persistent abdominal pain, bloody stools or hematuria underwent sigmoidoscopy or cystoscopy to identify the source of bleeding, and underwent blood counts for surveillance of the severity of the complications. Common Terminology Criteria for Adverse Events Version 4.0 was used to score the maximum late toxicities, including gastrointestinal (GI) and genitourinary (GU) complications (22).
Study endpoints and statistical analysis. The primary endpoints were local relapse-free survival (LRFS) and cumulative incidences of grade 2 or more complications of adjacent GI or GU tracts because of the association with the direct treatment efficacy across three treatment regimes. A comparison of the categorical and continuous variables among groups was performed using the ANOVA and Chi-square test. A multivariate analysis using binary logistic regression was carried out to estimate the odds ratio (OR) of complications among the variables examined. Overall survival (OS) and LRFS were calculated using the Kaplan-Meier method. The log-rank test and Cox regression analysis were performed to examine the effects of explanatory variables on these endpoints. Statistical significance was considered when a two-sided p-value was <0.05. Patient survival was measured from the date of radiotherapy initiation to the last follow-up. The latency of complications was measured from the end of radiotherapy to the last follow-up. All statistical analyses were performed using a commercial software package (SPSS 13.0 for Windows, Chicago, IL, USA).
Results
Within a median follow-up duration of 60 months for the 2DBT group and 47 months for the IGBT group, 187 patients were alive and 66 patients had died. Moreover, 198 patients had no evidence of disease progression, whereas 55 patients had disease progression (infield recurrence, distant metastasis, and both in 28, 41, and 14 patients, respectively). Among the 28 patients with infield recurrence, one experienced sole pelvic lymph node relapse. In summary, 226 patients remained relapse-free at primary sites, whereas 27 patients experienced local recurrence. As depicted in Figures 2 and 3, the 4-year LRFS for 2DBT and IGBT groups was 89% and 87% (p=0.68), whereas the 4-year OS for 2DBT and IGBT groups was 70% and 76% (p=0.32), respectively. Table II lists the result of the Cox regression analyses and disclosed that IGBT did not lead to a superior outcome in terms of OS or LRFS. The adverse features for OS were new stage IIIA-IVA disease [p=0.04, hazard ratio (HR) 1.21, 95% confidence interval (CI)=1.01-1.47] and existence of paraaortic lymph node metastasis (p=0.005, HR 2.36, 95%CI=1.32-4.28), whereas prognostic factors for LRFS were age 65 years (p=0.024, HR=3.47, 95%CI=1.36-8.33) and new stage IIIA-IVA disease (p=0.027, HR=1.43, 95%CI=1.04-1.96), respectively. Subgroup analysis was carried out for IGBT group (Table III). The evidence of obstructive uropathy and HR-CTV values were two predictors for inferior LRFS in the Cox regression analysis. The cumulative EQD2 to the HR-CTV was not associated with local failure.
The incidences of various endpoints of GI or GU toxicities across the treatment groups are summarized in Table IV. The median duration of GI and GU complication was 15 months (range=4-29) and 27 months (range=3-56), respectively. The cumulative rate of grade 2 and higher GI complication was 21.3% for 2DBT group and 8.5% for IGBT group (p=0.007), whereas that of grade 2 and higher GU injury was 11.8 % for the 2DBT group and 1.7% for the IGBT group (p=0.002). The actuarial hazard curves are depicted in Figure 4. The 4-year actuarial GI complication rate was 27% for 2DBT group and 10% for IGBT group (p=0.022), whereas that of GU complication rate was 17% for 2DBT group and 3% for IGBT group (p=0.017). The cumulative rate of grade 3 and higher complication was 10.3% for 2DBT group and 1.7% for IGBT group (p=0.03), whereas that of grade 3 and higher GU injury was 4.4% for 2DBT group and 0.9% for IGBT group (p=0.08). According to most endpoints, 2DBT group experienced a higher probability of late complications compared with IGBT group.
Using toxicity profile of 2DBT group as a reference, Table V indicates that the independent factors which decreased grade 2 and higher GI toxicities was the application of the IGBT [p=0.015, odds ratio (OR)=0.40, 95%CI=0.19-0.84]. The IGBT also contributed the reduction of grade 2 and higher GU complications (p=0.009, OR=0.14, 95%CI=0.05-0.69). When lumping any events with grade 2 or above GI or GU complications together, the employing the IGBT decreased the risk of late sequalae (p=0.001, OR=0.30, 95%CI=0.15-0.60). In addition, the IGBT could reduce grade 3 and higher GI or GU toxicities (p=0.003, OR=0.10, 95%CI=0.02-0.45).
Discussion
In patients with advanced cervical cancer, it would be not ethically feasible to conduct phase 3 trials to compare the advantage of IGBT over conventional 2DBT. Another barrier of cost-effectiveness analysis was that the impact of EBRT techniques should be assessed together due to the cumulative effect. Using the two matching cohorts with uniform EBRT and the same histology, we first disclosed the impact of IGBT on reduction of major complications for these patients. Although a longer follow-up duration for IGBT group would be ideal to confirm the differences, our findings could provide where the cost-effectiveness of modern technique is a concern, particularly where resources are limited.
For patients with locally advanced cervical cancer, this is a pilot study to compare the clinical outcome of IMRT plus IGBT over IMRT plus 2DBT. Although the application of IMRT technique is believed to result in the OARs being exposed to a lower dose of radiation and consequently reduced toxicities, phase 3 studies compared IMRT with non-IMRT techniques remain limited in the setting of definitive CRT (23, 24). Hasselle et al. (25) reported the rate of grade 3 and greater complications in 89 patients with intact cervix treated with IMRT plus low-dose rate brachytherapy was 4% and 5% for GI and GU system, respectively. In addition, Kidd et al. (26) showed a great difference in the incidence of late toxicities between the groups. The IMRT group had only a 6% rate of Grade 3 or greater GI or GU toxicity, versus 17% for the non-IMRT group (p=0.0017). Taken together, the application of IMRT ought to be one of the determinants of late toxicities when using conventional brachytherapy.
Unlike those treated in the postoperative setting, in which irradiation dose is mainly prescribed by EBRT, brachytherapy always plays an important role in determining the final outcome for patients with an intact uterus. Thus, IGBT is major approach that might be used to increase therapeutic ratio. In this study, the control rate was comparable to other international studies (2-10). Although the mean total EQD2 of HR-CTV-D90 for IGBT group was 87.6 Gy10, the dose-response curve was not obvious. Dimopoulos et al. studied a cohort of 141 patients with cervical cancer treated with IGBT, and they suggested that local control rates greater than 95% can be achieved when the cumulative D90 for HR-CTV is 87 Gy or greater (27). Above this dose, local failure rate was 4% (3 of 68) compared to 20% (15 of 73) for doses less than 87 Gy. Therefore, local control could be further optimized if dose escalation through the implementation of interstitial implant could be done in our practice.
Using a variety of treatment schedules of IGBT, several studies indicated the low rates of grade 3 and higher complications ranged from 0% to 14% (2-9, 28). Except for the historic data reported by Vienna group (28), there was a paucity of studies comparing the late toxicities between IGBT and 2DBT. In general, the cumulative rate of grade 2 or grade 3 and higher complications in 2DBT group were similar to that of these studies (2-9). Despite the majority of the urinary and rectal complications occurring within 2 to 3 years after the completion of therapy, the risk of developing late bladder complications might occur up to 25 years after treatment, as pointed out by Eifel et al. (29). Thus, a long-term observational study is essential to verify the true incidence of bladder complication. Interestingly, the mean cumulative EQD2 of D2cc for the bladder in our IGBT group was 67.1 Gy3, which was far less than the value of 101 Gy, which could result in a 10% risk of grade 2 or more GU complications (28, 30). The disparity was due to the fact that the strategy of bladder dilatation was not adopted during our IGBT application. Given that the GI toxicities were not remarkably elevated by this approach, it can become a feasible method to minimize bladder dose.
The findings of this study should be interpreted cautiously because they represent a retrospective study design in a single institute. The median follow-up duration in the IGRT group was shorter than that of the 2DBT group. Nonetheless, several potential bias could be excluded when matching variables between the groups, such as lymph node status or histological types. In addition, although the benefit of the preferable dose distribution was intensified by using IMRT, a routine implementation of image-guided radiotherapy combined with timely adaptive radiotherapy might be the best approach. By reducing setup error and correcting for uncertainty after tumor regression, these approaches allow a reduction in the margin that is added to the CTV. In this way, the therapeutic index ought to be promoted. Finally, implementation of a combined interstitial-intracavitary applicator will be another approach to optimize the treatment result (31). The use of additional interstitial needles provides sufficient prescribed dose to eccentric tumors, whereas the dose to OARs was within standard limits for intracavitary brachytherapy alone. Accordingly, a combination of high-quality IMRT and IGBT will probably become a benchmarking guidance for the treatment of advanced cervical cancer.
In summary, this comparative study disclosed that primary control was similar when comparing IGBT with 2DBT for locally advanced cervical squamous cell carcinoma treated in the IMRT era. However, the therapeutic ratio could be increased by IGBT through minimizing the late toxicities. The result will be helpful to institutions where the cost-effectiveness of IGBT is a concern, particularly where resources are limited. More long-term observational studies are required to verify these findings.
Acknowledgements
This study is supported in part by grants from China Medical University Hospital (DMR-107-186, and DMR-108-201).
Footnotes
Authors' Contributions
SW Chen was responsible for the study design. All authors collected the data and provided some intellectual content. JA Liang and SW Chen performed statistical analyses, interpreted data, and drafted the article. SW Chen approved the version to be submitted. All authors read and approved the final manuscript.
Ethical approval
This study was approved by a local institutional review board [CMUH 107-REC3-119].
Conflicts of Interest
All Authors declare no conflicts of interest.
- Received March 31, 2019.
- Revision received April 29, 2019.
- Accepted May 2, 2019.
- Copyright© 2019, International Institute of Anticancer Research (Dr. George J. Delinasios), All rights reserved