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Journal of Contemporary Brachytherapy
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5/2022
vol. 14
 
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Original paper

The impact of different treatment protocols on achieved radiation doses of high-dose-rate brachytherapy for locally advanced cervical cancer: a comparison between 2 fractions in 1 application and separate applications for each fraction

Ester Jääskeläinen
1
,
Maarit Anttila
1
,
Jan-Erik Palmgren
2
,
Henna Kärkkäinen
1

  1. Department of Gynecology and Obstetrics, Kuopio University Hospital, Kuopio, Finland
  2. Radiotherapy Department, Kuopio University Hospital, Kuopio, Finland
J Contemp Brachytherapy 2022; 14, 5: 446–451
Online publish date: 2022/11/02
Article file
- The impact.pdf  [0.22 MB]
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Purpose

External beam radiotherapy (EBRT) combined with concomitant weekly cisplatin-based chemotherapy and followed by brachytherapy (BT), is the treatment of choice for patients with locally advanced cervical carcinoma (LACC). Brachytherapy improves clinical outcomes and has become the standard of care nowadays. The technique called ‘three-dimensional image-guided adaptive BT’ (IGABT) has evolved over the last 20 years, and today increasingly in the form of magnetic resonance imaging (MRI)-guided BT. In 2000, the GEC-ESTRO GYN working group was established to develop and unify gynecological IGABT [1-3]. Recommendations for IGABT contouring and dose reporting for LACC have been published by the working group. The group initiated a multicenter prospective study, called “International study on MRI-based brachytherapy in cervical cancer” (EMBRACE-1) in 2008. Based on the results of this study, dose prescription recommendations have been created for primary tumor targets and organs at risk (OARs). This subject has been considered by the International Commission on Radiation Units and Measurements (ICRU) Report 89, and published as “Prescribing, recording, and reporting brachytherapy for cancer of the cervix” [4].

While the benefit of BT in definitive radiotherapy of LACC is undeniable, there have been major differences in its’ implementation, including low-dose-rate (LDR), high-dose-rate (HDR), and pulsed-dose-rate (PDR) BT. A new possibility with a lower price is electronic brachytherapy, but its’ disadvantage is the lack of compatibility with interstitial needles [5]. HDR-BT is the most common modality applied in BT today. Modern HDR-IGABT is a complex medical procedure, which requires resources. HDR-BT for LACC consists of 2-5 fractions, with prescription doses of 3.5-9 Gy [6-9] delivered intracavitarily, and if needed, also with an interstitial component. Treatment protocols with two or more fractions implemented by a single application on consecutive days may save resources. A previous study demonstrated that geometric differences in the applicator position relative to the target and OARs had only a minor overall dosimetric effect, when one applicator insertion was used for the delivery of two HDR fractions within a 16-20-hour time interval [10].

To our knowledge, no studies have been published comparing the effect of brachytherapy implementations (keeping the applicator in situ overnight, or performing an application for each of the fractions), with respect to delivered doses to the target and OARs. Therefore, the aim of this study was to assess the dosimetric effects on (1) the delivered radiotherapy doses, and (2) the clinical and toxicity results as well as (3) the difference in cost, when four BT fractions were performed with two applicator insertions versus four separate insertions for each of the four fractions.

Material and methods

In this retrospective study, we analyzed the data of all LACC patients treated with a curative intent by MRI-based IGABT from January 2009 to December 2018 in Kuopio University Hospital, Finland. Study cohort of 117 patients and treatment protocol have been previously reported in detail [11]. Briefly, all patients had received EBRT, and most of them had also been treated concurrently with chemotherapy. EBRT was immediately followed by MR image-guided HDR brachytherapy, either delivered intracavitarily, or in a combined intra-cavitary and interstitial form. Brachytherapy was performed with four fractions administered over two weeks. The dose for each BT fraction was 7 Gy prescribed to high-risk clinical target volume (HR-CTV). An interstitial ring applicator or advanced gynecological applicator with a possibility of oblique needles (both Elekta™) was utilized, and in some cases, separate free-hand needles, which were not inserted through the applicator’s needle holes were used. The first applicator insertion was planned based on T2-weighted diagnostic and control (performed during the last week of chemo/radiotherapy) MRI, and gynecological examination (at the time of diagnosis and at the time of applicator insertion).

Contouring and dose optimization were performed based on MRI, according to ICRU/GEC-ESTRO and EMBRACE recommendations. There were no essential changes in the implementation of treatment during the study period. The plan was optimized using an automatic dose optimization algorithm, and then corrected using graphic and manual optimization (treatment planning system changed from BrachyVision (Varian Medical Systems™) to Oncentra Brachy (Elekta™) in 2016), and standardized loading patterns were not used. Planning aim (PA) of a total dose including EBRT and BT to 90% of HR-CTV (HR-CTV D90), converted into radiobiologically equivalent 2 Gy fractions (using an α/β value of 10 Gy) was preferably 90 Gy, but at least (hard constraint) 85 Gy. For OARs (using an α/β value of 3 Gy), optimization goals (hard constraints) of D2cm3 doses were < 90 Gy for the bladder, and < 75 Gy for the rectum and sigmoid. For the recto-vaginal point, the optimization goal was 75 Gy, but this was not evaluated in this study. The bowel was only systematically contoured in later cases.

Initially, our BT protocol comprised two HDR fractions delivered on consecutive days, with one applicator insertion. MR imaging was performed on the day of applicator insertion, and control computer tomography (CT) was performed on the next day. CT and MR images were fused using applicator geometry. Locations of interstitial needles were verified, and the position was corrected if necessary. For the target volume, we used HR-CTV contoured on the previous day. OARs were always contoured to new images if there had been a motion. Dose distribution was then revised and corrected if necessary. Reporting of the doses to HR-CTV and OARs was based upon the updated results. A similar pattern was repeated on the following week. Since 2015, applicator insertion with MRI and planning has mainly been conducted separately for each of the four fractions. CT imaging has not been used in the planning.

Statistical analyses were performed using IBM SPSS software, version 26. The groups were compared with standard statistical tests. Pearson’s chi-square test and Fisher’s exact test were applied to evaluate categorical variables, and 2-sided independent samples t-test was used for normally distributed continuous variables. Descriptive information was presented as percentages for categorical variables and as means (standard deviations; SD) or medians (ranges) for continuous variables. For statistical significance, an alpha level of 0.05 was considered.

Results

Over a 10-year period, we treated 117 LACC patients with a curative intent with EBRT ± chemotherapy and BT. Our study cohort was treated with two different BT schedules: four fractions completed either in two applicator insertions (n = 54, 46.2%, group 1) or with four separate insertions (n = 63, 53.8%, group 2). Background characteristics of the patients, tumors, and brachytherapy implementation are presented in Table 1.

Table 1

Comparison of the patients, tumors, and implementation of brachytherapy in the two study groups

VariableGroup 1, n = 54Group 2, n = 63p-value
Age (years), median (range)59 (27-88)51 (31-79)0.011
FIGO 2009 stage, n pts (%)I5 (9.4)7 (10.9)0.37
II33 (62.3)45 (70.3)
III10 (18.9)5 (7.8)
IV5 (9.4)7 (10.9)
Tumor maximum width on MRI (cm), mean (SD)5.7 (1.9)5.5 (1.6)0.66
HR-CTV volume (cm3), mean (SD)46.8 (25.8)43.1 (19.3)0.38
Interstitial needles, n pts (%)Yes45 (84.9)64 (100.0)0.001
No8 (15.1)0 (0.00)

The mean delivered dose to HR-CTV D90 was 93.7 Gy (SD = 6.1) for the entire group of patients; there were no differences in the mean delivered doses to the target volume between the patients treated according to these two BT schedules. The mean HR-CTV D90 was 93.0 Gy (SD = 7.4) for group 1, and 94.0 Gy (SD = 5.4) for group 2 (p = 0.40). With respect to OARs, the dose (D2cm3) to the rectum was significantly higher in the group 1 than in the group 2 (67.0 Gy vs. 63.6 Gy, respectively, p = 0.01). No differences between the groups were detected in the doses to the bladder or sigmoid (79.8 Gy vs. 80.8 Gy, p = 0.42, and 65.8 Gy vs. 67.5 Gy, p = 0.22, respectively).

Nevertheless, the fulfillment of both PAs to HR-CTV D90 (soft constraint 85 Gy and hard constraint 90 Gy) was less often achieved in the patients treated with two applications than in the patients treated with four applications. The PA of 85 Gy was not achieved in 16.7% of the patients in group 1 compared with only 3.2% in the group 2 (p = 0.022). For the PA of 90 Gy, a significant difference was found (p = 0.027). However, no significant differences were detected in the cases that exceeded the constraints for OARs (Table 2).

Table 2

Fulfillment of the planning aims for target volumes and keeping delivered doses to organs at risk under pre-defined targets

Volumes and dosesGroup 1, n = 54 n (%)Group 2, n = 63 n (%)p-value
HR-CTV D90 (≥ 85 Gy)45 (83.3)61 (96.8)0.022
HR-CTV D90 (≥ 90 Gy)36 (66.7)53 (84.1)0.027
D2cm3 bladder (< 90 Gy)51 (94.4)61 (96.8)0.660
D2cm3 rectum (< 75 Gy)45 (83.3)59 (93.7)0.087
D2cm3 sigmoid (< 75 Gy)50 (92.6)53 (84.1)0.250

[i] HR-CTV D90 – minimum dose to 90% of high-risk clinical target volume, D2cm3 – minimum dose to maximally irradiated 2 cm3

If necessary, the subsequent applicator insertion was amended (the type or size of applicator, or the number or position of interstitial needles was changed) to cover the target volume better. Alterations of this kind were possible once in the group 1, while in the group 2, there were three opportunities to correct the position of the applicator and needles. The mean delivered doses of HR-CTV D90 per fraction and the number of needles per fraction are presented in Table 3.

Table 3

HR-CTV D90 delivered doses and number of interstitial needles used per fraction, fractions 1 to 4

FractionGroup 1, n = 54Group 2, n = 63
HR-CTV D90 dose (Gy), mean (SD)Number of needles, mean (SD)HR-CTV D90 dose (Gy), mean (SD)Number of needles, mean (SD)
Fraction 17.7 (1.2)3.5 (2.3)7.6 (1.2)4.8 (2.6)
Fraction 27.6 (1.1)3.5 (2.3)7.9 (0.8)5.6 (2.7)
Fraction 37.9 (1.0)3.9 (2.5)8.1 (0.5)5.8 (2.6)
Fraction 47.8 (1.0)3.9 (2.5)8.0 (0.6)5.8 (2.5)

[i] HR-CTV D90 – minimum dose to 90% of high-risk clinical target volume

We divided the patients into three groups according to the HR-CTV volume (small tumors: ≤ 30 cm3, medium-sized tumors: 30.1-50 cm3, and large tumors: > 50 cm3), and performed a sub-group analysis. Table 4 presents the dose volume parameters and fulfillment of PAs of 85 Gy and 90 Gy for HR-CTV D90 for the volume sub-groups. In the groups of small and medium tumors, there was no difference between different application protocols, but a significant difference was detected with tumors larger than 50 cm3. With the largest tumors treated in the group 1, the PAs of 85 Gy and 90 Gy were less often achieved than in the group 2 (p = 0.010 and p = 0.043, respectively). In addition, the HR-CTV D90 mean dose was significantly better in the group 2 (p = 0.09). The two different treatment protocols had no effect on the doses delivered to OARs in the three volume sub-groups.

Table 4

HR-CTV D90 doses and fulfillment of the planning aims of 85 Gy (hard constraint) and 90 Gy (soft constraint) in different target volume groups

Volume groupsnHR-CTV D90 mean dose (SD)Fulfilled PA 85 GyFulfilled PA 90 Gy
Group 1Group 2p-valueGroup 1Group 2p-valueGroup 1Group 2p-value
Vol. ≤ 30 cm33097.5 (6.1)95.9 (6.2)0.5091.7%94.4%1.0091.7%83.3%0.63
Vol. 30.1-50 cm34893.6 (5.4)93.8 (4.2 )0.8895.2%96.3%1.0071.4%85.2%0.30
Vol. > 50 cm33989.8 (8.5)93.4 (3.7)0.0966.7%100.0%0.01047.6%83.3%0.043

[i] HR-CTV D90 – minimum dose to 90% of high-risk clinical target volume, volume groups – patients sub-divided according to the volume of HR-CTV, PA – planning aim

Intra-operative utero-vaginal complications, mostly uterine perforations, occurred in 17% and 27% of cases in the groups 1 and 2, respectively (p = 0.18). Needle placement directly adjacent to OARs or suspected perforation of OARs occurred in 3.7% and 7.9% of cases, respectively (p = 0.45). However, none of these required specific treatment, and none of the cases presented with significant bleeding when the interstitial component was removed.

We analyzed available follow-up information to assess the impact of different treatment schedules on the clinical results for the whole study population, and separately for the group with largest tumors. No difference was detected in the local control at three months between the groups or in late complications (Table 5).

Table 5

Occurrence of complications and local control at 3 months after brachytherapy

ComplicationWhole study populationTumor volume > 50cm3
Group 1Group 2p-valueGroup 1Group 2p-value
nN%nN%nN%nN%
Intra-operative utero-vaginal complications95416.7176327.00.1852123.851827.80.78
Any late complication335164.7335461.10.70142166.781457.10.57
G3-4 late complications75113.775413.00.9132114.331421.40.66
GI complications65111.85549.30.6832114.30140.00.26
Complete response at 3 months475192.2555796.50.42192190.5151693.80.72

[i] n – number of patients with mentioned features, N – number of patients with follow-up data available, GI complications – gastro-intestinal complications

To analyze the costs, we randomly selected three patients from each group and considered as typical cases. The differences in costs were due to additional MRI and procedures with anesthesia in the group 2. The mean costs for two treatment weeks were €15,785 and €20,310, in the groups 1 and 2, respectively. Therefore, two fractions delivered with one applicator insertion resulted in approximately 22.3% of lower costs.

Discussion

This retrospective study investigated the effect of two different BT protocols, i.e., two BT fractions in one applicator insertion on consecutive days, repeated the following week, or a separate applicator insertion for each of the four fractions, with respect to the delivered radiation doses in 117 patients with locally advanced cervical cancer. According to the results, applicator insertions separately for each of the four BT fractions more frequently allowed the fulfillment of PAs of 85 Gy (hard constraint) and 90 Gy (soft constraint) to HR-CTV D90, as compared with a schedule of four fractions with two applicator insertions.

In previous studies, it has been demonstrated that BT has an important role in the treatment of LACC, since BT improves local control and overall survival in comparison with external radio/chemotherapy alone [12-15]. Unified international instructions for contouring, dose optimization, and reporting as well as guidelines for dose planning aims for target volumes and OARs have been developed by the GEC-ESTRO GYN working group and EMBRACE study group [1,3,7,16]. However, there is still no globally recognized standardized fractionation scheme. A wide variety of regimens have been used by different institutions [8,9,17,18]. In Europe, due to the influence of EMBRACE study, a frequently used schedule involves four BT fractions of 7 Gy [19]. In the United States, the most common schedule for BT is four to five fractions of 5.5-6 Gy per fraction [20,21]. Low-income countries with lower resources and a significantly higher incidence of cervical cancer can face challenges with this expensive cancer treatment. This may result in protocols with fewer fractions and a larger dose per fraction [17,22,23]. In addition, due to COVID-19 and the need to save healthcare resources, an institution in Yale, USA, changed the schedule of BT to a single application: three fractions treated within one week with 8 Gy per fraction [24].

Evidence suggests that local control benefits from the delivered dose of 85 Gy to HR-CTV D90, with the dose of 90 Gy further improving this result [25]. When evaluating treatment method in terms of dosimetric result, fulfilling PAs for a larger proportion of patients is a more informative parameter than the calculated mean dose of study population. In this study, the PAs were fulfilled significantly more often with four separate applicator insertions. The PA of 85 Gy was fulfilled in 83% and in 97% of cases, and the PA of 90 Gy in 67% and in 84% of cases with two and four insertions, respectively. According to the sub-group analysis, large tumors gained the most benefit from the four insertions. In other words, this benefit from separate applications was emphasized in the most challenging cases.

Occasionally, it is very difficult to initially achieve a good position of the applicator and needles, because only MR image with the applicator in situ makes it easier to identify the best positions of interstitial needles to cover the target. Therefore, additional insertions of the applicator can help in achieving better doses.

However, in this study, the better delivered doses did not translate into better remission rates or decreased late toxicity. Comparably with previous studies, grade 3-4 late complications were observed in 13-14% and a complete response at 3 months in 92-97% of our study population. In the EMBRACE-1 study, grade 3-5 late complications were detected in 14.6% of patients, and 5-year local control was 92% [19]. Similarly, RetroEMBRACE study detected persistent disease after treatment in 13 out of 488 patients (complete response, 97%) [25].

Other institutions have previously reported a low-rate of severe intra-operative complications [26,27]. Nevertheless, four versus two invasive applicator insertion procedures potentially carries a higher risk of early complications. None of our patients experienced a severe intra-operative complication, despite the multiple applicator insertions.

Moreover, a negative side of additional applications is the higher price of a treatment. Therefore, by delivering two fractions with one insertion, it is possible to save costs relating to the procedure and anesthesia. There is evidence indicating that if the applicator is left in place overnight, it has an insignificant dosimetric effect on the delivered second dose [10]. Nonetheless, the position of the applicator and needles must not change between fractions, and this must be confirmed by imaging. Using CT imaging on the second day of treatment instead of MRI is more affordable. OARs (e.g., sigma) typically change position and need re-delineation. Previous studies have suggested that execution of a dose-optimized previous day plan of brachytherapy in subsequent fraction, resulted in an increase of D2cc doses to OARs [28,29]. Therefore, the work of a medical physicist is required for image fusion, verifying the position of the applicator, and correcting the dose optimization. By contrast, being overnight with an applicator in situ, the patient also needs more care and analgesia, which reduces the savings mentioned above. Our analysis indicated that in typical cases, it is possible to save about 22% of the costs by keeping the applicator in situ overnight. However, if pain management is insufficient and the patient needs strong medication and more intensive monitoring, this reduces the savings.

The weakness of this study is that it was retrospective in nature, and data were collected over a long period of time (from 2009 to 2018). In addition, our institution’s learning curve occurred at the beginning of the study period (this only refers to group 1 patients), and we also used more interstitial needles for group 2 patients, which is presumably an effect of longer experience. In the sub-group analysis, the groups were also small, which may have affected the results. Additionally, we could not analyze cost-effectiveness.

Conclusions

According to this study, four applications conferred the achievement of PA to HR-CTV, and larger tumors in particular gained the most benefit. However, no significant increase was observed in the risk of early complications resulting from a higher number of invasive procedures. Nevertheless, brachytherapy is a rather expensive treatment, so the advantages of multiple applications must be weighed against the costs.

Acknowledgements

During writing of this article, Ester Jääskeläinen received funding from Paavo Koistinen Foundation and Finnish Cultural Foundation.

Disclosure

The authors report no conflict of interest.

References

1 

Haie-Meder C, Pötter R, Van Limbergen E et al. Recommendations from Gynaecological (GYN) GEC-ESTRO Working Group☆ (I): concepts and terms in 3D image based 3D treatment planning in cervix cancer brachytherapy with emphasis on MRI assessment of GTV and CTV. Radiother Oncol 2005; 74: 235-245.

2 

Tan LT, Tanderup K, Kirisits C et al. Image-guided adaptive radiotherapy in cervical cancer. Semin Radiat Oncol 2019; 29: 284-298.

3 

Pötter R, Haie-Meder C, Limbergen EV et al. Recommendations from gynaecological (GYN) GEC ESTRO working group (II): Concepts and terms in 3D image-based treatment planning in cervix cancer brachytherapy–3D dose volume parameters and aspects of 3D image-based anatomy, radiation physics, radiobiology. Radiother Oncol 2006; 78: 67-77.

4 

International Commission on Radiation Units and Measurements: Prescribing, Recording, and Reporting Brachytherapy for Cancer of the Cervix. J ICRU 2013; 13: NP.

5 

Lozares-Cordero S, Gonzalez-Perez V, Pellejero-Pellejero S et al. Feasibility of electronic brachytherapy in cervix cancer-A dosimetric comparison of different brachytherapy techniques. Brachytherapy 2022; 21: 389-396.

6 

Villafranca E, Navarrete P, Sola A et al. Image-guided brachytherapy in cervical cancer: Experience in the Complejo Hospitalario de Navarra. Rep Pract Oncol Radiother 2018; 23: 510-516.

7 

Tanderup K, Nesvacil N, Kirchheiner K et al. Evidence-based dose planning aims and dose prescription in image-guided brachytherapy combined with radiochemotherapy in locally advanced cervical cancer. Semin Radiat Oncol 2020; 30: 311-327.

8 

le Guyader M, Lam Cham Kee D, Thamphya B et al. High-dose-rate brachytherapy boost for locally advanced cervical cancer: Oncological outcome and toxicity analysis of 4 fractionation schemes. Clin Transl Radiat Oncol 2021; 32: 15-23.

9 

Thakur P, Dogra E, Gupta M et al. Comparison of iso-effective and cost-effective high-dose-rate brachytherapy treatment schedules in cervical cancer–regional cancer center experience. J Contemp Brachytherapy 2019; 11: 428-435.

10 

Lang S, Nesvacil N, Kirisits C et al. Uncertainty analysis for 3D image-based cervix cancer brachytherapy by repetitive MR imaging: assessment of DVH-variations between two HDR fractions within one applicator insertion and their clinical relevance. Radiother Oncol 2013; 107: 26-31.

11 

Jääskeläinen E, Kärkkäinen H, Palmgren J et al. MRI-guided brachytherapy for locally advanced cervical cancer: Program initiation, learning curve and dose delivery results in Kuopio University Hospital. Brachytherapy 2021; 20: 738-747.

12 

Han K, Milosevic M, Fyles A et al. Trends in the utilization of brachytherapy in cervical cancer in the United States. Int J Radiat Oncol Biol Phys 2013; 87: 111-119.

13 

Sturdza A, Pötter R, Fokdal LU et al. Image guided brachytherapy in locally advanced cervical cancer: Improved pelvic control and survival in RetroEMBRACE, a multicenter cohort study. Radiother Oncol 2016; 120: 428-433.

14 

Tanderup K, Eifel PJ, Yashar CM et al. Curative radiation therapy for locally advanced cervical cancer: brachytherapy is NOT optional. Int J Radiat Oncol Biol Phys 2014; 88: 537-539.

15 

Korenaga TK, Yoshida EJ, Pierson W et al. Better late than never: Brachytherapy is more important than timing in treatment of locally advanced cervical cancer. Gynecol Oncol 2022; 164: 348-356.

16 

Pötter R, Tanderup K, Kirisits C et al. The EMBRACE II study: The outcome and prospect of two decades of evolution within the GEC-ESTRO GYN working group and the EMBRACE studies. Clin Transl Radiat Oncol 2018; 9: 48-60.

17 

Patel FD, Kumar P, Karunanidhi G et al. Optimization of high-dose-rate intracavitary brachytherapy schedule in the treatment of carcinoma of the cervix. Brachytherapy 2011; 10: 147-153.

18 

Möller S, Mordhorst LB, Hermansson RS et al. Combined external pelvic chemoradiotherapy and image-guided adaptive brachytherapy in treatment of advanced cervical carcinoma: experience from a single institution. J Contemp Brachytherapy 2020; 12: 356-366.

19 

Pötter R, Tanderup K, Schmid MP et al. MRI-guided adaptive brachytherapy in locally advanced cervical cancer (EMBRACE-I): a multicentre prospective cohort study. Lancet Oncol 2021; 22: 538-547.

20 

Viswanathan AN, Beriwal S, De Los Santos JF et al. American Brachytherapy Society consensus guidelines for locally advanced carcinoma of the cervix. Part II: high-dose-rate brachytherapy. Brachytherapy 2012; 11: 47-52.

21 

Albuquerque K, Hrycushko BA, Harkenrider MM et al. Compendium of fractionation choices for gynecologic HDR brachytherapy-An American Brachytherapy Society Task Group Report. Brachytherapy 2019; 18: 429-436.

22 

Mahantshetty U, Gurram L, Bushra S et al. Single application multifractionated image guided adaptive high-dose-rate brachytherapy for cervical cancer: dosimetric and clinical outcomes. Int J Radiat Oncol Biol Phys 2021; 111: 826-834.

23 

Mahantshetty U, Gudi S, Singh R et al. Indian Brachytherapy Society Guidelines for radiotherapeutic management of cervical cancer with special emphasis on high-dose-rate brachytherapy. J Contemp Brachytherapy 2019; 11: 293-306.

24 

Damast S, Tien CJ, Young M et al. Single application hybrid interstitial brachytherapy for cervical cancer: an institutional approach during the COVID-19 pandemic. J Contemp Brachytherapy 2022; 14: 66-71.

25 

Tanderup K, Fokdal LU, Sturdza A et al. Effect of tumor dose, volume and overall treatment time on local control after radiochemotherapy including MRI guided brachytherapy of locally advanced cervical cancer. Radiother Oncol 2016; 120: 441-446.

26 

Dimopoulos JCA, Kirisits C, Petric P et al. The Vienna applicator for combined intracavitary and interstitial brachytherapy of cervical cancer: Clinical feasibility and preliminary results. Int J Radiat Oncol Biol Phys 2006; 66: 83-90.

27 

Tambas M, Tavli B, Bilici N et al. Computed tomography-guided optimization of needle insertion for combined intracavitary/interstitial brachytherapy with Utrecht applicator in locally advanced cervical cancer. Pract Radiat Oncol 2021; 11: 272-281.

28 

Kirisits C, Lang S, Dimopoulos J et al. Uncertainties when using only one MRI-based treatment plan for subsequent high-dose-rate tandem and ring applications in brachytherapy of cervix cancer. Radiother Oncol 2006; 81: 269-275.

29 

Pasha T, Hassan HN, Radhakrishna N et al. Evaluation of dosimetric impact of inter-application and intra-application variations in fractionated high-dose-rate intra-cavitary brachytherapy of cervical cancer. J Contemp Brachytherapy 2021; 13: 627-632.

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