• Female
• Humans
• Uterine Cervical Neoplasms/radiotherapy
• Workflow
• Brachytherapy/methods
• Magnetic Resonance Imaging/methods
• Radiotherapy, Image-Guided/methods
• Radiotherapy Dosage

• 3d-printing
• Cervical cancer
• image guided adaptive brachytherapy
• interstitial
• treatment individualization

• Female
• Humans
• Middle Aged
• Uterine Cervical Neoplasms/radiotherapy
• Brachytherapy/methods
• Radiotherapy Dosage
• Pelvis
• Radiotherapy Planning, Computer-Assisted/methods
• Printing, Three-Dimensional

• ART
• IGRT
• cervix cancer
• external beam radiotherapy
• image-guided brachytherapy

• Female
• Humans
• Uterine Cervical Neoplasms/pathology
• Radiotherapy Dosage
• Treatment Outcome
• Neoplasm Staging
• Rectum
• Magnetic Resonance Imaging/methods
• Brachytherapy/methods

• Female
• Pregnancy
• Humans
• Young Adult
• Adult
• Middle Aged
• Aged
• Brachytherapy
• Uterine Cervical Neoplasms/radiotherapy
• Ethiopia/epidemiology
• Retrospective Studies
• Radiation Oncology
• Neoplasms, Second Primary

To compare the dosimetric influence of applicator displacement on two-dimensional brachytherapy (2D-BT) and three-dimensional brachytherapy (3D-BT) for cervical cancer. Nineteen patients who received computed tomography-guided tandem-and-ovoid (T&O) brachytherapy were retrospectively selected. Both 2D (point-based) and 3D (volume-based) plans with and without virtual applicator displacement in the 3 axes were created for each patient. Dose changes at point A, D₉₀ of the high-risk clinical target volume (HR-CTV) and intermediate-risk CTV (IR-CTV), and the D_0.1cc, D_1cc, D_2cc, and D_5cc of organs-at-risk (OARs) caused by applicator displacement were evaluated. Both 2D-BT and 3D-BT plans were sensitive to T&O applicator displacement. The D₉₀ of the CTV and the dose at point A were very sensitive to applicator displacement in the right–left direction (X-axis). An applicator shift of >2 mm in the X-axis resulted in a change of >5% in the dose at point A and D₉₀ of HR-CTV and IR-CTV. In addition, the doses to the OARs were mostly affected by applicator displacement in the anterior–posterior direction (Z-axis). A displacement of <1.5 mm in the Z-axis was required to avoid a dose change of >10% for OARs. For both 2D-BT and 3D-BT plans, T&O displacement greater than  ± 2 mm in the X-axis or T&O applicator displacement  ± 1.5 mm in the Z-axis resulted in significant dose changes to the tumor and OARs. In comparison with 3D-BT plans, 2D-BT plans delivered a higher dose to the tumor, and the OARs received more undesirable doses when applicator displacement occurred. The influence of applicator displacement on the doses to the tumor and OARs differed between 2D-BT and 3D-BT. Physicians should take individual patient differences into account when selecting a brachytherapy plan to mitigate the influence of applicator displacement.

• 2D brachytherapy
• 3D brachytherapy
• applicator displacement
• cervical cancer
• dosimetric influence

• Brachytherapy
• Cancer
• Cervical cancer
• Col de l’utérus
• Curiethérapie
• Functional imaging
• Imagerie fonctionnelle
• Prostate
• Prostate cancer

• Brachytherapy/methods
• Diagnostic Imaging
• Female
• Humans
• Radiotherapy Dosage
• Uterine Cervical Neoplasms/pathology

• Cervix cancer
• Intracavitary and interstitial brachytherapy
• MR-guided adaptive brachytherapy
• Parallel and oblique needles

• Early-stage cervical cancer
• Hysterectomy
• Image-guided adaptive brachytherapy
• Minimally invasive surgery
• Preoperative brachytherapy

• Adult
• Aged
• Aged, 80 and over
• Brachytherapy/adverse effects
• Brachytherapy/methods
• Combined Modality Therapy
• Disease-Free Survival
• Female
• Humans
• Middle Aged
• Minimally Invasive Surgical Procedures/methods
• Neoplasm Staging
• Perioperative Care/methods
• Radiotherapy, Image-Guided/methods
• Retrospective Studies
• Treatment Outcome
• Uterine Cervical Neoplasms/diagnostic imaging
• Uterine Cervical Neoplasms/pathology
• Uterine Cervical Neoplasms/radiotherapy
• Uterine Cervical Neoplasms/surgery

To investigate the role of transrectal ultrasound guidance in interstitial brachytherapy for cervical cancer.

Forty-eight patients who underwent interstitial brachytherapy treatment for cervical cancer between January 2017 and January 2018 were enrolled in the study. The distances between each inserted needle and the lesion were measured at seven sites by ultrasound (D1-D7) and compared to the corresponding distances (M1-M7) when visualised with nuclear magnetic resonance imaging (MRI). Measurements were paired on the basis of the observation sites, e.g. D1 and M1, D2 and M2. The statistical differences, intraclass correlation coefficients (ICCs), and linear relationships for the paired measurements were calculated.

No significant differences were found between the paired M and D measurements, with all ICCs showing high levels of concordance (0.81-0.93).

Transrectal ultrasound showed strong agreement with MRI results in determining the position of the inserted needles. Transrectal ultrasound is a useful tool for guided interstitial brachytherapy and is appropriate for widespread use in the treatment of locally advanced cervical cancer.

• brachytherapy
• cervical cancer
• transrectal ultrasound
• ultrasound guidance

• Contouring
• Image-guided adaptive brachytherapy
• Locally advanced cervical cancer
• MRI
• Transrectal ultrasound

• Antineoplastic Agents, Alkylating/therapeutic use
• Brachytherapy/methods
• Carcinoma, Squamous Cell/diagnostic imaging
• Carcinoma, Squamous Cell/drug therapy
• Carcinoma, Squamous Cell/radiotherapy
• Chemotherapy, Adjuvant
• Cisplatin/therapeutic use
• Female
• Humans
• Magnetic Resonance Imaging/methods
• Multimodal Imaging/methods
• Observer Variation
• Prospective Studies
• Radiotherapy, Image-Guided/methods
• Tomography, X-Ray Computed/methods
• Ultrasound, High-Intensity Focused, Transrectal/methods
• Uterine Cervical Neoplasms/diagnostic imaging
• Uterine Cervical Neoplasms/drug therapy
• Uterine Cervical Neoplasms/radiotherapy

• Medical University of Vienna

• bibliometric analysis
• brachytherapy
• cervical cancer
• external beam radiotherapy
• most cited articles
• vosviewer

• Austria/epidemiology
• Bibliometrics
• Biology/statistics & numerical data
• Brachytherapy/methods
• Canada/epidemiology
• Databases, Factual
• Female
• France/epidemiology
• Humans
• Medical Oncology/statistics & numerical data
• Middle Aged
• Physics/statistics & numerical data
• Publications/statistics & numerical data
• Publications/trends
• Radiation Oncology/statistics & numerical data
• United Kingdom/epidemiology
• United States/epidemiology
• Uterine Cervical Neoplasms/radiotherapy

Purpose: This study aimed to develop a volumetric independent dose calculation (vIDC) system for verification of the treatment plan in image-guided adaptive brachytherapy (IGABT) and to evaluate the feasibility of the vIDC in clinical practice with simulated cases.

Methods: The vIDC is based on the formalism of TG-43. Four simulated cases of cervical cancer were selected to retrospectively evaluate the dose distributions in IGABT. Some reference point doses, such as points A and B and rectal points, were calculated by vIDC using absolute coordinate. The 3D dose volume was also calculated to acquire dose-volume histograms (DVHs) with grid resolutions of 1.0 × 1.0 (G_1.0), 2.5 × 2.5 (G_2.5), and 0.5 × 0.5 mm² (G_0.5). Dosimetric parameters such as D_90% and D_2cc doses covering 90% of the high-risk critical target volume (HR-CTV) and 2 cc of the organs at risk (OARs) were obtained from DVHs. D_90% also converted to equivalent dose in 2-Gy fractions (EQD2) to produce the same radiobiological effect as external beam radiotherapy. In addition, D_90% was obtained in two types with or without the applicator volume to confirm the effect of the applicator itself. Validation of the vIDC was also performed using gamma evaluation by comparison with Monte Carlo simulation.

Results: The average percentage difference of point doses was <2.28%. The DVHs for the HR-CTV and OARs showed no significant differences between the vIDC and the treatment planning system (TPS). Without considering the applicator volume, the D_90% of the HR-CTV calculated by the vIDC decreases with a decreasing calculated dose-grid size (32.4, 5.65, and −2.20 cGy in G_2.5, G_1.0, and G_0.5, respectively). The overall D_90% is higher when considering the applicator volume. The converted D_90% by EQD2 ranged from −1.29 to 1.00%. The D_2cc of the OARs showed that the averaged dose deviation is <10 cGy regardless of the dose-grid size. Based on gamma analysis, the passing rate was 98.81% for 3%/3-mm criteria.

Conclusion: The vIDC was developed as an independent dose verification system for verification of the treatment plan in IGABT. We confirmed that the vIDC is suitable for second-check dose validation of the TPS under various conditions.

• American Association of Physicists in Medicine Task Group 43
• dose grid
• equivalent dose in 2-Gy fractions
• image-guided adaptive brachytherapy
• independent dose calculation system

• Bibliometric analysis
• Brachytherapy
• Cervical cancer
• Most cited articles

• Brachytherapy
• Dose distribution
• Interstitial brachytherapy
• Intracavitary brachytherapy

• Cervical cancer
• Dose-effect
• Intarcavitary/interstitial brachytherapy

To evaluate the clinical use of 3D printing technology for the modelling of individual applicators for advanced gynecological tumors in magnetic resonance imaging (MRI)-based brachytherapy (BT).

We tested individually designed 3D-printed applicators in nine patients with advanced gynecological cancer. Before BT was performed, all patients were treated with external beam radiotherapy (EBRT). The most common indication for individualized BT was advanced gynecological tumors where the use of standard BT applicators was not feasible. Other indications were suboptimal dose-volume histogram (DVH) parameters for high-risk clinical target volume (CTV-T_HR) at the first BT (V₁₀₀ ≤ 90% of CTV-T_HR volume and D₉₈ ≤ 80%, D₉₀ ≤ 100%, and D₁₀₀ ≤ 60% of dose aim). The EQD₂ dose aim to the target volume D₉₀ CTV-T_HR per one BT fraction was 20 Gy for cervical or recurrent endometrial cancer and 16 Gy for vaginal cancer patient. The first BT with the standard applicator in situ was used as the virtual plan for designing a 3D-printed applicator. The next BT was performed with a 3D-printed applicator in situ. The primary endpoint was to improve CTV-T_HR DVH parameters without exceeding the dose to the organs at risk (OARs).

All DVH parameters for CTV-T_HR were significantly higher with the use of an individually designed applicator. Mean D₉₀ CTV-T_HR improved from 14.1 ±5.4 Gy to 22.0 ±2.5 Gy and from 7.1 Gy to 16.2 Gy for cervical/recurrent endometrial and vaginal cancer, respectively (p < 0.001). The mean D_2cm³ bladder, rectum, sigmoid, and bowel dose was within institutional dose constraints, and increased from 13.0 ±1.5 Gy to 13.6 ±1.5 Gy (p = 0.045), 10.8 ±1.2 Gy to 11.7 ±1.3 Gy (p = 0.004), 8.9 ±3.2 Gy to 10.3 ±3.3 Gy (p = 0.008), and 8.7 ±3.8 Gy to 9.2 ±3.1 Gy (p = 0.2).

With the use of individual 3D-printed applicators, all DVH parameters for CTV-T_HR significantly improved without compromising the dose constraints for the OARs.

• 3D printing
• gynecological cancer
• image-guided brachytherapy

The dose distributions obtained from three imaging approaches for target delineation in cervical cancer using high-dose-rate (HDR) brachytherapy were investigated.

Ten cervical cancer patients receiving four fractions of HDR brachytherapy were enrolled. Based on different imaging approaches, three brachytherapy plans were developed for each patient: with the high-risk clinical target volume (HRCTV) delineated on magnetic resonance (MRI) images for every fraction (approach A; MRI-only); on MRI for the first fraction and computed tomography (CT) images for the subsequent fractions (approach B; MRI_1st/CT); and on CT images for all fractions (approach C; CT-only). The volume, height, width at point A, width at maximum level, and dosimetric parameters (D₁₀₀, D₉₈, D₉₅, and D₉₀ of the HRCTV; and D_0.1cc, D_1cc, and D_2cc of all organs at risk, or organ at risk – OAR: bladder, rectum, sigmoid colon, and bowel) provided by each approach were compared.

The mean HRCTV volume, width, and height obtained from approach C (CT-only) were overestimated compared to those from approaches A (MRI-only) and B (MRI_1st/CT). The doses to the HRCTV for approaches A and B were similar. However, the HRCTV doses for approach C were significantly lower than those for approaches A and B for all parameters (D₉₅-D₁₀₀). As to the OAR, the three approaches showed no differences.

A combination of MRI and CT is a safe alternative approach for cervical cancer HDR brachytherapy. The technique provides comparable dosimetric outcomes to MRI-based planning, while being more cost-effective.

• CT
• MRI
• brachytherapy
• cervix cancer
• target delineation

Modern three‐dimensional image‐guided intracavitary high dose rate (HDR) brachytherapy is often used in combination with external beam radiotherapy (EBRT) to manage cervical cancer. Intrafraction motion of critical organs relative to the HDR applicator in the time between the planning CT and treatment delivery can cause marked deviations between the planned and delivered doses. This study examines offline adaptive planning techniques that may reduce intrafraction uncertainties by shortening the time between the planning CT and treatment delivery. Eight patients who received EBRT followed by HDR boosts were retrospectively reviewed. A CT scan was obtained for each insertion. Four strategies were simulated: (A) plans based on the current treatment day CT; (B) plans based on the first fraction CT; (C) plans based on the CT from the immediately preceding fraction; (D) plans based on the closest anatomically matched previous CT, using all prior plans as a library. Strategies B, C, and D allow plans to be created prior to the treatment day insertion, and then rapidly compared with the new CT. Equivalent doses in 2 Gy for combined EBRT and HDR were compared with online adaptive plans (strategy A) at D₉₀ and D₉₈ for the high‐risk CTV (HR‐CTV), and D_2 cc for the bladder, rectum, sigmoid, and bowel. Compared to strategy A, D₉₀ deviations for the HR‐CTV were −0.5 ± 2.8 Gy, −0.9 ± 1.0 Gy, and −0.7 ± 1.0 Gy for Strategies B, C, and D, respectively. D_2 cc changes for rectum were 2.7 ± 5.6 Gy, 0.6 ± 1.7 Gy, and 1.1 ± 2.4 Gy for Strategies B, C, and D. With the exception of one patient using strategy B, no notable variations for bladder, sigmoid, and bowel were found. Offline adaptive planning techniques can shorten time between CT and treatment delivery from hours to minutes, with minimal loss of dosimetric accuracy, greatly reducing the chance of intrafraction motion.

• Image-guided brachytherapy
• offline adaptive planning

• Cervical cancer
• GEC-ESTRO guidelines
• Image guided brachytherapy

• Bladder morbidity
• Locally advanced cervical cancer
• MRI-guided adaptive brachytherapy

• Adult
• Aged
• Aged, 80 and over
• Brachytherapy/adverse effects
• Brachytherapy/methods
• Chemoradiotherapy/adverse effects
• Cisplatin/administration & dosage
• Cisplatin/adverse effects
• Female
• Humans
• Lower Urinary Tract Symptoms/chemically induced
• Lower Urinary Tract Symptoms/etiology
• Magnetic Resonance Imaging/methods
• Middle Aged
• Morbidity
• Patient Reported Outcome Measures
• Prospective Studies
• Radiation Injuries/chemically induced
• Radiation Injuries/etiology
• Radiotherapy, Image-Guided/adverse effects
• Radiotherapy, Image-Guided/methods
• Urinary Bladder/drug effects
• Urinary Bladder/radiation effects
• Urinary Tract/drug effects
• Urinary Tract/radiation effects
• Uterine Cervical Neoplasms/diagnostic imaging
• Uterine Cervical Neoplasms/drug therapy
• Uterine Cervical Neoplasms/radiotherapy
• Uterine Cervical Neoplasms/therapy
• Young Adult

Purpose: To report the efficacy and late side effects(LSEs) of CT-based image-guided brachytherapy for the treatment of cervical cancer.

Materials: Between 2008 and 2014, 100 patients with FIGO stage IIB-IVA cervical carcinoma were analyzed. The patients received pelvic irradiation (45-50 Gy in 25 fractions) with concurrent chemotherapy, whereas the mean prescribed EBRT dose, including initial and boost doses to positive lymph nodes, ranged from 54 to 64 Gy. Afterwards, intracavitary(IC) or combined intracavitary/interstitial(IC/IS) brachytherapy was performed using a CT-based procedure with prescribed doses of 6 or 8 Gy in 3-7 fractions.

Results: The median follow-up time was 46 months. The 5-year local control, distant metastasis-free survival, and overall survival rates were 88.9%, 81.8%, 77.9%, respectively. IC/IS brachytherapy improved the HR-CTV D90 compared with IC (p<0.01). Seven patients (7.0%) had grade 2 bladder LSEs and none had grade 3/4 bladder LSEs. There was no significant relationship between bladder LSEs and the dose-volume histogram (p>0.05 for all). Thirty-seven patients (37%) had grade 2 rectal LSEs, 3(3%) had grade 3 rectal LSE. The rectum D_1cc, D_2cc, and D_5cc values were significantly higher in patients with grades 2/3 rectal toxicity than in those with grades 0/1 (p<0.05 for all). There was no grade 2 and above small bowel LSEs.

Conclusions: CT-based brachytherapy planning can achieve excellent local control with acceptable morbidity. HR-CTV D90 can increase in the IC/IS group compared with the IC group. The D_1cc, D_2cc, and D_5cc all showed excellent predictive values for rectal LSEs.

• brachytherapy
• cervical cancer
• computed tomography
• dose-volume histogram
• late side effects

The purpose of this study was to analyze the effect of 2D conventional brachytherapy (CBT) compared to 3D MRI-guided brachytherapy (IGBT) with and without the use of interstitial needles on local control, overall survival, and toxicity in patients treated for cervical cancer with radiation or chemoradiation.

A retrospective analysis was performed of biopsy-proven FIGO IB-IVA cervical cancer patients, treated with primary radiation or chemoradiation, followed by brachytherapy (BT) between January 1997 and July 2016. Endpoints were local control, overall survival, and toxicity.

Of 126 patients included, 35 have been treated with CBT, 31 with IGBT without needles (IC), and 60 with IGBT with needles (ICIS). External beam radiotherapy (EBRT) had mostly been delivered concurrently with chemotherapy (weekly cisplatin). Overall local control was 93% after 1 year, and 88% after 3 years. Overall 3-year survival was 75%, and 5-year survival was 66%. The 3D technique (IGBT cohorts) showed a trend for an improved local control and overall survival (p = 0.05) compared to the 2D technique (CBT cohort). A decrease in toxicity was observed from 17% (2D cohort) to 12% (3D cohort). The use of interstitial needles was associated with a higher high-risk clinical target volume (HR-CTV) dose (11.3 Gy vs. 9.9 Gy) and a lower D_2cc bladder dose (10.9 Gy vs. 14.7 Gy, both p < 0.01).

In cervical cancer treatment, the use of a 3D brachytherapy technique (MRI-guided with or without interstitial needles) showed a trend towards an increased local control and improved overall survival with reduced toxicity, compared to the conventional 2D brachytherapy technique. The use of interstitial needles allowed dose sculpting, resulting in delivery of higher doses to the HR-CTV, while reducing radiation doses to organs at risk, such as the bladder.

• MRI-guided brachytherapy
• brachytherapy
• cervical cancer
• interstitial needles

• Bowel
• Cervical cancer
• Contouring

• (170.2150) Medical and biological imaging
• (170.3880) Endoscopic imaging
• (170.7230) Urology

• Cervical cancer
• Interstitial brachytherapy
• Practice pattern
• Utilization

Standard applicators for cervical cancer Brachytherapy (BT) do not always achieve acceptable balance between target volume and normal tissue irradiation. We aimed to develop an innovative method of Target-volume Density Mapping (TDM) for modelling of novel applicator prototypes with optimal coverage characteristics. Patients and methods. Development of Contour-Analysis Tool 2 (CAT-2) software for TDM generation was the core priority of our task group. Main requests regarding software functionalities were formulated and guided the coding process. Software validation and accuracy check was performed using phantom objects. Concepts and terms for standardized workflow of TDM post-processing and applicator development were introduced.

CAT-2 enables applicator-based co-registration of Digital Imaging and Communications in Medicine (DICOM) structures from a sample of cases, generating a TDM with pooled contours in applicator-eye-view. Each TDM voxel is assigned a value, corresponding to the number of target contours encompassing that voxel. Values are converted to grey levels and transformed to DICOM image, which is transported to the treatment planning system. Iso-density contours (IDC) are generated as lines, connecting voxels with same grey levels. Residual Volume at Risk (RVR) is created for each IDC as potential volume that could contain organs at risk. Finally, standard and prototype applicators are applied on the TDM and virtual dose planning is performed. Dose volume histogram (DVH) parameters are recorded for individual IDC and RVR delineations and characteristic curves generated. Optimal applicator configuration is determined in an iterative manner based on comparison of characteristic curves, virtual implant complexities and isodose distributions.

Using the TDM approach, virtual applicator prototypes capable of conformal coverage of any target volume, can be modelled. Further systematic assessment, including studies on clinical feasibility, safety and effectiveness are needed before routine use of novel prototypes can be considered.

• applicators
• brachytherapy
• cervical cancer

The purpose of this study was to evaluate adaptive daily planning for cervical cancer patients who underwent high‐dose‐rate intracavitary brachytherapy (HDR‐BT) using comprehensive interfractional organ motion measurements. This study included 22 cervical cancer patients who underwent 5 fractions of HDR‐BT. Regions of interest (ROIs) including high‐risk clinical tumor volume (HR‐CTV) and organs at risk (OARs) were manually contoured on daily CT images. All patients were clinically treated with adaptive daily plans (ADP), which involved ROI delineation and dose optimization at each treatment fraction. Single treatment plans (SP) were retrospectively generated by applying the first treatment fraction's dwell times adjusted for decay and dwell positions of the applicator to subsequent treatment fractions. Various existing similarity metrics were calculated for the ROIs to quantify interfractional organ variations. A novel similarity (JRARM) score was established, which combined both volumetric overlap metrics (DSC, JSC, and RVD) and distance metrics (ASD, MSD, and RMSD). Linear regression was performed to determine a relationship between interfractional organ variations of various similarity metrics and D2cc variations from both plans. Wilcoxon signed‐rank tests were used to assess ADP and SP by comparing EQD2D2cc(α/β=3) for OARs. For interfractional organ variations, the sigmoid demonstrated the greatest variations based on the JRARM, DSC, and RMSD metrics. Comparisons between paired ROIs showed differences in metrics at each treatment fraction. RVD, MSD, and RMSD were found to be significantly correlated to D2cc variations for bladder and sigmoid. The comparison between plans found ADP provided lower EQD2 D2cc of OARs than SP. Specifically, the sigmoid demonstrated statistically significant dose variations (p=0.015). Substantial interfractional organ motion occurs during HDR‐BT based on comprehensive measurements and may significantly affect D2cc of OARs. Adaptive daily planning provides improved dose sparing for OARs compared to single planning with the extent of sparing being different among OARs.

PACS number(s): 87.55.D, 87.55.de, 87.55.kh, 87.57.nj

• Adult
• Aged
• Brachytherapy
• Female
• Humans
• Imaging, Three-Dimensional
• Magnetic Resonance Imaging
• Middle Aged
• Prospective Studies
• Radiotherapy Planning, Computer-Assisted
• Treatment Outcome
• Uterine Cervical Neoplasms/pathology
• Uterine Cervical Neoplasms/radiotherapy

• National Natural Science Foundation of China

• Cervical cancer
• Computed tomography
• Interstitial brachytherapy

This study was designed to determine whether volumetric imaging could identify consistent alternative prescription methods to Manchester/point A when prescribing radiation dose in the treatment of cervical cancer using HDR intracavitary brachytherapy (ICBT). One hundred and twenty‐five treatment plans of 25 patients treated for carcinoma of the cervix were reviewed retrospectively. Each patient received 5 fractions of HDR ICBT following initial cisplatin‐based pelvic chemoradiation, and radiation dose was originally prescribed to point A (ICRU‐38). The gross tumor volume (GTV) and high‐risk clinical target volume (HR‐CTV) were contoured in three dimensions on the CT datasets, and inferior–superior, anterior–posterior, and left–right dimensions HR‐CTV were recorded along with multiple anatomic and skeletal dimensions for each patient. The least square–best fit regression lines were plotted between one half of the HR‐CTV width and pelvic cavity dimension at femoral head level and at maximum cavity dimension. The points in both plots lie reasonably close to straight lines and are well defined by straight lines with slopes of 0.15 and 0.17; intercept on y‐axes of ‐0.08 and ‐0.03, point A, at the same level as defined based on applicator coordinates, is defined using this correlation, which is a function of distance between femoral heads/dimensions of maximum pelvic cavity width. Both relations, defined by straight lines, provide an estimated location of point A, which provides adequate coverage to the HR‐CTV compared to the point A defined based on applicator coordinates. The point A defined based on femoral head distance would, therefore, be a reasonable surrogate to use for dose prescription because of subjective variation of cavity width dimension. Simple surrogate anatomic/skeletal landmarks can be useful for prescribing radiation dose when treating cervical cancer using intracavitary brachytherapy in limited‐resource settings. Our ongoing work will continue to refine these models.

PACS number(s): 87.55.D‐, 87.55.ne

Intensity modulated radiation therapy (IMRT) compensation based on 3D high-dose-rate (HDR) intracavitary brachytherapy (ICBT) boost technique (ICBT + IMRT) has been used in our hospital for advanced cervix carcinoma patients. The purpose of this study was to compare the dosimetric results of the four different boost techniques (the conventional 2D HDR intracavitary brachytherapy [CICBT], 3D optimized HDR intracavitary brachytherapy [OICBT], and IMRT-alone with the applicator in situ).

For 30 patients with locally advanced cervical carcinoma, after the completion of external beam radiotherapy (EBRT) for whole pelvic irradiation 45 Gy/25 fractions, five fractions of ICBT + IMRT boost with 6 Gy/fractions for high risk clinical target volume (HRCTV), and 5 Gy/fractions for intermediate risk clinical target volume (IRCTV) were applied. Computed tomography (CT) and magnetic resonance imaging (MRI) scans were acquired using an in situ CT/MRI-compatible applicator. The gross tumor volume (GTV), the high/intermediate-risk clinical target volume (HRCTV/IRCTV), bladder, rectum, and sigmoid were contoured by CT scans.

For ICBT + IMRT plan, values of D₉₀, D₁₀₀ of HRCTV, D₉₀, D₁₀₀, and V₁₀₀ of IRCTV significantly increased (p < 0.05) in comparison to OICBT and CICBT. The D_2cc values for bladder, rectum, and sigmoid were significantly lower than that of CICBT and IMRT alone. In all patients, the mean rectum V₆₀ Gy values generated from ICBT + IMRT and OICBT techniques were very similar but for bladder and sigmoid, the V₆₀ Gy values generated from ICBT + IMRT were higher than that of OICBT. For the ICBT + IMRT plan, the standard deviations (SD) of D₉₀ and D_2cc were found to be lower than other three treatment plans.

The ICBT + IMRT technique not only provides good target coverage but also maintains low doses (D_2cc) to the OAR. ICBT + IMRT is an optional technique to boost parametrial region or tumor of large size and irregular shape when intracavitary/interstitial brachytherapy cannot be used.

• IMRT
• brachytherapy
• cervical cancer
• cervix carcinoma
• dosimetry

• brachytherapy
• cervical cancer
• image guidance
• ultrasound