Stereotactic Body Radiotherapy for Locally Advanced Pancreatic Cancer Using Optical Surface Management System - AlignRT as an Optical Body Surface Motion Management in Deep Breath Hold Patients: Results from a Single-Arm Retrospective Study.

Purpose: To assess the efficacy and safety of stereotactic body radiotherapy for patients with unresectable, locally advanced pancreatic cancer using Optical Surface Management System - AlignRT (OSMS-AlignRT) as an optical body surface motion management in deep breath hold. Patients and
Methods: Forty-five patients diagnosed with locally advanced pancreatic cancer were treated with stereotactic body radiotherapy in 3 or 5 fractions, and received varying BED10 (median 79.5 Gy) from April 2017 to December 2020. All patients were treated in deep breath hold with OSMS-AlignRT used as optical body surface motion management. Thirty-three patients received systemic treatment before and/or after stereotactic body radiotherapy, and twelve patients received no systemic treatment. In this retrospective, observational, single-arm study, primary endpoints were overall survival and freedom from local progression (ie, local control). Secondary endpoints were progression-free survival and toxicity. Actuarial survival analysis and univariate analysis were investigated.
Results: Data from forty-five patients were analyzed. Median follow-up was 15 months. One-year freedom from local progression and survival were 95.5% and 71.1%, respectively. Median progression-free survival was 14 months. Median overall survival from diagnosis for all patients was 17 months, and 19 months for patients alive at the time of analysis. No patient had >G2 toxicity.
Conclusion: Stereotactic body radiotherapy for locally advanced pancreatic cancer using OSMS-AlignRT as optical body surface motion management in deep breath hold patients is an effective and safe local treatment option, with no >G2 toxicity, and could be a promising therapeutic option with acceptable toxicity, either as a single treatment or in a multimodal regimen. OSMS-AlignRT provided accurate and reliable body surface motion management during stereotactic body radiotherapy.

Plain Language Summary

Patients diagnosed with unresectable, locally advanced pancreatic cancer represent a particular problem in oncology, due to the challenges in local treatment.

As there are still no published data on OSMS-AlignRT as optical body surface motion management during stereotactic body radiotherapy for locally advanced pancreatic cancer, our study aimed to evaluate the efficacy and safety of this treatment approach.

During stereotactic body radiotherapy, OSMS-AlignRT reliably monitors both steadiness of patients’ deep breath hold and all additional possible movements (eg, drifts).

The tumor and organs at risk are more clearly visible on planning MSCT and on daily cone beam CT scans in deep breath hold, which makes contouring, treatment planning, and daily image guidance easier and more reliable compared with free breathing.

During the treatment in deep breath hold, the organs at risk move away from the tumor, which makes them easier to spare from excess of radiation.

Stereotactic body radiotherapy in deep breath hold requires compliant patient to be adequately conducted.

Stereotactic body radiotherapy as a local treatment for locally advanced pancreatic cancer using OSMS-AlignRT for body surface motion management presented in our study as an effective, safe, and well tolerated option with favorable clinical outcomes: median overall survival was 17 months, 1-year local control and 1-year survival were 95.5% and 71.1%, respectively, with no > G2 toxicity.

Introduction

Pancreatic cancer is generally one of the deadliest cancers, and will potentially represent the second leading cause of cancer death by 2030.1 Median survival for resected patients following adjuvant therapy ranges from 20–28 months.2–5 In general, 50–80% of patients are affected by locoregional relapse, over 70% by systemic relapse; for radically resected patients, 5-year survival rate is around 10–20%, and 30% experience isolated locoregional disease progression.6,7

The subgroup of patients with surgically unresectable, locally advanced pancreatic cancer (LAPC) represents a particular problem in oncology, due to the challenges in local treatment. In recent years, stereotactic body radiotherapy (SBRT) has emerged as an effective and safe form of local treatment for patients with LAPC.8,9

Motion management plays a crucial role in sparing surrounding organs at risk (OARs) during SBRT. The duodenum, the stomach, and the small bowel are among the most highly radiosensitive OARs in the abdomen and it is critical to spare them from any excess radiation.10–12 Mitigation of respiratory motions is typically achieved with commercially available abdominal compressing devices. Respiratory gating uses correlation of the tumor’s position in selected phase of breathing cycle with external surrogate, and this correlation accounts only for respiratory motion.13 Generation of the 4D-CT internal tumor volume (ITV) is another technique to compensate for tumor movements, but ITV does not accurately represent the daily tumor motions, as significant discrepancies of the abdominal target’s positions are frequently observed between planning multi-sliced computed tomography (MSCT) and daily cone-beam computed tomography (CBCT) for the same patients.14 Deep breath hold (DBH) during SBRT is also a possible motion management technique, but requires adequate monitoring to be sufficiently accurate.15 Intrafractional fiducial-implanted tumor tracking technique is most often used in robotic arm based linacs.16,17 However, not all patients are candidates for fiducial implantation, due topossible unfavorable anatomy or medical conditions that prevent them from safe implantation, and general contraindications for contrast-enhanced CT (MSCT). Magnetic resonance (MR) - linacs use on-board cine-MR imaging devices for intrafractional motion management. The technique is non-invasive and very accurate, but some gating uncertainties still remain due to the time delay of the MRI.

The primary goal of this study was to evaluate the efficacy and safety of SBRT for LAPC using OSMS-AlignRT as optical body surface motion management in deep breath hold patients. Furthermore, we aimed to report our clinical outcomes (overall survival, local and distal disease control, and toxicity) with this treatment approach, to compare them with previously reported data (achieved with different motion management techniques and fractionation regimens), and to present our experiences and workflow with this motion management technique. After thoroughly conducting a search of Pub Med Central database, we found no published data on the use of OSMS-AlignRT during SBRT for LAPC. Surface guidance is most commonly used during radiotherapy for thoracic and abdominal targets – breast,18,19 lung, liver and adrenal tumors.20

Patients and Methods

Patients

Medical data of 45 consecutive patients diagnosed with LAPC were analyzed in this retrospective, single-arm, single-institution, observational study, approved by the Institutional ethics committee. All patients were treated from April 2017 to December 2020, and were available for regular follow-up. Patients’ characteristics are shown in Table 1.

Table 1

Patients’ Characteristics

Number of patients	45
Mean age in years	67 (range 45–87)
Sex (M: F)	20: 25
Primary site
Head	33 (73%)
Body/tail	12 (27%)
Systemic treatment
Gemcitabine-based	16 (36%)
FOLFIRINOX	17 (38%)
No systemic treatment	12 (27%)
Median CTV (cm3)	45 (range 7.2–136.2)
Median PTV (cm3)	103.8 (range 32.8–217.6)

Abbreviations: CTV, clinical target volume; FOLFIRINOX, fluorouracil/leucovorin/irinotecan/oxaliplatin; PTV, planning target volume.

Prior to treatment, all patients were considered and approved for SBRT by our institution’s multidisciplinary tumor board. Inclusion criteria were: unresectable, histologically proven pancreatic adenocarcinoma, age ≥18, ECOG 0–2, radiologically negative regional lymph nodes and no signs of distant metastasis, gastric or duodenal obstruction, and no previous abdominal radiotherapy. Unresectable pancreatic cancer was defined according to the arterial and venous criteria for resectability status.2,21 All procedures performed were in accordance with the national medical ethical standards and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. Standard written informed treatment consent was signed by, and obtained from every patient.

As our Institution does not provide systemic therapy, it was indicated and provided by each patient’s referring medical oncologists’ team, and administered appropriately at least seven days before and after SBRT, due to the possible toxicities.

Optical Surface Management System – AlignRT

OSMS-AlignRT (Vision RT, London, UK) is an optical monitoring system of body surface movements during radiotherapy, consisting of three camera units.22 Each unit uses a projector of a pseudo-random speckle pattern of red light that illuminates the patient’s body surface, and image sensors to three dimensionally reconstruct the patient’s body surface contour in thousands of points (Figure 1A). The system tracks any movements of the body contour in real time with a frequency of 5–10 Hz and submillimeter accuracy, is non-invasive, and does not use ionizing radiation for tracking. It can be used both for patient positioning and motion tracking. Furthermore, combined with CBCT, it allows for more reliable image guidance. According to the manufacturer’s specifications, the lag time of the system is < 100 milliseconds.

Figure 1

OSMS-AlignRT – pseudo-random speckle pattern of red light on patient body surface (A). ROI (green) on a body contour (magenta) (B).

The default body contour (DBC) is defined as a patient’s body contour on planning MSCT. Region of interest (ROI) is a part of the body surface contour, best suited for tracking, defined by user, typically the region of upper abdomen above the PTV (Figure 1B). During the treatment, OSMS-AlignRT monitors the alignment of a patient’s body contour ROI on the treatment table with an ROI of DBC. Gating windows allow tolerable mismatch of ROIs in any direction within specified values. While ROIs are aligned within the gating windows, OSMS-AlignRT is “in green” and the beam is “on”. When the ROIs’ mismatch exceeds the gating windows, OSMS-AlignRT goes “in red” and automatically shuts off the beam.

Stereotactic Body Radiotherapy

Patients were in supine position either on a wing-board or vacuum pillow, with their arms above the head. No further immobilization was used. Treatments were delivered by a Varian EDGE linear accelerator (Varian Medical Systems, Palo Alto, California, USA). DBH was in inhale phase for all patients.

A contrast-free MSCT scan in DBH with a slice thickness of 1 mm was acquired for all patients for the purpose of treatment planning. Routinely, contrast-free MRIs (T1 and T2) of the abdomen in DBH were also acquired for all patients, and subsequently coregistered (with deformable registration methods) with planning MSCT. The clinical target volume (CTV) was defined as the gross tumor volume (GTV) with no additional margins. CTV was delineated on the T1 or T2 images of the MRI, and further corrected on MSCT scan, as needed. OARs were contoured on planning MSCT scans. If the lesion or the OARs were not clearly visible on contrast-free imaging, additional contrast-enhanced MSCT (with late arterial phase) and/or contrast-enhanced MR of the abdomen were acquired and subsequently coregistered (with deformable registration methods) with planning MSCT.

SBRT plans were optimized and delivered using Volumetric Arc Therapy. Beam energy of 6 and/or 10 MV, with Flattening Filter Free photon beams was used for all patients, to achieve best dose distributions, while having plans with low modulation and high QA passing rates. Biological effective dose was calculated using alpha/beta = 10 Gy for tumor (BED10). Three fractionation regimens were used (corresponding BED10 and number of patients treated are listed respectively):

5 x 8 Gy (BED10 = 72 Gy), 22 patients (48.9%)

3 x 12 Gy (BED10 = 79.2 Gy), 12 patients (26.7%)

5 x 9 Gy (BED10 = 85.5 Gy), 11 patients (24.4%)

Median BED10 was 79.2 Gy.

The optimal fractionation regimen for each patient was chosen to achieve the goal of OARs sparing (Table 2).23,24 The primary OARs were: the stomach, the duodenum, and the small intestine. The dose-volume constraints for them were:

Table 2

Summary of Planning Dose–Volume Objectives

OARs	Three Fractions	Five Fractions
Stomach, Duodenum, and Small Intestine	V (31, 4 Gy) < 1 cm3	V (42 Gy) < 1 cm3
	V (23, 3Gy) < 5 cm3	V (25, 4 Gy) < 5 cm3
	V (16, 1Gy) < 10 cm3	V (17, 6 Gy) < 10 cm3
Liver	V (17 Gy) < 700 cm3	V (21 Gy) < 700 cm3
Great vessels	Dmax < 45 Gy	Dmax < 53 Gy
Spinal cord	Dmax < 22 Gy	Dmax < 30 Gy
Kidneys	V (14, 4 Gy) < 200 cm3	V (17, 5 Gy) < 200 cm3

Abbreviations: Dmax, maximal dose; Gy, Gray; OARs, organs at risk; V (dose), volume receiving dose (in Gy).

3-fraction: V (1 cm3) < 31.4 Gy, V (5 cm3) < 23.2 Gy, V (10 cm3) < 16.7 Gy.

5-fraction: V (1 cm3) < 36 Gy, V (5 cm3) < 25.5 Gy and V (10 cm3) < 18.5 Gy.

We followed Radiation Therapy Oncology Group (RTOG) recommendations for the dose–volume constraints for other OARs.

The dose was applied heterogeneously, and there was no planning constraint on the maximum dose as long as it was located inside the planning target volume (PTV). Average maximum of the prescription dose was 126% (± 5.2%). Average Conformity Index was 1.10 ± 0.05. A required target coverage V (98–99.5%) of the prescribed dose for the PTV was 80% (Figure 2). Target coverage was prioritized over OAR sparing as long as previously mentioned OAR constraints were met. No replans were done.

Figure 2

Typical GTV (A) and dose distribution (80–130% of prescribed isodose) in colorwash (B).

The therapeutic position of the tumor was defined as the anatomical position of the tumor on the planning MSCT in DBH. OSMS-AlignRT was used as gating management. Gating windows were set to 3 mm, according to manufacturer’s specifications for abdominal lesions.

During daily treatments, the workflow was as follows:

Prior to treatment, OSMS-AlignRT was loaded with DBC from planning system for the patient.

Initial positioning of the patient in free breathing on the treatment table was performed using laser guidance and CBCT.

The patient was instructed to take and hold deep breath the same way as during the MSCT planning, and alignment of the ROI of body contour on a treatment table with the ROI of the DBC was confirmed with OSMS-AlignRT (“in green”).

The CBCT in DBH with OSMS-AlignRT “in green” was then repeated to further check the alignment of the GTV on planning MSCT with the GTV on CBCT, and patient’s position was corrected as needed.

Patient was instructed to breathe freely for a while.

Patient was then instructed to take and hold deep breath again, the treatment started when OSMS-AlignRT came “in green” and as long as OSMS-AlignRT remained “in green”, the treatment beam was “on”.

When the patient could not hold the breath anymore, or body contour moved out of gating window for any other reason (OSMS-AlignRT “in red”), the beam was automatically shut off.

Steps 5.– 7 were then repeated to the end of the fraction.

Given the possible additional movements of the tumor in the body, the PTV to CTV margin was 5 mm for all patients which was, in our opinion, sufficient to compensate for residual/intrinsic tumor motions, with no need for further compensation for patient’s positioning uncertainties before or during the fraction, for several reasons:

CBCT with OSMS-AlignRT “in green” was performed before the start of each fraction, to check the patient’s positioning and alignment of the GTV on planning MSCT with the GTV on CBCT.

The same routine was repeated regularly after 50% of planned dose delivery to re-check the patient’s position and to correct any eventual mismatch.

If OSMS-AlignRT detected significant and permanent deviation of ROIs at any time during the fraction, the same routine was repeated.

According to the system’s reports, the “beam on” was on average 10–15% of total treatment time, calculated from the first beam engage to the end of the fraction. Average time per fraction on a treatment couch was 30 minutes for patients treated in 5 fractions, and 42 minutes for patients treated in 3 fractions.

Patients’ Preparations for the Treatment in DBH

Prior to treatment planning, all patients were “tested” on OSMS-AlignRT, to determine if they could adequately (repeatedly and consistently for at least 20 seconds) hold their breath. If needed, further breathing coaching was performed, and the test was repeated. Also, all patients were provided with written recommendations on diet, including instructions to stop taking food and drinks 2–3 hours before the treatment, and to take proton-inhibitors and antiflatulent drugs (eg, simethicone) to reduce flatulence and weight loss during the treatment, all in order to minimize daily anatomical variations. For the same reasons, the time from the planning to the start of the treatment was kept as short as possible (on average 7–10 days).

Response Evaluation and Follow-Up

Follow-up was regularly scheduled every three months after SBRT by the treating radiation oncologist with clinical examination and a contrast-enhanced MSCT scan. Local and distant control were defined according to RECIST criteria.25 Acute and late toxicity was scored according to the National Cancer Institute (NCI) Common Terminology Criteria for Adverse Events (CTCAE) v4.03.

Statistical Analysis

The conformity index (CI) was defined as the ratio of the volume of the 80% isodose line to the volume of the PTV. Endpoints were: overall survival (OS), freedom from local progression or local control (FFLP/LC), progression-free survival (PFS), and toxicity rate. One-year survival was calculated as the ratio of patients that survived at least one year (12 months) and all patients. FFLP was calculated from the time of diagnosis to the first finding of local progression. Local relapse was defined as radiological progression of the primary lesion within the PTV. PFS was calculated from the time of diagnosis to the first assessment of disease progression. Patients that did not develop disease progression were censored at the date of the last scan. OS was calculated from the time of diagnosis to death. FFLP, PFS, and OS rates were calculated by Kaplan-Meier method; the Log rank test statistic was used for univariate analysis. A significant difference was considered when P ≤ 0.05.

Results

Median follow-up was 15 months (range 5–56 months). Median OS was 17 months (range 6–56 months). Fifteen (33.3%) patients were alive at the time of analysis. Median follow-up in this subgroup was 18 months (range 13–56 months) and median OS was 19 months (range 13–56 months). Median time from diagnosis to SBRT was 3 months (range 1–8 months). Table 3 summarizes the results for FFLP, PFS and OS from diagnosis, and OS from the treatment (OSt). In Figure 3A an actuarial curve for OS is shown.

Table 3

Summary of the Actuarial Analysis for FFLP, PFS, OS and OSt

Endpoints	Median	One-Year
FFLP	14 months*	95.5%
PFS	14 months, (95% Cl: 11.8 to 15.2)	68.9%
OS	17 months, (95% CI: 14.8 to 21.3)	71.1%
OSt	14 months, (95% CI: 11.5 to 18)	57.8%

Note: *Five cases of local failure at 7, 12, 14, 20 and 25 months.

Abbreviations: CI, confidence interval; FFLP, freedom from local progression; PFS, progression-free survival; OS, overall survival; OSt, overall survival from treatment.

Figure 3

Actuarial curve of overall survival for all patients (A). Actuarial curve of survival for patients receiving/not receiving chemotherapy (Log rank, P = 0.0235) (B). Actuarial curve of survival for patients with/without systemic progression (Log rank, P = 0.0241) (C). Actuarial curve of survival for patients with tumor volume < 45 ccm/tumor volume > 45 ccm (Log rank, P = 0.1577) (D).

Thirty-three patients (73.3%) received systemic treatment. Twelve patients (26.7%) received no systemic treatment (Table 1). Nineteen patients (57.5%) received chemotherapy before (2–4 cycles) and after SBRT, and 14 patients (42.5%) received chemotherapy only after SBRT. On actuarial analysis, patients that received chemotherapy had better OS (P = 0.024) (Figure 3B). No patient was surgically treated or re-irradiated during follow-up.

Five patients (11%) had radiological local disease progression (at 7, 12, 14, 20 and 25 months, all accompanied by distal progression). Nine patients (20%) had radiological local regression. The remaining 31 patients (69%) had radiologically stable local disease. Median PFS was 14 months (range 5–25 months). Thirty-five patients (77.8%) had systemic progression of the disease, and ten (22.2%) had stable state. On actuarial analysis, patients that had no systemic progression had better OS (P = 0.024) (Figure 3C).

Median GTV was 45 cm3 (range 7.2–136.2 cm3) and median PTV was 103.8 cm3 (range 32.8–217.6 cm3). After thorough statistical analysis, we found no impact of tumor volume on survival (P = 0.1577) (Figure 3D).

Twenty-nine (64.4%) patients had grade 1 or 2 acute toxicities: nausea, fatigue, and abdominal spasm or pain, that were successfully treated with symptomatic treatment. Five patients (11.1%) had G2 late toxicity (abdominal spasm or pain, and/or gastroesophageal reflux), developed 6 months or more after SBRT, that were successfully treated with symptomatic treatment. No acute or late toxicity G3 (bleeding from gastrointestinal track or perforations) was reported.

Discussion

In the last years SBRT in the treatment of LAPC has been investigated with a goal of confirming the assumed impact of LC on OS, impact of dose escalation on LC, and the importance of adequate motion management.

Zhu et al in study from 2019 concluded that BED10 ≥ 60 Gy might be required to achieve better LC in pancreatic cancer.26 Comito et al used SBRT for LAPC with an abdominal compression for motion mitigation, with BED10 = 78.8 Gy. One-year FFLP and OS were 87% and 85% respectively, and median OS was 19 months. Significant positive correlation between FFLP as well as OS was shown.27 Seo used respiratory gating for motion management during SBRT for a total of 79 patients with LAPC, with median BED10 = 47.6 Gy. Median OS was 16 months, and the 1-year OS, PFS and FFLP rates were 85%, 57%, and 96%, respectively. Isolated local progression occurred in 7 patients (11%), distant metastasis in 51 patients (80%), and both in 6 patients (9%), respectively.28

In numerous other studies published in the last years, 1-year FFLPs were reported ranging from 40–96%, median OSs were ranging from 10–20 months, and applied BED10s were ranging from 37.5–102.6 Gy.11,27–37 Clinical outcomes presented in our study are rather comparable with those from previously cited studies, with 1-year FFLP of 95.5%, 1-year OS of 71.1%, median OS of 17 months, and BED10 of 79.2 Gy. The number of enrolled patients and median follow-up time in our study are also comparable with those from previously cited studies. Similar clinical outcomes were reported recently, in 2020, by Chuong et al from their experience with 5-fraction adaptive MR-guided SBRT for LAPC,38 and in pooled analysis from Mahadevan et al of tumor control probability models to evaluate the comparative effectiveness of the various SBRT treatment regimens used in the treatment of patients with LAPC (HyTEC review).39

According to our experience, OSMS-AlignRT provided accurate and reliable body surface motion tracking during all treatments. Lens et al in their study, monitored solely steadiness of breath hold, using SpiroDynr’X system, which registered airflow through a mouthpiece with a spirometer, and reported significant residual tumor movements.15 We used OSMS-AlignRT along with CBCT for initial patient positioning, and to monitor both steadiness of breath hold and any possible additional patient’s movements (eg, drifting, coughing), that could contribute to overall tumor’s motions during the treatment. Additional intrinsic/residual tumor motions (eg, caused by peristalsis, heartbeat) were principally compensated for with PTV to CTV margins.

It is our impression that the accurate and reliable body surface motion management of patients’ DBH and additional movements during the treatments, provided by OSMS-AlignRT, allowed us to safely apply ablative doses to the tumor, while keeping the doses to the OARs within the recommended dose-volume constraints. This approach could have contributed to favorable clinical outcomes and acceptable toxicity presented in our study. In our experience, planning and conducting SBRT for LAPC in DBH had the following advantages: 1) clear visibility of the tumor and OARs on planning MSCT and on daily CBCTs, which made contouring, treatment planning and daily image guidance easier and more reliable, 2) moving the OARs away from the GTV, which made them easier to spare from the excess radiation, and 3) no need for abdominal compression or rigid immobilization of the patients. The following disadvantages were observed, as well: 1) need for patient’s strict compliance during all steps of the treatment, 2) favoring the patients with a better performance status, and 3) prolongation of the treatment time on a table.

The majority of treated patients (77.8%) had systemic (regional and/or distal) progression of the disease during follow-up, and had statistically significant inferior OS. Furthermore, statistically significantly better OS was observed for patients that received chemotherapy before and/or after SBRT. Local control in our study was satisfactory, as only 5 patients (11.1%) had local disease progression during follow-up. We performed thorough statistical analysis to determine possible “cut off” value of tumor volume that would yield statistically significant impact on survival. As no such value was found, we presented the actuarial curve of survival for patients with tumor volume larger and smaller than median tumor volume. This finding is contrary to previously published data. Toxicity profile of SBRT was very acceptable, with 64.4% of patients experiencing mild to moderately acute toxicities.

Conclusion

Our results indicate that SBRT for LAPC using OSMS-AlignRT as optical body surface motion management provides favorable clinical outcomes and allows for safe dose delivery with acceptably low toxicities, but requires compliant patients. This treatment could be considered as an effective, safe, and well tolerated local therapeutic option for LAPC, as a single treatment, and probably even more effective as part of multimodal treatment.

Future studies and trials are needed to evaluate the role of OSMS-AlignRT for optical body surface motion tracking during SBRT for primary and secondary malignancies of other localizations.