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Research Article | | Peer-Reviewed

Assessing Surface Guided Radiation Therapy Benefits for Paediatric Cancer Patients: Dosimetric Implications of Intrafractional Motion - An Institutional Review

Sunil Murali Maurya Amol Kakade Prasad Raj Dandekar* Ajinkya Gupte Ananda Rao Jadhav Sachin Rasal Omkar Awate Sanket Patil Manish Bhosale Alok Pathak
Published in Journal of Cancer Treatment and Research (Volume 12, Issue 3)
Received: 30 July 2024     Accepted: 26 August 2024     Published: 20 September 2024
Views:       Downloads:
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Abstract

Introduction/Background: SGRT, a real-time imaging technique, offers continuous monitoring and motion control during treatment. The investigation aims to assess potential dosimetric alterations in target coverage due to intrafractional motion, considering its impact on patient safety and treatment efficiency. Materials and Methods: A retrospective chart review was conducted to assess intrafractional shifts in 18 paediatric cancer patients. Patient setup employed SGRT using AlignRT (Vision RT Ltd., UK), and the PTV was aligned with CBCT. The study introduced induced shifts of 3 mm, 5 mm, and 7 mm during treatment delivery, assessing their impact on portal dosimetry results for both treatment fields. The gamma index criteria (3%, 3 mm) were employed to evaluate dosimetric accuracy. Results: A total of 18 patients were included, and induced shifts were analyzed for their impact on the planned gamma index values. Significant differences were observed between the Planned Gamma Index and induced shifts of 3 mm, 5 mm, and 7 mm for both treatment fields, highlighting the dosimetric implications of intrafractional motion in paediatric cases. Conclusion: Surface Guided Radiation Therapy (SGRT) is concluded to offer a comprehensive array of benefits for paediatric cases. The dosimetric implications of induced shifts underscore the importance of SGRT in ensuring accurate and safe treatment for paediatric cancer patients.

Published in Journal of Cancer Treatment and Research (Volume 12, Issue 3)
DOI 10.11648/j.jctr.20241203.13
Page(s) 56-61
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

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Copyright © The Author(s), 2024. Published by Science Publishing Group
Previous article
Keywords

Surface Guided Radiotherapy, Paediatric Cancer, Dosimetry

1. Introduction/Background
The growing acceptance and validation of Surface Guided Radiation Therapy (SGRT) as a promising imaging technique has supported its recent adoption. SGRT offers real-time feedback for patient positioning, continuous monitoring during treatment sessions, and motion control (such as beam-gating during free-breathing or deep-inspiration breath-hold). Recent advancements in SGRT are particularly notable in specialized radiotherapy areas, such as accelerated partial breast irradiation and particle radiotherapy.
[1]
SGRT systems utilize a combination of a projector and one or multiple camera units to record a real-time 3D surface of patients. The calculation of necessary corrections for the patient's position in translational and rotational directions is based on a reference surface relative to the treatment isocenter position. There are four primary optical surface scanning technologies applied in radiotherapy, namely laser scanners, time-of-flight systems, stereovision systems, and structured light systems
[2-7] 
Optical surface scanners, valued for their elevated spatial and temporal resolution, have demonstrated their significance in enhancing the radiation therapy process, particularly in terms of patient positioning and monitoring.
[8, 9]
SGRT functions as a tool embodying a "four-eyes principle," facilitating constant monitoring of patient positioning. This contributes to the enhancement of patient safety and comfort, while concurrently establishing standardized workflows with increased precision and reproducibility.
[10-14] 
It possesses the capability to enhance clinical outcomes by ensuring precise irradiation of the target while minimizing exposure to surrounding healthy tissue.
[15]
In the context of patient positioning, SGRT emerges as a highly effective tool with the potential to reduce overall treatment duration and minimize imaging dose. This effectiveness stems from various factors: firstly, SGRT furnishes real-time, in-room information regarding the complete surface and positioning of the patient. Secondly, for superficial tumors, where surface deviations can serve as a reliable indicator of tumor motion, SGRT offers more precise positioning compared to traditional 3-point lasers. This improved precision may even lead to a reduction in the frequency of required daily imaging in specific cases. Lastly, for deeper-seated tumors without a direct correlation between surface deviations and tumor movement, daily imaging remains essential. However, SGRT plays a crucial role in expediting the image registration process, thereby mitigating the need for multiple imaging sessions.
[16, 17]
As suggested in AAPM TG 75 for the reduction of imaging dose, SGRT can be recognized as a step in image guidance that can be carried out without the use of ionizing radiation.
[18]
In the context of paediatric treatments, the utilization of SGRT for intra-fraction monitoring is not a widespread practice and there is limited existing literature on this subject.
[19]
Radiation Therapy is generally painless and non-invasive, but it can distress children due to unfamiliarity with the procedure, new faces, separation from parents, and the equipment's sounds. Maintaining stillness during RT is essential for optimal results and safety, often requiring repeated sedation or even general anesthesia for the youngest patients.
[20]
SGRT systems have been integrated into paediatric treatments as a safety measure to facilitate patient positioning and offer an additional layer of error detection. If there are deviations in parts of the patient's surface from the reference position established during the planning CT set-up, or if the calculated isocentric deviations surpass a specified threshold, the beam can be halted. The objective of this study is to investigate the potential dosimetric alterations affecting target coverage as a result of intra-fractional motion in paediatric patients treated with or without general anaesthesia.
2. Materials and Methods
A retrospective chart review was undertaken to assess intrafractional shifts in 18 paediatric cancer patients. Patient setup employed SGRT using AlignRT (Vision RT Ltd., UK) and the planning target volume (PTV) was aligned with CBCT. Following the acquisition of a new SGRT reference image, patients were continuously monitored during treatment. If SGRT detected any intrafractional shift exceeding 3 mm in any direction for more than 2 seconds, the Auto Beam hold feature paused treatment. Subsequently, CBCT scans were repeated, and shift measurements were recorded. These patients were evaluated for intrafractional shifts greater than 3 mm, based on the standard Gamma index criteria (3%, 3mm), to assess potential dosimetric impacts on PTV coverage and the minimum and maximum PTV doses. The gamma index serves as a valuable dosimetric verification tool, assessing the conformity of a Treatment Planning System (TPS) plan with the measured plan and offering a quantitative measure of dose agreement. It is commonly employed in patient-specific Intensity-Modulated Radiation Therapy (IMRT) Quality Assurance (QA). In clinical practice, a widely accepted criterion for the gamma index is 3 mm distance-to-agreement and 3% dose-difference, achieving a passing rate of 90%. The reported detection limit for this evaluation is 4.07 mm distance-to-agreement and 4.07% dose-difference.
[21-23]
TrueBeam STx linear accelerator from Varian Medical Systems (Palo Alto, CA, USA) equipped with high-definition multileaf collimator (HD-MLC), which uses 32 central 2.5 mm-width leaves and 28 outer 5 mm-width leaves on each MLC bank (widths projected to isocenter). AlignRT features an automatic beam-hold capability that activates when patient movements or rotations exceed a threshold of 3 mm in any direction. In such instances, the system automatically interrupts the beam to ensure precise and accurate radiation delivery. All patients were treated with Dual Arc Volumetric Modulated Arc Therapy (VMAT). Patient specific QA for VMAT plans was performed using Varian’s Portal Dosimetry.
In our retrospective analysis using the treatment planning system, we evaluated portal dosimetry results for both Arc 1 and Arc 2 treatment fields. For each arc, we assessed whether the delivered plan met the gamma index criteria (3%, 3 mm). Subsequently, we introduced induced shifts of 3 mm, 5 mm, and 7 mm—derived from SGRT real-time monitoring—applied either laterally or longitudinally during treatment delivery. It's essential to highlight that these shifts were induced artificially, and during actual treatment, the automatic beam hold activates when patient movements exceed 3 mm. After applying these induced shifts, we recalculated the portal dosimetry to determine if the planned gamma index criteria were still satisfied.
3. Results
A total of 18 patients were included in the study. Patient characteristics are described in Table 1. In terms of lateral shift, the median Planned Gamma Index value was 98.15, while 3mm was 94.50, 5mm was 86.80 and 7mm was 82.15 for field 1. Explain gamma index. Normality of the data was tested using the Shapiro-Wilk test. A Wilcoxon signed-rank test showed that there was a significant difference between the Planned Gamma Index and 3 mm (p-value = 0.000). Also, there was a significant difference between the Planned Gamma Index and 5 mm (p-value = 0.000). There was a significant difference between the Planned Gamma Index and 7 mm (p-value = 0.000). The median Planned Gamma Index value was 97.90, while 3mm was 92.80, 5mm was 85.85 and 7mm was 81.30 for field 2. A Wilcoxon signed-rank test showed that there was a significant difference between the Planned Gamma Index and 3 mm (p-value = 0.000). Also, there was a significant difference between the Planned Gamma Index and 5 mm (p-value = 0.000). There was a significant difference between the Planned Gamma Index and 7 mm (p-value = 0.000). [Table 2]
Table 1. Patient Characteristics.

Sr. No

Age

Diagnosis

Site

1

3

Embryonal Rhabdomyosarcoma Forearm with D2 Spine metastasis

Spine + Forearm

2

2

Right Neuroblastoma

Abdomen + Pelvis

3

14

Classic Hodgkins Lymphoma of Mediastinum

Thorax

4

3

Mediastinal Neuroblastoma

Abdomen

5

2

High Grade Non-Infantile Left Neuroblastoma

Abdomen + Pelvis

6

4

Metastatic Neuroblastoma

Abdomen

7

4

Wilms Tumor for Lung Bath

Thorax

8

3

Wilms Tumor for Lung Bath

Thorax

9

2

Retroperitoneal PNET

Abdomen + Pelvis

10

8

Ewings Sarcoma Left Pelvic Bone with Lung Metastasis

Thorax + Pelvis

11

9

Ewing's Sarcoma

Abdomen

12

9

Ewing's Sarcoma

Thorax

13

9

Classical Hodgkin's Lymphoma

Neck

14

6

Pelvic Embryonal Rhabdomyosarcoma

Pelvis

15

2

Metastatic Germ Cell Tumor

Pelvis

16

6

Wilm's tumor

Abdomen + Pelvis

17

4

Neuroblastoma

Abdomen+ Pelvis

18

1

Wilm's tumor

Abdomen
Table 2. Lateral shift.

Variable

Frequency

Mean

SD

p50

IQR

p-value

Arc 1

Planned Gamma Index

18

97.82

1.59

98.15

2.80

3mm

18

91.28

9.25

94.50

5.70

0.000

5 mm

18

79.22

16.95

86.80

13.80

0.000

7 mm

18

73.22

20.61

82.15

18.20

0.000

Arc 2

Planned Gamma Index

18

97.69

1.52

97.90

2.50

3mm

18

90.58

6.99

92.80

3.90

0.000

5 mm

18

78.68

15.08

85.85

21.10

0.000

7 mm

18

72.55

18.61

81.30

26.20

0.000
Table 3. Longitudinal shift.

Variable

Frequency

Mean

SD

p50

IQR

p-value

Arc 1

Planned Gamma Index

18

97.82

1.59

98.15

2.80

3mm

18

90.61

6.59

93.60

8.70

0.000

5 mm

18

81.05

13.01

86.20

13.30

0.000

7 mm

18

75.48

16.51

82.35

14.40

0.000

Arc 2

Planned Gamma Index

18

97.69

1.52

97.90

2.50

3mm

18

91.29

5.79

92.65

7.40

0.000

5 mm

18

81.54

11.44

87.15

8.60

0.000

7 mm

18

75.87

14.95

82.90

9.70

0.000
The median Planned Gamma Index value was 98.15, while 3mm was 93.60, 5mm was 86.20 and 7mm was 82.35 for arc 2. Normality of the data was tested using the Shapiro-Wilk test. A Wilcoxon signed-rank test showed that there was a significant difference between the Planned Gamma Index and 3 mm (p-value = 0.000). Also, there was a significant difference between the Planned Gamma Index and 5 mm (p-value = 0.000). There was a significant difference between the Planned Gamma Index and 7 mm (p-value = 0.000). The median Planned Gamma Index value was 97.90, while 3mm was 92.65, 5mm was 87.15 and 7mm was 82.90 for field 2. A Wilcoxon signed-rank test showed that there was a significant difference between the Planned Gamma Index and 3 mm (p-value = 0.000). Also, there was a significant difference between the Planned Gamma Index and 5 mm (p-value = 0.000). There was a significant difference between the Planned Gamma Index and 7 mm (p-value = 0.000). [Table 3]
4. Discussion
Intra-fraction monitoring of paediatric treatments using SGRT is not extensively adopted, and there is limited literature available on the subject.
[19]
In a documented case where SGRT was employed in conjunction with a linear accelerator operating in the Flattening Filter-Free (FFF) mode, the case involved palliative radiation treatment for an 18-month-old boy experiencing a recurrence of Wilms tumor. The child presented with a substantial anterior mediastinal mass causing a critical obstruction in the airway. Notably, the use of SGRT allowed for the administration of the treatment in a brief duration without the need for anesthesia.
[24]
Arthur J Olch et. al at Children's Hospital, Los Angeles specialized in the exclusive treatment of children, adolescents, and young adults using SGRT at their setup. SGRT provides real-time information on the alignment between the patient's pose at treatment setup and simulation, enabling correction of setup errors before acquiring X-ray-based setup verification images in image-guided radiation therapy (IGRT). This capability reduces the use of ionizing radiation for patient positioning and minimizes setup and imaging time. Specifically, SGRT's ability to detect translational and rotational shifts proves more beneficial for treating long segments of the spine compared to reliance solely on skin marks. SGRT facilitates rapid adjustments in multiple directions, such as correcting lateral position, pitch, and roll simultaneously, which is challenging with external lasers and skin marks alone. Prior to using SGRT, maintaining skin marks on children throughout treatment was problematic. Permanent markers and transparent medical dressings were used, but challenges arose due to factors like sweating, vigorous play, bathing, and fading, leading to mark loss. SGRT eliminates the stress and difficulties associated with skin marks for both patients and staff. Without SGRT, treatment staff relies on closed-circuit television images, with manual interruption required if movement is detected during treatment. SGRT's direct hardware interface with the linear accelerator allows automatic pausing when movement exceeds predefined thresholds, providing confidence in correct treatment positioning. With SGRT monitoring, at their centre children as young as 4 years old could be treated without anaesthesia, as the system automatically detects and adjusts for movement within set tolerances. Real-time intra-fraction monitoring with SGRT enables safe and efficient treatment, even in palliative cases where anaesthesia is not ideal, allowing treatment for young patients with large mediastinal masses who would not have been candidates otherwise.
[25]
5. Conclusion
In conclusion, SGRT offers a comprehensive array of benefits for paediatric cases. Notably, SGRT excels in real-time monitoring and detecting intrafraction motion during paediatric treatment. It enables safe and precise treatment without additional radiation exposure, no tattooing, boasts a high-resolution 3D topographic imaging system, and offers a large field of view with excellent immobilization verification accuracy. Additionally, SGRT seamlessly integrates with IGRT, reducing setup time in pediatric patients, enhancing workflow consistency, and minimizing operator variability.
Abbreviations

SGRT

Surface Guided Radiation Therapy

AAPM TG-75

The American Association of Physicists in Medicine Task Group - 75

PTV

Planning Target Volume

IMRT

Intensity Modulated Radiation Therapy

QA

Quality Assurance

HD-MLC

High-Definition Multileaf Collimator

VMAT

Volumetric Modulated Arc Therapy

FFF

Flattening Filter Free

IGRT

Image Guided Radiation Therapy
Author Contributions
Sunil Murali Maurya: Conceptualization, Data curation, Investigation, Methodology, Supervision, Writing – original draft
Amol Kakade: Data curation, Methodology, Supervision, Writing – review & editing
Prasad Raj Dandekar: Methodology, Supervision, Writing – review & editing
Ajinkya Gupte: Formal Analysis, Investigation, Writing – original draft, Writing – review & editing
Anand Rao Jadhav: Conceptualization, Data curation, Methodology, Resources, Software, Supervision, Validation. Writing – review & editing
Sachin Rasal: Methodology, Software, Validation
Omkar Awate: Methodology, Software, Validation
Sanket Patil: Methodology, Resources, Software, Validation
Manish Bhosale: Methodology, Resources, Software, Validation
Alok Pathak: Methodology, Resources, Software, Validation
Ethics Statement
Our study didn't involve humans or animals and didn't require ethics approval.
Conflicts of Interest
The authors declare no conflicts of interests.
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    Maurya, S. M., Kakade, A., Dandekar, P. R., Gupte, A., Jadhav, A. R., et al. (2024). Assessing Surface Guided Radiation Therapy Benefits for Paediatric Cancer Patients: Dosimetric Implications of Intrafractional Motion - An Institutional Review. Journal of Cancer Treatment and Research, 12(3), 56-61. https://doi.org/10.11648/j.jctr.20241203.13

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    Maurya, S. M.; Kakade, A.; Dandekar, P. R.; Gupte, A.; Jadhav, A. R., et al. Assessing Surface Guided Radiation Therapy Benefits for Paediatric Cancer Patients: Dosimetric Implications of Intrafractional Motion - An Institutional Review. J. Cancer Treat. Res. 2024, 12(3), 56-61. doi: 10.11648/j.jctr.20241203.13

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    AMA Style

    Maurya SM, Kakade A, Dandekar PR, Gupte A, Jadhav AR, et al. Assessing Surface Guided Radiation Therapy Benefits for Paediatric Cancer Patients: Dosimetric Implications of Intrafractional Motion - An Institutional Review. J Cancer Treat Res. 2024;12(3):56-61. doi: 10.11648/j.jctr.20241203.13

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  • @article{10.11648/j.jctr.20241203.13,
  author = {Sunil Murali Maurya and Amol Kakade and Prasad Raj Dandekar and Ajinkya Gupte and Ananda Rao Jadhav and Sachin Rasal and Omkar Awate and Sanket Patil and Manish Bhosale and Alok Pathak},
  title = {Assessing Surface Guided Radiation Therapy Benefits for Paediatric Cancer Patients: Dosimetric Implications of Intrafractional Motion - An Institutional Review
},
  journal = {Journal of Cancer Treatment and Research},
  volume = {12},
  number = {3},
  pages = {56-61},
  doi = {10.11648/j.jctr.20241203.13},
  url = {https://doi.org/10.11648/j.jctr.20241203.13},
  eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jctr.20241203.13},
  abstract = {Introduction/Background: SGRT, a real-time imaging technique, offers continuous monitoring and motion control during treatment. The investigation aims to assess potential dosimetric alterations in target coverage due to intrafractional motion, considering its impact on patient safety and treatment efficiency. Materials and Methods: A retrospective chart review was conducted to assess intrafractional shifts in 18 paediatric cancer patients. Patient setup employed SGRT using AlignRT (Vision RT Ltd., UK), and the PTV was aligned with CBCT. The study introduced induced shifts of 3 mm, 5 mm, and 7 mm during treatment delivery, assessing their impact on portal dosimetry results for both treatment fields. The gamma index criteria (3%, 3 mm) were employed to evaluate dosimetric accuracy. Results: A total of 18 patients were included, and induced shifts were analyzed for their impact on the planned gamma index values. Significant differences were observed between the Planned Gamma Index and induced shifts of 3 mm, 5 mm, and 7 mm for both treatment fields, highlighting the dosimetric implications of intrafractional motion in paediatric cases. Conclusion: Surface Guided Radiation Therapy (SGRT) is concluded to offer a comprehensive array of benefits for paediatric cases. The dosimetric implications of induced shifts underscore the importance of SGRT in ensuring accurate and safe treatment for paediatric cancer patients.
},
 year = {2024}
}

    Copy | Download 

  • TY  - JOUR
T1  - Assessing Surface Guided Radiation Therapy Benefits for Paediatric Cancer Patients: Dosimetric Implications of Intrafractional Motion - An Institutional Review

AU  - Sunil Murali Maurya
AU  - Amol Kakade
AU  - Prasad Raj Dandekar
AU  - Ajinkya Gupte
AU  - Ananda Rao Jadhav
AU  - Sachin Rasal
AU  - Omkar Awate
AU  - Sanket Patil
AU  - Manish Bhosale
AU  - Alok Pathak
Y1  - 2024/09/20
PY  - 2024
N1  - https://doi.org/10.11648/j.jctr.20241203.13
DO  - 10.11648/j.jctr.20241203.13
T2  - Journal of Cancer Treatment and Research
JF  - Journal of Cancer Treatment and Research
JO  - Journal of Cancer Treatment and Research
SP  - 56
EP  - 61
PB  - Science Publishing Group
SN  - 2376-7790
UR  - https://doi.org/10.11648/j.jctr.20241203.13
AB  - Introduction/Background: SGRT, a real-time imaging technique, offers continuous monitoring and motion control during treatment. The investigation aims to assess potential dosimetric alterations in target coverage due to intrafractional motion, considering its impact on patient safety and treatment efficiency. Materials and Methods: A retrospective chart review was conducted to assess intrafractional shifts in 18 paediatric cancer patients. Patient setup employed SGRT using AlignRT (Vision RT Ltd., UK), and the PTV was aligned with CBCT. The study introduced induced shifts of 3 mm, 5 mm, and 7 mm during treatment delivery, assessing their impact on portal dosimetry results for both treatment fields. The gamma index criteria (3%, 3 mm) were employed to evaluate dosimetric accuracy. Results: A total of 18 patients were included, and induced shifts were analyzed for their impact on the planned gamma index values. Significant differences were observed between the Planned Gamma Index and induced shifts of 3 mm, 5 mm, and 7 mm for both treatment fields, highlighting the dosimetric implications of intrafractional motion in paediatric cases. Conclusion: Surface Guided Radiation Therapy (SGRT) is concluded to offer a comprehensive array of benefits for paediatric cases. The dosimetric implications of induced shifts underscore the importance of SGRT in ensuring accurate and safe treatment for paediatric cancer patients.

VL  - 12
IS  - 3
ER  -

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