首个Cherenkov成像系统在社区医院的临床应用

Q1 Nursing Technical Innovations and Patient Support in Radiation Oncology Pub Date : 2022-12-01 DOI:10.1016/j.tipsro.2022.08.011

Erli Chen , Brian W. Pogue , Petr Bruza , Daniel A. Alexander , Nancy L. Andino , Savannah M. Decker , Danielle M. Gaudet , David J. Gladstone , Melinda J. Lake , Steven R. Levene , Jennifer L. Michelson , Hila L. Robinson , Debra N. Stallings , John E. Starkey , Lesley A. Jarvis

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引用次数: 0

摘要

目的记录首个Cherenkov成像系统一年来的临床应用经验，并分享我们开发的利用Cherenkov成像提高实时治疗传递准确性的方法。方法安装Cherenkov成像系统，进行调试和校正，供临床使用。制定了最佳的房间照明条件和成像设置协议，以优化图像质量和患者体验。切伦科夫图像分析治疗设置和光束传送验证。结果在某社区医院成功实施了临床切伦科夫成像系统。一些放射治疗患者的设置异常被发现:1)对侧乳房的出口剂量，2)由于锁骨上野的头部旋转而导致的下巴剂量，3)束传送过程中患者的运动，以及4)部分之间手臂位置的大变化(0.5 cm至5 cm)。该系统用于电子治疗束的深度吸气屏气(DIBH)治疗。临床过程和程序得到改进，以减轻已发现的问题，以确保治疗交付的安全性并提高治疗的准确性。结论Cherenkov成像系统是提高我院治疗传递安全性和准确性的重要临床工具。只需要很少的训练，治疗师就能在治疗过程中根据需要调整或纠正治疗姿势。随着Cherenkov软件的未来发展，Cherenkov成像系统可以为所有3D和临床设置患者提供每日表面引导放疗(SGRT)和实时治疗交付质量控制，而无需像标准kV, MV和CBCT图像验证那样增加额外的辐射图像剂量。Cherenkov成像可以大大提高临床效率和准确性，使实时剂量传递一致性验证和SGRT成为现实。

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Clinical implementation of the first Cherenkov imaging system in a community-based hospital

Purpose

To document experiences with one year of clinical implementation of the first Cherenkov imaging system and share the methods that we developed to utilize Cherenkov imaging to improve treatment delivery accuracy in real-time.

Methods

A Cherenkov imaging system was installed commissioned and calibrated for clinical use. The optimal room lighting conditions and imaging setup protocols were developed to optimize both image quality and patient experience. The Cherenkov images were analyzed for treatment setup and beam delivery verification.

Results

We have successfully implemented a clinical Cherenkov imaging system in a community-based hospital. Several radiation therapy patient setup anomalies were found in 1) exit dose to the contralateral breast, 2) dose to the chin due to head rotation for a supraclavicular field, 3) intrafractional patient motion during beam delivery, and 4) large variability (0.5 cm to 5 cm) in arm position between fractions. The system was used to deliver deep inspiration breath hold (DIBH) treatment delivery of an electron treatment beam. Clinical process and procedures were improved to mitigate the identified issues to ensure treatment delivery safety and to improve treatment accuracy.

Conclusion

The Cherenkov imaging system has proven to be a valuable clinical tool for the improvement of treatment delivery safety and accuracy at our hospital. With only minimal training the therapists were able to adjust or correct treatment positions during treatment delivery as needed. With future Cherenkov software developments Cherenkov imaging systems could provide daily surface guided radiotherapy (SGRT) and real time treatment delivery quality control for all 3D and clinical setup patients without adding additional radiation image dose as in standard kV, MV and CBCT image verifications. Cherenkov imaging can greatly improve clinical efficiency and accuracy, making real time dose delivery consistency verification and SGRT a reality.

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