Initial clinical experience with a video-based patient positioning system

• Published in: International journal of radiation oncology, biology, physics Vol. 45; no. 1; pp. 205 - 213
• Main Authors: Johnson, L.S., Milliken, B.D., Hadley, S.W., Pelizzari, C.A., Haraf, D.J., Chen, G.T.Y.
• Format: Journal Article
• Language: English
• Published: New York, NY Elsevier Inc 01.08.1999; Elsevier
• Subjects: Algorithms; Biological and medical sciences; Conformal radiotherapy; Cross-Over Studies; Electronic portal imaging; Head and neck; Head and Neck Neoplasms - radiotherapy; Humans; Immobilization; Medical sciences; Patient positioning; Physical Phenomena; Physics; Prospective Studies; Radiotherapy, Conformal - instrumentation; Radiotherapy, Conformal - methods; Radiotherapy. Instrumental treatment. Physiotherapy. Reeducation. Rehabilitation, orthophony, crenotherapy. Diet therapy and various other treatments (general aspects); Research Design; Retrospective Studies; Technology. Biomaterials. Equipments. Material. Instrumentation; Videotape Recording; Immobilization; Head and neck; Conformal radiotherapy; Electronic portal imaging; Patient positioning; Performance evaluation; Human; Indication; Radiotherapy; Portal imaging; Video recording; Optimization; Guidance; Patient position; Treatment planning
• ISSN: 0360-3016; 1879-355X
• DOI: 10.1016/S0360-3016(99)00182-0

Purpose: To report initial clinical experience with an interactive, video-based patient positioning system that is inexpensive, quick, accurate, and easy to use. Methods and Materials: System hardware includes two black-and-white CCD cameras, zoom lenses, and a PC equipped with a frame grabber. Custom software is used to acquire and archive video images, as well as to display real-time subtraction images revealing patient misalignment in multiple views. Two studies are described. In the first study, video is used to document the daily setup histories of 5 head and neck patients. Time-lapse cine loops are generated for each patient and used to diagnose and correct common setup errors. In the second study, 6 twice-daily (BID) head and neck patients are positioned according to the following protocol: at am setups conventional treatment room lasers are used; at pm setups lasers are used initially and then video is used for 1–2 minutes to fine-tune the patient position. Lateral video images and lateral verification films are registered off-line to compare the distribution of setup errors per patient, with and without video assistance. Results: In the first study, video images were used to determine the accuracy of our conventional head and neck setup technique, i.e., alignment of lightcast marks and surface anatomy to treatment room lasers and the light field. For this initial cohort of patients, errors ranged from σ = 5 to 7 mm and were patient-specific. Time-lapse cine loops of the images revealed sources of the error, and as a result, our localization techniques and immobilization device were modified to improve setup accuracy. After the improvements, conventional setup errors were reduced to σ = 3 to 5 mm. In the second study, when a stereo pair of live subtraction images were introduced to perform daily “on-line” setup correction, errors were reduced to σ = 1 to 3 mm. Results depended on patient health and cooperation and the length of time spent fine-tuning the position. Conclusion: An interactive, video-based patient positioning system was shown to reduce setup errors to within 1 to 3 mm in head and neck patients, without a significant increase in overall treatment time or labor-intensive procedures. Unlike retrospective portal image analysis, use of two live-video images provides the therapists with immediate feedback and allows for true 3-D positioning and correction of out-of-plane rotation before radiation is delivered. With significant improvement in head and neck alignment and the elimination of setup errors greater than 3 to 5 mm, margins associated with treatment volumes potentially can be reduced, thereby decreasing normal tissue irradiation.