Superficial vessel‐based near infrared‐assisted patient position recognition and real‐time monitoring system (VIPS) for radiotherapy: A proof‐of‐concept study

Abstract

AbstractBackgroundThe accuracy and precision of patient position in radiotherapy process have dramatic impacts on the tumor local control and therapy‐related side effects, and there exist demands to explore effective positioning solutions, particularly in the era with great progress in imaging recognition and matching.PurposeSuperficial vessel‐based near infrared‐assisted patient position recognition and real‐time monitoring system (VIPS) was proposed to develop an automated, operator‐independent and skin marker‐free imaging system to improve patient setup and intrafractional motion monitoring.MethodsVIPS includes two components, the imaging module and the image alignment software. Using a simulated blood vessel model, multiple NIR sources with various wavelength and bolus (pseudo‐skin) were evaluated in terms of imaging quality to determine the optimal light source and the upper limit of superficial fatty tissue thickness. Then the performance of VIPS with reference to either CBCT or laser setup system was conducted using 3D phantom and clinical cases enrolled into the registered clinical trial. The position displacement from VIPS and laser system was compared, as well as the systematic and random errors of VIPS setup procedure.ResultsThe NIR light source with the combined wavelengths of 760 nm + 940 nm (S760+940 nm) provided the best performance among multiple tested light sources. The bolus (superficial fatty layer) thickness over 5 mm could dramatically compromise the NIR detection of vessels beneath. In the phantom study, the translational positional displacements according to VIPS guidance were within the submillimeter level with reference to CBCT, indicative of high setup accuracy. The clinical trial showed the prototype VIPS could effectively detect and control position displacement of patients in translational and rotational directions within an acceptable range, which was non‐inferior to conventional laser/skin marker system.ConclusionThis proof‐of‐concept study validated the feasibility and reliability of VIPS in guiding radiotherapy setup. However, limitations and technical challenges should be resolved prior to further clinical evaluation, including isocenter alignment, potential NIR image distortion and the impact of the superficial tissues on the recognition of vessels.