On the Development of a Light Dosimetry Planning Tool for Photodynamic Therapy in Arbitrary Shaped Cavities: Initial Results

Previous dosimetric studies during photodynamic therapy (PDT) of superficial lesions within a cavity such as the nasopharynx, demonstrated significant intra‐ and interpatient variations in fluence rate build‐up as a result of tissue surface re‐emitted and reflected photons, which depends on the optical properties. This scattering effect affects the response to PDT. Recently, a meta‐tetra(hydroxyphenyl)chlorin‐mediated PDT study of malignancies in the paranasal sinuses after salvage surgery was initiated. These geometries are complex in shape, with spatially varying optical properties. Therefore, preplanning and in vivo dosimetry is required to ensure an effective fluence delivered to the tumor. For this purpose, two 3D light distribution models were developed: first, a simple empirical model that directly calculates the fluence rate at the cavity surface using a simple linear function that includes the scatter contribution as function of the light source to surface distance. And second, an analytical model based on Lambert’s cosine law assuming a global diffuse reflectance constant. The models were evaluated by means of three 3D printed optical phantoms and one porcine tissue phantom. Predictive fluence rate distributions of both models are within ± 20% accurate and have the potential to determine the optimal source location and light source output power settings. Two independent models were developed that generate the fluence rate distribution at the surface of arbitrary complex geometry for a given light source location. Both models were validated by means of optical phantom experiments. The presented models have the potential to calculate the most optimal source location for intracavity m‐THPC–mediated photodynamic therapy of residual tumor in sinonasal defects after surgery.