Irradiance uniformity is an important parameter for a Photodynamic Therapy (PDT) device. The calibration and verification of a LED array light source based on computer vision technology were implemented and carried out. First, the correlation coefficients between the pulse width modulate value and the irradiance were calibrated. Then, the correction of the actual light center and divergence angle were solved by image processing to reduce errors from each LED lens. Finally, uniformity was optimized according to the irradiance formula of the Lambertian source. The lowest coefficients of variation of irradiance were 4.87% in a [Formula: see text] area and 3.55% in a [Formula: see text] area within the depth range of 8–12[Formula: see text]cm when the expected irradiance was 100[Formula: see text]mW/cm2. This finding indicated that the light source can achieve a more uniform illumination and provide a better therapeutic effect for the PDT of port-wine stains.
Photodynamic therapy (PDT) is a minimally invasive method for treating oral leukoplakia. In this paper, we propose a portable PDT device consisting of a flexible circuit board with a liquid flow cooling module on the back. The light source size was 17[Formula: see text][Formula: see text][Formula: see text]mm, and the irradiation area of the light source was up to 100[Formula: see text]mm2. The irradiance range of this device was from 10[Formula: see text]mW/cm2 to 100[Formula: see text]mW/cm2. Simulation and experimental results showed that the irradiance coefficient variation for a treatment area of 81[Formula: see text]mm2 was less than 7%. At an irradiance of 100[Formula: see text]mW/cm2, a device surface temperature of lower than 42∘C can be achieved to satisfy the safety requirements under the conditions that the temperature of cooling liquid is 10∘C and the liquid flow speed is above 12[Formula: see text]mL/min.
Photodynamic therapy (PDT) has shown significant potential for skin disease treatment. As a key element, light is critical to influencing its treatment outcome, and light dosimetry is an issue of much concern for researchers. However, because of three-dimensional irregularity in shape and patient’s movement during the therapy, irradiance hardly keeps uniform on the lesion and flux measurement remains a challenge. In this work, we report the development of a three-dimensional image-guided PDT system, and the method of dynamic irradiance planning and flux monitoring for lesions in different poses. This system comprises a three-dimensional camera for monitoring patients’ movement during therapy, a computer for data analysis and processing, and a homemade LED array for forming uniform irradiance on lesions. Simulations on lesions of the face and arm show that the proposed system significantly increases effective therapy area, enhances irradiance uniformity, is able to visualize flux on the lesion, and reduces risks of burns during PDT. The developed PDT system is promising for optimizing procedures of PDT and providing better treatment outcomes by delivering controllable irradiance and flux on lesions even when a patient is moving.
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