Sensitivity investigation of open-ended coaxial probe in skin cancer detection

Open-ended coaxial probe method is one of the most common modalities in measuring dielectric properties (DPs) of biological tissues. Due to the significant differences between the tumors and normal tissues in DPs, the technique can be used to detect skin cancer in the early stage. Although various studies have been reported, systematic assessment is in urgent need to advance it to clinical applications, for its parameters interactions and detecting limitations remained unclear. In this study, we aim to provide a comprehensive examination of this method, including the minimum detectable tumor size by using a three-layer skin model via simulation and demonstrated that open-ended coaxial probe method can be used for detection of early-stage skin cancer. The smallest detecting size are subject to different subtypes: for BCC, inside the skin is 0.5 mm radius x 0.1 mm height; for SCC, inside the skin is 1.4 mm x 1.3 mm in radius and height; the smallest distinguishing size of BCC is 0.6 mm x 0.7 mm in radius and height; for SCC is 1.0 mm x 1.0 mm in radius and height; for MM is 0.7 mm x 0.4 mm in radius and height. The experiment results showed that sensitivity was affected by tumor dimension, probe size, skin height, and cancer subtype. The probe is more sensitive to cylinder tumor radius than height growing on the surface of the skin while the smallest size probe is the most sensitive among the working probes. We provide a detailed systematic evaluation of the parameters employed in the method for further applications.

Automated summary

The open-ended coaxial probe method is commonly used to measure the dielectric properties of biological tissues and can be used to detect skin cancer in the early stage. This study provides a comprehensive examination of the method and determines the minimum detectable tumor size for different subtypes of skin cancer through simulation.