The goal of this observational study is to find out if Raman Spectroscopy, a type of imaging, can be used to determine the size of skin cancer tumors. The main question it aims to answer is: -Can Raman Spectroscopy help figure out how far a tumor spreads? This study will take measurements using laser light from an experimental, handheld probe by lightly touching the skin.
Radiation therapy is an alternative to surgery for localized tumors with excellent tumor control and cosmetic outcome. Raman Spectroscopy has potential to be a useful non-invasive, non-destructive, real-time, in-vivo tool for differentiation of cancerous vs. non-cancerous tissues. With this knowledge and future studies, this will ultimately guide skin brachytherapy more accurately and avoid unnecessary radiation to cosmetically and functionally important tissues including eyelid, nose, lips or skin folds. The purpose of this study is to determine the feasibility of Raman Spectroscopy to identify microscopic infiltration extent of skin cancer beyond grossly visible tumor, using artificial intelligence methods of supervised and un-supervised machine learning algorithms, including pattern recognition, convolutional neural networks, k-means clustering and principal component analysis.
Study Type
OBSERVATIONAL
Enrollment
20
The probe is approximately the size of a pen or pencil. The handheld probe is connected to the laser source using a cable. The probe is placed in light contact with the skin. The features of the laser light after it bounces off the skin is collected. This measurement can allow us to see tissue characteristics. This is a single session that will take approximately 15 minutes.
This light source will create the laser light that will pass through the cable and through the handheld probe onto the skin.
Stony Brook Hospital
Stony Brook, New York, United States
RECRUITINGFeasibility of Raman Spectroscopy to observe differences in Raman spectra between visible lesion, skin surrounding lesion and contralateral normal skin.
Collect the Raman spectroscopy data starting from the center of visible lesion moving outward and also contralateral normal skin. Observe the different spectra peak wavelengths and intensities, which correspond to different chemical composition of the tissue. The Raman Spectra has units of wavelength Raman shift (1/centimeter) on the horizontal axis and arbitrary units of intensity on the vertical axis.
Time frame: 1 year
Compare the size of clinically defined margin and Raman-defined margin
After generating a sufficient model for predicting cancerous from non-cancerous tissue based on Raman spectra, compare the volume of the clinically defined margin (uniform 1-2 centimeter margin upon clinical discretion) to the Raman-defined margin. The Raman-defined margin will not be used for treatment. The volume is measured in cc (cubic centimeter).
Time frame: 1 year
Compare the dose delivered to surrounding critical structures when using clinically defined margin and Raman-defined margin
Radiation dose to the critical structures (e.g., eyes) from the plan using clinically defined margin (uniform 1-2 centimeter margin upon clinical discretion) will be collected. A second plan (not to be used for treatment) will be generated based on the Raman-defined margin. The dose to critical structures will be compared for both plans. The unit for dose will be centiGray (cGy).
Time frame: 1 year
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