Abstract
Optical interrogation of suspicious skin lesions is standard care in the management of skin cancer worldwide. Morphological and functional markers of malignancy are often combined to improve expert human diagnostic power. We propose the evaluation of the combination of two independent optical biomarkers of skin tumours concurrently. The morphological modality of reflectance confocal microscopy (RCM) is combined with the functional modality of laser Doppler flowmetry, which is capable of quantifying tissue perfusion. To realize the idea, we propose laser feedback interferometry as an implementation of RCM, which is able to detect the Doppler signal in addition to the confocal reflectance signal. Based on the proposed technique, we study numerical models of skin tissue incorporating two optical biomarkers of malignancy: (i) abnormal red blood cell velocities and concentrations and (ii) anomalous optical properties manifested through tissue confocal reflectance, using Monte Carlo simulation. We also conduct a laboratory experiment on a microfluidic channel containing a dynamic turbid medium, to validate the efficacy of the technique. We quantify the performance of the technique by examining a signal to background ratio (SBR) in both the numerical and experimental models, and it is shown that both simulated and experimental SBRs improve consistently using this technique. This work indicates the feasibility of an optical instrument, which may have a role in enhanced imaging of skin malignancies.
Highlights
Melanoma and keratinocyte skin cancers (KSCs) are the most common types of cancers affecting fair-skinned populations [1,2,3] with incidence increasing about 4% per year worldwide [4]
Basal Cell Carcinoma (BCC) constitutes approximately 80% of KSCs, and metastases are rare, basal cell carcinoma (BCC) still imposes a significant burden of disease [3,4]
We examine the proposed technique numerically by applying it to typical simulated models of KSCs, carried out by means of Monte Carlo algorithms adapted for this application, and experimentally by conducting an experiment using an laser feedback interferometry (LFI) system providing in-depth images of a dynamic turbid medium flowing in a microfluidic channel
Summary
Melanoma and keratinocyte skin cancers (KSCs) are the most common types of cancers affecting fair-skinned populations [1,2,3] with incidence increasing about 4% per year worldwide [4]. The cure rate is high in KSCs, such as basal cell carcinoma (BCC) and squamous cell carcinoma (SCC), they can become aggressive [3,4,5]. Responsible for about 20% of KSCs, is associated with moderate risk of metastasis [3,4]. Basal Cell Carcinoma (BCC) constitutes approximately 80% of KSCs, and metastases are rare, BCC still imposes a significant burden of disease [3,4]. To alleviate this burden, early non-invasive detection schemes are required.
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