Engineering Vascularized Skin-mimetic Phantom for Non-invasive Raman Spectroscopy

Overview

Journal Sens Actuators B Chem

Date 2024 Mar 25

PMID 38524639

Authors

Piyush Raj

Lintong Wu

Saransh Arora

Raj Bhatt

Yi Zuo

Zhiwei Fang

Remco Verdoold

Tanja Koch

Luo Gu

Ishan Barman

Affiliations

Soon will be listed here.

Abstract

Recent advances in Raman spectroscopy have shown great potential for non-invasive analyte sensing, but the lack of a standardized optical phantom for these measurements has hindered further progress. While many research groups have developed optical phantoms that mimic bulk optical absorption and scattering, these materials typically have strong Raman scattering, making it difficult to distinguish metabolite signals. As a result, solid tissue phantoms for spectroscopy have been limited to highly scattering tissues such as bones and calcifications, and metabolite sensing has been primarily performed using liquid tissue phantoms. To address this issue, we have developed a layered skin-mimetic phantom that can support metabolite sensing through Raman spectroscopy. Our approach incorporates millifluidic vasculature that mimics blood vessels to allow for diffusion akin to metabolite diffusion in the skin. Furthermore, our skin phantoms are mechanically mimetic, providing an ideal model for development of minimally invasive optical techniques. By providing a standardized platform for measuring metabolites, our approach has the potential to facilitate critical developments in spectroscopic techniques and improve our understanding of metabolite dynamics .

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