Snapshot depth sensitive Raman spectroscopy in layered tissues

Liu, Wei; Ong, Yi Hong; Yu, Xiao Jun; Ju, Jian; Perlaki, Clint Michael; Liu, Linbo; Liu, Quan

doi:10.1364/oe.24.028312

Cited by 14 publications

(9 citation statements)

References 36 publications

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“…For applications such as experimental microdosimetry 10 that require a smaller spatial resolution of ~1 µm, a single mode laser and a microscope objective with a larger numerical aperture (NA), along with a point‐by‐point mapping could be used in the setup to achieve this higher resolution. The advantageous feature of the longer depth of focus of ~34 µm for concurrent accumulation of the Raman signal from the polyester laminate, can still be retained in the high (1 µm) spatial resolution setup, by implementing an approach based on, for example, depth‐sensitive Raman spectroscopy 42 …”

Section: Discussionmentioning

confidence: 99%

High spatial resolution dosimetry with uncertainty analysis using Raman micro‐spectroscopy readout of radiochromic films

et al. 2021

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Purpose The purpose of this work is to develop a new approach for high spatial resolution dosimetry based on Raman micro‐spectroscopy scanning of radiochromic film (RCF). The goal is to generate dose calibration curves over an extended dose range from 0 to 50 Gy and with improved sensitivity to low (<2 Gy) doses, in addition to evaluating the uncertainties in dose estimation associated with the calibration curves. Methods Samples of RCF (EBT3) were irradiated at a broad dose range of 0.03–50 Gy using an Elekta Synergy clinical linear accelerator. Raman spectra were acquired with a custom‐built Raman micro‐spectroscopy setup involving a 500 mW, multimode 785 nm laser focused to a lateral spot diameter of 30 µm on the RCF. The depth of focus of 34 µm enabled the concurrent collection of Raman spectra from the RCF active layer and the polyester laminate. The preprocessed Raman spectra were normalized to the intensity of the 1614 cm−1 Raman peak from the polyester laminate that was unaltered by radiation. The mean intensities and the corresponding standard deviation of the active layer Raman peaks at 696, 1445, and 2060 cm−1 were determined for the 150 × 100 µm2 scan area per dose value. This was used to generate three calibration curves that enabled the conversion of the measured Raman intensity to dose values. The experimental, fitting, and total dose uncertainty was determined across the entire dose range for the dosimetry system of Raman micro‐spectroscopy and RCF. Results In contrast to previous work that investigated the Raman response of RCFs using different methods, high resolution in the dose response of the RCF, even down to 0.03 Gy, was obtained in this study. The dynamic range of the calibration curves based on all three Raman peaks in the RCF extended up to 50 Gy with no saturation. At a spatial resolution of 30 × 30 µm2, the total uncertainty in estimating dose in the 0.5–50 Gy dose range was [6–9]% for all three Raman calibration curves. This consisted of the experimental uncertainty of [5–8]%, and the fitting uncertainty of [2.5–4.5]%. The main contribution to the experimental uncertainty was determined to be from the scan area inhomogeneity which can be readily reduced in future experiments. The fitting uncertainty could be reduced by performing Raman measurements on RCF samples at further intermediate dose values in the high and low dose range. Conclusions The high spatial resolution experimental dosimetry technique based on Raman micro‐spectroscopy and RCF presented here, could become potentially useful for applications in microdosimetry to produce meaningful dose estimates in cellular targets, as well as for applications based on small field dosimetry that involve high dose gradients.

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Section: Discussionmentioning

confidence: 99%

High spatial resolution dosimetry with uncertainty analysis using Raman micro‐spectroscopy readout of radiochromic films

et al. 2021

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“…These technical limitations can lead to a simple qualitative sampling with a significant cross-talk among different layers. 20 In the Coherent RS technique, the difference due a vibrational mode frequency generated by two light sources (referred as pump and Stokes beam) results in the acquisition of signal for a specific molecular bond of interest. The coherent addition of the Raman signal from different molecules improves the signal compared to spontaneous Raman, typically by up to ~10 5 .…”

Section: Principle and Techniquesmentioning

confidence: 99%

Raman Spectroscopy in Skeletal Tissue Disorders and Tissue Engineering: Present and Prospective

Fosca

Basoli

Bella

et al. 2022

Tissue Engineering Part B: Reviews

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Musculoskeletal disorders are the most common reason of chronic pain and disability, representing an enormous socioeconomic burden worldwide. In this review, new biomedical application fields for Raman spectroscopy (RS) technique related to skeletal tissues are discussed, showing that it can provide a comprehensive profile of tissue composition in situ , in a rapid, label-free, and nondestructive manner. RS can be used as a tool to study tissue alterations associated to aging, pathologies, and disease treatments. The main advantage with respect to currently applied methods in clinics is its ability to provide specific information on molecular composition, which goes beyond other diagnostic tools. Being compatible with water, RS can be performed without pretreatment on unfixed, hydrated tissue samples, without any labeling and chemical fixation used in histochemical methods. This review first provides the description of the basic principles of RS as a biotechnology tool and is introduced into the field of currently available RS-based techniques, developed to enhance Raman signals. The main spectral processing, statistical tools, fingerprint identification, and available databases are mentioned. The recent literature has been analyzed for such applications of RS as tendon and ligaments, cartilage, bone, and tissue engineered constructs for regenerative medicine. Several cases of proof-of-concept preclinical studies have been described. Finally, advantages, limitations, future perspectives, and challenges for the translation of RS into clinical practice have been also discussed. Impact statement Raman spectroscopy (RS) is a powerful noninvasive tool giving access to molecular vibrations and characteristics of samples in a wavelength window of 600 to 3200 cm −1 , thus giving access to a molecular fingerprint of biological samples in a nondestructive way. RS could not only be used in clinical diagnostics, but also be used for quality control of tissues and tissue-engineered constructs, reducing number of samples, time, and the variety of analysis required in the quality control chain before implantation.

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“…The system was evaluated on the basis of its ability to acquire signals from different depths of tissue phantoms, as well as ex vivo animal and in vivo human (fingernail) tissue. 68 Multimodality skin tissue phantoms have also been employed in studies to demonstrate the effectiveness of combined system approaches, such as in the case of a photo-acoustic Raman probe. 69 The multi-layer agarose phantom employed in the study, contained Intralipid and nigrosin dye to simulate skin tissue with a malignant tumor, represented by a trans -stilbene inclusion.…”

Section: Tissue Phantoms In Biomedical Applicationsmentioning

confidence: 99%

Tissue Phantoms for Biomedical Applications in Raman Spectroscopy: A Review

Vardaki

Kourkoumelis

2020

Biomed Eng Comput Biol

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Raman spectroscopy is a group of analytical techniques, currently applied in several research fields, including clinical diagnostics. Tissue-mimicking optical phantoms have been established as an essential intermediate stage for medical applications with their employment from spectroscopic techniques to be constantly growing. This review outlines the types of tissue phantoms currently employed in different biomedical applications of Raman spectroscopy, focusing on their composition and optical properties. It is therefore an attempt to present an informed range of options for potential use to the researchers.

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Snapshot depth sensitive Raman spectroscopy in layered tissues

Cited by 14 publications

References 36 publications

High spatial resolution dosimetry with uncertainty analysis using Raman micro‐spectroscopy readout of radiochromic films

High spatial resolution dosimetry with uncertainty analysis using Raman micro‐spectroscopy readout of radiochromic films

Raman Spectroscopy in Skeletal Tissue Disorders and Tissue Engineering: Present and Prospective

Tissue Phantoms for Biomedical Applications in Raman Spectroscopy: A Review

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