2016
DOI: 10.1364/oe.24.028312
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Snapshot depth sensitive Raman spectroscopy in layered tissues

Abstract: Depth sensitive Raman spectroscopy has been shown effective in the detection of depth dependent Raman spectra in layered tissues. However, the current techniques for depth sensitive Raman measurements based on fiber-optic probes suffer from poor depth resolution and significant variation in probe-sample contact. In contrast, those lens based techniques either require the change in objective-sample distance or suffer from slow spectral acquisition. We report a snapshot depth-sensitive Raman technique based on a… Show more

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Cited by 15 publications
(9 citation statements)
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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%
“…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%
“…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%
“…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%