Geometry-Dependent Spectroscopic Contrast in Deep Tissues

Xin Ge; Hongying Tang; Xianghong Wang; Xinyu Liu; Si Chen; Nanshuo Wang; Guangming Ni; Xiaojun Yu; Shufen Chen; Haitao Liang; En Bo; Lulu Wang; Cilwyn Shalitha Braganza; Chenjie Xu; Steven M. Rowe; Guillermo J. Tearney; Linbo Liu

doi:10.1016/j.isci.2019.08.046

Geometry-Dependent Spectroscopic Contrast in Deep Tissues

Xin Ge, Hongying Tang, Xianghong Wang, Xinyu Liu, Si Chen, Nanshuo Wang, Guangming Ni, Xiaojun Yu, Shufen Chen, Haitao Liang, En Bo, Lulu Wang, Cilwyn Shalitha Braganza, Chenjie Xu, Steven M. Rowe, Guillermo J. Tearney, Linbo Liu

School of Automation

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

Nano-structures of biological systems can produce diverse spectroscopic effects through interactions with broadband light. Although structured coloration at the surface has been extensively studied, natural spectroscopic contrasts in deep tissues are poorly understood, which may carry valuable information for evaluating the anatomy and function of biological systems. Here we investigated the spectroscopic characteristics of an important geometry in deep tissues at the nanometer scale: packed nano-cylinders, in the near-infrared window, numerically predicted and experimentally proved that transversely oriented and regularly arranged nano-cylinders could selectively backscatter light of the long wavelengths. Notably, we found that the spectroscopic contrast of nanoscale fibrous structures was sensitive to the pressure load, possibly owing to the changes in the orientation, the degree of alignment, and the spacing. To explore the underlying physical basis, we further developed an analytical model based on the radial distribution function in terms of their radius, refractive index, and spatial distribution.

Original language	English
Pages (from-to)	965-975
Number of pages	11
Journal	iScience
Volume	19
DOIs	https://doi.org/10.1016/j.isci.2019.08.046
State	Published - 27 Sep 2019

Keywords

Infrared Optics
Medical Imaging
Optical Imaging
Spectroscopy

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10.1016/j.isci.2019.08.046

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title = "Geometry-Dependent Spectroscopic Contrast in Deep Tissues",

abstract = "Nano-structures of biological systems can produce diverse spectroscopic effects through interactions with broadband light. Although structured coloration at the surface has been extensively studied, natural spectroscopic contrasts in deep tissues are poorly understood, which may carry valuable information for evaluating the anatomy and function of biological systems. Here we investigated the spectroscopic characteristics of an important geometry in deep tissues at the nanometer scale: packed nano-cylinders, in the near-infrared window, numerically predicted and experimentally proved that transversely oriented and regularly arranged nano-cylinders could selectively backscatter light of the long wavelengths. Notably, we found that the spectroscopic contrast of nanoscale fibrous structures was sensitive to the pressure load, possibly owing to the changes in the orientation, the degree of alignment, and the spacing. To explore the underlying physical basis, we further developed an analytical model based on the radial distribution function in terms of their radius, refractive index, and spatial distribution.",

keywords = "Infrared Optics, Medical Imaging, Optical Imaging, Spectroscopy",

author = "Xin Ge and Hongying Tang and Xianghong Wang and Xinyu Liu and Si Chen and Nanshuo Wang and Guangming Ni and Xiaojun Yu and Shufen Chen and Haitao Liang and En Bo and Lulu Wang and Braganza, {Cilwyn Shalitha} and Chenjie Xu and Rowe, {Steven M.} and Tearney, {Guillermo J.} and Linbo Liu",

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year = "2019",

month = sep,

day = "27",

doi = "10.1016/j.isci.2019.08.046",

language = "英语",

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TY - JOUR

T1 - Geometry-Dependent Spectroscopic Contrast in Deep Tissues

AU - Ge, Xin

AU - Tang, Hongying

AU - Wang, Xianghong

AU - Liu, Xinyu

AU - Chen, Si

AU - Wang, Nanshuo

AU - Ni, Guangming

AU - Yu, Xiaojun

AU - Chen, Shufen

AU - Liang, Haitao

AU - Bo, En

AU - Wang, Lulu

AU - Braganza, Cilwyn Shalitha

AU - Xu, Chenjie

AU - Rowe, Steven M.

AU - Tearney, Guillermo J.

AU - Liu, Linbo

PY - 2019/9/27

Y1 - 2019/9/27

N2 - Nano-structures of biological systems can produce diverse spectroscopic effects through interactions with broadband light. Although structured coloration at the surface has been extensively studied, natural spectroscopic contrasts in deep tissues are poorly understood, which may carry valuable information for evaluating the anatomy and function of biological systems. Here we investigated the spectroscopic characteristics of an important geometry in deep tissues at the nanometer scale: packed nano-cylinders, in the near-infrared window, numerically predicted and experimentally proved that transversely oriented and regularly arranged nano-cylinders could selectively backscatter light of the long wavelengths. Notably, we found that the spectroscopic contrast of nanoscale fibrous structures was sensitive to the pressure load, possibly owing to the changes in the orientation, the degree of alignment, and the spacing. To explore the underlying physical basis, we further developed an analytical model based on the radial distribution function in terms of their radius, refractive index, and spatial distribution.

AB - Nano-structures of biological systems can produce diverse spectroscopic effects through interactions with broadband light. Although structured coloration at the surface has been extensively studied, natural spectroscopic contrasts in deep tissues are poorly understood, which may carry valuable information for evaluating the anatomy and function of biological systems. Here we investigated the spectroscopic characteristics of an important geometry in deep tissues at the nanometer scale: packed nano-cylinders, in the near-infrared window, numerically predicted and experimentally proved that transversely oriented and regularly arranged nano-cylinders could selectively backscatter light of the long wavelengths. Notably, we found that the spectroscopic contrast of nanoscale fibrous structures was sensitive to the pressure load, possibly owing to the changes in the orientation, the degree of alignment, and the spacing. To explore the underlying physical basis, we further developed an analytical model based on the radial distribution function in terms of their radius, refractive index, and spatial distribution.

KW - Infrared Optics

KW - Medical Imaging

KW - Optical Imaging

KW - Spectroscopy

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U2 - 10.1016/j.isci.2019.08.046

DO - 10.1016/j.isci.2019.08.046

M3 - 文章

AN - SCOPUS:85072039126

SN - 2589-0042

VL - 19

SP - 965

EP - 975

JO - iScience

JF - iScience

ER -

Geometry-Dependent Spectroscopic Contrast in Deep Tissues

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Keywords

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