Non‐Invasive Detection, Precise Localization, and Perioperative Navigation of In Vivo Deep Lesions Using Transmission Raman Spectroscopy

Wu, Zhenyu; Deng, Banglin; Zhou, Yutong; Xie, Haibo; Liu, Lin; Ye, Jian

doi:10.1002/advs.202301721

Cited by 9 publications

(3 citation statements)

References 68 publications

(56 reference statements)

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“…Other GERT geometries are possible to synthesis and have different optical responses [17]. For example, structures such as petal-like Au core@Ag@SERS NMs have shown great results in biomedical applications [55,56]. Secondly, we used DDA to describe the potential SERS enhancement experienced by Raman molecules when placed inside NM, as compared to the SERS enhancement when Raman molecules are placed on the outer side of the surface of the NMs.…”

Section: Discussionmentioning

confidence: 99%

An Investigation on the Use of Au@SiO2@Au Nanomatryoshkas as Gap-Enhanced Raman Tags

Eldridge,

Gomrok,

Barr

et al. 2023

Nanomaterials

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Gap-enhanced Raman tags are a new type of optical probe that have wide applications in sensing and detection. A gap-enhanced Raman tag is prepared by embedding Raman molecules inside a gap between two plasmonic metals such as an Au core and Au shell. Even though placing Raman molecules beneath an Au shell seems counter-intuitive, it has been shown that such systems produce a stronger surface-enhanced Raman scattering response due to the strong electric field inside the gap. While the theoretical support of the stronger electric field inside the gap was provided in the literature, a comprehensive understanding of how the electric field inside the gap compares with that of the outer surface of the particle was not readily available. We investigated Au@SiO2@Au nanoparticles with diameters ranging from 35 nm to 70 nm with varying shell (2.5–10 nm) and gap (2.5–15 nm) thicknesses and obtained both far-field and near-field spectra. The extinction spectra from these particles always have two peaks. The low-energy peak redshifts with the decreasing shell thickness. However, when the gap thickness decreases, the low-energy peaks first blueshift and then redshift, producing a C-shape in the peak position. For every system we investigated, the near-field enhancement spectra were stronger inside the gap than on the outer surface of the nanoparticle. We find that a thin shell combined with a thin gap will produce the greatest near-field enhancement inside the gap. Our work fills the knowledge gap between the exciting potential applications of gap-enhanced Raman tags and the fundamental knowledge of enhancement provided by the gap.

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Section: Discussionmentioning

confidence: 99%

An Investigation on the Use of Au@SiO2@Au Nanomatryoshkas as Gap-Enhanced Raman Tags

Eldridge,

Gomrok,

Barr

et al. 2023

Nanomaterials

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“…133,192−195 For energy systems, the challenge lies in unveiling interfacial reactions hardly reached by the traditional methodology under real working conditions. With the aid of a deeper penetration depth of either ∼3000 μm by the spatially offset Raman spectroscopy and or even 40 mm by transmission Raman spectroscopy, 196,197 and the development of optical alignment, it is very promising for the in situ/operando SERS on biology and energy systems.…”

Section: Challenges and Opportunitiesmentioning

confidence: 99%

“…For biological systems, the challenge lies in preserving biomolecules in their natural state while obtaining SERS spectra for investigating molecular interactions like drug–protein, protein–DNA, and protein–protein interactions. − When it comes to the cell and tissue level investigation, the spatiotemporal heterogeneity becomes obvious, and it is expected to reveal intriguing phenomena in single-cell analysis with minimized perturbations. ,− For energy systems, the challenge lies in unveiling interfacial reactions hardly reached by the traditional methodology under real working conditions. With the aid of a deeper penetration depth of either ∼3000 μm by the spatially offset Raman spectroscopy and or even 40 mm by transmission Raman spectroscopy, , and the development of optical alignment, it is very promising for the in situ /operando SERS on biology and energy systems.…”

Section: Challenges and Opportunitiesmentioning

confidence: 99%

Surface-Enhanced Raman Spectroscopy: Current Understanding, Challenges, and Opportunities

Ma,

Pan,

Wang

et al. 2024

ACS Nano

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While surface-enhanced Raman spectroscopy (SERS) has experienced substantial advancements since its discovery in the 1970s, it is an opportunity to celebrate achievements, consider ongoing endeavors, and anticipate the future trajectory of SERS. In this perspective, we encapsulate the latest breakthroughs in comprehending the electromagnetic enhancement mechanisms of SERS, and revisit CT mechanisms of semiconductors. We then summarize the strategies to improve sensitivity, selectivity, and reliability. After addressing experimental advancements, we comprehensively survey the progress on spectrum−structure correlation of SERS showcasing their important role in promoting SERS development. Finally, we anticipate forthcoming directions and opportunities, especially in deepening our insights into chemical or biological processes and establishing a clear spectrum−structure correlation.

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NIR‐II Luminescence in Cr⁴⁺ Activated CaYGaO₄ toward Non‐Invasive Temperature Sensing and Composition Detection

Wang,

Liu,

Xia

2023

Laser & Photonics Reviews

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Near‐infrared (NIR) II region (1000–1700 nm) lighting sources possess special potential for temperature sensing and quantitative composition analysis. However, it is a challenge to tune the luminescence toward such long wavelength NIR‐II emission. Herein, Cr4+ ions occupation is designed and verified in olivine‐type CaYGaO4 as [CrO4] tetrahedron by site occupancy confinement. Under 620 nm red light excitation, the phosphors display broadband NIR‐II emission centered at 1330 nm with a full width at half maximum (FWHM) of 233 nm, resulting from spin‐allowed 3T2 to 3A2 transition of Cr4+ ions in Td symmetry. The optical thermometry application is demonstrated by decoding the spectral shift and decay times varying with temperature, and the maximum relative sensitivities are 5.82% and 0.78% K−1, respectively. Furthermore, a flexible film containing CaYGaO4:Cr4+ is fabricated to implement the non‐invasive detections of fillet temperature and NH3 concentration in ammonia. This work represents a step toward developing next‐generation NIR‐II luminescence materials and widens non‐invasive detection applications.

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Non‐Invasive Detection, Precise Localization, and Perioperative Navigation of In Vivo Deep Lesions Using Transmission Raman Spectroscopy

Cited by 9 publications

References 68 publications

An Investigation on the Use of Au@SiO2@Au Nanomatryoshkas as Gap-Enhanced Raman Tags

An Investigation on the Use of Au@SiO2@Au Nanomatryoshkas as Gap-Enhanced Raman Tags

Surface-Enhanced Raman Spectroscopy: Current Understanding, Challenges, and Opportunities

NIR‐II Luminescence in Cr⁴⁺ Activated CaYGaO₄ toward Non‐Invasive Temperature Sensing and Composition Detection

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Non‐Invasive Detection, Precise Localization, and Perioperative Navigation of In Vivo Deep Lesions Using Transmission Raman Spectroscopy

Cited by 9 publications

References 68 publications

An Investigation on the Use of Au@SiO2@Au Nanomatryoshkas as Gap-Enhanced Raman Tags

An Investigation on the Use of Au@SiO2@Au Nanomatryoshkas as Gap-Enhanced Raman Tags

Surface-Enhanced Raman Spectroscopy: Current Understanding, Challenges, and Opportunities

NIR‐II Luminescence in Cr4+ Activated CaYGaO4 toward Non‐Invasive Temperature Sensing and Composition Detection

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Product

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NIR‐II Luminescence in Cr⁴⁺ Activated CaYGaO₄ toward Non‐Invasive Temperature Sensing and Composition Detection