Depth‐Resolved Localization Microangiography in the NIR‐II Window

Zhou, Quanyu; Nozdriukhin, Daniil; Chen, Zhenyue; Glandorf, Lukas; Hofmann, Urs; Reiss, Michael; Tang, Lin; Deán‐Ben, Xosé Luís; Razansky, Daniel

doi:10.1002/advs.202204782

Cited by 10 publications

(4 citation statements)

References 58 publications

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“…Moreover, recent advantages in imaging modalities can even allow for depth‐resolved stereo vision. [ 64 ] This said, the general improvements in optical equipment will enable enhanced resolution and signal‐to‐noise ratios, with decreasing costs in the future. As outlined in Supporting Information Figure S16, we aimed to test the imaging approach with the clinically most relevant fragment sizes.…”

Section: Resultsmentioning

confidence: 99%

Material‐Intrinsic NIR‐Fluorescence Enables Image‐Guided Surgery for Ceramic Fracture Removal

Nißler,

Totter,

Walter

et al. 2024

Adv Healthcare Materials

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Hip arthroplasty effectively treats advanced osteoarthritis and has therefore been entitled as “operation of the 20th century.” With demographic shifts, the USA alone is projected to perform up to 850,000 arthroplasties annually by 2030. Many implants now feature a ceramic head, valued for strength and wear resistance. Nonetheless, a fraction, up to 0.03% may fracture during their lifespan, demanding complex removal procedures. To address this, a radiation‐free, fluorescence‐based image‐guided surgical technique is proposed. The method uses ceramics' inherent fluorescence, demonstrated through chemical and optical analysis of prevalent implant types. Specifically, Biolox delta® implants exhibit strong fluorescence around 700 nm with a 74% photoluminescence quantum yield. We identified emission tails extending into the near‐infrared (NIR‐I) biological transparency range, forming a vital prerequisite for the label‐free visualization of fragments. This ruby‐like fluorescence can be attributed to Cr within the zirconia‐toughened alumina matrix, enabling the detection of even deep‐seated millimeter‐sized fragments via camera‐assisted techniques. Additionally, fluorescence microscopy detects μm‐sized ceramic particles, enabling debris visualization in synovial fluid or histological samples. This label‐free optical imaging approach employs readily accessible equipment and can seamlessly transition to clinical settings without significant regulatory barriers, thereby enhancing the safety, efficiency, and minimally invasive nature of fractured ceramic implant removal.This article is protected by copyright. All rights reserved

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Section: Resultsmentioning

confidence: 99%

Material‐Intrinsic NIR‐Fluorescence Enables Image‐Guided Surgery for Ceramic Fracture Removal

Nißler,

Totter,

Walter

et al. 2024

Adv Healthcare Materials

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“…Its high-resolution optoacoustic microscopy counterpart sacrifices imaging speed and/or field-of-view (FOV) to attain capillary level resolution in the lateral plane, yet it provides poor axial resolution that hinders accurate depiction of three-dimensional microvascular networks 12,13 . Recently, localization-based approaches, such as ultrasound localization microscopy (ULM) 14 , localization optoacoustic tomography (LOT) 15 and widefield fluorescence localization microscopy (WFLM) 16 are gaining interest due to their high spatial resolution as well as intrinsic velocity measurements across large FOVs. However, ULM and LOT are not yet able to resolve the capillary bed whilst WFLM is only suitable for superficial investigations further lacking depth resolution.…”

Section: Introductionmentioning

confidence: 99%

Bessel Beam Optical Coherence Microscopy Enables Multiscale Assessment of Cerebrovascular Network Morphology and Function

Glandorf,

Wittmann,

Droux

et al. 2024

Preprint

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Understanding the morphology and function of large-scale cerebrovascular networks is crucial for studying brain health and disease. However, reconciling the demands for imaging on a broad scale with the precision of high-resolution volumetric microscopy has been a persistent challenge. In this study, we introduce Bessel beam optical coherence microscopy with an extended focus to capture the full cortical vascular hierarchy in mice over 1000 x 1000 x 360 um3 field-of-view at capillary level resolution. The post- processing pipeline leverages a supervised deep learning approach for precise 3D segmentation of high-resolution angiograms, hence permitting reliable examination of microvascular structures at multiple spatial scales. Coupled with high-sensitivity Doppler optical coherence tomography, our method enables the computation of both axial and transverse blood velocity components as well as vessel specific blood flow direction, facilitating a detailed assessment of morpho-functional characteristics across all vessel dimensions. Through graph-based analysis, we deliver insights into vascular connectivity, all the way from individual capillaries to broader network interactions, a task traditionally challenging for in vivo studies. The new imaging and analysis framework extends the frontiers of research into cerebrovascular function and neurovascular pathologies.

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“…[ 1 , 2 , 3 , 4 , 5 ] Photons, particularly those in the visible and near‐infrared regions of the electromagnetic spectrum, specifically interact with endogenous molecules and bioengineered materials in living organisms in a non‐invasive manner, thus represent a powerful tool for studying biological processes in the intact in vivo environment. [ 6 , 7 , 8 ] Optical microscopy remains a workhorse in modern biological discovery with recent technological progress enabling the visualization of cellular dynamics at previously unachievable spatiotemporal rates. [ 9 , 10 , 11 , 12 ] However, the depth range covered by optical microscopy methods is restricted by the strong scattering of photons within biological tissues.…”

Section: Introductionmentioning

confidence: 99%

Multi‐Scale Volumetric Dynamic Optoacoustic and Laser Ultrasound (OPLUS) Imaging Enabled by Semi‐Transparent Optical Guidance

Nozdriukhin,

Kalva,

Özsoy

et al. 2023

Advanced Science

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Major biological discoveries are made by interrogating living organisms with light. However, the limited penetration of un‐scattered photons within biological tissues limits the depth range covered by optical methods. Deep‐tissue imaging is achieved by combining light and ultrasound. Optoacoustic imaging exploits the optical generation of ultrasound to render high‐resolution images at depths unattainable with optical microscopy. Recently, laser ultrasound has been suggested as a means of generating broadband acoustic waves for high‐resolution pulse‐echo ultrasound imaging. Herein, an approach is proposed to simultaneously interrogate biological tissues with light and ultrasound based on layer‐by‐layer coating of silica optical fibers with a controlled degree of transparency. The time separation between optoacoustic and ultrasound signals collected with a custom‐made spherical array transducer is exploited for simultaneous 3D optoacoustic and laser ultrasound (OPLUS) imaging with a single laser pulse. OPLUS is shown to enable large‐scale anatomical characterization of tissues along with functional multi‐spectral imaging of chromophores and assessment of cardiac dynamics at ultrafast rates only limited by the pulse repetition frequency of the laser. The suggested approach provides a flexible and scalable means for developing a new generation of systems synergistically combining the powerful capabilities of optoacoustics and ultrasound imaging in biology and medicine.

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Depth‐Resolved Localization Microangiography in the NIR‐II Window

Cited by 10 publications

References 58 publications

Material‐Intrinsic NIR‐Fluorescence Enables Image‐Guided Surgery for Ceramic Fracture Removal

Material‐Intrinsic NIR‐Fluorescence Enables Image‐Guided Surgery for Ceramic Fracture Removal

Bessel Beam Optical Coherence Microscopy Enables Multiscale Assessment of Cerebrovascular Network Morphology and Function

Multi‐Scale Volumetric Dynamic Optoacoustic and Laser Ultrasound (OPLUS) Imaging Enabled by Semi‐Transparent Optical Guidance

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