High‐resolution imaging of the human incudostapedial joint using synchrotron‐radiation phase‐contrast imaging

Rohani, Seyed Alireza; Allen, Danielg.; Gare, Bradley; Zhu, Ning; Agrawal, Sumitk.; Ladak, Hanifm.

doi:10.1111/jmi.12864

Cited by 8 publications

(3 citation statements)

References 32 publications

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“…High-resolution imaging of human cartilage with X-PCI is reported in recent literature to reach a micron resolution [ 37 , 38 ], which only depicts the cell distribution. Therefore, another innovation is that nano-tomography achieves a sub-micron resolution, which enables depiction of details within a single cell and for the first time as a radiographic technique the depiction of tissue density variations around chondrocytes corresponding to a differing biochemical composition (e.g.…”

Section: Discussionmentioning

confidence: 99%

Multiscale X-ray phase contrast imaging of human cartilage for investigating osteoarthritis formation

et al. 2021

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Background The evolution of cartilage degeneration is still not fully understood, partly due to its thinness, low radio-opacity and therefore lack of adequately resolving imaging techniques. X-ray phase-contrast imaging (X-PCI) offers increased sensitivity with respect to standard radiography and CT allowing an enhanced visibility of adjoining, low density structures with an almost histological image resolution. This study examined the feasibility of X-PCI for high-resolution (sub-) micrometer analysis of different stages in tissue degeneration of human cartilage samples and compare it to histology and transmission electron microscopy. Methods Ten 10%-formalin preserved healthy and moderately degenerated osteochondral samples, post-mortem extracted from human knee joints, were examined using four different X-PCI tomographic set-ups using synchrotron radiation the European Synchrotron Radiation Facility (France) and the Swiss Light Source (Switzerland). Volumetric datasets were acquired with voxel sizes between 0.7 × 0.7 × 0.7 and 0.1 × 0.1 × 0.1 µm3. Data were reconstructed by a filtered back-projection algorithm, post-processed by ImageJ, the WEKA machine learning pixel classification tool and VGStudio max. For correlation, osteochondral samples were processed for histology and transmission electron microscopy. Results X-PCI provides a three-dimensional visualization of healthy and moderately degenerated cartilage samples down to a (sub-)cellular level with good correlation to histologic and transmission electron microscopy images. X-PCI is able to resolve the three layers and the architectural organization of cartilage including changes in chondrocyte cell morphology, chondrocyte subgroup distribution and (re-)organization as well as its subtle matrix structures. Conclusions X-PCI captures comprehensive cartilage tissue transformation in its environment and might serve as a tissue-preserving, staining-free and volumetric virtual histology tool for examining and chronicling cartilage behavior in basic research/laboratory experiments of cartilage disease evolution.

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Section: Discussionmentioning

confidence: 99%

Multiscale X-ray phase contrast imaging of human cartilage for investigating osteoarthritis formation

et al. 2021

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“…The synchrotron-based PhC-microCT has enabled the high-contrast visualization of the middle ear [30]; indeed, recently, it was shown that this technique can be successfully applied to image the ultrastructural characteristics of the human incudostapedial joint [31].…”

Section: Auditory Apparatusmentioning

confidence: 99%

High-Resolution Phase-Contrast Tomography on Human Collagenous Tissues: A Comprehensive Review

Furlani,

Riberti,

Gatto

et al. 2023

Tomography

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Phase-contrast X-ray imaging is becoming increasingly considered since its first applications, which occurred almost 30 years ago. Particular emphasis was placed on studies that use this technique to investigate soft tissues, which cannot otherwise be investigated at a high resolution and in a three-dimensional manner, using conventional absorption-based settings. Indeed, its consistency and discrimination power in low absorbing samples, unified to being a not destructive analysis, are pushing interests on its utilization from researchers of different specializations, from botany, through zoology, to human physio-pathology research. In this regard, a challenging method for 3D imaging and quantitative analysis of collagenous tissues has spread in recent years: it is based on the unique characteristics of synchrotron radiation phase-contrast microTomography (PhC-microCT). In this review, the focus has been placed on the research based on the exploitation of synchrotron PhC-microCT for the investigation of collagenous tissue physio-pathologies from solely human samples. Collagen tissues’ elasto-mechanic role bonds it to the morphology of the site it is extracted from, which could weaken the results coming from animal experimentations. Encouraging outcomes proved this technique to be suitable to access and quantify human collagenous tissues and persuaded different researchers to approach it. A brief mention was also dedicated to the results obtained on collagenous tissues using new and promising high-resolution phase-contrast tomographic laboratory-based setups, which will certainly represent the real step forward in the diffusion of this relatively young imaging technique.

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“…In addition to laboratory or clinical micro-CT scanners [20,21], static synchrotron-based X-ray microtomography has allowed new morphological studies of the inner and middle ear. By harnessing the unique properties of synchrotron radiation, this technique provides enhanced spatial resolution and soft tissue contrast by exploiting phase contrast in addition to absorption contrast, making it ideal for investigating delicate anatomical structures without destruction [22][23][24]. More recently, we were also able to perform dynamic synchrotron-based X-ray microtomography for the rst time on unstained fresh-frozen human ear specimen and extract the threedimensional information of the dynamic behavior of the auditory ossicles during sound stimulation of 110 dB and 120 dB SPL at 128 Hz [25].…”

Section: Introductionmentioning

confidence: 99%

Dynamic X-ray Microtomography vs. Laser-Doppler Vibrometry: A Comparative Study

Ivanovic,

Cheng,

Schmeltz

et al. 2024

Preprint

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Purpose: There are challenges in understanding the biomechanics of the human middle ear, and established methods for studying this system show significant limitations. In this study, we evaluate a novel dynamic imaging technique based on synchrotron X-ray microtomography designed to assess the biomechanical properties of the human middle ear by comparing it to laser-Doppler vibrometry (LDV). Methods: We examined three fresh-frozen temporal bones (TB) using dynamic synchrotron-based X-ray microtomography for 256 Hz and 512 Hz, stimulated at 110 dB and 120 dB SPL. In addition, we performed measurements on these TBs using 1D LDV, a well-established method. Results: The normalized displacement values (µm/Pa) at the umbo and the posterior crus of the stapes are consistent or within 5-10 dB differences between all LDV and dynamic microtomography measurements and previously reported literature references. In general, the overall behavior is similar between the two measurement techniques. Conclusion: In conclusion, our results demonstrate the suitability of dynamic synchrotron-based X-ray microtomography in studying the middle ear’s biomechanics. However, this study shows that better standardization regarding acoustic stimulation and measurement points is needed to better compare the two measurement techniques.

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High‐resolution imaging of the human incudostapedial joint using synchrotron‐radiation phase‐contrast imaging

Cited by 8 publications

References 32 publications

Multiscale X-ray phase contrast imaging of human cartilage for investigating osteoarthritis formation

Multiscale X-ray phase contrast imaging of human cartilage for investigating osteoarthritis formation

High-Resolution Phase-Contrast Tomography on Human Collagenous Tissues: A Comprehensive Review

Dynamic X-ray Microtomography vs. Laser-Doppler Vibrometry: A Comparative Study

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