Air-Jet based optical coherence elastography: processing and mechanical interpretation of brain tumor data

Detrez, Nicolas; Burhan, Sazgar; Rewerts, Katharina; Kren, Jessica; Hagel, Christian; Bonsanto, Matteo M.; Theisen-Kunde, Dirk; Huber, Robert; Brinkmann, Ralf

doi:10.1117/12.2649835

Cited by 2 publications

(1 citation statement)

References 6 publications

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“…To verify the functionality of this approach, the results are compared with those obtained with conventional PhS-OCE, where only the phase signal of the acquired signal was analyzed. The unwrapping algorithm for retrieving the true phase has already been presented and its robustness and functionality have been verified by histological results [5][6][7].…”

Section: Methodsmentioning

confidence: 94%

Advanced FFT-based contrast approach for MHz optical coherence elastography

Burhan,

Detrez,

Göb

et al. 2023

Optical Coherence Imaging Techniques and Imaging in Scattering Media V

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Optical coherence elastography represents mechanical characteristics of biological tissue in so-called mechanical contrast maps. In addition to the standard intensity image, the contrast map illustrates numerous mechanical tissue features that would otherwise be undetectable. This is of great interest as abnormal physiological changes influence the mechanical behavior of the tissue. We demonstrate an advanced mechanical contrast approach based on the phase signal of our 3.2 MHz optical coherence tomography system. The robustness and performance of this contrast approach is evaluated and discussed based on preliminary results.

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Section: Methodsmentioning

confidence: 94%

Advanced FFT-based contrast approach for MHz optical coherence elastography

Burhan,

Detrez,

Göb

et al. 2023

Optical Coherence Imaging Techniques and Imaging in Scattering Media V

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Mechanical characteristics of glioblastoma and peritumoral tumor-free human brain tissue

Kren,

Skambath,

Kuppler

et al. 2024

Acta Neurochir

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Background The diagnosis of brain tumor is a serious event for the affected patient. Surgical resection is a crucial part in the treatment of brain tumors. However, the distinction between tumor and brain tissue can be difficult, even for experienced neurosurgeons. This is especially true in the case of gliomas. In this project we examined whether the biomechanical parameters elasticity and stress relaxation behavior are suitable as additional differentiation criteria between tumorous (glioblastoma multiforme; glioblastoma, IDH-wildtype; GBM) and non-tumorous, peritumoral tissue. Methods Indentation measurements were used to examine non-tumorous human brain tissue and GBM samples for the biomechanical properties of elasticity and stress-relaxation behavior. The results of these measurements were then used in a classification algorithm (Logistic Regression) to distinguish between tumor and non-tumor. Results Differences could be found in elasticity spread and relaxation behavior between tumorous and non-tumorous tissue. Classification was successful with a sensitivity/recall of 83% (sd = 12%) and a precision of 85% (sd = 9%) for detecting tumorous tissue. Conclusion The findings imply that the data on mechanical characteristics, with particular attention to stress relaxation behavior, can serve as an extra element in differentiating tumorous brain tissue from non-tumorous brain tissue.

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Air-Jet based optical coherence elastography: processing and mechanical interpretation of brain tumor data

Cited by 2 publications

References 6 publications

Advanced FFT-based contrast approach for MHz optical coherence elastography

Advanced FFT-based contrast approach for MHz optical coherence elastography

Mechanical characteristics of glioblastoma and peritumoral tumor-free human brain tissue

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