Optical coherence elastography with osmotically induced strains: Preliminary demonstration for express detection of cartilage degradation
Optical coherence elastography (OCE) demonstrated impressive abilities for diagnosing tissue types/states using differences in their biomechanics. Usually, OCE visualizes tissue deformation induced by some additional stimulus (e.g., contact compression or auxiliary elastic‐wave excitation). We propo...
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Veröffentlicht in: | Journal of biophotonics 2024-07, Vol.17 (7), p.e202400016-n/a |
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Sprache: | eng |
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Zusammenfassung: | Optical coherence elastography (OCE) demonstrated impressive abilities for diagnosing tissue types/states using differences in their biomechanics. Usually, OCE visualizes tissue deformation induced by some additional stimulus (e.g., contact compression or auxiliary elastic‐wave excitation). We propose a new variant of OCE with osmotically induced straining (OIS‐OCE) and demonstrate its application to assess various stages of proteoglycan content degradation in cartilage. The information‐bearing signatures in OIS‐OCE are the magnitude and rate of strains caused by the application of osmotically active solutions onto the sample surface. OCE examination of the induced strains does not require special tissue preparation, the osmotic stimulation is highly reproducible, and strains are observed in noncontact mode. Several minutes suffice to obtain a conclusion. These features are promising for intraoperative method usage when express assessment of tissue state is required during surgical operations. The “waterfall” images demonstrate the development of cumulative osmotic strains in control and degraded cartilage samples.
A new variant of optical coherence elastography with osmotically induced straining (OIS‐OCE) is proposed. It is applied to differentiate stages of proteoglycan‐content degradation in cartilage. OIS‐OCE does not require special tissue preparation, osmotic stimulation is highly reproducible, and strains are observed in noncontact mode. Several minutes suffice to obtain a conclusion. |
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ISSN: | 1864-063X 1864-0648 1864-0648 |
DOI: | 10.1002/jbio.202400016 |