Optical coherence tomography (OCT) is a pivotal imaging modality in ophthalmology for real-time, visualization of retinal structures. To enhance the capability and safety of OCT, this study focuses on the development of a micro intraocular OCT probe. The demand for minimal invasiveness and precise imaging drives the need for advanced probe designs that can access tight and sensitive areas, such as the ocular sclera. A novel OCT probe was engineered using a piezoelectric tube with quartered electrodes to drive Lissajous scanning movements at the end of a single-mode fiber. This design allows the probe to enter the eyeball through a scleral opening. Structural innovation enables the outer diameter of the endoscopic OCT probe to be adjusted from 13G (2.41 mm) to 25G (0.51 mm), accommodating various imaging field sizes and ensuring compatibility with different scleral incisions. The fabricated micro intraocular OCT probe successfully performed preliminary imaging experiments on fingers. The Lissajous scanning facilitated comprehensive coverage of the target area, enhancing the imaging capabilities. The integration of a piezoelectric tube with quartered outside electrodes into the OCT probe design proved effective for achieving precise control over scanning movements and adaptability to different surgical needs. The design characteristics and practical applications demonstrated the probe's potential in clinical settings.
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http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11080653 | PMC |
http://dx.doi.org/10.3389/fbioe.2024.1391630 | DOI Listing |
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