Sharp images with flexible fibers
Endoscopes allow to see into a patient’s body but their large diameter hampers their application in sensitive body regions. Researchers have discovered a new way to transfer image information through multimodal fibers with almost no distortion.
06/13/2018 · News · Leibniz-Institut für Photonische Technologien · Forschungsergebnis · Mathematik, Natur- und Ingenieurwissenschaften
An international team of scientists has discovered a new way to transfer image information through multimodal fibers with almost no distortion - even if the fiber is bent. The results of the study, to which scientist from the Leibniz-Institute of Photonic Technology Jena (Leibniz IPHT) contributed, were published on 6th June in the highly-cited journal Physical Review Letters.
Endoscopes allow doctors to see into a patient’s body like through a keyhole. Typically, the images are transmitted via a bundle of several hundreds of optical fibers. They account for the relatively large diameter of the endoscopes that hampers their application in sensitive body regions such as the brain. A team of international researchers around Prof. Tomáš Čižmár, scientist at Leibniz IPHT, studies multimodal optical fiber probes, in which high-resolution images can be transmitted through just one single hair-thin fiber. For applications such as the survey of single brain cells ‘at work’ in a living organism, the probes must be first and foremost flexible. This is a challenge, as with the bending of the fiber the transferred image is distorted in several ways.
For several years Čižmár already works on a solution to optimize the transfer of image information in multimodal fibers. “Previously, we have shown that the influence of bending on the light propagation can be predicted and the image restored using computer calculations. But the correction is very complicated and we need to know the exact shape of the probe”, explains Čižmár, who heads the Fiberoptics department at Leibniz IPHT since 2017.
Now, the scientists discovered that fibers exhibiting a specific refraction index profile provide a new and much more simple approach. “We came to the idea to use gradient index fibers for image transfer. Other than in common fibers, the light refraction across the fiber diameter does not change abruptly, but gradually in shape of a curve”, says Čižmár. Firstly, the researchers simulated the light propagation in the fibers with theoretical models. The results suggested that the signal transmission in the fibers is almost immune to movement and bending due to the unique refraction index profile. “In experiments, we managed to proof our ideas only partially. The graded index fibers are indeed much less sensitive towards deformation compared to conventional step index fibers. Nevertheless, we observe a residual slight distortion of the images, which we assign to deviations from the ideal parabolic refraction index profile of the commercial fibers”, explains first author of the publication Dirk Boonzajer Flaes the extraordinary results. The researchers focus now on the development of gradient index fibers with enhanced optical properties and their application for medical imaging.
The original article “Robustness of light-transport processes to bending deformations in graded-index multimode waveguides” by Dirk E. Boonzajer Flaes, Jan Stopka, Sergey Turtaev, Johannes F. de Boer, Tomáš Tyc, and Tomáš Čižmár appeared online in Physical Review Letters on 6th June 2018.
Dr. Anja Schulz
Leibniz-Institute of Photonic Technology (IPHT)
Tel.: +49 3641 206 064