S
Stephen A. Boppart
Researcher at University of Illinois at Urbana–Champaign
Publications - 684
Citations - 33772
Stephen A. Boppart is an academic researcher from University of Illinois at Urbana–Champaign. The author has contributed to research in topics: Optical coherence tomography & Laser. The author has an hindex of 90, co-authored 631 publications receiving 31497 citations. Previous affiliations of Stephen A. Boppart include Harvard University & Boston University.
Papers
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Inverse scattering for optical coherence tomography
TL;DR: Inverse scattering theory for optical coherence tomography (OCT) is developed in this paper, and the results are used to produce algorithms to resolve three-dimensional object structure, taking into account the finite beam width, diffraction, and defocusing effects.
Journal Article
Investigation of Developing Embryonic Morphology Using Optical Coherence Tomography
TL;DR: This study investigates the application of OCT for imaging developing structure in Rana pipiens, Xenopus laevis, and Brachydanio rerio by measuring backscattered infrared light.
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Microscopic imaging and spectroscopy with scattered light.
TL;DR: The fundamental methodologies used to acquire and interpret optical scatter data are reviewed and current advances in optical scatter techniques and computational methods are presented.
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Computational high-resolution optical imaging of the living human retina
Nathan D. Shemonski,Fredrick A. South,Yuan Zhi Liu,Steven G. Adie,P. Scott Carney,Stephen A. Boppart +5 more
TL;DR: A fully automated computational approach is demonstrated that enables high-resolution in vivo ophthalmic imaging without the need for hardware-based adaptive optics and demonstrates that computational methods in coherent microscopy are applicable in highly dynamic living systems.
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A flexible perforated microelectrode array for extended neural recordings
TL;DR: A flexible and perforated 32-element planar microelectrode array has been fabricated and used to measure evoked potentials in brain slices and showed an average increase of 10 h to the viability of the slice while using the perforations versus nonperforated arrays.