Handheld multi‐modal imaging for point‐of‐care skin diagnosis based on akinetic integrated optics optical coherence tomography

A handheld skin imaging system with joint optical coherence tomography (OCT) at 1300 nm and digital epiluminescence microscopy (EM) is presented. The 2 modalities are physically co‐registered in a common‐path configuration. The instrument is enabled by a dedicated planar lightwave circuit with a foo...

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Veröffentlicht in:	Journal of biophotonics 2018-10, Vol.11 (10), p.e201800193-n/a
Hauptverfasser:	Sancho‐Durá, Juan, Zinoviev, Kirill, Lloret‐Soler, Juan, Rubio‐Guviernau, Jose Luis, Margallo‐Balbás, Eduardo, Drexler, Wolfgang
Format:	Artikel
Sprache:	eng
Schlagworte:	Butterflies & moths dermatology Diagnostic systems Field of view Integrated optics Medical imaging Microelectromechanical systems Microscopy Miniaturization multimodality imaging Optical Coherence Tomography Optics Scanning Skin Tomography Weight Workflow
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container_title	Journal of biophotonics
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creator	Sancho‐Durá, Juan Zinoviev, Kirill Lloret‐Soler, Juan Rubio‐Guviernau, Jose Luis Margallo‐Balbás, Eduardo Drexler, Wolfgang
description	A handheld skin imaging system with joint optical coherence tomography (OCT) at 1300 nm and digital epiluminescence microscopy (EM) is presented. The 2 modalities are physically co‐registered in a common‐path configuration. The instrument is enabled by a dedicated planar lightwave circuit with a footprint of only 1.1 × 19.5 mm2 that provides akinetic axial OCT scanning at speeds up to 24 kHz. Lateral scanning is implemented through a low‐voltage Micro Electro‐Mechanical System (MEMS) mirror packaged with the axial scanner in a hermetic butterfly module. The OCT system, with a volume of only 80 × 27 × 14 mm3, achieves an isotropic resolution of ~11 μm in tissue, −93 dB sensitivity, 12 mm lateral field of view, and an axial scanning range of 2.8 mm in air. The complete battery‐powered device has a weight of 3 kg in a tablet format, enabling point‐of‐care use cases. This work shows that integration of complementary imaging modalities through miniaturization technology results in clinically valuable instruments supporting a patient‐centered diagnostic imaging workflow. A handheld skin imaging system with joint optical coherence tomography (OCT) at 1300 nm and digital epiluminescence microscopy is presented. The instrument is enabled by a dedicated planar lightwave circuit (1.1 × 19.5 mm2 footprint) providing akinetic axial OCT scanning. The OCT engine (80 × 27 × 14 mm3 in volume), achieves ~11 μm of isotropic resolution in tissue, −93 dB sensitivity, 12 mm field of view, and 2.8 mm axial scanning range in air.
doi_str_mv	10.1002/jbio.201800193
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A handheld skin imaging system with joint optical coherence tomography (OCT) at 1300 nm and digital epiluminescence microscopy is presented. The instrument is enabled by a dedicated planar lightwave circuit (1.1 × 19.5 mm2 footprint) providing akinetic axial OCT scanning. The OCT engine (80 × 27 × 14 mm3 in volume), achieves ~11 μm of isotropic resolution in tissue, −93 dB sensitivity, 12 mm field of view, and 2.8 mm axial scanning range in air.</description><identifier>ISSN: 1864-063X</identifier><identifier>EISSN: 1864-0648</identifier><identifier>DOI: 10.1002/jbio.201800193</identifier><identifier>PMID: 29992726</identifier><language>eng</language><publisher>Weinheim: WILEY‐VCH Verlag GmbH & Co. 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The 2 modalities are physically co‐registered in a common‐path configuration. The instrument is enabled by a dedicated planar lightwave circuit with a footprint of only 1.1 × 19.5 mm2 that provides akinetic axial OCT scanning at speeds up to 24 kHz. Lateral scanning is implemented through a low‐voltage Micro Electro‐Mechanical System (MEMS) mirror packaged with the axial scanner in a hermetic butterfly module. The OCT system, with a volume of only 80 × 27 × 14 mm3, achieves an isotropic resolution of ~11 μm in tissue, −93 dB sensitivity, 12 mm lateral field of view, and an axial scanning range of 2.8 mm in air. The complete battery‐powered device has a weight of 3 kg in a tablet format, enabling point‐of‐care use cases. This work shows that integration of complementary imaging modalities through miniaturization technology results in clinically valuable instruments supporting a patient‐centered diagnostic imaging workflow. A handheld skin imaging system with joint optical coherence tomography (OCT) at 1300 nm and digital epiluminescence microscopy is presented. The instrument is enabled by a dedicated planar lightwave circuit (1.1 × 19.5 mm2 footprint) providing akinetic axial OCT scanning. 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subjects	Butterflies & moths dermatology Diagnostic systems Field of view Integrated optics Medical imaging Microelectromechanical systems Microscopy Miniaturization multimodality imaging Optical Coherence Tomography Optics Scanning Skin Tomography Weight Workflow
title	Handheld multi‐modal imaging for point‐of‐care skin diagnosis based on akinetic integrated optics optical coherence tomography
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