Anti-confocal versus confocal assessment of the middle ear simulated by Monte Carlo methods

Jung, David S.; Crowe, John A.; Birchall, John P.; Somekh, Michael Geoffrey; See, C. W.

doi:10.1364/boe.6.003820

Cited by 3 publications

(2 citation statements)

References 9 publications

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“…Hence, our approach is to combine a spatial filtering method and spectroscopy in order to improve the diagnostic accuracy. In a previous paper [13] we introduced the anti-confocal system to allow multi-wavelength measurements through the eardrum while rejecting background signal from the eardrum. The system was simulated and its performance compared to the conventional confocal system showing superiority of the anticonfocal system for this measurement and its ability to detect signal from the mucosa while rejecting background from the eardrum.…”

Section: Introductionmentioning

confidence: 99%

Anti-confocal assessment of middle ear inflammation

Jung¹,

Crowe²,

Birchall³

et al. 2016

Biomed. Opt. Express

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To improve the diagnostic prediction of recurrence of otitis media with effusion after surgery, an anti-confocal system combined with spectroscopic measurements is proposed to reject unwanted signals from the eardrum and assess the blood content. The anti-confocal system was experimentally evaluated on both optical middle ear phantom and human skin. Results showed effective rejection of signals from the eardrum using a central stop replacing the confocal pinhole, while still detecting signals from the middle ear mucosa. The system is sensitive to changes in blood content, but scattering and absorption characteristics of the eardrum can distort the measurement. Confocal detection of eardrum properties was shown to be a promising approach to correct measurements.

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Section: Introductionmentioning

confidence: 99%

Anti-confocal assessment of middle ear inflammation

Jung¹,

Crowe²,

Birchall³

et al. 2016

Biomed. Opt. Express

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“…In this feature issue of Biomedical Optics Express, we have collected several papers that represent some of the technologies discussed at the Bio-Optics: Design and Application. These papers highlight advances in diagnostic microscopy [1][2][3][4][5], optical coherence tomography [6], multimodal imaging [7,8] and selected applications [9,10]. Together, they present a set of interesting instrumentation developments in the field biomedical optics.…”

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confidence: 99%

Introduction to the bio-optics: design and application

Tkaczyk¹,

Xu²

2015

Biomed. Opt. Express

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Abstract:The "Bio-Optics: Design and Application" symposium, held on April 12-15, 2015, in Vancouver, BC, was an important step in a continuous journey to closely connect technological design advancement and biomedical applications. The symposium presented a broad range of innovations in diagnostic devices, endoscopy, optical microscopy, optical coherence tomography, multi-modal imaging, and highlighted specific applications including cancer diagnostics, detection of infectious disease and point of care, as well as microsurgery treatment.© 2015 Optical Society of America OCIS codes: (000.1200) Announcements, awards, news, and organizational activities; (000.0000) General. References and links1. X. Lin, J. Wu, G. Zheng, and Q. Dai, "Camera array based light field microscopy," Biomed. Opt. Express 6(9), 3179-3189 (2015). 2. K. Guo, J. Liao, Z. Bian, X. Heng, and G. Zheng, "InstantScope: a low-cost whole slide imaging system with instant focal plane detection," Biomed. Opt. Express 6(9), 3210-3216 (2015). 3. J. L. Burnett, J. L. Carns, and R. Richards-Kortum, "In vivo microscopy of hemozoin: towards a needle free diagnostic for malaria," Biomed. Opt. Express 6(9), 3462-3474 (2015). 4. G. D. Vigil and S. S. Howard, "Photophysical characterization of sickle cell disease hemoglobin by multi-photon microscopy," Biomed. Opt. Express 6(10), 4098-4104 (2015). 5. A. Forcucci, M. E. Pawlowski, C. Majors, R. Richards-Kortum, and T. S. Tkaczyk, "All-plastic, miniature, digital fluorescence microscope for three part white blood cell differential measurements at the point of care," Biomed. Opt. Express 6(11), 4433-4446 (2015). 6. Y. Zhao, J. R. Maher, J. Kim, M. A. Selim, H. Levinson, and A. Wax, "Evaluation of burn severity in vivo in a mouse model using spectroscopic optical coherence tomography," Biomed. Opt. Express 6(9), 3339-3345 (2015). 7. H. M. Leung and A. F. Gmitro, "Fluorescence and reflectance spectral imaging system for a murine mammary window chamber model," Biomed. Opt. Express 6(8), 2887-2894 (2015). 8. K. Tanha, A. M. Pashazadeh, and B. W. Pogue, "Review of biomedical Čerenkov luminescence imaging applications," Biomed. Opt. Express 6(8), 3053-3065 (2015). 9. S. Feng, W. Wang, I. T. Tai, G. Chen, R. Chen, and H. Zeng, "Label-free surface-enhanced Raman spectroscopy for detection of colorectal cancer and precursor lesions using blood plasma," Biomed. Opt. Express 6(9), 3494-3502 (2015). 10. D. S. Jung, J. A. Crowe, J. P. Birchall, M. G. Somekh, and C. W. See, "Anti-confocal versus confocal assessment of the middle ear simulated by Monte Carlo methods," Biomed. Opt. Express 6(10), 3820-3825 (2015).Optical instrumentation for bio-imaging is an important component of biological and medical science progress. On the other hand, biomedical applications are critical drivers for technology development in optics and photonics. The development of optics in biological and biomedical sciences (i.e.,bio-optics) requires not only deep insight into the applications but also the synergistic collaborations of many fields, inclu...

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Advances in Monte Carlo Simulation for Light Propagation in Tissue

Periyasamy

Pramanik

2017

IEEE Rev. Biomed. Eng.

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Monte Carlo (MC) simulation for light propagation in tissue is the gold standard for studying the light propagation in biological tissue and has been used for years. Interaction of photons with a medium is simulated based on its optical properties. New simulation geometries, tissue-light interaction methods, and recording techniques recently have been designed. Applications, such as whole mouse body simulations for fluorescence imaging, eye modeling for blood vessel imaging, skin modeling for terahertz imaging, and human head modeling for sinus imaging, have emerged. Here, we review the technical advances and recent applications of MC simulation.

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Anti-confocal versus confocal assessment of the middle ear simulated by Monte Carlo methods

Cited by 3 publications

References 9 publications

Anti-confocal assessment of middle ear inflammation

Anti-confocal assessment of middle ear inflammation

Introduction to the bio-optics: design and application

Advances in Monte Carlo Simulation for Light Propagation in Tissue

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