Jeremy D Rogers

Overview

Explore the profile of Jeremy D Rogers including associated specialties, affiliations and a list of published articles.

Snapshot

Articles 47

Citations 777

Followers 0

Related Specialties

Ophthalmology

Radiology

Biomedical Engineering

Top 10 Co-Authors

Vadim Backman

Hemant K Roy

Andrew J Radosevich

Nikhil N Mutyal

Vladimir Turzhitsky

Allen Taflove

Ilker R Capoglu

Kevin W Eliceiri

Prabhakar Pradhan

Valentina Stoyneva

Published In

Opt Lett

Biomed Opt Express

Opt Express

J Biomed Opt

Appl Opt

Affiliations

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Recent Articles

21.

Modulation of light-enhancement to symbiotic algae by light-scattering in corals and evolutionary trends in bleaching

Marcelino L, Westneat M, Stoyneva V, Henss J, Rogers J, Radosevich A, et al.

PLoS One . 2013 May; 8(4):e61492. PMID: 23630594

Calcium carbonate skeletons of scleractinian corals amplify light availability to their algal symbionts by diffuse scattering, optimizing photosynthetic energy acquisition. However, the mechanism of scattering and its role in coral...

22.

Can OCT be sensitive to nanoscale structural alterations in biological tissue?

Yi J, Radosevich A, Rogers J, Norris S, Capoglu I, Taflove A, et al.

Opt Express . 2013 Apr; 21(7):9043-59. PMID: 23571994

Exploration of nanoscale tissue structures is crucial in understanding biological processes. Although novel optical microscopy methods have been developed to probe cellular features beyond the diffraction limit, nanometer-scale quantification remains...

23.

Structural length-scale sensitivities of reflectance measurements in continuous random media under the Born approximation

Radosevich A, Yi J, Rogers J, Backman V

Opt Lett . 2012 Dec; 37(24):5220-2. PMID: 23258058

Which range of structures contributes to light scattering in a continuous random media, such as biological tissue? In this Letter, we present a model to study the structural length-scale sensitivity...

24.

Open source software for electric field Monte Carlo simulation of coherent backscattering in biological media containing birefringence

Radosevich A, Rogers J, Capoglu I, Mutyal N, Pradhan P, Backman V

J Biomed Opt . 2012 Nov; 17(11):115001. PMID: 23123973

ABSTRACT. We present an open source electric field tracking Monte Carlo program to model backscattering in biological media containing birefringence, with computation of the coherent backscattering phenomenon as an example....

25.

A fiber optic probe design to measure depth-limited optical properties in-vivo with low-coherence enhanced backscattering (LEBS) spectroscopy

Mutyal N, Radosevich A, Gould B, Rogers J, Gomes A, Turzhitsky V, et al.

Opt Express . 2012 Oct; 20(18):19643-57. PMID: 23037017

Low-coherence enhanced backscattering (LEBS) spectroscopy is an angular resolved backscattering technique that is sensitive to sub-diffusion light transport length scales in which information about scattering phase function is preserved. Our...

26.

Near-field penetrating optical microscopy: a live cell nanoscale refractive index measurement technique for quantification of internal macromolecular density

Strasser S, Shekhawat G, Rogers J, Dravid V, Taflove A, Backman V

Opt Lett . 2012 Feb; 37(4):506-8. PMID: 22344088

Quantification of intracellular nanoscale macromolecular density distribution is a fundamental aspect to understanding cellular processes. We report a near-field penetrating optical microscopy (NPOM) technique to directly probe the internal nanoscale...

27.

Measurement of the spatial backscattering impulse-response at short length scales with polarized enhanced backscattering

Radosevich A, Mutyal N, Turzhitsky V, Rogers J, Yi J, Taflove A, et al.

Opt Lett . 2011 Dec; 36(24):4737-9. PMID: 22179867

In this Letter, we describe an easy to implement technique to measure the spatial backscattering impulse-response at length scales shorter than a transport mean free path with resolution of better...

28.

Measurement of optical scattering properties with low-coherence enhanced backscattering spectroscopy

Turzhitsky V, Radosevich A, Rogers J, Mutyal N, Backman V

J Biomed Opt . 2011 Jul; 16(6):067007. PMID: 21721828

Low-coherence enhanced backscattering (LEBS) is a depth selective technique that allows noninvasive characterization of turbid media such as biological tissue. LEBS provides a spectral measurement of the tissue reflectance distribution...

29.

Alternate formulation of enhanced backscattering as phase conjugation and diffraction: derivation and experimental observation

Rogers J, Stoyneva V, Turzhitsky V, Mutyal N, Pradhan P, Capoglu I, et al.

Opt Express . 2011 Jul; 19(13):11922-31. PMID: 21716426

Enhanced backscattering (EBS), also known as weak localization of light, is derived using the Huygens-Fresnel principle and backscattering is generally shown to be the sum of an incoherent baseline and...

30.

Numerical simulation of partially coherent broadband optical imaging using the finite-difference time-domain method

Capoglu I, White C, Rogers J, Subramanian H, Taflove A, Backman V

Opt Lett . 2011 May; 36(9):1596-8. PMID: 21540939

Rigorous numerical modeling of optical systems has attracted interest in diverse research areas ranging from biophotonics to photolithography. We report the full-vector electromagnetic numerical simulation of a broadband optical imaging...