Human Photonics Laboratory

Publications

Authors: Type:

2014

  • [DOI] N. Agarwal, A. M. Biancardi, F. W. Patten, A. P. Reeves, and E. J. Seibel, “Three-dimensional DNA image cytometry by optical projection tomographic microscopy for early cancer diagnosis,” Journal of medical imaging, vol. 1, iss. 1, p. 17501, 2014.
    [Bibtex]
    @article{Agarwal2014a,
    author = {Agarwal, Nitin and Biancardi, Alberto M. and Patten, Florence W. and Reeves, Anthony P. and Seibel, Eric J.},
    doi = {10.1117/1.JMI.1.1.017501},
    issn = {2329-4302},
    journal = {Journal of Medical Imaging},
    keywords = {11,18,20,2014,accepted for publication may,cancer diagnosis,dna index,flow cytometry,image cytometry,imaging,online jun,optical projection tomography microscope,paper 14002pr received jan,published,revised manuscript received apr,three-dimensional image processing,volumetric},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = jun,
    number = {1},
    pages = {017501},
    title = {{Three-dimensional DNA image cytometry by optical projection tomographic microscopy for early cancer diagnosis}},
    url = {http://medicalimaging.spiedigitallibrary.org/article.aspx?doi=10.1117/1.JMI.1.1.017501},
    volume = {1},
    year = {2014}
    }
  • N. Agarwal, Y. Xie, F. W. Patten, A. P. Reeves, and E. J. Seibel, “DNA Ploidy Measure of Feulgen-Stained Cancer Cells using Three-Dimensional Image Cytometry,” in 2014 health innovations and point-of-care technologies conference, Seattle, WA, 2014, pp. 6-9.
    [Bibtex]
    @inproceedings{Agarwal2014,
    address = {Seattle, WA},
    author = {Agarwal, Nitin and Xie, Yiting and Patten, Florence W and Reeves, Anthony P and Seibel, Eric J},
    booktitle = {2014 Health Innovations and Point-of-Care Technologies Conference},
    isbn = {9781479929184},
    keywords = {Biomarkers,Imaging,Medical devices},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    pages = {6--9},
    title = {{DNA Ploidy Measure of Feulgen-Stained Cancer Cells using Three-Dimensional Image Cytometry}},
    year = {2014}
    }
  • [DOI] M. R. Burkhardt, T. D. Soper, W. J. Yoon, and E. J. Seibel, “Controlling the Trajectory of a Flexible Ultrathin Endoscope for Fully Automated Bladder Surveillance,” Ieee/asme transactions on mechatronics, vol. 19, iss. 1, pp. 366-373, 2014.
    [Bibtex]
    @article{Burkhardt2014,
    author = {Burkhardt, Matthew R. and Soper, Timothy D. and Yoon, Woon Jong and Seibel, Eric J.},
    doi = {10.1109/TMECH.2013.2237783},
    issn = {1083-4435},
    journal = {IEEE/ASME Transactions on Mechatronics},
    mendeley-groups = {HPL,HPL/Bladder Scan},
    month = feb,
    number = {1},
    pages = {366--373},
    title = {{Controlling the Trajectory of a Flexible Ultrathin Endoscope for Fully Automated Bladder Surveillance}},
    url = {http://ieeexplore.ieee.org/lpdocs/epic03/wrapper.htm?arnumber=6423927},
    volume = {19},
    year = {2014}
    }
  • [DOI] R. Das, A. Agrawal, M. P. Upton, and E. J. Seibel, “Optically clearing tissue as an initial step for 3D imaging of core biopsies to diagnose pancreatic cancer,” in Optical interactions with tissue and cells xxv, 2014, p. 89410N.
    [Bibtex]
    @inproceedings{Das2014,
    author = {Das, Ronnie and Agrawal, Aishwarya and Upton, Melissa P. and Seibel, Eric J.},
    booktitle = {Optical Interactions with Tissue and Cells XXV},
    doi = {10.1117/12.2041114},
    editor = {Jansen, E. Duco and Thomas, Robert J. and Wilmink, Gerald J. and Ibey, Bennett L.},
    keywords = {3d imaging,3d pathology,an initial step for,core biopsy processing,diagnose pancreatic cancer,of core biopsies to,optical clearing,optically clearing tissue as,specimen preparation},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = feb,
    pages = {89410N},
    title = {{Optically clearing tissue as an initial step for 3D imaging of core biopsies to diagnose pancreatic cancer}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2041114},
    volume = {8941},
    year = {2014}
    }
  • [DOI] R. Das, C. W. Burfeind, G. M. Kramer, and E. J. Seibel, “Pathology in a tube: Step 1. Fixing, staining, and transporting pancreatic core biopsies in a microfluidic device for 3D imaging,” in Microfluidics, biomems, and medical microsystems xii, 2014, p. 89760R.
    [Bibtex]
    @inproceedings{Das2014b,
    author = {Das, Ronnie and Burfeind, Chris W. and Kramer, Greg M. and Seibel, Eric J.},
    booktitle = {Microfluidics, BioMEMS, and Medical Microsystems XII},
    doi = {10.1117/12.2041106},
    editor = {Gray, Bonnie L. and Becker, Holger},
    keywords = {3d imaging,3d pathology,a microfluidic device for,core biopsy transport,fixing,optical imaging,pancreatic core biopsies in,pathology in a tube,sample preparation,staining and transporting,step 1,tissue microfluidics},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = mar,
    pages = {89760R},
    title = {{Pathology in a tube: Step 1. Fixing, staining, and transporting pancreatic core biopsies in a microfluidic device for 3D imaging}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2041106},
    volume = {8976},
    year = {2014}
    }
  • R. Das, T. Nguyen, S. D. Lim, M. O. Donnell, R. K. Wang, and E. J. Seibel, “Feasibility of a hybrid elastographic-microfluidic device to rapidly process and assess pancreatic cancer biopsies for pathologists,” in 2014 health innovations and point-of-care technologies conference, Seattle, 2014, pp. 271-275.
    [Bibtex]
    @inproceedings{Das2014a,
    address = {Seattle},
    author = {Das, Ronnie and Nguyen, Thu-mai and Lim, Saniel D and Donnell, Matt O and Wang, Ruikang K and Seibel, Eric J},
    booktitle = {2014 Health Innovations and Point-of-Care Technologies Conference},
    isbn = {9781479929184},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    pages = {271--275},
    title = {{Feasibility of a hybrid elastographic-microfluidic device to rapidly process and assess pancreatic cancer biopsies for pathologists}},
    year = {2014}
    }
  • Y. Gong, R. S. Johnston, D. C. Melville, and E. J. Seibel, “Axial-stereo 3D optical metrology of internally machined parts using high-quality imaging from a scanning laser endoscope,” in International symposium on optomechatronic technologies (isot), 2014, pp. 6-9.
    [Bibtex]
    @inproceedings{Gong2014,
    author = {Gong, Yuanzheng and Johnston, Richard S and Melville, C David and Seibel, Eric J},
    booktitle = {International Symposium on Optomechatronic Technologies (ISOT)},
    keywords = {3d optical metrology,axial-stereo,internal,machine vision,non-contact inspection,scanning laser,surface},
    mendeley-groups = {HPL,HPL/SFE\_3D\_metrology},
    pages = {6--9},
    title = {{Axial-stereo 3D optical metrology of internally machined parts using high-quality imaging from a scanning laser endoscope}},
    year = {2014}
    }
  • [DOI] Y. Gong, T. D. Soper, V. W. Hou, D. Hu, B. Hannaford, and E. J. Seibel, “Mapping surgical fields by moving a laser-scanning multimodal scope attached to a robot arm,” Medical imaging 2014: image-guided procedures, robotic interventions, and modeling, vol. 9036, p. 90362S, 2014.
    [Bibtex]
    @article{Gong2014a,
    author = {Gong, Yuanzheng and Soper, Tomothy D. and Hou, Vivian W. and Hu, Danying and Hannaford, Blake and Seibel, Eric J.},
    doi = {10.1117/12.2044165},
    editor = {Yaniv, Ziv R. and Holmes, David R.},
    journal = {Medical Imaging 2014: Image-Guided Procedures, Robotic Interventions, and Modeling},
    keywords = {3d surface mosaic,fluorescence-guided surgery,image-guided therapy,machine vision,medical robotics},
    mendeley-groups = {HPL/SFE\_surgery\_guidance},
    month = mar,
    pages = {90362S},
    title = {{Mapping surgical fields by moving a laser-scanning multimodal scope attached to a robot arm}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2044165},
    volume = {9036},
    year = {2014}
    }
  • [DOI] V. W. Hou, C. Yang, L. Y. Nelson, and E. J. Seibel, “The development of a simplified epithelial tissue phantom for the evaluation of an autofluorescence mitigation algorithm,” in Design and perfomance validation of phantoms used in conjuction with optical measurement of tissue vi, 2014, p. 894506.
    [Bibtex]
    @inproceedings{Hou2014,
    author = {Hou, Vivian W. and Yang, Chenying and Nelson, Leonard Y. and Seibel, Eric J.},
    booktitle = {Design and Perfomance Validation of Phantoms Used in Conjuction with Optical Measurement of Tissue VI},
    doi = {10.1117/12.2040167},
    editor = {Nordstrom, Robert J. and Bouchard, Jean-Pierre and Allen, David W.},
    keywords = {autofluorescence mitigation,collagen,endoscope,esophageal adenocarcinoma,evaluation of an autofluorescence,fluorescence,for the,mitigation algorithm,optical phantom,scanning fiber,simplified epithelial tissue phantom,the development of a},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = mar,
    pages = {894506},
    title = {{The development of a simplified epithelial tissue phantom for the evaluation of an autofluorescence mitigation algorithm}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2040167},
    volume = {8945},
    year = {2014}
    }
  • [DOI] P. Z. McVeigh, R. Sacho, R. a Weersink, V. M. Pereira, W. Kucharczyk, E. J. Seibel, B. C. Wilson, and T. Krings, “High-resolution angioscopic imaging during endovascular neurosurgery.,” Neurosurgery, vol. 75, iss. 2, p. 171–80; discussion 179–80, 2014.
    [Bibtex]
    @article{McVeigh2014,
    author = {McVeigh, Patrick Z and Sacho, Raphael and Weersink, Robert a and Pereira, Vitor M and Kucharczyk, Walter and Seibel, Eric J and Wilson, Brian C and Krings, Timo},
    doi = {10.1227/NEU.0000000000000383},
    isbn = {0000000000000},
    issn = {1524-4040},
    journal = {Neurosurgery},
    keywords = {angioscopy,cerebral vasculature,coiling,endoscopy,endovascular therapy,flow diverter},
    mendeley-groups = {HPL,HPL/SFE\_small\_lumen\_imaging},
    month = aug,
    number = {2},
    pages = {171--80; discussion 179--80},
    pmid = {24762703},
    title = {{High-resolution angioscopic imaging during endovascular neurosurgery.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=4086773\&tool=pmcentrez\&rendertype=abstract},
    volume = {75},
    year = {2014}
    }
  • [DOI] A. W. Templeton, K. Webb, J. H. Hwang, E. J. Seibel, and M. Saunders, “Scanning fiber endoscopy: a novel platform for cholangioscopy.,” Gastrointestinal endoscopy, vol. 79, iss. 6, pp. 1000-1, 2014.
    [Bibtex]
    @article{Templeton2014,
    author = {Templeton, Adam W and Webb, Kevin and Hwang, Joo Ha and Seibel, Eric J and Saunders, Michael},
    doi = {10.1016/j.gie.2013.12.005},
    issn = {1097-6779},
    journal = {Gastrointestinal endoscopy},
    mendeley-groups = {HPL/SFE\_small\_lumen\_imaging},
    month = jun,
    number = {6},
    pages = {1000--1},
    pmid = {24462166},
    publisher = {Elsevier},
    title = {{Scanning fiber endoscopy: a novel platform for cholangioscopy.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/24462166},
    volume = {79},
    year = {2014}
    }
  • [DOI] M. Timoshchuk, L. Zhang, B. a. Dickinson, J. S. Ridge, A. S. Kim, C. T. Baltuck, L. Y. Nelson, J. H. Berg, and E. J. Seibel, “Guided fluorescence diagnosis of childhood caries: preliminary measures correlate with depth of carious decay,” in Lasers in dentistry xx, 2014, p. 892904.
    [Bibtex]
    @inproceedings{Timoshchuk2014,
    author = {Timoshchuk, Mari-Alina and Zhang, Liang and Dickinson, Brian a. and Ridge, Jeremy S. and Kim, Amy S. and Baltuck, Camille T. and Nelson, Leonard Y. and Berg, Joel H. and Seibel, Eric J.},
    booktitle = {Lasers in Dentistry XX},
    doi = {10.1117/12.2041648},
    editor = {Rechmann, Peter and Fried, Daniel},
    keywords = {autofluorescence,dental caries,image-guided diagnosis,laser-induced fluorescence spectroscopy,optical biopsy,pilot clinical study,scanning fiber endoscope,spectral analysis},
    mendeley-groups = {HPL,HPL/SFE dental},
    month = feb,
    pages = {892904},
    title = {{Guided fluorescence diagnosis of childhood caries: preliminary measures correlate with depth of carious decay}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2041648},
    volume = {8929},
    year = {2014}
    }
  • [DOI] C. Yang, V. W. Hou, L. Y. Nelson, R. S. Johnston, D. C. Melville, and E. J. Seibel, “Multi-spectral scanning fiber endoscope with concurrent autofluorescence mitigation for enhanced target-to-background ratio imaging,” in Endoscopic microscopy ix, 2014, p. 89270I.
    [Bibtex]
    @inproceedings{Yang2014,
    author = {Yang, Chenying and Hou, Vivian W. and Nelson, Leonard Y. and Johnston, Richard S. and Melville, C. David and Seibel, Eric J.},
    booktitle = {Endoscopic Microscopy IX},
    doi = {10.1117/12.2038553},
    editor = {Suter, Melissa J. and Lam, Stephen and Brenner, Matthew and Tearney, Guillermo J. and Wang, Thomas D.},
    keywords = {autofluorescence,fluorescein,fluorescence,molecular diagnostic imaging,multi-,multi-modal imaging,scanning fiber endoscope,spectral imaging,target-to-background ratio,wide-field endoscopy},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = mar,
    pages = {89270I},
    title = {{Multi-spectral scanning fiber endoscope with concurrent autofluorescence mitigation for enhanced target-to-background ratio imaging}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2038553},
    volume = {8927},
    year = {2014}
    }
  • C. Yang, V. W. Hou, E. J. Girard, L. Y. Nelson, and E. J. Seibel, “Target-to-background enhancement in multispectral endoscopy with background autofluorescence mitigation for quantitative molecular imaging Target-to-background enhancement in multispectral endoscopy with background autofluorescence,” Journal of biomedical optics, vol. 19, iss. 7, p. 076014–1–16, 2014.
    [Bibtex]
    @article{Yang2014a,
    author = {Yang, Chenying and Hou, Vivian W and Girard, Emily J and Nelson, Leonard Y and Seibel, Eric J},
    journal = {Journal of biomedical optics},
    keywords = {autofluorescence,cancer detection,contrast,flexible endoscopy,fluorescein,fluorescence,molecular diagnostic imaging,multispectral imaging,real-time imaging,scanning fiber endo-,scope,target-to-background ratio,wide-field fluorescence imaging},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    number = {7},
    pages = {076014--1--16},
    title = {{Target-to-background enhancement in multispectral endoscopy with background autofluorescence mitigation for quantitative molecular imaging Target-to-background enhancement in multispectral endoscopy with background autofluorescence}},
    volume = {19},
    year = {2014}
    }
  • [DOI] P. Deladurantaye, A. Paquet, C. Paré, H. Zheng, M. Doucet, D. Gay, M. Poirier, J. Cormier, O. Mermut, B. C. Wilson, and E. J. Seibel, “Advances in engineering of high contrast CARS imaging endoscopes,” Optics express, vol. 22, iss. 21, p. 25053, 2014.
    [Bibtex]
    @article{Deladurantaye2014,
    author = {Deladurantaye, Pascal and Paquet, Alex and Par\'{e}, Claude and Zheng, Huimin and Doucet, Michel and Gay, David and Poirier, Michel and Cormier, Jean-Fran\c{c}ois and Mermut, Ozzy and Wilson, Brian C. and Seibel, Eric J.},
    doi = {10.1364/OE.22.025053},
    issn = {1094-4087},
    journal = {Optics Express},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs},
    month = oct,
    number = {21},
    pages = {25053},
    title = {{Advances in engineering of high contrast CARS imaging endoscopes}},
    url = {http://www.opticsinfobase.org/abstract.cfm?URI=oe-22-21-25053},
    volume = {22},
    year = {2014}
    }

2013

  • [DOI] S. U. Tran, J. S. Ridge, L. Y. Nelson, and E. J. Seibel, “Laser investigation of the non-uniformity of fluorescent species in dental enamel,” in Lasers in dentistry xix, 2013, p. 85660L.
    [Bibtex]
    @inproceedings{Tran2013,
    author = {Tran, Stephanie U. and Ridge, Jeremy S. and Nelson, Leonard Y. and Seibel, Eric J.},
    booktitle = {Lasers in Dentistry XIX},
    doi = {10.1117/12.2002519},
    editor = {Rechmann, Peter and Fried, Daniel},
    keywords = {autofluorescence,enamel,ii erosion,interprismatic,prismatic,type i and type},
    mendeley-groups = {HPL,HPL/SFE dental},
    month = mar,
    pages = {85660L},
    title = {{Laser investigation of the non-uniformity of fluorescent species in dental enamel}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2002519},
    volume = {8566},
    year = {2013}
    }
  • [DOI] C. Yang, V. Hou, L. Y. Nelson, and E. J. Seibel, “Color-matched esophagus phantom for fluorescent imaging,” in Design and performance validation of phantoms used in conjuction with optical measurement of tissue v, 2013, p. 85830F.
    [Bibtex]
    @inproceedings{Yang2013a,
    author = {Yang, Chenying and Hou, Vivian and Nelson, Leonard Y. and Seibel, Eric J.},
    booktitle = {Design and Performance Validation of Phantoms Used in Conjuction with Optical Measurement of Tissue V},
    doi = {10.1117/12.2000834},
    editor = {Nordstrom, Robert J.},
    keywords = {barrett,distance compensation,fluorescence,fluorescence quantification,imaging,molecular,phantoms,s esophagus,scanning fiber endoscope,tissue color},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = feb,
    pages = {85830F},
    title = {{Color-matched esophagus phantom for fluorescent imaging}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2000834},
    volume = {8583},
    year = {2013}
    }
  • [DOI] C. Yang, V. Hou, L. Y. Nelson, and E. J. Seibel, “Color-matched and fluorescence-labeled esophagus phantom and its applications.,” Journal of biomedical optics, vol. 18, iss. 2, p. 26020, 2013.
    [Bibtex]
    @article{Yang2013b,
    abstract = {We developed a stable, reproducible three-dimensional optical phantom for the evaluation of a wide-field endoscopic molecular imaging system. This phantom mimicked a human esophagus structure with flexibility to demonstrate body movements. At the same time, realistic visual appearance and diffuse spectral reflectance properties of the tissue were simulated by a color matching methodology. A photostable dye-in-polymer technology was applied to represent biomarker probed "hot-spot" locations. Furthermore, fluorescent target quantification of the phantom was demonstrated using a 1.2 mm ultrathin scanning fiber endoscope with concurrent fluorescence-reflectance imaging.},
    author = {Yang, Chenying and Hou, Vivian and Nelson, Leonard Y and Seibel, Eric J},
    doi = {10.1117/1.JBO.18.2.026020},
    issn = {1560-2281},
    journal = {Journal of biomedical optics},
    keywords = {Algorithms,Color,Esophagoscopy,Esophagoscopy: instrumentation,Esophagoscopy: methods,Esophagoscopy: statistics \& numerical data,Esophagus,Fluorescent Dyes,Humans,Latex,Molecular Imaging,Molecular Imaging: instrumentation,Molecular Imaging: methods,Molecular Imaging: statistics \& numerical data,Optical Fibers,Optical Phenomena,Phantoms, Imaging},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = feb,
    number = {2},
    pages = {26020},
    pmid = {23403908},
    title = {{Color-matched and fluorescence-labeled esophagus phantom and its applications.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3569733\&tool=pmcentrez\&rendertype=abstract},
    volume = {18},
    year = {2013}
    }
  • [DOI] C. Yang, V. Hou, L. Y. Nelson, and E. J. Seibel, “Mitigating fluorescence spectral overlap in wide-field endoscopic imaging.,” Journal of biomedical optics, vol. 18, iss. 8, p. 86012, 2013.
    [Bibtex]
    @article{Yang2013c,
    abstract = {The number of molecular species suitable for multispectral fluorescence imaging is limited due to the overlap of the emission spectra of indicator fluorophores, e.g., dyes and nanoparticles. To remove fluorophore emission cross-talk in wide-field multispectral fluorescence molecular imaging, we evaluate three different solutions: (1) image stitching, (2) concurrent imaging with cross-talk ratio subtraction algorithm, and (3) frame-sequential imaging. A phantom with fluorophore emission cross-talk is fabricated, and a 1.2-mm ultrathin scanning fiber endoscope (SFE) is used to test and compare these approaches. Results show that fluorophore emission cross-talk could be successfully avoided or significantly reduced. Near term, the concurrent imaging method of wide-field multispectral fluorescence SFE is viable for early stage cancer detection and localization in vivo. Furthermore, a means to enhance exogenous fluorescence target-to-background ratio by the reduction of tissue autofluorescence background is demonstrated.},
    author = {Yang, Chenying and Hou, Vivian and Nelson, Leonard Y and Seibel, Eric J},
    doi = {10.1117/1.JBO.18.8.086012},
    issn = {1560-2281},
    journal = {Journal of biomedical optics},
    keywords = {Algorithms,Artifacts,Endoscopy,Endoscopy: methods,Image Enhancement,Image Enhancement: methods,Image Interpretation, Computer-Assisted,Image Interpretation, Computer-Assisted: methods,Microscopy, Fluorescence, Multiphoton,Microscopy, Fluorescence, Multiphoton: methods,Reproducibility of Results,Sensitivity and Specificity},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = aug,
    number = {8},
    pages = {86012},
    pmid = {23966226},
    title = {{Mitigating fluorescence spectral overlap in wide-field endoscopic imaging.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3767456\&tool=pmcentrez\&rendertype=abstract},
    volume = {18},
    year = {2013}
    }
  • [DOI] C. Yang, T. D. Soper, and E. J. Seibel, “Detecting fluorescence hot-spots using mosaic maps generated from multimodal endoscope imaging,” in Endoscopic microscopy viii, 2013, p. 857508.
    [Bibtex]
    @inproceedings{Yang2013,
    author = {Yang, Chenying and Soper, Timothy D. and Seibel, Eric J.},
    booktitle = {Endoscopic Microscopy VIII},
    doi = {10.1117/12.2002219},
    editor = {Tearney, Guillermo J. and Wang, Thomas D.},
    keywords = {barrett,fluorescence imaging,hot-spots detection,mosaicking,multimodal imaging,s esophagus,scanning fiber endoscope},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = mar,
    pages = {857508},
    title = {{Detecting fluorescence hot-spots using mosaic maps generated from multimodal endoscope imaging}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.2002219},
    volume = {8575},
    year = {2013}
    }
  • [DOI] L. Zhang, A. S. Kim, J. S. Ridge, L. Y. Nelson, J. H. Berg, and E. J. Seibel, “Trimodal detection of early childhood caries using laser light scanning and fluorescence spectroscopy : clinical prototype laser light scanning and fluorescence spectroscopy :,” Journal of biomedical optics, vol. 18, iss. 11, p. 111412–1 — 111412–8, 2013.
    [Bibtex]
    @article{Zhang2013a,
    author = {Zhang, Liang and Kim, Amy S and Ridge, Jeremy S and Nelson, Leonard Y and Berg, Joel H and Seibel, Eric J},
    doi = {10.1117/1.JBO.18},
    journal = {Journal of biomedical optics},
    keywords = {12,13,2013,26,28,accepted for publication jul,autofluorescence,caries detection,clinical prototype,laser-induced fluorescence,light,multimodal device,near-ultraviolet,online aug,paper 130284sspr received apr,published,revised manuscript received jun,scanning fiber endoscope,scattering},
    mendeley-groups = {HPL,HPL/SFE dental},
    number = {11},
    pages = {111412--1 -- 111412--8},
    title = {{Trimodal detection of early childhood caries using laser light scanning and fluorescence spectroscopy : clinical prototype laser light scanning and fluorescence spectroscopy :}},
    volume = {18},
    year = {2013}
    }

2012

  • [DOI] B. P. Joshi, S. J. Miller, C. M. Lee, E. J. Seibel, and T. D. Wang, “Multispectral endoscopic imaging of colorectal dysplasia in vivo.,” Gastroenterology, vol. 143, iss. 6, pp. 1435-7, 2012.
    [Bibtex]
    @article{Joshi2012,
    author = {Joshi, Bishnu P and Miller, Sharon J and Lee, Cameron M and Seibel, Eric J and Wang, Thomas D},
    doi = {10.1053/j.gastro.2012.08.053},
    issn = {1528-0012},
    journal = {Gastroenterology},
    keywords = {Adenoma,Adenoma: diagnosis,Adenoma: pathology,Colorectal Neoplasms,Colorectal Neoplasms: diagnosis,Colorectal Neoplasms: pathology,Diagnostic Imaging,Diagnostic Imaging: methods,Endoscopy, Gastrointestinal,Endoscopy, Gastrointestinal: methods,Humans,Optical Imaging,Optical Imaging: methods,Video Recording},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = dec,
    number = {6},
    pages = {1435--7},
    pmid = {23041325},
    publisher = {Elsevier Inc.},
    title = {{Multispectral endoscopic imaging of colorectal dysplasia in vivo.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3547605\&tool=pmcentrez\&rendertype=abstract},
    volume = {143},
    year = {2012}
    }
  • [DOI] Q. Miao, A. P. Reeves, F. W. Patten, and E. J. Seibel, “Multimodal 3D imaging of cells and tissue, bridging the gap between clinical and research microscopy.,” Annals of biomedical engineering, vol. 40, iss. 2, pp. 263-76, 2012.
    [Bibtex]
    @article{Miao2012,
    abstract = {Absorption dyes are widely used in traditional cytology and pathology clinical practice, while fluorophores and nanoparticles are more often used in biologic research. Optical projection tomographic microscopy (OPTM) is a platform technology that can image the same specimen in multiple modes in 3D, providing morphologic and molecular information concurrently and in exact co-registration. The depth-of-field of a high numerical aperture objective is extended by scanning the focal plane through the sample to generate an optical projection image. Samples of cells or tissue are brought into the OPTM instrument through a microcapillary tube filled with optical index-matching gel. Multiple optical projection images are taken from different perspectives by rotating the tube. Computed tomography (CT) algorithms are applied to these optical projection images to reconstruct 3D structure of the sample. Image segmentation and analysis based on these 3D images provide quantitative biosignatures for cancer diagnosis that represents a clear improvement over conventional 2D image analysis. In this article, we introduce the OPTM platform, optical Cell-CT, and Tissue-CT instruments, and some applications using these OPTM instruments.},
    author = {Miao, Qin and Reeves, Anthony P and Patten, Florence W and Seibel, Eric J},
    doi = {10.1007/s10439-011-0411-5},
    issn = {1573-9686},
    journal = {Annals of biomedical engineering},
    keywords = {Animals,Cell Line, Tumor,Fibroblasts,Fibroblasts: cytology,Humans,Imaging, Three-Dimensional,Imaging, Three-Dimensional: methods,Microscopy,Microscopy: methods,Muntjacs,Tomography, Optical,Tomography, Optical: methods},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = feb,
    number = {2},
    pages = {263--76},
    pmid = {21984512},
    title = {{Multimodal 3D imaging of cells and tissue, bridging the gap between clinical and research microscopy.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/21984512},
    volume = {40},
    year = {2012}
    }
  • [DOI] S. J. Miller, C. M. Lee, B. P. Joshi, A. Gaustad, E. J. Seibel, and T. D. Wang, “Targeted detection of murine colonic dysplasia in vivo with flexible multispectral scanning fiber endoscopy.,” Journal of biomedical optics, vol. 17, iss. 2, p. 21103, 2012.
    [Bibtex]
    @article{Miller2012,
    abstract = {Gastrointestinal cancers are heterogeneous and can overexpress several protein targets that can be imaged simultaneously on endoscopy using multiple molecular probes. We aim to demonstrate a multispectral scanning fiber endoscope for wide-field fluorescence detection of colonic dysplasia. Excitation at 440, 532, and 635 nm is delivered into a single spiral scanning fiber, and fluorescence is collected by a ring of light-collecting optical fibers placed around the instrument periphery. Specific-binding peptides are selected with phage display technology using the CPC;Apc mouse model of spontaneous colonic dysplasia. Validation of peptide specificity is performed on flow cytometry and in vivo endoscopy. The peptides KCCFPAQ, AKPGYLS, and LTTHYKL are selected and labeled with 7-diethylaminocoumarin-3-carboxylic acid (DEAC), 5-carboxytetramethylrhodamine (TAMRA), and CF633, respectively. Separate droplets of KCCFPAQ-DEAC, AKPGYLS-TAMRA, and LTTHYKL-CF633 are distinguished at concentrations of 100 and 1 $\mu$M. Separate application of the fluorescent-labeled peptides demonstrate specific binding to colonic adenomas. The average target/background ratios are 1.71 ± 0.19 and 1.67 ± 0.12 for KCCFPAQ-DEAC and AKPGYLS-TAMRA, respectively. Administration of these two peptides together results in distinct binding patterns in the blue and green channels. Specific binding of two or more peptides can be distinguished in vivo using a novel multispectral endoscope to localize colonic dysplasia on real-time wide-field imaging.},
    author = {Miller, Sharon J and Lee, Cameron M and Joshi, Bishnu P and Gaustad, Adam and Seibel, Eric J and Wang, Thomas D},
    doi = {10.1117/1.JBO.17.2.021103},
    issn = {1560-2281},
    journal = {Journal of biomedical optics},
    keywords = {Adenocarcinoma,Adenocarcinoma: pathology,Animals,Cell Line, Tumor,Colonic Neoplasms,Colonic Neoplasms: pathology,Endoscopes, Gastrointestinal,Equipment Design,Equipment Failure Analysis,Fiber Optic Technology,Fiber Optic Technology: instrumentation,Image Enhancement,Image Enhancement: instrumentation,Mice,Mice, Knockout,Microscopy, Fluorescence, Multiphoton,Microscopy, Fluorescence, Multiphoton: instrumentation,Molecular Imaging,Molecular Imaging: instrumentation},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs,HPL/SFE\_multispectral\_fluorescence},
    month = feb,
    number = {2},
    pages = {021103},
    pmid = {22463021},
    title = {{Targeted detection of murine colonic dysplasia in vivo with flexible multispectral scanning fiber endoscopy.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3380821\&tool=pmcentrez\&rendertype=abstract},
    volume = {17},
    year = {2012}
    }
  • [DOI] A. P. Reeves, E. J. Seibel, M. G. Meyer, T. Apanasovich, and A. Biancardi, “Nuclear cytoplasmic cell evaluation from 3D optical CT microscope images,” in Medical imaging 2012: computer-aided diagnosis, 2012, p. 83153C.
    [Bibtex]
    @inproceedings{Reeves2012,
    author = {Reeves, Anthony P. and Seibel, Eric J. and Meyer, Michael G. and Apanasovich, Tatiyana and Biancardi, Alberto},
    booktitle = {Medical Imaging 2012: Computer-Aided Diagnosis},
    doi = {10.1117/12.912399},
    editor = {van Ginneken, Bram and Novak, Carol L.},
    keywords = {cell structure,ct microscope,nuclear cytoplasmic ratio,optical topographical microscopy},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = feb,
    pages = {83153C},
    title = {{Nuclear cytoplasmic cell evaluation from 3D optical CT microscope images}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.912399},
    volume = {8315},
    year = {2012}
    }
  • [DOI] E. J. Seibel, J. a. Jo, D. C. Melville, R. S. Johnston, C. R. Naumann, and M. D. Saunders, “Image-guided intervention in the human bile duct using scanning fiber endoscope system,” in Optical fibers and sensors for medical diagnostics and treatment applications xii, 2012, p. 82180B.
    [Bibtex]
    @inproceedings{Seibel2012a,
    author = {Seibel, Eric J. and Jo, Javier a. and Melville, C. David and Johnston, Richard S. and Naumann, Christopher R. and Saunders, Michael D.},
    booktitle = {Optical FIbers and Sensors for Medical Diagnostics and Treatment Applications XII},
    doi = {10.1117/12.910070},
    keywords = {cholangioscope,flexible endoscope,fluorescence lifetime,image-guided biopsy,laser endoscopy,medical},
    mendeley-groups = {HPL/SFE\_small\_lumen\_imaging},
    month = feb,
    pages = {82180B},
    title = {{Image-guided intervention in the human bile duct using scanning fiber endoscope system}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.910070},
    volume = {8218},
    year = {2012}
    }
  • [DOI] E. J. Seibel, T. D. Soper, M. R. Burkhardt, M. P. Porter, and J. W. Yoon, “Multimodal flexible cystoscopy for creating co-registered panoramas of the bladder urothelium,” in Photonic therapeutics and diagnostics viii, 2012, p. 82071A–82071A–7.
    [Bibtex]
    @inproceedings{Seibel2012,
    author = {Seibel, Eric J. and Soper, Timothy D. and Burkhardt, Matthew R. and Porter, Michael P. and Yoon, W. Jong},
    booktitle = {Photonic Therapeutics and Diagnostics VIII},
    doi = {10.1117/12.909035},
    editor = {Kollias, Nikiforos and Choi, Bernard and Zeng, Haishan and Kang, Hyun Wook and Knudsen, Bodo E. and Wong, Brian Jet-Fei and Ilgner, Justus F. and Izdebski, Krzysztof and Suter, Melissa J. and Lam, Stephen and Brenner, Matthew and Gregory, Kenton W. and Tearney, Guillermo J. and Marcu, Laura and Hirschberg, Henry and Madsen, Steen and Mahadevan-Jansen, Anita and Jansen, E. Duco and Mandelis, Andreas},
    keywords = {biomarker,computer-aided diagnosis,cystoscope,diagnosis,early cancer detection,endoscopy,fluorescence,mosaic,photodynamic},
    mendeley-groups = {HPL,HPL/Bladder Scan},
    month = feb,
    pages = {82071A--82071A--7},
    title = {{Multimodal flexible cystoscopy for creating co-registered panoramas of the bladder urothelium}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=1344233},
    volume = {8207},
    year = {2012}
    }
  • [DOI] T. D. Soper, M. P. Porter, and E. J. Seibel, “Surface mosaics of the bladder reconstructed from endoscopic video for automated surveillance.,” Ieee transactions on bio-medical engineering, vol. 59, iss. 6, pp. 1670-80, 2012.
    [Bibtex]
    @article{Soper2012,
    abstract = {Flexible cystoscopy is frequently performed for recurrent bladder cancer surveillance, making it the most expensive cancer to treat over the patient's lifetime. An automated bladder surveillance system is being developed to robotically scan the bladder surface using an ultrathin and highly flexible endoscope. Such a system would allow cystoscopic procedures to be overseen by technical staff while urologists could review cystoscopic video postoperatively. In this paper, we demonstrate a method for reconstructing the surface of the whole bladder from endoscopic video using structure from motion. Video is acquired from a custom ultrathin and highly flexible endoscope that can retroflex to image the entire internal surface of the bladder. Selected frames are subsequently stitched into a mosaic and mapped to a reconstructed surface, creating a 3-D surface model of the bladder that can be expediently reviewed. Our software was tested on endoscopic video of an excised pig bladder. The resulting reconstruction possessed a projection error of 1.66 pixels on average and covered 99.6\% of the bladder surface area.},
    author = {Soper, Timothy D and Porter, Michael P and Seibel, Eric J},
    doi = {10.1109/TBME.2012.2191783},
    issn = {1558-2531},
    journal = {IEEE transactions on bio-medical engineering},
    keywords = {Algorithms,Animals,Cystoscopy,Cystoscopy: methods,Image Interpretation, Computer-Assisted,Image Interpretation, Computer-Assisted: methods,Pattern Recognition, Automated,Pattern Recognition, Automated: methods,Reproducibility of Results,Sensitivity and Specificity,Swine,Urinary Bladder,Urinary Bladder: cytology,Video Recording,Video Recording: methods},
    mendeley-groups = {HPL,HPL/Bladder Scan},
    month = jun,
    number = {6},
    pages = {1670--80},
    pmid = {22481800},
    title = {{Surface mosaics of the bladder reconstructed from endoscopic video for automated surveillance.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/22481800},
    volume = {59},
    year = {2012}
    }
  • [DOI] J. W. Yoon, M. a Brown, P. G. Reinhall, S. Park, and E. J. Seibel, “Design and preliminary study of custom laser scanning cystoscope for automated bladder surveillance.,” Minimally invasive therapy & allied technologies : mitat : official journal of the society for minimally invasive therapy, vol. 21, iss. 5, pp. 320-8, 2012.
    [Bibtex]
    @article{Yoon2012,
    author = {Yoon, W Jong and Brown, Matthew a and Reinhall, Per G and Park, Sangtae and Seibel, Eric J},
    doi = {10.3109/13645706.2011.653374},
    issn = {1365-2931},
    journal = {Minimally invasive therapy \& allied technologies : MITAT : official journal of the Society for Minimally Invasive Therapy},
    keywords = {Algorithms,Cystoscopy,Cystoscopy: methods,Humans,Image Processing, Computer-Assisted,Lasers,Lasers: diagnostic use,Research Design,Software,Time Factors,Urinary Bladder,Urinary Bladder Neoplasms,Urinary Bladder Neoplasms: diagnosis,Urinary Bladder Neoplasms: pathology,Urinary Bladder: pathology},
    mendeley-groups = {HPL,HPL/Bladder Scan},
    month = sep,
    number = {5},
    pages = {320--8},
    pmid = {22332891},
    title = {{Design and preliminary study of custom laser scanning cystoscope for automated bladder surveillance.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/22332891},
    volume = {21},
    year = {2012}
    }
  • [DOI] L. Zhang, L. Y. Nelson, J. H. Berg, J. M. Eichenholz, and E. J. Seibel, “Optical Measure of Enamel Health: Ability to Triage High Risk Children in Communities without Dental Practitioners,” 2012 ieee global humanitarian technology conference, pp. 345-349, 2012.
    [Bibtex]
    @article{Zhang2012,
    author = {Zhang, Liang and Nelson, Leonard Y. and Berg, Joel H. and Eichenholz, Jason M. and Seibel, Eric J.},
    doi = {10.1109/GHTC.2012.52},
    isbn = {978-1-4673-3016-9},
    journal = {2012 IEEE Global Humanitarian Technology Conference},
    keywords = {- autofluorescence,alert practitioners to the,and portable means to,autofluorescence,autofluorescence ratio,caries,effective,global disease,laser-induced fluorescence,laser-induced fluorescence spectroscopy,of early childhood caries,risk,spectroscopy,will help manage this},
    mendeley-groups = {HPL,HPL/SFE dental},
    month = oct,
    pages = {345--349},
    publisher = {Ieee},
    title = {{Optical Measure of Enamel Health: Ability to Triage High Risk Children in Communities without Dental Practitioners}},
    url = {http://ieeexplore.ieee.org/lpdocs/epic03/wrapper.htm?arnumber=6387074},
    year = {2012}
    }
  • [DOI] L. Zhang, L. Y. Nelson, and E. J. Seibel, “Spectrally enhanced imaging of occlusal surfaces and artificial shallow enamel erosions with a scanning fiber endoscope.,” Journal of biomedical optics, vol. 17, iss. 7, p. 76019, 2012.
    [Bibtex]
    @article{Zhang2012a,
    abstract = {An ultrathin scanning fiber endoscope, originally developed for cancer diagnosis, was used to image dental occlusal surfaces as well as shallow artificially induced enamel erosions from human extracted teeth (n=40). Enhanced image resolution of occlusal surfaces was obtained using a short-wavelength 405-nm illumination laser. In addition, artificial erosions of varying depths were also imaged with 405-, 404-, 532-, and 635-nm illumination lasers. Laser-induced autofluorescence images of the teeth using 405-nm illumination were also obtained. Contrast between sound and eroded enamel was quantitatively computed for each imaging modality. For shallow erosions, the image contrast with respect to sound enamel was greatest for the 405-nm reflected image. It was also determined that the increased contrast was in large part due to volume scattering with a smaller component from surface scattering. Furthermore, images obtained with a shallow penetration depth illumination laser (405 nm) provided the greatest detail of surface enamel topography since the reflected light does not contain contributions from light reflected from greater depths within the enamel tissue. Multilayered Monte Carlo simulations were also performed to confirm the experimental results.},
    author = {Zhang, Liang and Nelson, Leonard Y and Seibel, Eric J},
    doi = {10.1117/1.JBO.17.7.076019},
    issn = {1560-2281},
    journal = {Journal of biomedical optics},
    keywords = {Dental Enamel,Dental Enamel: pathology,Diagnosis, Oral,Diagnosis, Oral: instrumentation,Endoscopes,Equipment Design,Equipment Failure Analysis,Fiber Optic Technology,Fiber Optic Technology: instrumentation,Humans,Image Enhancement,Image Enhancement: instrumentation,Luminescent Measurements,Luminescent Measurements: instrumentation,Microscopy, Confocal,Microscopy, Confocal: instrumentation,Reproducibility of Results,Sensitivity and Specificity,Tooth Erosion,Tooth Erosion: pathology},
    mendeley-groups = {HPL,HPL/SFE dental},
    month = jul,
    number = {7},
    pages = {076019},
    pmid = {22894502},
    title = {{Spectrally enhanced imaging of occlusal surfaces and artificial shallow enamel erosions with a scanning fiber endoscope.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3602825\&tool=pmcentrez\&rendertype=abstract},
    volume = {17},
    year = {2012}
    }

2011

  • [DOI] M. A. B. Blank, M. Friedrich, J. D. Hamilton, P. Lee, J. Berg, and E. J. Seibel, “Laser Scanning Dental Probe for Endodontic Root Canal Treatment,” in Lasers in dentistry xvii, 2011, p. 788403–788403–7.
    [Bibtex]
    @inproceedings{Blank2011,
    author = {Blank, Molly A. B. and Friedrich, Michal and Hamilton, Jeffrey D. and Lee, Peggy and Berg, Joel and Seibel, Eric J.},
    booktitle = {Lasers in Dentistry XVII},
    doi = {10.1117/12.875274},
    editor = {Rechmann, Peter and Fried, Daniel},
    keywords = {cracks,endodontics,endoscope,imaging,laser scanning,root canal},
    mendeley-groups = {HPL,HPL/SFE dental},
    month = feb,
    pages = {788403--788403--7},
    title = {{Laser Scanning Dental Probe for Endodontic Root Canal Treatment}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=732326},
    volume = {7884},
    year = {2011}
    }
  • [DOI] J. E. Chandler, D. C. Melville, C. M. Lee, M. D. Saunders, M. R. Burkhardt, and E. J. Seibel, “Improving Patient and User Safety during Endoscopic Investigation of the Pancreatic and Biliary Ducts,” in Design and quality for biomedical technologies iv, 2011, p. 789103–789103–11.
    [Bibtex]
    @inproceedings{Chandler2011,
    author = {Chandler, John E. and Melville, C. David and Lee, Cameron M. and Saunders, Michael D. and Burkhardt, Matthew R. and Seibel, Eric J.},
    booktitle = {Design and Quality for Biomedical Technologies IV},
    doi = {10.1117/12.873326},
    editor = {Raghavachari, Ramesh and Liang, Rongguang},
    keywords = {bending,endoscopic retrograde cholangiopancreatography,endoscopic safety,ercp,fluoroscopy,pancreatitis,scanning fiber endoscope,tip},
    mendeley-groups = {HPL,HPL/SFE\_small\_lumen\_imaging},
    month = feb,
    pages = {789103--789103--11},
    title = {{Improving Patient and User Safety during Endoscopic Investigation of the Pancreatic and Biliary Ducts}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=732886},
    volume = {7891},
    year = {2011}
    }
  • J. E. Chandler, C. M. Lee, A. P. Babchanik, D. C. Melville, M. D. Saunders, and E. J. Seibel, “Evaluation of a novel , ultrathin , tip-bending endoscope in a synthetic force-sensing pancreas with comparison to medical guide wires,” Medical devices: evidence and research, vol. 5, pp. 1-12, 2011.
    [Bibtex]
    @article{Chandler2011a,
    author = {Chandler, John E and Lee, Cameron M and Babchanik, Alexander P and Melville, C David and Saunders, Michael D and Seibel, Eric J},
    journal = {Medical Devices: Evidence and Research},
    keywords = {endoscopic retrograde cholangiopancreatography,ercp,minimally invasive therapy,pancreatic cancer,scanning fiber endoscope,sfe},
    mendeley-groups = {HPL,HPL/SFE\_small\_lumen\_imaging},
    pages = {1--12},
    title = {{Evaluation of a novel , ultrathin , tip-bending endoscope in a synthetic force-sensing pancreas with comparison to medical guide wires}},
    volume = {5},
    year = {2011}
    }
  • [DOI] H. G. Hoffman, G. T. Chambers, W. J. Meyer, L. L. Arceneaux, W. J. Russell, E. J. Seibel, T. L. Richards, S. R. Sharar, and D. R. Patterson, “Virtual reality as an adjunctive non-pharmacologic analgesic for acute burn pain during medical procedures.,” Annals of behavioral medicine : a publication of the society of behavioral medicine, vol. 41, iss. 2, pp. 183-91, 2011.
    [Bibtex]
    @article{Hoffman2011,
    author = {Hoffman, Hunter G and Chambers, Gloria T and Meyer, Walter J and Arceneaux, Lisa L and Russell, William J and Seibel, Eric J and Richards, Todd L and Sharar, Sam R and Patterson, David R},
    doi = {10.1007/s12160-010-9248-7},
    issn = {1532-4796},
    journal = {Annals of behavioral medicine : a publication of the Society of Behavioral Medicine},
    keywords = {Analgesia,Analgesia: methods,Attention,Attention: physiology,Brain,Brain: physiopathology,Burns,Burns: complications,Burns: physiopathology,Burns: therapy,Humans,Magnetic Resonance Imaging,Pain,Pain Management,Pain: complications,User-Computer Interface},
    mendeley-groups = {HPL/VR\_Hunter\_Hoffman},
    month = apr,
    number = {2},
    pages = {183--91},
    pmid = {21264690},
    title = {{Virtual reality as an adjunctive non-pharmacologic analgesic for acute burn pain during medical procedures.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/21264690},
    volume = {41},
    year = {2011}
    }
  • [DOI] M. J. Kundrat, P. G. Reinhall, and E. J. Seibel, “Method to Achieve High Frame Rates in a Scanning Fiber Endoscope,” Journal of medical devices, vol. 5, iss. 3, p. 34501, 2011.
    [Bibtex]
    @article{Kundrat2011a,
    author = {Kundrat, Matthew J. and Reinhall, Per G. and Seibel, Eric J.},
    doi = {10.1115/1.4004646},
    issn = {19326181},
    journal = {Journal of Medical Devices},
    mendeley-groups = {HPL,HPL/fiber-scan-dynamics-control},
    number = {3},
    pages = {034501},
    title = {{Method to Achieve High Frame Rates in a Scanning Fiber Endoscope}},
    url = {http://medicaldevices.asmedigitalcollection.asme.org/article.aspx?articleid=1451905},
    volume = {5},
    year = {2011}
    }
  • [DOI] M. J. Kundrat, P. G. Reinhall, C. M. Lee, and E. J. Seibel, “High Performance Open Loop Control of Scanning with a Small Cylindrical Cantilever Beam.,” Journal of sound and vibration, vol. 330, iss. 8, pp. 1762-1771, 2011.
    [Bibtex]
    @article{Kundrat2011,
    abstract = {The steady state response motion of a base excited cantilever beam with circular cross-section excited by a unidirectional displacement will fall along a straight line. However, achieving straight-line motion with a real cantilever beam of circular cross-section is difficult to accomplish. This is due to the fact that nonlinear effects, small deviations from circularity, asymmetric boundary conditions, and actuator cross coupling can induce whirling. The vast majority of previous work on cantilever beam whirling has focused on the effects of system nonlinearities. We show that whirling is a much broader problem in the design of resonant beam scanners in that the onset of whirling does not depend on large amplitude of motion. Rather, whirling is the norm in real systems due to small system asymmetries and actuator cross coupling. It is therefore necessary to control the growth of the whirling motion when a unidirectional beam motion is desired. We have developed a novel technique to identify the two eigen directions of the beam. Base excitation generated by virtual electrodes along these orthogonal eigen axes of the cantilever beam system generates tip vibration without whirl. This leads to accurate open loop control of the motion of the beam through the combined actuation of two pairs of orthogonally placed actuator electrodes.},
    author = {Kundrat, Matthew J and Reinhall, Per G and Lee, Cameron M and Seibel, Eric J},
    doi = {10.1016/j.jsv.2010.10.019},
    issn = {0022-460X},
    journal = {Journal of sound and vibration},
    mendeley-groups = {HPL,HPL/fiber-scan-dynamics-control},
    month = apr,
    number = {8},
    pages = {1762--1771},
    pmid = {21359102},
    publisher = {Elsevier},
    title = {{High Performance Open Loop Control of Scanning with a Small Cylindrical Cantilever Beam.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3045204\&tool=pmcentrez\&rendertype=abstract},
    volume = {330},
    year = {2011}
    }
  • [DOI] C. V. Maani, H. G. Hoffman, M. Morrow, A. Maiers, K. Gaylord, L. L. McGhee, and P. a DeSocio, “Virtual reality pain control during burn wound debridement of combat-related burn injuries using robot-like arm mounted VR goggles.,” The journal of trauma, vol. 71, iss. 1 Suppl, p. S125–30, 2011.
    [Bibtex]
    @article{Maani2011,
    author = {Maani, Christopher V and Hoffman, Hunter G and Morrow, Michelle and Maiers, Alan and Gaylord, Kathryn and McGhee, Laura L and DeSocio, Peter a},
    doi = {10.1097/TA.0b013e31822192e2},
    issn = {1529-8809},
    journal = {The Journal of trauma},
    keywords = {Adult,Afghan Campaign 2001-,Burns,Burns: surgery,Debridement,Debridement: methods,Eyeglasses,Humans,Iraq War, 2003-2011,Male,Military Personnel,Pain Management,Pain Measurement,Robotics,User-Computer Interface,Young Adult},
    mendeley-groups = {HPL/VR\_Hunter\_Hoffman},
    month = jul,
    number = {1 Suppl},
    pages = {S125--30},
    pmid = {21795888},
    title = {{Virtual reality pain control during burn wound debridement of combat-related burn injuries using robot-like arm mounted VR goggles.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/21795888},
    volume = {71},
    year = {2011}
    }
  • [DOI] Q. Miao, J. Hayenga, M. G. Meyer, T. Neumann, F. Patten, A. C. Nelson, and E. J. Seibel, “High resolution optical projection tomographic microscopy for 3D tissue imaging,” in Three-dimensional and multidimensional microscopy: image acquisition and processing xviii, 2011, p. 79040L–79040L–5.
    [Bibtex]
    @inproceedings{Miao2011,
    author = {Miao, Qin and Hayenga, Jon and Meyer, Michael G. and Neumann, Thomas and Patten, Florence and Nelson, Alan C. and Seibel, Eric J.},
    booktitle = {Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XVIII},
    doi = {10.1117/12.873485},
    editor = {Conchello, Jose-Angel and Cogswell, Carol J. and Wilson, Tony and Brown, Thomas G.},
    keywords = {needle biopsy,three-dimensional microscopy,tissue imaging,tomographic imaging},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = feb,
    pages = {79040L--79040L--5},
    title = {{High resolution optical projection tomographic microscopy for 3D tissue imaging}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=719108},
    volume = {7904},
    year = {2011}
    }
  • [DOI] T. D. Soper, J. E. Chandler, M. P. Porter, and E. J. Seibel, “Constructing spherical panoramas of a bladder phantom from endoscopic video using bundle adjustment,” in Medical imaging 2011: visualization, image-guided procedures, and modeling, 2011, p. 796417–796417–12.
    [Bibtex]
    @inproceedings{Soper2011,
    author = {Soper, Timothy D. and Chandler, John E. and Porter, Michael P. and Seibel, Eric J.},
    booktitle = {Medical Imaging 2011: Visualization, Image-Guided Procedures, and Modeling},
    doi = {10.1117/12.878299},
    editor = {Wong, Kenneth H. and {Holmes III}, David R.},
    keywords = {bladder,bundle adjustment,cystoscopy,endoscopy,feature,mosaic,stitching,structure from motion},
    mendeley-groups = {HPL,HPL/Bladder Scan},
    month = mar,
    pages = {796417--796417--12},
    title = {{Constructing spherical panoramas of a bladder phantom from endoscopic video using bundle adjustment}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=726114},
    volume = {7964},
    year = {2011}
    }
  • [DOI] L. Zhang, L. Y. Nelson, and E. J. Seibel, “Red-shifted fluorescence of sound dental hard tissue.,” Journal of biomedical optics, vol. 16, iss. 7, p. 71411, 2011.
    [Bibtex]
    @article{Zhang2011,
    abstract = {Autofluorescence spectra were recorded in vitro from dentin, enamel, and whole teeth. The spectra exhibited a broad peak shifted by about 50 to 75 nm from the excitation wavelength and the shape of the spectra remained similar regardless of the excitation wavelength. The maximum of the autofluorescence spectra also exhibited a red-shift that depended upon the laser excitation wavelength. The amplitude of the red-shifted fluorescence spectra produced by 444 and 532 nm excitation lasers were compared to that produced by a 405 nm excitation laser. It was determined that the autofluorescence amplitude was not proportional to the inverse fourth power of the excitation laser wavelength. Therefore, the red-shifted fluorescence is not compatible with the previously proposed mechanism of Raman scattering. Instead, the mechanism giving rise to the laser-induced dental autofluorescence is explained by the red-edge-excitation effect.},
    author = {Zhang, Liang and Nelson, Leonard Y and Seibel, Eric J},
    doi = {10.1117/1.3606572},
    issn = {1560-2281},
    journal = {Journal of biomedical optics},
    keywords = {Dental Enamel,Dental Enamel: chemistry,Dentin,Dentin: chemistry,Fluorescence,Humans,Lasers,Lasers: diagnostic use,Scattering, Radiation,Spectrometry, Fluorescence,Spectrometry, Fluorescence: methods,Spectrometry, Fluorescence: statistics \& numerical data,Spectrum Analysis, Raman,Tooth,Tooth: chemistry},
    mendeley-groups = {HPL,HPL/SFE dental},
    month = jul,
    number = {7},
    pages = {071411},
    pmid = {21806257},
    title = {{Red-shifted fluorescence of sound dental hard tissue.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/21806257},
    volume = {16},
    year = {2011}
    }
  • B. G. Saar, R. S. Johnston, C. W. Freudiger, S. X. Xie, and E. J. Seibel, “Coherent Raman scanning fiber endoscopy.,” Optics letters, vol. 36, iss. 13, pp. 2396-8, 2011.
    [Bibtex]
    @article{Saar2011,
    abstract = {Coherent Raman scattering methods allow for label-free imaging of tissue with chemical contrast and high spatial and temporal resolution. However, their imaging depth in scattering tissue is limited to less than 1 mm, requiring the development of endoscopes to obtain images deep inside the body. Here, we describe a coherent Raman endoscope that provides stimulated Raman scattering images at seven frames per second using a miniaturized fiber scanner, a custom-designed objective lens, and an optimized scheme for collection of scattered light from the tissue. We characterize the system and demonstrate chemical selectivity in mouse tissue images.},
    author = {Saar, Brian G and Johnston, Richard S and Freudiger, Christian W and Xie, X Sunney and Seibel, Eric J},
    issn = {1539-4794},
    journal = {Optics letters},
    keywords = {Animals,Endoscopy,Endoscopy: methods,Mice,Skin,Spectrum Analysis, Raman,Spectrum Analysis, Raman: methods},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs},
    month = jul,
    number = {13},
    pages = {2396--8},
    pmid = {21725423},
    title = {{Coherent Raman scanning fiber endoscopy.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3164497\&tool=pmcentrez\&rendertype=abstract},
    volume = {36},
    year = {2011}
    }

2010

  • H. G. Hoffman, B. T. Schowengerdt, C. M. Lee, J. Magula, and E. J. Seibel, “64 . 1 : Display Technologies for Therapeutic Applications of Virtual Reality,” in Sid symposium digest of technical papers, 2010, pp. 949-952.
    [Bibtex]
    @inproceedings{Hoffman2010,
    author = {Hoffman, Hunter G and Schowengerdt, Brian T and Lee, Cameron M and Magula, Jeff and Seibel, Eric J},
    booktitle = {SID Symposium Digest of Technical Papers},
    mendeley-groups = {HPL,HPL/Display},
    pages = {949--952},
    title = {{64 . 1 : Display Technologies for Therapeutic Applications of Virtual Reality}},
    year = {2010}
    }
  • [DOI] C. M. Lee, C. J. Engelbrecht, T. D. Soper, F. Helmchen, and E. J. Seibel, “Scanning fiber endoscopy with highly flexible, 1 mm catheterscopes for wide-field, full-color imaging.,” Journal of biophotonics, vol. 3, iss. 5-6, pp. 385-407, 2010.
    [Bibtex]
    @article{Lee2010,
    abstract = {In modern endoscopy, wide field of view and full color are considered necessary for navigating inside the body, inspecting tissue for disease and guiding interventions such as biopsy or surgery. Current flexible endoscope technologies suffer from reduced resolution when device diameter shrinks. Endoscopic procedures today, using coherent fiber-bundle technology on the scale of 1 mm, are performed with such poor image quality that the clinician's vision meets the criteria for legal blindness. Here, we review a new and versatile scanning fiber-imaging technology and describe its implementation for ultrathin and flexible endoscopy. This scanning fiber endoscope (SFE) or catheterscope enables high-quality, laser-based, video imaging for ultrathin clinical applications, while also providing new options for in vivo biological research of subsurface tissue and high resolution fluorescence imaging.},
    author = {Lee, Cameron M and Engelbrecht, Christoph J and Soper, Timothy D and Helmchen, Fritjof and Seibel, Eric J},
    doi = {10.1002/jbio.200900087},
    issn = {1864-0648},
    journal = {Journal of biophotonics},
    keywords = {Animals,Catheterization,Color,Elasticity,Endoscopes,Humans},
    mendeley-groups = {HPL,HPL/SFE\_Review\_Articles},
    month = jun,
    number = {5-6},
    pages = {385--407},
    pmid = {20336702},
    title = {{Scanning fiber endoscopy with highly flexible, 1 mm catheterscopes for wide-field, full-color imaging.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=3163080\&tool=pmcentrez\&rendertype=abstract},
    volume = {3},
    year = {2010}
    }
  • Q. Miao, J. Hayenga, M. G. Meyer, T. Neumann, A. C. Nelson, and E. J. Seibel, “Resolution improvement in optical projection tomography by the focal scanning method.,” Optics letters, vol. 35, iss. 20, pp. 3363-5, 2010.
    [Bibtex]
    @article{Miao2010a,
    abstract = {Optical projection tomography (OPT) requires the depth of field (DOF) of the lens to cover at least half of the sample. There is a trade-off between obtaining high resolution with a high-NA lens and obtaining large DOF with a low-NA lens. The DOF of a high-NA objective lens can be extended by scanning its focal plane through the sample. We call this extended DOF image a "pseudoprojection." Images reconstructed from these pseudoprojections have isometric resolution, which can be the same as the lateral resolution of the high-NA objective. The focal scanning method produces an over 10× improvement in OPT resolution.},
    author = {Miao, Qin and Hayenga, Jon and Meyer, Michael G and Neumann, Thomas and Nelson, Alan C and Seibel, Eric J},
    issn = {1539-4794},
    journal = {Optics letters},
    keywords = {Algorithms,Animals,Cell Line,Cytological Techniques,Cytological Techniques: methods,Image Processing, Computer-Assisted,Image Processing, Computer-Assisted: methods,Imaging, Three-Dimensional,Imaging, Three-Dimensional: methods,Microscopy, Fluorescence,Microscopy, Fluorescence: methods,Muntjacs,Staining and Labeling,Tomography, Optical,Tomography, Optical: methods},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = oct,
    number = {20},
    pages = {3363--5},
    pmid = {20967067},
    title = {{Resolution improvement in optical projection tomography by the focal scanning method.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/20967067},
    volume = {35},
    year = {2010}
    }
  • [DOI] Q. Miao, J. Yu, M. G. Meyer, J. R. Rahn, T. Neumann, A. C. Nelson, and E. J. Seibel, “Dual-modal optical projection tomography microscopy for cancer diagnosis,” in Three-dimensional and multidimensional microscopy: image acquisition and processing xvii, 2010, p. 75700H–75700H–7.
    [Bibtex]
    @inproceedings{Miao2010,
    author = {Miao, Qin and Yu, Julia and Meyer, Michael G. and Rahn, J. R. and Neumann, Thomas and Nelson, Alan C. and Seibel, Eric J.},
    booktitle = {Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XVII},
    doi = {10.1117/12.839824},
    editor = {Conchello, Jose-Angel and Cogswell, Carol J. and Wilson, Tony and Brown, Thomas G.},
    keywords = {coregistration,fluorescence biomarker imaging,three-dimensional microscopy,tomographic imaging},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = feb,
    pages = {75700H--75700H--7},
    title = {{Dual-modal optical projection tomography microscopy for cancer diagnosis}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=780888},
    volume = {7570},
    year = {2010}
    }
  • Q. Miao, J. Yu, R. J. Rahn, M. G. Meyer, T. Neumann, A. C. Nelson, and E. J. Seibel, “Dual-mode optical projection tomography microscope using gold nanorods and hematoxylin-stained cancer cells.,” Optics letters, vol. 35, iss. 7, pp. 1037-9, 2010.
    [Bibtex]
    @article{Miao2010b,
    abstract = {An optical projection tomography microscope (OPTM) can improve axial resolution by viewing a sample from different perspectives. Here, we report a dual-mode OPTM that can generate 3D images of single cancer cells in both absorption mode and polarization mode. Cancer cells were labeled with hematoxylin for absorption imaging and nanorods for polarization imaging. Absorption images can provide morphologic information, and polarization images can provide molecular information. The combination of molecular detection and 3D cytological cell analysis may help with early cancer diagnosis.},
    author = {Miao, Qin and Yu, Julia and Rahn, J Richard and Meyer, Michael G and Neumann, Thomas and Nelson, Alan C and Seibel, Eric J},
    issn = {1539-4794},
    journal = {Optics letters},
    keywords = {Cell Line, Tumor,Contrast Media,Equipment Design,Equipment Failure Analysis,Gold,Gold: diagnostic use,Hematoxylin,Humans,Image Enhancement,Image Enhancement: instrumentation,Image Enhancement: methods,Lung Neoplasms,Lung Neoplasms: pathology,Microscopy,Microscopy: instrumentation,Nanostructures,Nanostructures: diagnostic use,Nanostructures: ultrastructure,Reproducibility of Results,Sensitivity and Specificity,Tomography,Tomography: instrumentation},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = apr,
    number = {7},
    pages = {1037--9},
    pmid = {20364209},
    title = {{Dual-mode optical projection tomography microscope using gold nanorods and hematoxylin-stained cancer cells.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/20364209},
    volume = {35},
    year = {2010}
    }
  • B. T. Schowengerdt, H. G. Hoffman, C. M. Lee, D. C. Melville, and E. J. Seibel, “57 . 1 : Near-to-Eye Display using Scanning Fiber Display Engine Abstract :,” in Sid symposium digest of technical papers, 2010, pp. 848-851.
    [Bibtex]
    @inproceedings{Schowengerdt2010b,
    author = {Schowengerdt, Brian T and Hoffman, Hunter G and Lee, Cameron M and Melville, C David and Seibel, Eric J},
    booktitle = {SID Symposium Digest of Technical Papers},
    mendeley-groups = {HPL,HPL/Display},
    pages = {848--851},
    title = {{57 . 1 : Near-to-Eye Display using Scanning Fiber Display Engine Abstract :}},
    year = {2010}
    }
  • B. T. Schowengerdt, R. S. Johnston, C. M. Lee, D. C. Melville, and E. J. Seibel, “1 mm x 7 mm Full-Color Pico Projector using Scanning Optical Fiber,” in Ite and sid, 2010, pp. 1447-1450.
    [Bibtex]
    @inproceedings{Schowengerdt2010a,
    author = {Schowengerdt, Brian T and Johnston, Richard S and Lee, Cameron M and Melville, C David and Seibel, Eric J},
    booktitle = {ITE and SID},
    mendeley-groups = {HPL,HPL/Display},
    pages = {1447--1450},
    title = {{1 mm x 7 mm Full-Color Pico Projector using Scanning Optical Fiber}},
    year = {2010}
    }
  • B. T. Schowengerdt, M. Murari, and E. J. Seibel, “44 . 1 : Volumetric Display using Scanned Fiber Array Abstract :,” in Sid symposium digest of technical papers, 2010, pp. 653-656.
    [Bibtex]
    @inproceedings{Schowengerdt2010c,
    author = {Schowengerdt, Brian T and Murari, Mrinal and Seibel, Eric J},
    booktitle = {SID Symposium Digest of Technical Papers},
    mendeley-groups = {HPL,HPL/Display},
    pages = {653--656},
    title = {{44 . 1 : Volumetric Display using Scanned Fiber Array Abstract :}},
    year = {2010}
    }
  • B. T. Schowengerdt and E. J. Seibel, “3D Volumetric Scanned Light Display with Multiple Fiber Optic Light Sources,” in Ite and sid, 2010, pp. 1257-1260.
    [Bibtex]
    @inproceedings{Schowengerdt2010,
    author = {Schowengerdt, Brian T and Seibel, Eric J},
    booktitle = {ITE and SID},
    mendeley-groups = {HPL,HPL/Display},
    pages = {1257--1260},
    title = {{3D Volumetric Scanned Light Display with Multiple Fiber Optic Light Sources}},
    year = {2010}
    }
  • E. J. Seibel, “Side-stepping the valley of death in New York City,” Ieee potentials, pp. 14-18, 2010.
    [Bibtex]
    @article{Seibel2010,
    author = {Seibel, Eric J},
    journal = {IEEE Potentials},
    mendeley-groups = {HPL/TCE},
    pages = {14--18},
    title = {{Side-stepping the valley of death in New York City}},
    year = {2010}
    }
  • [DOI] T. D. Soper, D. R. Haynor, R. W. Glenny, and E. J. Seibel, “In vivo validation of a hybrid tracking system for navigation of an ultrathin bronchoscope within peripheral airways.,” Ieee transactions on bio-medical engineering, vol. 57, iss. 3, pp. 736-45, 2010.
    [Bibtex]
    @article{Soper2010,
    abstract = {Transbronchial biopsy of peripheral lung nodules is hindered by the inability to access lesions endoluminally due to the large diameter of conventional bronchoscopes. An ultrathin scanning fiber bronchoscope has recently been developed to advance image-guided biopsy several branching generations deeper into the peripheral airways. However, navigating a potentially complex 3-D path to the region of interest presents a challenge to the bronchoscopist. An accompanying guidance system has also been developed to track the bronchoscope through the airways, and display its position and intended path on a virtual display. Intraoperative localization of the bronchoscope was achieved by combining electromagnetic tracking (EMT) and image-based tracking (IBT). An error-state Kalman filter was used to model the disagreement between the two tracking sources. The positional tracking error was reduced from 14.22 and 14.92 mm by independent EMT and IBT, respectively, to 6.74 mm using the hybrid approach. Hybrid tracking of the scope orientation and respiratory motion compensation further improved tracking accuracy and stability, resulting in an average tracking error of 3.33 mm and 10.01 degrees.},
    author = {Soper, Timothy D and Haynor, David R and Glenny, Robb W and Seibel, Eric J},
    doi = {10.1109/TBME.2009.2034733},
    issn = {1558-2531},
    journal = {IEEE transactions on bio-medical engineering},
    keywords = {Animals,Biopsy,Biopsy: methods,Bronchi,Bronchi: anatomy \& histology,Bronchoscopes,Bronchoscopy,Bronchoscopy: methods,Humans,Image Processing, Computer-Assisted,Image Processing, Computer-Assisted: methods,Lung Neoplasms,Lung Neoplasms: pathology,Lung Neoplasms: surgery,Reproducibility of Results,Surgery, Computer-Assisted,Surgery, Computer-Assisted: methods,Swine},
    mendeley-groups = {HPL,HPL/Navigating\_SFE\_bronchoscope},
    month = mar,
    number = {3},
    pages = {736--45},
    pmid = {19846362},
    title = {{In vivo validation of a hybrid tracking system for navigation of an ultrathin bronchoscope within peripheral airways.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/19846362},
    volume = {57},
    year = {2010}
    }

2009

  • [DOI] M. G. Meyer, M. Fauver, R. J. Rahn, T. Neumann, F. W. Patten, E. J. Seibel, and A. C. Nelson, “Automated cell analysis in 2D and 3D: A comparative study,” Pattern recognition, vol. 42, iss. 1, pp. 141-146, 2009.
    [Bibtex]
    @article{Meyer2009,
    author = {Meyer, Michael G. and Fauver, Mark and Rahn, J. Richard and Neumann, Thomas and Patten, Florence W. and Seibel, Eric J. and Nelson, Alan C.},
    doi = {10.1016/j.patcog.2008.06.018},
    issn = {00313203},
    journal = {Pattern Recognition},
    keywords = {automated classification},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = jan,
    number = {1},
    pages = {141--146},
    title = {{Automated cell analysis in 2D and 3D: A comparative study}},
    url = {http://linkinghub.elsevier.com/retrieve/pii/S0031320308002495},
    volume = {42},
    year = {2009}
    }
  • [DOI] Q. Miao, B. Hawthorne, M. Meyer, R. J. Rahn, T. Neumann, A. C. Nelson, and E. J. Seibel, “Dual Modal Three-Dimensional Imaging of Single Cell Using Optical Projection Tomography Microscope,” Advances in imaging, p. NWA2, 2009.
    [Bibtex]
    @article{Miao2009a,
    address = {Washington, D.C.},
    author = {Miao, Qin and Hawthorne, Benjamin and Meyer, Michael and Rahn, J. Richard. and Neumann, Thomas and Nelson, Alan C. and Seibel, Eric J.},
    doi = {10.1364/NTM.2009.NWA2},
    isbn = {978-1-55752-871-1},
    journal = {Advances in Imaging},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    pages = {NWA2},
    publisher = {Osa},
    title = {{Dual Modal Three-Dimensional Imaging of Single Cell Using Optical Projection Tomography Microscope}},
    url = {http://www.opticsinfobase.org/abstract.cfm?URI=NTM-2009-NWA2},
    year = {2009}
    }
  • [DOI] Q. Miao, R. J. Rahn, A. Tourovskaia, M. G. Meyer, T. Neumann, A. C. Nelson, and E. J. Seibel, “Dual-modal three-dimensional imaging of single cells with isometric high resolution using an optical projection tomography microscope.,” Journal of biomedical optics, vol. 14, iss. 6, p. 64035, 2009.
    [Bibtex]
    @article{Miao2009b,
    abstract = {The practice of clinical cytology relies on bright-field microscopy using absorption dyes like hematoxylin and eosin in the transmission mode, while the practice of research microscopy relies on fluorescence microscopy in the epi-illumination mode. The optical projection tomography microscope is an optical microscope that can generate 3-D images of single cells with isometric high resolution both in absorption and fluorescence mode. Although the depth of field of the microscope objective is in the submicron range, it can be extended by scanning the objective's focal plane. The extended depth of field image is similar to a projection in a conventional x-ray computed tomography. Cells suspended in optical gel flow through a custom-designed microcapillary. Multiple pseudoprojection images are taken by rotating the microcapillary. After these pseudoprojection images are further aligned, computed tomography methods are applied to create 3-D reconstruction. 3-D reconstructed images of single cells are shown in both absorption and fluorescence mode. Fluorescence spatial resolution is measured at 0.35 microm in both axial and lateral dimensions. Since fluorescence and absorption images are taken in two different rotations, mechanical error may cause misalignment of 3-D images. This mechanical error is estimated to be within the resolution of the system.},
    author = {Miao, Qin and Rahn, J Richard and Tourovskaia, Anna and Meyer, Michael G and Neumann, Thomas and Nelson, Alan C and Seibel, Eric J},
    doi = {10.1117/1.3275470},
    issn = {1560-2281},
    journal = {Journal of biomedical optics},
    keywords = {Animals,Cell Line,Cytological Techniques,Cytological Techniques: methods,Female,Image Processing, Computer-Assisted,Image Processing, Computer-Assisted: methods,Imaging, Three-Dimensional,Imaging, Three-Dimensional: methods,Metaphase,Metaphase: physiology,Microscopy, Fluorescence,Microscopy, Fluorescence: methods,Muntjacs,Staining and Labeling,Staining and Labeling: methods,Tomography, Optical,Tomography, Optical: methods},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    number = {6},
    pages = {064035},
    pmid = {20059273},
    title = {{Dual-modal three-dimensional imaging of single cells with isometric high resolution using an optical projection tomography microscope.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/20059273},
    volume = {14},
    year = {2009}
    }
  • [DOI] Q. Miao, R. J. Rahn, R. C. Bryant, C. a. Lancaster, A. Tourovskaia, T. Neumann, E. J. Seibel, and A. C. Nelson, “Multimodal Three-dimensional Imaging with Isometric High Resolution using Optical Projection Tomography,” in Medical imaging 2009: biomedical applications in molecular, structural, and functional imaging, 2009, p. 72620V–72620V–8.
    [Bibtex]
    @inproceedings{Miao2009,
    author = {Miao, Qin and Rahn, J. Richard and Bryant, Ryland C. and Lancaster, Christy a. and Tourovskaia, Anna and Neumann, Thomas and Seibel, Eric J. and Nelson, Alan C.},
    booktitle = {Medical Imaging 2009: Biomedical Applications in Molecular, Structural, and Functional Imaging},
    doi = {10.1117/12.813844},
    editor = {Hu, Xiaoping P. and Clough, Anne V.},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = feb,
    pages = {72620V--72620V--8},
    title = {{Multimodal Three-dimensional Imaging with Isometric High Resolution using Optical Projection Tomography}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=815700},
    volume = {7262},
    year = {2009}
    }
  • B. T. Schowengerdt, C. M. Lee, R. S. Johnston, D. C. Melville, and E. J. Seibel, “37 . 1 : Invited Paper : 1-mm Diameter , Full-color Scanning Fiber Pico Projector Scanning Fiber Pico Projector,” in Sid symposium digest of technical papers, 2009, pp. 522-525.
    [Bibtex]
    @inproceedings{Schowengerdt2009,
    author = {Schowengerdt, Brian T and Lee, Cameron M and Johnston, Richard S and Melville, C David and Seibel, Eric J},
    booktitle = {SID Symposium Digest of Technical Papers},
    mendeley-groups = {HPL,HPL/Display},
    pages = {522--525},
    title = {{37 . 1 : Invited Paper : 1-mm Diameter , Full-color Scanning Fiber Pico Projector Scanning Fiber Pico Projector}},
    year = {2009}
    }
  • B. T. Schowengerdt, C. M. Lee, R. S. Johnston, D. C. Melville, and E. J. Seibel, “Angle in a Scanning Fiber Pico Projector,” in Sid symposium digest of technical papers, 2009, pp. 1783-1786.
    [Bibtex]
    @inproceedings{Schowengerdt2009a,
    author = {Schowengerdt, Brian T and Lee, Cameron M and Johnston, Richard S and Melville, C David and Seibel, Eric J},
    booktitle = {SID Symposium Digest of Technical Papers},
    mendeley-groups = {HPL,HPL/Display},
    pages = {1783--1786},
    title = {{Angle in a Scanning Fiber Pico Projector}},
    year = {2009}
    }
  • [DOI] E. J. Seibel, D. C. Melville, J. K. C. Lung, A. P. Babchanik, C. M. Lee, R. S. Johnston, and J. a. Dominitz, “Swallowable Capsule with Air Channel for Improved Image-Guided Cancer Detection in the Esophagus,” in Medical imaging 2009: visualization, image-guided procedures, and modeling, 2009, p. 72611C–72611C–7.
    [Bibtex]
    @inproceedings{Seibel2009a,
    author = {Seibel, Eric J. and Melville, C. David and Lung, Jonathan K. C. and Babchanik, Alexander P. and Lee, Cameron M. and Johnston, Richard S. and Dominitz, Jason a.},
    booktitle = {Medical Imaging 2009: Visualization, Image-Guided Procedures, and Modeling},
    doi = {10.1117/12.812320},
    editor = {Miga, Michael I. and Wong, Kenneth H.},
    keywords = {7261,72611c,and modeling,barrett,cancer screening,edited by michael i,endoscopic procedures,esophageal sphincter,gastroesophageal junction,image-guided procedures,kenneth h,lower,medical imaging 2009,miga,of spie vol,proc,s esophagus,tethered-capsule endoscope,unsedated intervention,visualization,wong},
    mendeley-groups = {HPL/TCE},
    month = feb,
    pages = {72611C--72611C--7},
    title = {{Swallowable Capsule with Air Channel for Improved Image-Guided Cancer Detection in the Esophagus}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=1335722},
    volume = {7261},
    year = {2009}
    }
  • [DOI] E. J. Seibel, T. a Brentnall, and J. a Dominitz, “New endoscopic and cytologic tools for cancer surveillance in the digestive tract.,” Gastrointestinal endoscopy clinics of north america, vol. 19, iss. 2, pp. 299-307, 2009.
    [Bibtex]
    @article{Seibel2009,
    abstract = {Cancer surveillance is an increasing part of everyday practice in gastrointestinal Endoscopy due to the identification of high-risk groups from genetic and biomarker testing, genealogic and epidemiologic studies, and the increasing number of cancer survivors. An efficient surveillance program requires a cost-effective means for image-guided cancer detection and biopsy. A laser-based tethered-capsule endoscope with enhanced spectral imaging is introduced for unsedated surveillance of the lower esophagus. An ultrathin version of this same endoscope technology provides a 1.2-mm guidewire with imaging capability and cannula-style tools are proposed for image-guided biopsy. Advanced three-dimensional cell visualization techniques are described for increasing the sensitivity of early cancer diagnosis from hematoxylin-stained cells sampled from the pancreatic and biliary ducts.},
    author = {Seibel, Eric J and Brentnall, Teresa a and Dominitz, Jason a},
    doi = {10.1016/j.giec.2009.02.002},
    issn = {1558-1950},
    journal = {Gastrointestinal endoscopy clinics of North America},
    keywords = {Bile Duct Neoplasms,Bile Duct Neoplasms: diagnosis,Bile Duct Neoplasms: pathology,Bile Duct Neoplasms: prevention \& control,Capsule Endoscopy,Cost-Benefit Analysis,Endoscopy, Gastrointestinal,Endoscopy, Gastrointestinal: economics,Endoscopy, Gastrointestinal: methods,Endoscopy, Gastrointestinal: standards,Fiber Optic Technology,Gastrointestinal Neoplasms,Gastrointestinal Neoplasms: diagnosis,Gastrointestinal Neoplasms: pathology,Gastrointestinal Neoplasms: prevention \& control,Humans,Image Interpretation, Computer-Assisted,Imaging, Three-Dimensional,Intestinal Mucosa,Intestinal Mucosa: cytology,Intestinal Mucosa: pathology,Mass Screening,Mass Screening: economics,Mass Screening: instrumentation,Mass Screening: methods,Pancreatic Neoplasms,Pancreatic Neoplasms: diagnosis,Pancreatic Neoplasms: pathology,Pancreatic Neoplasms: prevention \& control,Precancerous Conditions,Precancerous Conditions: diagnosis,Precancerous Conditions: pathology,Sensitivity and Specificity,Sentinel Surveillance},
    mendeley-groups = {HPL,HPL/SFE\_Review\_Articles},
    month = apr,
    number = {2},
    pages = {299--307},
    pmid = {19423026},
    title = {{New endoscopic and cytologic tools for cancer surveillance in the digestive tract.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2679952\&tool=pmcentrez\&rendertype=abstract},
    volume = {19},
    year = {2009}
    }
  • [DOI] T. D. Soper, D. R. Haynor, R. W. Glenny, and E. J. Seibel, “Validation of CT-Video Registration for Guiding a Novel Ultrathin Bronchoscope to Peripheral Lung Nodules Using Electromagnetic Tracking,” in Medical imaging 2009: visualization, image-guided procedures, and modeling, 2009, p. 72610C–72610C–13.
    [Bibtex]
    @inproceedings{Soper2009,
    author = {Soper, Timothy D. and Haynor, David R. and Glenny, Robb W. and Seibel, Eric J.},
    booktitle = {Medical Imaging 2009: Visualization, Image-Guided Procedures, and Modeling},
    doi = {10.1117/12.812329},
    editor = {Miga, Michael I. and Wong, Kenneth H.},
    mendeley-groups = {HPL,HPL/Navigating\_SFE\_bronchoscope},
    month = feb,
    pages = {72610C--72610C--13},
    title = {{Validation of CT-Video Registration for Guiding a Novel Ultrathin Bronchoscope to Peripheral Lung Nodules Using Electromagnetic Tracking}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=815263},
    volume = {7261},
    year = {2009}
    }
  • [DOI] J. W. Yoon, S. Park, P. G. Reinhall, and E. J. Seibel, “Development of an Automated Steering Mechanism for Bladder Urothelium Surveillance,” Journal of medical devices, vol. 3, iss. 1, p. 11004, 2009.
    [Bibtex]
    @article{Yoon2009,
    author = {Yoon, W. Jong and Park, Sangtae and Reinhall, Per G. and Seibel, Eric J.},
    doi = {10.1115/1.3054381},
    issn = {19326181},
    journal = {Journal of Medical Devices},
    keywords = {active,bladder surveillance,optimal path,programmable remote steering,segmented actuators,shape memory alloy},
    mendeley-groups = {HPL,HPL/Bladder Scan},
    number = {1},
    pages = {011004},
    title = {{Development of an Automated Steering Mechanism for Bladder Urothelium Surveillance}},
    url = {http://medicaldevices.asmedigitalcollection.asme.org/article.aspx?articleid=1473876},
    volume = {3},
    year = {2009}
    }

2008

  • [DOI] T. Neumann, Q. Miao, J. Yu, M. Fauver, M. Meyer, R. J. Rahn, C. a Lancaster, E. J. Seibel, and A. C. Nelson, “Simultaneous 3D imaging of morphology and nanoparticle distribution in single cells with the Cell-CT technology.,” in Conference proceedings : annual international conference of the ieee engineering in medicine and biology society. ieee engineering in medicine and biology society. annual conference, 2008, pp. 379-81.
    [Bibtex]
    @inproceedings{Neumann2008,
    abstract = {The Cell-CT is an optical projection tomography microscope (OPTM) developed for high resolution 3D imaging of single cells based on absorption stains and brightfield microscopy. In this study we demonstrate the use of the Cell-CT in multi-color mode for simultaneous imaging of cellular 3D morphology and the 3D distribution of nanoparticle clusters in the cytoplasm. The ability to image cellular processes in relation to cellular compartments with a non-fluorescence 3D technology opens new perspectives for molecular research.},
    author = {Neumann, Thomas and Miao, Qin and Yu, Julia and Fauver, Mark and Meyer, Michael and Rahn, J Richard and Lancaster, Christy a and Seibel, Eric J and Nelson, Alan C},
    booktitle = {Conference proceedings : Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual Conference},
    doi = {10.1109/IEMBS.2008.4649169},
    isbn = {9781424418152},
    issn = {1557-170X},
    keywords = {Algorithms,Animals,Cell Line,Cell Size,Computer-Assisted,Computer-Assisted: methods,Image Enhancement,Image Enhancement: methods,Image Interpretation,Imaging,Lung Neoplasms,Lung Neoplasms: metabolism,Lung Neoplasms: pathology,Nanoparticles,Nanoparticles: analysis,Optical,Optical: methods,Particle Size,Rats,Reproducibility of Results,Sensitivity and Specificity,Subcellular Fractions,Subcellular Fractions: metabolism,Subcellular Fractions: pathology,Three-Dimensional,Three-Dimensional: methods,Tomography,Tumor},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = jan,
    pages = {379--81},
    pmid = {19162672},
    title = {{Simultaneous 3D imaging of morphology and nanoparticle distribution in single cells with the Cell-CT technology.}},
    url = {http://www.ncbi.nlm.nih.gov/pubmed/19162672},
    volume = {2008},
    year = {2008}
    }
  • B. T. Schowengerdt, M. J. Kundrat, C. M. Lee, R. S. Johnston, D. C. Melville, P. G. Reinhall, and E. J. Seibel, “P-251L : Late-News Poster : Miniature Wide-Throw-Angle Scanning Fiber Projection Display Technical Summary and Results :,” in Sid symposium digest of technical papers, 2008, pp. 2102-2105.
    [Bibtex]
    @inproceedings{Schowengerdt2008,
    author = {Schowengerdt, Brian T and Kundrat, Matthew J and Lee, Cameron M and Johnston, Richard S and Melville, C David and Reinhall, Per G and Seibel, Eric J},
    booktitle = {SID Symposium Digest of Technical Papers},
    mendeley-groups = {HPL,HPL/Display},
    pages = {2102--2105},
    title = {{P-251L : Late-News Poster : Miniature Wide-Throw-Angle Scanning Fiber Projection Display Technical Summary and Results :}},
    year = {2008}
    }
  • [DOI] E. J. Seibel, C. M. Brown, J. a Dominitz, and M. B. Kimmey, “Scanning single fiber endoscopy: a new platform technology for integrated laser imaging, diagnosis, and future therapies.,” Gastrointestinal endoscopy clinics of north america, vol. 18, iss. 3, p. 467–78, viii, 2008.
    [Bibtex]
    @article{Seibel2008,
    abstract = {Remote optical imaging of human tissue in vivo has been the foundation for the growth of minimally invasive medicine. This article describes a new type of endoscopic imaging that has been developed and applied to the human esophagus, pig bile duct, and mouse colon. The technology is based on a single optical fiber that is scanned at the distal tip of an ultrathin and flexible shaft that projects red, green, and blue laser light onto tissue in a spiral pattern. The resulting images are high-quality color video that is expected to produce future endoscopes that are thinner, longer, more flexible, and able to directly integrate the many recent advances of laser diagnostics and therapies.},
    author = {Seibel, Eric J and Brown, Christopher M and Dominitz, Jason a and Kimmey, Michael B},
    doi = {10.1016/j.giec.2008.05.001},
    issn = {1052-5157},
    journal = {Gastrointestinal endoscopy clinics of North America},
    keywords = {Animals,Endoscopes, Gastrointestinal,Endoscopy, Gastrointestinal,Endoscopy, Gastrointestinal: methods,Equipment Design,Fiber Optic Technology,Fiber Optic Technology: instrumentation,Gastrointestinal Diseases,Gastrointestinal Diseases: diagnosis,Humans,Laser Therapy,Laser Therapy: instrumentation,Optical Fibers},
    mendeley-groups = {HPL,HPL/SFE\_Review\_Articles},
    month = jul,
    number = {3},
    pages = {467--78, viii},
    pmid = {18674697},
    title = {{Scanning single fiber endoscopy: a new platform technology for integrated laser imaging, diagnosis, and future therapies.}},
    url = {http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=2553360\&tool=pmcentrez\&rendertype=abstract},
    volume = {18},
    year = {2008}
    }
  • E. J. Seibel, R. E. Carroll, J. A. Dominitz, R. S. Johnston, D. C. Melville, C. M. Lee, S. M. Seitz, S. Member, and M. B. Kimmey, “Tethered Capsule Endoscopy , A Low-Cost and High-Performance Alternative Technology for the Screening of Esophageal Cancer and Barrett ’ s Esophagus,” Ieee transactions on bio-medical engineering, vol. 55, iss. 3, pp. 1032-1042, 2008.
    [Bibtex]
    @article{Seibel2008a,
    author = {Seibel, Eric J and Carroll, Robert E and Dominitz, Jason A and Johnston, Richard S and Melville, C David and Lee, Cameron M and Seitz, Steven M and Member, Senior and Kimmey, Michael B},
    journal = {IEEE transactions on bio-medical engineering},
    mendeley-groups = {HPL/TCE},
    number = {3},
    pages = {1032--1042},
    title = {{Tethered Capsule Endoscopy , A Low-Cost and High-Performance Alternative Technology for the Screening of Esophageal Cancer and Barrett ’ s Esophagus}},
    volume = {55},
    year = {2008}
    }
  • C. J. Engelbrecht, R. S. Johnston, E. J. Seibel, and F. Helmchen, “Ultra-compact fiber-optic two-photon microscope for functional fluorescence imaging in vivo,” Optics express, vol. 16, iss. 8, pp. 5556-5564, 2008.
    [Bibtex]
    @article{Engelbrecht2008,
    author = {Engelbrecht, Christoph J and Johnston, Richard S and Seibel, Eric J and Helmchen, Fritjof},
    journal = {OPTICS Express},
    mendeley-groups = {HPL,HPL/SFE\_microscope-advanced designs},
    number = {8},
    pages = {5556--5564},
    title = {{Ultra-compact fiber-optic two-photon microscope for functional fluorescence imaging in vivo}},
    volume = {16},
    year = {2008}
    }

2007

  • [DOI] R. E. Carroll and S. M. Seitz, “Rectified Surface Mosaics,” in 2007 ieee 11th international conference on computer vision, 2007, pp. 1-8.
    [Bibtex]
    @inproceedings{Carroll2007,
    author = {Carroll, Robert E. and Seitz, Steven M.},
    booktitle = {2007 IEEE 11th International Conference on Computer Vision},
    doi = {10.1109/ICCV.2007.4409128},
    isbn = {978-1-4244-1630-1},
    mendeley-groups = {HPL/TCE},
    pages = {1--8},
    publisher = {Ieee},
    title = {{Rectified Surface Mosaics}},
    url = {http://ieeexplore.ieee.org/lpdocs/epic03/wrapper.htm?arnumber=4409128},
    year = {2007}
    }
  • [DOI] J. W. Yoon, P. G. Reinhall, and E. J. Seibel, “Analysis of electro-active polymer bending: A component in a low cost ultrathin scanning endoscope,” Sensors and actuators a: physical, vol. 133, iss. 2, pp. 506-517, 2007.
    [Bibtex]
    @article{Yoon2007,
    author = {Yoon, W. Jong and Reinhall, Per G. and Seibel, Eric J.},
    doi = {10.1016/j.sna.2006.04.037},
    issn = {09244247},
    journal = {Sensors and Actuators A: Physical},
    keywords = {active tip bending,catheter,composites,ionic conductive polymer metal,ipmc,low-cost,scanning fiber endoscope,single-use},
    mendeley-groups = {HPL},
    month = feb,
    number = {2},
    pages = {506--517},
    title = {{Analysis of electro-active polymer bending: A component in a low cost ultrathin scanning endoscope}},
    url = {http://linkinghub.elsevier.com/retrieve/pii/S0924424706003256},
    volume = {133},
    year = {2007}
    }

2005

  • M. Fauver, E. J. Seibel, R. J. Rahn, M. G. Meyer, F. W. Patten, T. Neumann, and A. C. Nelson, “Three-dimensional imaging of single isolated cell nuclei using optical projection tomography,” Optics express, vol. 13, iss. 11, pp. 432-444, 2005.
    [Bibtex]
    @article{Fauver2005,
    author = {Fauver, Mark and Seibel, Eric J and Rahn, J Richard and Meyer, Michael G and Patten, Florence W and Neumann, Thomas and Nelson, Alan C},
    journal = {OPTICS Express},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    number = {11},
    pages = {432--444},
    title = {{Three-dimensional imaging of single isolated cell nuclei using optical projection tomography}},
    volume = {13},
    year = {2005}
    }

2004

  • R. C. Bryant, C. M. Lee, R. A. Burstein, and E. J. Seibel, “59 . 2 : Engineering a Low-Cost Wearable Low Vision Aid based on Retinal Light Scanning,” in Sid symposium digest of technical papers, 2004, pp. 1540-1543.
    [Bibtex]
    @inproceedings{Bryant2004,
    author = {Bryant, Ryland C and Lee, Cameron M and Burstein, Robert A and Seibel, Eric J},
    booktitle = {SID Symposium Digest of Technical Papers},
    mendeley-groups = {HPL,HPL/Assistive\_devices},
    pages = {1540--1543},
    title = {{59 . 2 : Engineering a Low-Cost Wearable Low Vision Aid based on Retinal Light Scanning}},
    year = {2004}
    }
  • [DOI] M. Fauver, E. J. Seibel, J. R. Rahn, F. W. Patten, and A. C. Nelson, “Development of Micro-Optical Projection Tomography for 3D Analysis of Single Cells,” in Three-dimensional and multidimensional microscopy: image acquisition and processing xi, 2004, pp. 171-181.
    [Bibtex]
    @inproceedings{Fauver2004,
    author = {Fauver, Mark and Seibel, Eric J. and Rahn, J. R. and Patten, Florence W. and Nelson, Alan C.},
    booktitle = {Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XI},
    doi = {10.1117/12.530914},
    editor = {Conchello, Jose-Angel and Cogswell, Carol J. and Wilson, Tony},
    keywords = {Development of micro-optical projection tomography for 3D analysis of single cells},
    mendeley-groups = {HPL,HPL/3D\_OPTM},
    month = jul,
    pages = {171--181},
    title = {{Development of Micro-Optical Projection Tomography for 3D Analysis of Single Cells}},
    url = {http://proceedings.spiedigitallibrary.org/proceeding.aspx?articleid=1321747},
    volume = {5324},
    year = {2004}
    }