Real-time high-throughput identification, screening, characterization, and processing of biological specimen is of great interest to a host of areas spanning from cell biology and medicine to security and defense. Much like human biometrics, microorganisms exhibit natural signatures that can be used for identification. In this paper, we first overview two optical techniques, namely digital holographic microscopy and holographic optical tweezers which can non-invasively image, manipulate, and identify microorganisms in three dimensions. The two methods bear similarities in their optics and implementation. Thus, we have proposed a new approach to identification of micro/nano organisms and cells by combining the two methods of digital holographic microscopy and holographic optical tweezers which can be integrated into a single compact hardware. The proposed system can simultaneously sense, control, identify, and track cells and microorganisms in three dimensions. New possibilities that arise from the proposed method are discussed.
%0 Journal Article
%1 DaneshPanah:10
%A DaneshPanah, Mehdi
%A Zwick, Susanne
%A Schaal, Frederik
%A Warber, Michael
%A Javidi, Bahram
%A Osten, Wolfgang
%D 2010
%I OSA
%J J. Display Technol.
%K ito reviewed
%N 10
%P 490--499
%T 3D Holographic Imaging and Trapping for Non-Invasive Cell Identification and Tracking
%U http://jdt.osa.org/abstract.cfm?URI=jdt-6-10-490
%V 6
%X Real-time high-throughput identification, screening, characterization, and processing of biological specimen is of great interest to a host of areas spanning from cell biology and medicine to security and defense. Much like human biometrics, microorganisms exhibit natural signatures that can be used for identification. In this paper, we first overview two optical techniques, namely digital holographic microscopy and holographic optical tweezers which can non-invasively image, manipulate, and identify microorganisms in three dimensions. The two methods bear similarities in their optics and implementation. Thus, we have proposed a new approach to identification of micro/nano organisms and cells by combining the two methods of digital holographic microscopy and holographic optical tweezers which can be integrated into a single compact hardware. The proposed system can simultaneously sense, control, identify, and track cells and microorganisms in three dimensions. New possibilities that arise from the proposed method are discussed.
@article{DaneshPanah:10,
abstract = {Real-time high-throughput identification, screening, characterization, and processing of biological specimen is of great interest to a host of areas spanning from cell biology and medicine to security and defense. Much like human biometrics, microorganisms exhibit natural signatures that can be used for identification. In this paper, we first overview two optical techniques, namely digital holographic microscopy and holographic optical tweezers which can non-invasively image, manipulate, and identify microorganisms in three dimensions. The two methods bear similarities in their optics and implementation. Thus, we have proposed a new approach to identification of micro/nano organisms and cells by combining the two methods of digital holographic microscopy and holographic optical tweezers which can be integrated into a single compact hardware. The proposed system can simultaneously sense, control, identify, and track cells and microorganisms in three dimensions. New possibilities that arise from the proposed method are discussed.},
added-at = {2019-05-06T12:01:16.000+0200},
author = {DaneshPanah, Mehdi and Zwick, Susanne and Schaal, Frederik and Warber, Michael and Javidi, Bahram and Osten, Wolfgang},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2b6e92d7f157c616d151d9b82243097cc/vogelfrau},
interhash = {134cdca97fbd1bd45f2eb8ed1241486e},
intrahash = {b6e92d7f157c616d151d9b82243097cc},
journal = {J. Display Technol.},
keywords = {ito reviewed},
month = oct,
number = 10,
pages = {490--499},
publisher = {OSA},
timestamp = {2019-05-06T10:01:16.000+0200},
title = {3D Holographic Imaging and Trapping for Non-Invasive Cell Identification and Tracking},
url = {http://jdt.osa.org/abstract.cfm?URI=jdt-6-10-490},
volume = 6,
year = 2010
}