Award Abstract # 0931508
CPS: Small: Image Guided Autonomous Optical Manipulation of Cell Groups

NSF Org: CNS
Division Of Computer and Network Systems
Recipient: UNIVERSITY OF MARYLAND, COLLEGE PARK
Initial Amendment Date: September 8, 2009
Latest Amendment Date: August 7, 2012
Award Number: 0931508
Award Instrument: Standard Grant
Program Manager: Radhakisan Baheti
CNS  Division Of Computer and Network Systems
CSE  Directorate for Computer and Information Science and Engineering
Start Date: September 1, 2009
End Date: August 31, 2014 (Estimated)
Total Intended Award Amount: $550,000.00
Total Awarded Amount to Date: $550,000.00
Funds Obligated to Date: FY 2009 = $550,000.00
History of Investigator:
  • Petr Svec (Principal Investigator)
     petrsvec@umd.edu
  • Wolfgang Losert (Co-Principal Investigator)
  • Satyandra Gupta (Former Principal Investigator)
Recipient Sponsored Research Office: University of Maryland, College Park
 3112 LEE BUILDING
 COLLEGE PARK
 MD  US  20742-5100
(301)405-6269
Sponsor Congressional District: 04
Primary Place of Performance: University of Maryland, College Park
 3112 LEE BUILDING
 COLLEGE PARK
 MD  US  20742-5100
Primary Place of Performance
Congressional District:		 04
Unique Entity Identifier (UEI): NPU8ULVAAS23
Parent UEI: NPU8ULVAAS23
NSF Program(s): CDI TYPE II,
CPS-Cyber-Physical Systems
Primary Program Source: 01000910DB NSF RESEARCH & RELATED ACTIVIT
Program Reference Code(s): 7751, 7918, 7923, 9102, 9216, 9218, HPCC
Program Element Code(s): 775100, 791800
Award Agency Code: 4900
Fund Agency Code: 4900
Assistance Listing Number(s): 47.070

ABSTRACT

CPS: Small: Image Guided Autonomous Optical Manipulation of Cell Groups

The objective of this research is to create computational foundation, methods, and tools for efficient and autonomous optical micromanipulation using microsphere ensembles as grippers. The envisioned system will utilize a holographic optical tweezer, which uses multiple focused optical traps to position microspheres in three-dimensional space. The proposed approach will focus on the following areas. First, it will provide an experimentally validated optical-tweezers based workstation for concurrent manipulation of multiple cells. Second, it will provide algorithms for on-line monitoring of workspace to support autonomous manipulation. Finally, it will provide real-time image-guided motion planning strategies for transporting microspheres ensembles.

The proposed work will lead to a new way of autonomously manipulating difficult-to-trap or sensitive objects using microspheres ensembles as reconfigurable grippers. The proposed work will also lead to fundamental advances in several cyber physical systems areas by providing new approaches to micromanipulations, fast and accurate algorithms with known uncertainty bounds for on-line monitoring of moving microscale objects, and real-time motion planning algorithms to transport particle ensembles.

The ability to quickly and accurately manipulate individual cells with minimal training will enable researchers to conduct basic research at the cellular scale. Control over cell-cell interactions will enable unprecedented insights into cell signaling pathways and open up new avenues for medical diagnosis and treatment. The proposed integration of research with education will train students with a strong background in emerging robotics technologies and the inner workings of cells. These students will be in a unique position to rapidly develop and deploy specialized robotics technologies.

PUBLICATIONS PRODUCED AS A RESULT OF THIS RESEARCH

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(Showing: 1 - 10 of 15)
A.G. Banerjee and S.K. Gupta "Research in automated planning and control for micro manipulation" IEEE Transactions on Automation Science and Engineering , v.10 , 2013
A.G. Banerjee, S. Chowdhury, and S.K. Gupta "Optical tweezers: Autonomous robots for the manipulation of biological cells." IEEE Robotics and Automation Magazine , v.21 , 2014
A.G. Banerjee, S. Chowdhury, W. Losert, and S.K. Gupta "Real-time path planning for coordinated transport of multiple particles using optical tweezers" IEEE Transaction on Automation Science and Engineering , v.9 , 2012
A.G. Banerjee, S. Chowdhury, W. Losert, and S.K. Gupta "Survey on indirect optical manipulation of cells, nucleic acids, and motor proteins" Journal of Biomedical Optics , v.16 , 2011
A.G. Banerjee, S. Chowdhury, W. Losert, and S.K. Gupta "Survey on indirect optical manipulation of cells, nucleic acids, and motor proteins." Journal of Biomedical Optics , v.16 , 2011
A. Thakur, S. Chowdhury, P. Svec, C. Wang, W. Losert, and S.K. Gupta "Indirect pushing based automated micromanipulation of biological cells using optical tweezers" International Journal of Robotics Research , v.33 , 2014
B. Koss, S. Chowdhury, T. Aabo, S.K. Gupta, and W. Losert "Indirect optical gripping with triplet traps" Journal of Optical Society of America B , v.28 , 2011
B. Koss, S. Chowdhury, T. Aabo, SK Gupta, and W. Losert "Indirect Optical Gripping with Triplet Traps" Journal of the Optical Society of America B , v.28 , 2011
Brian Koss, Sagar Chowdhury, SK Gupta, and Wolfgang Losert "Indirect Optical Gripping with Triplet Traps" Journal of the Optical Society of America B , v.28 , 2011 , p.982
C. Wang, S. Chowdhury, S.K. Gupta, and W. Losert "Optical micromanipulation of active cells with minimum perturbations: direct and indirect pushing" Journal of Biomedical Optics , v.18 , 2013
C. Wang, S. Chowdhury, S.K. Gupta, and W. Losert. "Optical micromanipulation of active cells with minimum perturbations: direct and indirect pushing" Journal of Biomedical Optics , v.18 , 2013
(Showing: 1 - 10 of 15)

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