We will develop new technologies to employ quantum dots in biological imaging in vitro. In an evolving program, quantum dot technology will be developed specifically for (I) cell identification and tracking of cells in tissues, (2) tracking cell proliferation through multiple generations in tissues (3) vasculature location, and (4) deep 3-D imaging of Qdot-labeled polymer scaffold structures relative to the Qdot-labeled cells in engineered tissue models. Quantum Dots Corporation will prepare new types of Qdots that have properties suited to deep imaging of cells and structures in tissues. Particular emphasis will be placed on near infrared Qdots for imaging deeper in tissues. The Science and Technology Center at Carnegie Mellon University will then develop methods to derivatize Qdots for existing and new applications in cell biology. The STC will initially use available Qdots and conjugates, label cells by a variety of means, then test the cells for fluorescent brightness, stability of labeling, and cell survival and function. As newer quantum dots become available, they will be similarly tested and compared with existing Qdots and existing organic fluorescent probes, e.g., Alexa dyes and cyanine dyes. Fluorescence lifetime imaging capability will be added to the 3-D grating imager in the STC for enhancing signal-to-background in deep tissue imaging by taking advantage of the relatively long emission lifetime of Qdots. To obtain feedback for the development program we have included collaboration with the recently formed Bone Tissue Engineering Center at Carnegie Mellon University. In this collaboration we will examine the utility of the developing Qdot technology for studying cell location, movement and proliferation in the 3-D structures of engineered bone tissue. This is a particularly challenging and relevant system that requires Qdot technology to extend cell tracking to denser and more highly scattering tissue matrices, including hydroxyapatite-containing artificial bone matrices. By the conclusion of this project, we expect to have instrumentation and probes to perform time-resolved multicolor imaging at millimeter depth in many natural and artificial tissues. Thus the technology will be generic and have utility in many biological and medical applications.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
1R01EB000364-01
Application #
6424694
Study Section
Special Emphasis Panel (ZRG1-SRB (03))
Program Officer
Korte, Brenda
Project Start
2002-04-15
Project End
2007-03-31
Budget Start
2002-04-15
Budget End
2003-03-31
Support Year
1
Fiscal Year
2002
Total Cost
$642,504
Indirect Cost
Name
Carnegie-Mellon University
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
052184116
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213
Clausen, Mathias P; Arnspang, Eva C; Ballou, Byron et al. (2014) Simultaneous multi-species tracking in live cells with quantum dot conjugates. PLoS One 9:e97671
Mittal, Rowena; Bruchez, Marcel P (2011) Biotin-4-fluorescein based fluorescence quenching assay for determination of biotin binding capacity of streptavidin conjugated quantum dots. Bioconjug Chem 22:362-8
Mittal, Rowena; Bruchez, Marcel P (2009) Calibration of Flow Cytometry for Quantitative Quantum Dot Measurements. Curr Protoc Cytom Chapter 6:Unit6.26
Fitzpatrick, James A J; Andreko, Susan K; Ernst, Lauren A et al. (2009) Long-term persistence and spectral blue shifting of quantum dots in vivo. Nano Lett 9:2736-41
Ballou, Byron; Ernst, Lauren A; Andreko, Susan et al. (2009) Imaging vasculature and lymphatic flow in mice using quantum dots. Methods Mol Biol 574:63-74
Miller, Eric D; Phillippi, Julie A; Fisher, Gregory W et al. (2009) Inkjet printing of growth factor concentration gradients and combinatorial arrays immobilized on biologically-relevant substrates. Comb Chem High Throughput Screen 12:604-18
Smith, J D; Melhem, M E; Magge, K T et al. (2007) Improved growth factor directed vascularization into fibrin constructs through inclusion of additional extracellular molecules. Microvasc Res 73:84-94
Chakraborty, Subhasish K; Fitzpatrick, James A J; Phillippi, Julie A et al. (2007) Cholera toxin B conjugated quantum dots for live cell labeling. Nano Lett 7:2618-26
Ballou, Byron; Ernst, Lauren A; Andreko, Susan et al. (2007) Sentinel lymph node imaging using quantum dots in mouse tumor models. Bioconjug Chem 18:389-96
Lagerholm, B Christoffer (2007) Peptide-mediated intracellular delivery of quantum dots. Methods Mol Biol 374:105-12

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