1. Cell Micro-Manipulation and Nanoscale Probing Techniques
Terrence Dobrowsky
February 12, 2007
IGERT/HHMI Journal Club
2. Different Experimental Techniques and Mechanical Models for Cells Method used to observe will dictate response
Experimental observations lead to different models
Linking mechanical signals to biological signals
How cells mechanically respond under physical loads
3. Different Experimental Techniques and Mechanical Models for Cells
4. Optical Trapping�A Hands Off Manipulation of Cells
5. Optical Trapping�A Hands Off Manipulation of Cells
6. Experimental Setup
Objective used to converge laser
External lens on 3D mount
Leveled beam splitters and blocking filters
Optical Trapping�A Hands Off Manipulation of Cells
7. Atomic Force Microscopy�Multiple Levels of Information Multiple applications for cellular probing
Classical, Imaging live and fixed cells for a total 3D representation of adherent cellular structure
Cellular Elastography, Measuring the local viscoelastic properties of live cells
Molecular Force Probe, Measuring the dissociation kinetics of surface receptors through single molecule manipulation
8. Atomic Force Microscopy�Multiple Levels of Information AFM Basic Setup and principles
Surface mediated cantilever deflection
Photodetector measuring reflected laser displacement
Measure surface deformation with 10pm resolution
9. Atomic Force Microscopy�Multiple Levels of Information AFM Cantilevers tips are equipped with a specific geometry for function
10. Atomic Force Microscopy�Multiple Levels of Information Viscoelastic studies using AFM probing techniques
Quantifying local cellular elastic properties with regard to the cytoskeleton
11. Molecular Force Probe�AFM without the Microscopy Functionalizing Cantilevers as a live biological substrate
Receptor binding in native environment observed
Theoretical models are used to extract unstressed kinetic values
Bells Model
12. Quantum Dots�As Applied to Biological Problems Unique optical and spectroscopic properties
Broad adsorption
Narrow/Tunable emission
Photobleaching resistance
Long Luminescent lifetimes
13. Quantum Dots�As Applied to Biological Problems Hydrophobic inorganic surfactants
Stepped through
Maintaining optical yield while producing hydrophilic surface
Loss of stability, releasing heavy atoms into medium
Recently, di-block copolymers used
14. Quantum Dots�As Applied to Biological Problems Examples of current QD uses in biology
15. Quantum Dots�As Applied to Biological Problems RGD peptide = Tumor related Integrin Antagonist
16. Multiple-Particle-Tracking Microrheology Operates with understanding that physical contact alters mechanical properties of cells and cannot be used to measure those properties
In Vivo assay using nanoparticles to observe cellular elasticity and diffusion within cytoplasm
17. Multiple-Particle-Tracking Microrheology Upstream introduction before egg development
Downstream analysis during cellular division
18. What We Cant Measure�and How It is Always Present Future applications
19. Conclusions There are several methods to manipulate and probe cellular characteristics
Models are developed through those assays
Application of assays not originally designed for biological applications may hold the most promise
Quantitative values for comparison
By observing we alter the sample, how ever delicate we may be
