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NanoDLSayTM – A New Solution for Biomolecular
Detection and Analysis
February 2010 Copyright of Nano Discovery, Inc.
Biomolecular Detection and Analysis: the foundation of the whole modern life science research and medical diagnosis
February 2010 Copyright of Nano Discovery, Inc.
What is NanoDLSayTM: Gold Nanoparticle Coupled with Dynamic Light Scattering (DLS) for
Biomolecular Assay
Add sample
Incubate Measureby DLS
Increasing antigen concentration
Distribu
tion
50 100 Size (nm)
Assay Procedure
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antigen
Size increase
Gold nanoparticle-antibody conjugates
February 2010 Copyright of Nano Discovery, Inc.
Why Gold Nanoparticles (GNPs)?
Gold nanoparticles (GNPs) have exceptionally large light scattering cross section at or near their surface plasmon wavelength region
Gold nanoparticles scatter light 105 times stronger than a fluorescent dye molecule; 100s times stronger than polystyrene (PS) latex particles
The scattered light of gold nanoparticles does not suffer from the photobleaching often encountered in fluorescent molecules
Detection limit of DLS for GNPs can easily reach fM to aM range
Figure: Dark field optical images of GNPs mixed with human serum (A) and PS particles (B)
GNPs
Serum
A
GNPs
PS particle
B C
Gold nanorods
February 2010 Copyright of Nano Discovery, Inc.
Dynamic Light Scattering (DLS)
Scattered light intensity fluctuation
Autocorrelate intensity fluctuations
Sample solution
Laser beam
Detector
Correlator
Average particle size (nm)50 100 150
Inte
nsity
Dis
trib
utio
n Particle size and size distribution
Obtain results in minutes instead of hours and days Easy to conduct (a one-step process!) Almost labor-free, no special training needed Simple instrument ($40-60K, instead of $100sK +) Low cost and high sensitivity Can be easily adapted for protein panel analysis Extensive range of applications
Unique Features of NanoDLSayTM
February 2010 Copyright of Nano Discovery, Inc.
ELISA: takes days to prepare and hours to conduct the assay Western blot: takes days to complete, labor-intensive, special training Surface plasmon resonance: too expensive ($200-500K) Applications: limited
Comparison with Traditional Techniques:
Various Types of Gold Nanoparticle Size Change Upon Binding with Target Protein
Molecules
February 2010 Copyright of Nano Discovery, Inc.
Sandwich assay
Protein-protein interaction study
Protein complex/ aggregate detection
Particle size increase
Broad Applications of NanoDLSayTM
February 2010 Copyright of Nano Discovery, Inc.
General assay for protein detection & analysis Protein-protein interaction study Biomolecular binding kinetics study Receptor-ligand identification Antibody isotyping and quality control analysis Protein complex analysis Protein aggregation study Detection of non-protein biomolecules Detection of small chemicals and ions Protein inhibitor screening and drug development Biopharmaceutical research and development Detection of viruses and bacteria Nanoparticle bioconjugate development Nanoparticle quality control Nanoparticle size analysis
Application 1. As a General Sandwich Immunoassay for
Protein Detection
Huo, et al. JACS, 2008, 130, 2780-2782
Ave
rage
par
ticle
siz
e (n
m)
Target protein concentration
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Target protein
February 2010 Copyright of Nano Discovery, Inc.
• Two different monoclonal antibodies are conjugated to two different GNPs
• Sandwich structure formation between the target protein and two GNP probes will cause nanoparticle cluster formation, therefore, lead to the average particle size increase of the assay solution
• The average particle size increase can be correlated to target protein concentration
• Two monoclonal antibodies may be replaced by a polyclonal antibody
Application 2. Monitor Gold Nanoparticle Bioconjugation Process
and Quality Control
Nanoparticle size increase
• An extremely powerful tool to monitor gold nanoparticle bioconjugation process
• Analyze the quality, stability and binding affinity of gold nanoparticle bioconjugates
Huo, et al. Anal. Chem. 2009, 81, 9425-9432
Ave
rage
par
ticle
siz
e (n
m)
Incubation Time (min)
Ave
rage
par
ticle
siz
e (n
m)
Antibody Concentration (µg/mL)
In-situ monitoring of theadsorption process
Antibody concentration effect study
February 2010 Copyright of Nano Discovery, Inc.
Application 3. Protein-Protein Binding and
Interaction Study• In-situ monitoring of protein-protein
binding and interaction study• When target protein binds to protein
conjugated to gold nanoparticles, the particle size will increase
• A function very similar to the Surface Plasmon Resonance technique
• Example 1: can be used to confirm the binding affinity of bioconjugated gold nanoparticles
• Example 2: can be used for antibody isotyping and quality control analysis
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No interactionNo size increase
Huo, et al. American Biotechnology Laboratory 2010, in press
Ave
rage
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ticle
siz
e (n
m)
Incubation Time (min)
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Matching target protein
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February 2010 Copyright of Nano Discovery, Inc.
Application 4. Detect Protein Complex/Aggregate
Formation
February 2010 Copyright of Nano Discovery, Inc.
• Nonlinear increase of nanoparticle size at a critical target protein concentration• The particle size increases dramatically and quickly at this particle concentration• Particle size distribution curve often reveals very broad and multi-model polydispersed
distribution. Run-to-run variation is often large
How to identify protein complex/aggregate formation from NanoDLSay analysis:
Ave
rage
par
ticle
siz
e (n
m)
Target protein concentration
+
+
Size distribution curve
Rel
ativ
e In
tens
ity
Size distribution (nm)
Polydispersed
MonodispersedDose-Response Curve
1) Jans, H.; Liu, X.; Austin, L.; Maes, G.; Huo, Q. Dynamic light scattering as a powerful tool for gold nanoparticle bioconjugation and biomolecular binding study. Anal. Chem. 2009, 81, 9425-9432
2) Austin, L.; Liu, X.; Huo, Q. An immunoassay for monoclonal antibody isotyping and quality analysis using gold nanoparticles and dynamic light scattering. American Biotechnology Laboratory 2010, in press
3) Liu, X.; Huo, Q. A washing-free and amplification-free one-step homogeneous assay for protein detection using gold nanoparticle probes and dynamic light scattering. J. Immunol. Method 2009, 349, 38-44.
4) Dai, Q.; Liu, X.; Coutts, J.; Austin, L.; Huo, Q. A one-step highly sensitive method for DNA detection using dynamic light scattering. J. Am. Chem. Soc. 2008, 130, 8138-8139.
5) Liu, X.; Dai, Q.; Austin, L.; Coutts, J.; Knowles, G.; Zou, J.; Chen, H.; Huo, Q. A One-step homogeneous immunoassay for cancer biomarker detection using gold nanoparticle probes coupled with dynamic light scattering. J. Am. Chem. Soc. 2008, 130, 2780-2782. (also featured at JACS Select #5, 2009, free)
6) Ray, P.C. et al. Use of gold nanoparticles in a simple colorimetric and ultrasensitive dynamic light scattering assay: selective detection of arsenic in groundwater. Angew. Chem. Int. Ed. 2009, 48, 9668-9671.
Examples: Refer to Publications
For Further Information
Contact:
Nano Discovery Inc.Tel: 407-770-8954Email: [email protected]
12565 Research Parkway Suite 300, Orlando, FL 32826