Nanotechnology Research
Clay Harris and Rob Dolan
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Synchrotron
IR Microspectrometry of Nanotubes and Nanowires
Applications
of carbon nanotubes in modern science are both broad and far-reaching. Almost
all fields of science stand to benefit from nanotechnology research. The
purification of carbon nanotubes is of particular interest as a means to
distribute chemically similar nanotubes. These structurally identical
nanotubes can be bound to pharmaceuticals to be distributed in a targeted
fashion in the body. As the nanotubes pass through tissues they transport the
bound pharmaceutical as well, and are released from the nanotube into the
body at specific locations and times. However, structurally different
nanotubes have the potential to fail to release the pharmaceutical at the
correct time, or to fail to target the proper body tissue. To ensure release
and targeting, nanotubes must undergo a variety of purification processes to
assure obtaining as many nearly identical nanotubes as possible.
While
these purified nanotubes are chemically detectable, preliminary studies at
the NSLS have suggested that these nanotubes may not be as pure as originally
thought. Using the synchrotron light source, samples of both unpurified and
purified nanotubes were examined in the infrared (IR) spectral region.
Variations in spectral data clusters as the sample was translated spatially
suggest the presence of many different components. This raises several
questions about the purification process, and the reliability of chemical
detection of varying degrees of purification. How can it be certain that one
has made a desired nanotube? How does one located a desired nanotube in a
complex mixture? And how can one determine the level of variation in a
purified sample of nanotubes?
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Image of
nanotubes to be scanned
Click image for more images
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Data
Analysis and Interpretation
By
reducing sample data to their principal components, plotting those components
on a quantile-quantile (QQ) plot, and fitting multiple lines to the QQ graph,
it is possible to break the data set into its primary data clusters.
Calculating distances from the center of these clusters to all other points
in the data set yield chemical maps corresponding to the concentration of
each unique cluster. A current goal is to analyze these clusters and locate
physical sites where variations in the data occur. However, due to the volume
of data obtained at the NSLS, and the small number of people available to
interpret the data, analysis takes some time. The spatial resolution of
conventional synchrotron IR microspectrometry (µm scale) in comparison to the
size of the nanotubes (nm scale), complicates spectral data for nanotube
analysis. Near-field techniques (see
below) may soon help in this regard.
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Current
Research and Solutions
Hyperspectral
imaging tends to be data rich and information poor. Data volume has become a
bottleneck in many areas of research, increasing the time it takes to both
analyze and interpret data. Several methods are being developed that
preprocess data and reduce the time it takes to interpret the data. These
methods have been termed integrated computational imaging (ICI),
hyperspectral integrated computational imaging (HICI), and integrated sensing
and processing (ISP).
Using
ICI, computers both capture and analyze an image during the detection
process. ICI reduces the data load on the computer by downloading some of the
computations to the image sensor itself (Lodder, 2004). In HICI, a spectral
image is encoded at many different wavelengths simultaneously. ICI and HICI
incorporate Felgett's advantage, or multiplex advantage, in which collecting
data at all wavelengths at once reduces the
collection time required for obtaining the same signal-to-noise ratio
when compared to a dispersive technique that collects only one wavelength at
a time. HICI methods for collecting data are advantageous because they
compress a high volume of spectral information into a single image, which
saves time and decreases the final volume of data collected.
Through
the ISP process, the steps by which signals are detected and interpreted is
being completely reorganized, reworked, and optimized. Originally began by
Defense Advanced Research Projects Agency (DARPA), the project seeks to craft
new sensor systems that treat the total structure as a single end-to-end
process that can be optimized globally. ISP has created new mathematical
algorithms and produced new statistical methods by which both the speed of
sensing and amount of data are increasing, and the information gained is more
meaningful. By developing and implementing new ICI and ISP methods and
instruments, the bandwidth, volume of data to be interpreted, and amount of
time taken to interpret data are each being significantly reduced, while
maintaining a high level of meaningful information (Lodder, 2004).
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Nanotube data clusters (click for larger image)
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Molecular Factor Computing Near-Field Scanning Optical Microscopy (MFC-NSOM)
Conventional
NIR microscopes limit spatial resolution to about lambda/2, making the best
NIR spatial resolution 0.5-1 µm (Lodder, 2005). Details become lost after
light travels more than a wavelength from a feature smaller than lambda/2,
but with smaller wavelengths higher resolutions can be gained. To overcome
this limitation, our research is looking into the development of near-field
HICI devices.
The
near-field effect is achieved when a subwavelength-sized optical element is
placed at a subwavelength distance between the optical element and the
sample. Because the light travels only over a short distance, diffraction and
far-field characteristics are eliminated. Near-field techniques can enable a
resolution of 80-120 nm for a light source of 1200 nm (Lodder, 2005).
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MFC-NSOM using the NSLS as a light
source (click for larger image)
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By
developing instruments capable of realizing sub-micron spatial resolutions,
the boundaries of NIR microscopy can be expanded. NSOM makes possible the in
vivo imaging of cell membranes and other biological systems, the study of
single molecules, and the collection of new information on the orientation
and behavior of molecules. Building on this principle by the use of MFC, in
which molecular filters are used to encode specific wavelengths of light
corresponding to the analyte of interest, speeds near-field spectrometric
imaging sufficiently to make it practical in biological systems..
Using an MFC NIR-NSOM instrument, samples
of both purified and unpurified carbon nanotubes will be analyzed to create
an optical method to quickly determine if the desired structures are being
produced, and where. Materials are selected for use as molecular filters by
comparing their transmission spectra to the factor loadings correlating to
the analyte of interest. This produces images whose colors correlate to the
concentration of the analyte. For example, by searching for key differences
between unpurified and purified nanotube spectra, it is possible to find a
quick and easy means of identifying unpurified elements of a purified sample.
Because the light passes through a limited number of nondispersive optics,
the Jacquinot advantage (throughput advantage) also applies. This means that
a higher signal-to-noise ratio is maintained when compared to more
traditional NIR Methods.
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Calculating MFC Loadings
(click for larger image)
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Binding
an Anti-CRP molecule to a Nanowire
Recent
studies have shown that binding a receptor to a nanotube, and then that nanotube/receptor
to a protein, can affect nanotube conductivity. Such protein-bound nanowires can
be used as sensors to search for specific proteins in vitro or even in vivo.
By bonding an anti-CRP (C-reactive protein) to a nanowire, we hope to show
that a CRP "sniffing" nanowire sensor can be constructed. CRP (which
binds to anti-CRP) indicates inflammation that can lead to matrix protein
degradation and the rupture of vulnerable atherosclerotic plaque. If CRP is
present, it will bind to the anti-CRP on the sensor, causing an electrical
current of the nanowire to change. By searching for CRP above and below vulnerable
atherosclerotic plaque in a flowing blood stream, it may be possible to
locate trouble areas in which plaques are likely to rupture even in the
presence of arthritis (which dramatically elevates CRP) in the patient.
Attaching anti-CRP to the nanowire can be
complicated. The streptavidin process, which results in the formation of a
protein layer over the surface of the nanotubes, offers a potential means for
building the sensor. Biotinylated anti-CRP is allowed to bind to the
streptavidin layer, which anchors the sensing protein to the nanotube surface
(Lenihan et al., 2004). Simple electronics monitoring current in the nanowire
permit the detection of CRP.
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Nanotechnology
at ASRG
By
developing an MFC-NSOM, and combining it with the concept of sensing arrays
utilizing ISP methodology capable of ICI and HICI, sensors will be created that not only obtain
large quantities of data, but also analyze that data immediately. The
development of a nanowire "sniffer" capable of measuring CRP in
vulnerable plaque will provide a method for the identification of patients
susceptible to sudden cardiac death. Further research and development of
these analytical tools and methods may reduce the number of deaths due to
vulnerable plaque.
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References:
Lenihan, J. S.; Gavalas, V. G.; Wang, J.;
Andrews, R.; Bachas, L. G. Protein Immobilization on Carbon Nanotubes Through
a Molecular Adapter. J. Nanosci. Nanotech. 2004. Vol. 4, pp
600-604(5).
Lodder, R. A.; Harris, J. C. NIR-NSOM Using Hyperspectral Integrated
Computational Imaging. 2005.
Cassis, L. A.; Urbas, A.; Lodder, R. A.;
Hyperspectral integrated computational imaging. Anal. Bioana. Chem.
2004.
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