Research Projects
Micro-Electrodes with High
Charge Injection Capabilities for Neural stimulation (Sahin): Emerging applications of
functional electrical stimulation benefit from electrodes with small surface
areas that minimize the volume of neural tissue activated during stimulation
and permit fabrication of multi-electrode structures that minimize the tissue
disruption during implantation. However, small-area electrodes must deliver
higher current densities without introducing electrochemical reactions that
degrade the electrode or result in reaction products that damage the tissue
around the electrode electrode. Activated iridium is one of the materials of
choice for small electrodes with large current injection capabilities. Iridium
oxide surfaces can also be obtained by directly electroplating it onto other
metals such as gold and platinum. In this project, circular micro-surfaces
(diameter 70 micron) made of gold will be electroplated with iridium oxide and
the change in its impedance due to plating will be measured using an AC
impedance meter. Secondly, similar size surfaces made of iridium will be
activated using cyclic voltammetry (CV) and the
reduction in the electrode AC impedance will be observed. The experimenter will
become familiar with: 1. The importance of the materials used for
electrode-electrolyte interfaces in neural stimulation in terms of their charge
injection capabilities and, 2. The methods of obtaining small surfaces with
equal current specifications without causing irreversible faradaic
reactions that can cause tissue damage.
Protein Substrates for Platelet Function Monitoring (Jones):
Platelets in the blood are responsible for the formation of clots during
injury, but they can also form clots within the blood stream that directly
cause stroke,[1] heart attack[2-4], and complications
in artificial organs. We are studying
methods to assess platelet function by examining their behavior in
protein-coated microchannels. Such methods would enable the use of
therapies that would directly target specific platelet defects. Lithography techniques are used to generate
the channels, and the layer-by-layer assembly technique is used to apply the
protein coatings. For this research, a
large number of questions must be answered before the method can be considered
practical. The behavior of platelets
over a given protein substrate must be characterized, and there are dozens of
candidates for substrates. Several
undergraduate projects will be designed to measure adhesion on different
substrates. For a given protein, the
student will create and coat the channels, perform the experiments under flow
at well-controlled shear stresses, and compare the results to what is known
from the literature about the interaction of platelets with the protein. The platelets will be labeled with acridine orange, and overall platelet coverage, aggregate
size, separation and orientation will be determined through image
analysis. Other projects will use the
same methods to compare the adhesion patterns for different types of blood,
such as different animal species or breeds.
In addition, because the measurements are to be made under flow
conditions, it is important to determine how susceptible the coating is to
removal by shear stresses. Again, the
micro channels will be molded and coated with fibrinogen. An FITC-labeled antibody to fibrinogen will
be used to tag the coating, and the surface coating will be examined
microscopically and quantified by fluorescent intensity. The channels will then be subjected to flow
rates that provide physiological shear stresses, and the surface coatings will
be re-examined microscopically. The
understanding of the resistance to shear provided by this study will determine
modifications that may be necessary to the coating procedure and limitations of
the microchannel method.
Construction and testing of polymer microdevices
(Selmic): The discovery of the
first silicon transistor has dramatically changed the modern world. However, there are some applications where
silicon cannot be used, such as where an electronic device may come into
contact with a biological system and the lack of biocompatibility of silicon is
problematic. Furthermore, polymers are
often more suitable for some micromanufacturing
applications than is silicon. We have
been developing new methods for the design of electronic components that are
based on polymers rather than silicon.
This project lends itself to several undergraduate projects, such as the
construction and testing of an idea for a new polymer-based diode. Such a device would take advantage of the
alternating charge composition inherent in the layer-by-layer assembly process.
Embedded sensors for long-term
monitoring of infrastructure (Tayebi): Civil Infrastructure is deteriorating rapidly, and
substantial investments are being made for its upgrade. The size of investment
implies a much longer life of upgraded structures than what is now standard.
Composite materials present the almost unique solution for this problem.
However, their performance in civil infrastructure environments is unknown and
they need to be monitored closely and inexpensively. This project incorporates
MEMS sensors inside composites as part of their manufacture so that these
sensors can be interrogated during service life. The student will be provided with a specific
sensor and asked to test the viability of the sensor for long-term implantation
in a specified composite material. The
student will be asked to compare sensors of different sizes and measure both
the intelligibility of the remotely transmitted signal from the embedded
sensor. Next, the student will determine
the impact of the sensor on structural integrity through accelerated life
testing.
Microscaffolds for tissue
engineering (McShane): Tissue growth is highly dependent on geometry and the
chemical environment. Current tissue
engineering methods suffer from a lack of control over these two requirements
and inability to assess cell function.
Consequently, we are studying methods to fabricate structures with
precise dimensions and chemical components to control cell adhesion, alignment,
and growth, and we are incorporating sensing elements into these structures. However, many micro/nanofabrication methods
involve harsh chemicals that can destroy both nanosensing
elements and biological molecules. It is
important to establish simple, mild, and cost-effective processes to produce
such structures that will be useful in biological research and biotechnological
applications. The students involved will
develop novel techniques for 1) patterning polymeric materials, 2) integrating
optical sensing elements into these structures, and 3) determining the biocaompatibility of the final structures for different
cell types. The student will be asked to
apply microlithography and LbL assembly to generate a
specific pattern on a given substrate (e.g. multilayer thin film,
photosensitive polymer, or elastomer). He/she will integrate fluorescent indicators
into the structures, and test these indicators for response to known
concentrations of analytes. Finally, he/she will perform cell viability
studies on the structure. This paradigm
will be repeated for various patterns, substrates and sensing dyes by a number
of students. The understanding of the
cell-material interactions provided by this study will be useful in designing
surface and devices with topographical and chemical features to achieve desired
behavior.
Artificial Cells (Haynie): Research in the Bionanosystems
Engineering Laboratory, directed by Dr Don Haynie, is
focused on the development of artificial cells. Applications include
artificial red blood cells, drug delivery vehicles, and environmentally-safe microbioreactors. Areas of expertise in the research
group include peptide engineering, genetic modification of micro-organisms, and
thin film design, fabrication, and characterization. This laboratory
works closely with an early-stage start-up company called Artificial Cell Technologies,
Inc.
Controlled release of nano-encapsulated
drugs (
Modification of surface
coatings for cellular adhesion (Mills): As research in tissue engineering progresses, it has
become increasingly important to be able to develop artificial surfaces that
have properties that encourage the growth of specific cells along with the
expression of specific proteins from these cells. Dr. Mills is working closely with Drs Lvov, McShane Jones in examining the interaction of cells with
their microenvironment. The LbL technique is ideal for the required surface
modification. Dr. Mills’ primary
interest is in the chondrocytes found in the tempero-mandibular joint of the jaw. The undergraduate
student on this project will grow chondrocytes on
these nano-engineered surfaces, measure cell
viability, and determine, through immunohistochemistry,
the proteins that are produced by these cells.
Another student will assess cytotoxic effects
(inflammation, foreign body response, and formation of new tissue during wound
healing) of the various materials and structures used in the sensor
technology. A third student project will
be undertaken to examine the effect of mechanical stress on the chondrocytes. Again,
the cells will be cultured on a nano-coated surface
and then subjected to tensile stresses in a device custom made in Dr. Mills’
laboratory for this purpose. Cell
products and cytotoxicity will be assessed.