Abstract: A system and method sorts particles suspended in a fluid. The system includes a transverse flow filter and a microfluidic sorter. The transverse flow filter concentrates the particles in a retained portion of the fluid. The microfluidic sorter sorts the particles and includes a delivery channel and at least one sorting stage. The delivery channel is dimensioned to permit passage of all the particles in the retained fluid from the transverse flow filter. The delivery channel delivers the particles in the retained fluid to a respective input for each sorting stage and exhausts a remainder of both the particles and the retained fluid at a drain output. Each sorting stage has a labyrinth of interconnected passageways dimensioned to permit passage from the respective input to a respective output for the sorting stage of those of the particles smaller than a respective size for the sorting stage.

Abstract: A system for supplying hydrogen gas to a lighter-than-air (LTA) vehicle includes a manifold having multiple vessels. Each vessel has a first chamber that is separated from a second chamber by a barrier. A trigger assembly integrated with the barrier allows a liquid to be combined with a reactant and a catalyst in the second chamber to form a chemical reaction to generate hydrogen gas. A pressure relief valve located on each vessel opens to allow the hydrogen gas to exit when a predetermined pressure is reached, and the hydrogen gas is supplied to the LTA vehicle connected to the manifold.

Abstract: A device and method for detecting bacteria in a sample can include an optically transparent substrate and a phage that is known to react with the bacteria being detected. The phage can be tagged with a fluorescent tag such as DAPI or SBYR® Gold cyanine dye. Once fluorescently tagged, the phage-substrate combination can be illuminated with a light source, at a wavelength that corresponds to an excitation wavelength for the fluorescent tag to establish a baseline intensity for the device. The device can then be exposed to the sample and illuminated to establish a test intensity. The bacteria to be detected can be deemed as being present if the test intensity is less than the baseline intensity.

Abstract: A method uses flow cytometry to prepare surface enhanced Raman scattering (SERS) substrates for obtaining SERS spectra of bacteria. The method involves using a flow cytometer to sort bacterial cells into populations of bacterial cells based upon their biophysical characteristics. The cells may then be washed with a borate buffer to remove any chemical species that degrade the SERS response. A colloid-coated bacteria suspension is then created by mixing one of the populations of bacterial cells with SERS-active colloidal particles. The colloid-coated bacteria suspension is incubated until the SERS-active colloidal particles partition through the capsule and bind to the cell wall for each bacterial cell in the colloid-coated bacteria suspension. The colloid-coated bacteria suspension is then disposed onto a filter and a SERS spectra of the colloid-coated bacteria suspension is obtained using a Raman spectrometer.

Abstract: A device and method for determining total bacteria count in a sample can include the step of removing the eukaryotes from the sample by filtering the sample through a 0.45 ?m pore size syringe filter made of a low protein binding material. Next, the sample can be tagged with a fluorescent tag and illuminated with a light source at an excitation wavelength for the fluorescent tag. The resulting fluorescent intensity can be compared to a calibration curve to determine the total bacteria count. In cases where a total bacteria count of a specific bacteria is desired, a phage that is known to react with the bacteria of interest can fluorescently tagged and then mixed into the sample, and the combination can be illuminated to establish a test intensity for said sample, which can be used to obtain a total bacteria count for the bacteria species of interest.

Abstract: An apparatus comprising: a direct push probe configured to be pushed into a subsurface soil environment; a transparent window mounted to a side of the probe; a white light source mounted within the probe and positioned such that when the white light source is activated only white light exits the window; an ultraviolet (UV) light source mounted within the probe and positioned such that when the UV light source is activated only UV light having a given wavelength exits the window; and an imaging system disposed within the probe and configured to capture a white-light-only-illuminated image and a UV-light-induced-fluorescence image of the subsurface soil environment at a given depth, wherein the imaging system comprises a longpass filter to filter out the UV light having the given wavelength.

Abstract: A method uses flow cytometry to prepare surface enhanced Raman scattering (SERS) substrates for obtaining SERS spectra of bacteria. The method involves using a flow cytometer to sort bacterial cells into populations of bacterial cells based upon their biophysical characteristics. The cells may then be washed with a borate buffer to remove any chemical species that degrade the SERS response. A colloid-coated bacteria suspension is then created by mixing one of the populations of bacterial cells with SERS-active colloidal particles. The colloid-coated bacteria suspension is incubated until the SERS-active colloidal particles partition through the capsule and bind to the cell wall for each bacterial cell in the colloid-coated bacteria suspension. The colloid-coated bacteria suspension is then disposed onto a filter and a SERS spectra of the colloid-coated bacteria suspension is obtained using a Raman spectrometer.

Abstract: A system for generating hydrogen includes a vessel having a first chamber that is separated from a second chamber by a barrier. A trigger assembly integrated with the barrier allows a liquid to be combined with a reactant and a catalyst in the second chamber to form a chemical reaction to generate hydrogen gas. A pressure relief valve located on the vessel opens to allow the hydrogen gas to exit when a predetermined pressure is reached.

Abstract: A system for supplying hydrogen gas to a lighter-than-air (LTA) vehicle includes a manifold having multiple vessels. Each vessel has a first chamber that is separated from a second chamber by a barrier. A trigger assembly integrated with the barrier allows a liquid to be combined with a reactant and a catalyst in the second chamber to form a chemical reaction to generate hydrogen gas. A pressure relief valve located on each vessel opens to allow the hydrogen gas to exit when a predetermined pressure is reached, and the hydrogen gas is supplied to the LTA vehicle connected to the manifold.

Abstract: An apparatus comprising: a probe configured to be pushed into a subsurface soil environment; a transparent window mounted to a side of the probe; a broad-spectrum light source mounted within the probe and positioned such that when the light source is activated broad-spectrum light exits the window; a tunable optical filter mounted within the probe and positioned so as to receive, as an input, light reflected back through the window from the subsurface soil environment, wherein the filter comprises a plurality of settings at each of which the filter is configured to output light within a given wavelength range to the exclusion of other wavelength light ranges; and an imaging system disposed within the probe and configured to capture an image of the output light from the filter at each of the settings at a given depth of the probe in the subsurface soil environment.

Abstract: An apparatus comprising: a direct push probe configured to be pushed into a subsurface soil environment; a transparent window mounted to a side of the probe; a white light source mounted within the probe and positioned such that when the white light source is activated only white light exits the window; an ultraviolet (UV) light source mounted within the probe and positioned such that when the UV light source is activated only UV light having a given wavelength exits the window; and an imaging system disposed within the probe and configured to capture a white-light-only-illuminated image and a UV-light-induced-fluorescence image of the subsurface soil environment at a given depth, wherein the imaging system comprises a longpass filter to filter out the UV light having the given wavelength.

Abstract: A perchlorate detector comprising: surface-enhanced Raman spectroscopy (SERS)-active, magnetic, capture matrices that are selective for perchlorate, wherein the capture matrices are designed to be added to a sample solution; a detection chamber configured to hold the sample solution and the capture matrices; a selectively engageable magnet assembly coupled to the detection chamber such that when the magnet assembly is engaged or disengaged the capture matrices are respectively confined or not confined to a confinement region of the detection chamber; and a Raman spectrometer optically aligned with the confinement region of the detection chamber and configured to interrogate the capture matrices when the magnet assembly is engaged in order to detect and determine a concentration of perchlorate bound to the capture matrices.

Abstract: A method may include the steps of supplying current to the electrodes of an electrochemical cell according to a first charging profile, wherein the electrochemical cell has an anode, cathode, and electrolytic solution; maintaining a generally constant current between the electrodes; exposing the cell to an external field either during or after the termination of the deposition of deuterium absorbing metal on the cathode; and supplying current to the electrodes according to a second charging profile during the exposure of the cell to the external field. The electrolytic solution may include a metallic salt including palladium, and a supporting electrolyte, each dissolved in heavy water. The cathode may comprise a second metal that does not substantially absorb deuterium, such as gold. The external field may be a magnetic field.

Abstract: A Method to Incorporate a Fluorescent Internal Standard on Substrates (NC#098329). The method includes providing a substrate, operatively coupling internal standard particles to the substrate, forming an insulating buffer layer over the internal standard particles and the substrate, and forming a sensing polymer layer over the insulating buffer layer.

Abstract: Improved surface-enhanced Raman scattering (SERS) substrates comprising chemically-derivatized magnetic microparticles complexed with metal colloidal particles or substrates. The SERS substrates permit collection, detection, measurement, and/or analysis of analytes present at concentrations ranging parts per trillion to parts per billion. Further, compositions, methods, and devices that provide for rapid and/or sensitive detection of chemical compounds of interest present in small concentrations. The subject matter has use in the areas of homeland security and force protection, for example, in the detection of trace samples including, for example, BTEX (benzene, toluene, ethylbenzene, and xylenes), chlorinated solvents, TNT, nerve agents, blister agents, metal ions, anions, antigens, peptides, nucleic acids, spores, fungi, viruses, and bacteria.

Abstract: A technique for orienting and binding the head end of phage to a substrate is disclosed. The tail end of the phage is thereby made readily available for bacteria sensing.

Abstract: A thermoelectrically cooled surface-enhanced Raman Spectroscopy (TEC-SERS) fiber optic probe for real-time and in-situ monitoring of volatile organic compounds in gas, liquid, and soil environments. The TEC-SERS probe comprises a sample chamber for receiving a gas sample and a fiber optic Raman probe. The sample chamber comprises an inlet having a semipermeable membrane for separating moisture from the gas sample, a SERS substrate mounted on a thermoelectric cooler, a mass flow device for providing airflow, and an output port. The fiber optic Raman probe is operably coupled to a transparent window in the sample chamber for directing an optical excitation signal to irradiate the SERS substrate and for receiving a SERS optical signal from analytes from the gas sample that are in contact with the SERS substrate.

Abstract: A sensor system employs a thermo-electrically cooled surface enhanced Raman (SERS) structure that is positioned in a sample chamber. Gas or vapor that may contain an analyte of interest is introduced into the sample chamber so that the analyte may come into contact with the SERS structure. The SERS structure may be cooled to facilitate condensation of selected analytes onto the SERS structure. When in contact with each other, the analyte and SERS structure may be optically stimulated by an optical excitation signal to produce a unique spectral response that may be detected by a spectroanalysis system. The spectral response then may be correlated to a specific analyte, i.e., identified.

Abstract: A chemical detection sensor system comprises a support structure; multiple SERS chemical detection sensors supported by the support structure; multiple chemical reaction sensors, wherein each of the chemical reaction sensors is disposed for undergoing a state change in response to an occurrence of a chemical reaction at one of the SERS chemical detection sensors; a processor supported by the support structure for recording data representing occurrence of a chemical reaction at any of the chemical detection sensors in response to sensing the state change; and a power source for energizing the processor.

Abstract: A system for supplying hydrogen gas to a lighter-than-air (LTA) vehicle includes a manifold having multiple vessels. Each vessel has a first chamber that is separated from a second chamber by a barrier. A trigger assembly integrated with the barrier allows a liquid to be combined with a reactant and a catalyst in the second chamber to form a chemical reaction to generate hydrogen gas. A pressure relief valve located on each vessel opens to allow the hydrogen gas to exit when a predetermined pressure is reached, and the hydrogen gas is supplied to the LTA vehicle connected to the manifold.