Abstract: The present invention provides compositions and methods for targeting dendritic cells of the immune system. In particular, the compositions comprise carbon nanoparticles, optionally magnetic carbon nanoparticles comprising iron, which are preferentially endocytosed by dendritic cells compared to macrophages when contacted with a biological sample. The nanoparticles of the present invention may be functionalized to enhance delivery of biomolecules to dendritic cells.

Abstract: Bactericidal substrates and methods of functionalizing the surface of substrates with quaternary ammonium and quaternary phosphonium groups using non-equilibrium RF plasmas are provided. The methods include the step of treating the surface of a substrate with a plasma to create surface active sites. Some methods include the step of reacting the surface active sites with linker molecules, which are then reacted with quaternary ammonium precursor molecules to provide a substrate surface functionalized with quaternary ammonium precursor groups. Other methods react the surface active sites with polymer precursor molecules under plasma conditions to form a covalently-bound polymer layer having reactive sites. The polymer reactive sites are reacted with quaternary phosphonium precursor molecules to provide a substrate surface functionalized with quaternary phosphonium groups. Also provided are bactericidal substrates having immobilized, covalently-bound quaternary ammonium or quaternary phosphonium groups.

Abstract: Low- or atmospheric pressure RF plasma-enhanced thin film deposition methods are provided for the deposition of hydrophobic fluorinated thin films onto various substrates. The methods include at least two steps. In the first step, RF plasma-mediated deposition is used to deposit a fluorinated film onto a substrate surface. In a second step, plasma-generated active sites on the fluorinated film are quenched by reacting them with stable fluorinated gas-phase molecules in situ, in the absence of plasma, to provide a hydrophobic fluorinated thin film having a very low oxygen content. In some instances the hydrophobic fluorinated thin films have an atomic oxygen concentration of no more than about 3%.

Abstract: An apparatus and method are disclosed for producing nanoparticles in a dense fluid medium. The method is based on the formation of nanoparticles from nanoparticle precursors in a dense fluid medium in which a plasma discharge is created between electrodes submerged in the dense fluid medium. The electrodes define a plasma discharge zone between opposing electrode discharge faces and further define an internal cavitation zone into which a cavitation gas is released, creating bubbles in the dense fluid medium. The result is the efficient production of nanoparticles using a high-frequency, high-voltage electric field to react dense-phase precursors in an atmospheric pressure, low temperature environment.

Abstract: The present invention provides compositions and methods for targeting dendritic cells of the immune system. In particular, the compositions comprise carbon nanoparticles, optionally magnetic carbon nanoparticles comprising iron, which are preferentially endocytosed by dendritic cells compared to macrophages when contacted with a biological sample. The nanoparticles of the present invention may be functionalized to enhance delivery of biomolecules to dendritic cells.

Abstract: An apparatus is utilized for producing colloidal dispersions of nanoparticles of electrically conducting materials. The colloidal dispersions are produced in a dense media plasma reactor comprising at least one static electrode and at least one rotating electrode. The plasma reaction sputters off minute particles of the electrically conducting material from which the electrodes are made. Methods of using the colloidal dispersions thus made are also described. Colloidal dispersions of silver produced in this manner are highly effective for bactericidal purposes.

Abstract: Methods for producing plasma-treated, functionalized inorganic oxide surfaces are provided. The methods include the steps of subjecting an oxide surface to a plasma to create hydroxyl functionalities on the surface and reacting the hydroxyl functionalities with epoxy group-containing molecules in situ in the absence of plasma. Biomolecules may be immobilized on the resulting functionalized surfaces. The methods may be used to treat a variety of oxide surfaces, including glass, quartz, silica and metal oxides.

Abstract: Methods for producing plasma-treated, functionalized inorganic oxide surfaces are provided. The methods include the steps of subjecting an oxide surface to a plasma to create hydroxyl functionalities on the surface and reacting the hydroxyl functionalities with epoxy group-containing molecules in situ in the absence of plasma. Biomolecules may be immobilized on the resulting functionalized surfaces. The methods may be used to treat a variety of oxide surfaces, including glass, quartz, silica and metal oxides.

Abstract: In a milking machine teat cup wherein an animal to be milked has its teat inserted into a teat cup liner during milking, a first electrode extends about or within at least a portion of the teat cup liner. To clean and/or disinfect the liner, a second electrode is inserted into the liner and the two electrodes are charged so as to generate plasma in any free space between the inserted second electrode and the interior surface of the liner. The generated plasma species destroy organisms that cause mastitis, and can additionally kill other unwanted organisms and/or perform cleaning of the liner's interior.

Abstract: Low- or atmospheric pressure RF plasma-enhanced thin film deposition methods are provided for the deposition of hydrophobic fluorinated thin films onto various substrates. The methods include at least two steps. In the first step, RF plasma-mediated deposition is used to deposit a fluorinated film onto a substrate surface. In a second step, plasma-generated active sites on the fluorinated film are quenched by reacting them with stable fluorinated gas-phase molecules in situ, in the absence of plasma, to provide a hydrophobic fluorinated thin film having a very low oxygen content. In some instances the hydrophobic fluorinated thin films have an atomic oxygen concentration of no more than about 3%.

Abstract: A dielectric liquid having entrained bubbles of gas or vapor is subjected to an electric field applied between spaced electrodes (112, 116) which generates microdischarges (and thus plasma) within the bubbles, allowing modification of the properties of the dielectric liquid. The invention is particularly useful for treating hydrocarbon liquids such as gasolines and other liquid hydrocarbon fuels, which have extremely low dielectric constants. Generating microdischarges within bubbles in such fuels can create compounds useful for higher combustion efficiency and/or lower emissions in internal combustion engines. The invention may be directly implemented in an engine's fuel line upstream from the combustion chamber (e.g., immediately prior to a fuel injector), thereby allowing the invention to be usefully implemented for fuel treatment prior to combustion.

Abstract: An apparatus and method are disclosed for producing nanoparticles in a dense fluid medium. The method is based on the formation of nanoparticles from nanoparticle precursors in a dense fluid medium in which a plasma discharge is created between electrodes submerged in the dense fluid medium. The electrodes define a plasma discharge zone between opposing electrode discharge faces and further define an internal cavitation zone into which a cavitation gas is released, creating bubbles in the dense fluid medium. The result is the efficient production of nanoparticles using a high-frequency, high-voltage electric field to react dense-phase precursors in an atmospheric pressure, low temperature environment.

Abstract: Bactericidal substrates and methods of functionalizing the surface of substrates with quaternary ammonium and quaternary phosphonium groups using non-equilibrium RF plasmas are provided. The methods include the step of treating the surface of a substrate with a plasma to create surface active sites. Some methods include the step of reacting the surface active sites with linker molecules, which are then reacted with quaternary ammonium precursor molecules to provide a substrate surface functionalized with quaternary ammonium precursor groups. Other methods react the surface active sites with polymer precursor molecules under plasma conditions to form a covalently-bound polymer layer having reactive sites. The polymer reactive sites are reacted with quaternary phosphonium precursor molecules to provide a substrate surface functionalized with quaternary phosphonium groups. Also provided are bactericidal substrates having immobilized, covalently-bound quaternary ammonium or quaternary phosphonium groups.

Abstract: Methods for producing plasma-treated, functionalized carbon-containing surfaces are provided. The methods include the steps of subjecting a carbon-containing substrate to a plasma to create surface active sites on the surface of the substrate and reacting the surface active sites with stable spacer molecules in the absence of plasma. Biomolecules may be immobilized on the resulting functionalized surfaces. The methods may be used to treat a variety of carbon-containing substrates, including polymeric surfaces, diamond-like carbon films and carbon nanotubes and nanoparticles.

Abstract: A method and apparatus is utilized for producing colloidal dispersions of nanoparticles of electrically conducting materials. The colloidal dispersions are produced in a dense media plasma reactor comprising at least one static electrode and at least one rotating electrode. The plasma reaction sputters off minute particles of the electrically conducting material from which the electrodes are made. Methods of using the colloidal dispersions thus made are also described. Colloidal dispersions of silver produced in this manner are highly effective for bactericidal purposes.

Abstract: A plasma generator includes several plasma sources distributed in an array for plasma treatment of surfaces. Each plasma source includes first and second conductive electrodes. Each second electrode has a gas passage defined therein, and one of the first electrodes is situated within the gas passage in spaced relation from the second electrode, with each gas passage thereby constituting the free space for plasma generation between each pair of first and second electrodes. An insulating layer is interposed between the first and second electrodes to facilitate plasma formation via dielectric barrier discharge (DBD) in the gas passages between the first and second electrodes. The first electrodes may be provided in a monolithic structure wherein they all protrude from a common bed, and similarly the second electrodes may be monolithically formed by defining the gas passages within a common second electrode member.

Abstract: A method for disinfecting water and other dense fluid media containing microorganisms is carried out in a dense media plasma reactor. The plasma reaction in the reactor produces reactive species, such as electrons, ions, and free radicals that promote the inactivation of the microorganisms. In various embodiments, the plasma reaction also sputters off minute antimicrobial particles of the electrically conducting material from which the electrodes are made.

Abstract: A method for disinfecting water and other dense fluid media containing microorganisms is carried out in a dense media plasma reactor. The plasma reaction in the reactor produces reactive species, such as electrons, ions, and free radicals that promote the inactivation of the microorganisms. In various embodiments, the plasma reaction also sputters off minute antimicrobial particles of the electrically conducting material from which the electrodes are made.

Abstract: A membrane having a stable low-contact angle that is used as a template in forming biological microarrays is provided. The membrane is formed of a polymeric material that has been surface modified by a first plasma treatment and subsequently by a second plasma treatment. The surface modification accomplished by the first plasma treatment results in a significant reduction in the contact angle for the membrane, causing the membrane to become hydrophilic, and the surface modification by the second membrane treatment permanently stabilizes the reduction in the contact angle produced by the first plasma treatment. The resulting membrane allows a solution containing a biological material to wet the surface of the membrane such that the membrane can quickly and easily form a biological microarray on substrate in which the features of the array are distinctly formed on the substrate.

Abstract: Methods and apparata for plasma treatment provide a passage through dielectric material, which may be solid material (such as ceramic) or fluid material (such as appropriate liquids or gels). Electrodes are situated outside and adjacent to the passage, and they apply an electric field within the passage to generate plasma from gas traveling within the passage. The object to be plasma treated is situated within the passage, and process gas is supplied (1) to the passage between the exterior of the object and the surface of the passage walls if plasma treatment of the exterior surface of the object is desired; (2) within the interior of the object (as where the object is a hollow tube) if plasma treatment of the interior of the object is desired; or (3) both outside and inside the object and within the passage if plasma treatment of both exterior and interior surfaces is desired.