Method for plasma charging a probe

Details Method for plasma charging a probe Method for plasma charging a probe

2002-03-08

2004-04-20

Ngo, Hung V. (Department: 2831)

Electricity: electrical systems and devices

Electric charging of objects or materials

By charged gas irradiation

Reexamination Certificate

active

06724608

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to a method for use of plasma to apply a controlled charge to a surface.
BACKGROUND OF THE INVENTION
Within the disciplines of the clinical, industrial and life science laboratory, scientists perform methods and protocols with extremely small quantities of fluids. These fluids consist of many categories and types with various physical properties. Many times volumes are worked with that are between a drop (about 25 microliters) and a few nanoliters. There are a number of standard methods employed to transfer liquid compounds from a source by aspirating the liquid from such fluid holding device into the fluid dispensing device having a probe, cannula, pin tool or other similar component or plurality of components which move, manually or robotically, and then dispensing, from the same probe or plurality of probes, into another fluid holding device.
Four common techniques are (1) a scheme using a probe or cannula, that may or may not be coated with a layer of material or special coating, which is attached directly or by a tube to a pumping device, (2) a scheme using a disposable pipet instead of the probe/cannula but otherwise similar, (3) a scheme using a spray head with one or a plurality of openings and pumping system that physically propels multiple precisely metered microdroplets, and (4) a scheme using metal shafts with precisely machined hollowed out spaces at their ends that hold the fluid by surface tension (commonly referred to as a “pin tool”).
As routine a process as fluid transfer is in the laboratory, technical challenges to achieve suitable levels of precision and accuracy remain. As the volume decreases, it becomes progressively more technically challenging to aspirate and dispense these very small quantities of fluids due to the various effects of interaction between the dispensing device and the fluid. Droplet formation, as the fluid is dispensed, is a change in the shape of the fluid. The droplet experiences changes in internal forces during the process (e.g., surface tension, viscosity, and polarity) and in external forces due to interactions between the fluid and the surfaces of the probe, cannula, pin tool or other similar component (e.g., superficial and interfacial energies). It is desirable to control and be able to use these forces to improve the process. The use of low temperature atmospheric plasma in such a way so as to place a charge on the probe, cannula, pin tool or other similar component, in order to control properties of the surface of the probe, cannula, pin tool or other similar component in order to attract or repel the fluid accomplishes this desired objective. This control is achieved by metering the deposition of charge by the plasma. The optimum conditions for fluid transfer can be reached taking into consideration the application, fluid characteristics, the affect of any compound dissolved in the liquid, the affect of any particles or other physical matter in the liquid and the type of probe or delivery mechanism used.
The charge from the plasma on the surfaces of the probe, cannula, pin tool or other similar component will alter forces effecting droplet formation, the force required to release the droplet from the probe, cannula, pin tool or other similar component, the surface tension interaction between the liquid and the probe, cannula, pin tool or other similar component, and help suppress the formation of microdroplets (parts of the fluid being transferred that can break off) during dispensing. Some fluid dispensing devices allow the plasma to be pulled into the internal spaces of the probe, cannula or other similar component. The plasma generated surface effects on the fluid inside will have similar action as on the outside surfaces. Exposing the internal surfaces of the probe, cannula or other similar component adds additional control to the total affect of the plasma charge on the fluid handling process.
The same surface effect of the plasma charge on the surfaces of the dispensing device can be applied to the surfaces of the fluid containing device into or onto which the fluid is dispensed. The controlled charge can improve the flow of the small fluid droplets down the side wall of a tube or microplate well and will affect the shape of the fluid droplet formation at the bottom of a tube, microplate well or fluid processing surface. As volumes being transferred decrease, the affect of the plasma charge on the surface becomes more important. On fluid processing surfaces (surfaces onto which droplets are transferred but without a side wall defining a tube or well), the shape of the droplets on the surface determines the diameter and depth of the fluid at a defined droplet volume. The charge on the surface of the plate can alter and thereby control the forces of interaction between the droplet and the plate and, as a result, control these parameters.
Plasma technology is known in the art and is presently used in connection with a wide variety of applications. The most common uses of plasma are based on technologies that rely on the generation of plasma in a low pressure environment.
To sterilize medical devices, a technique known as glow discharge is often used, in which the items are sterilized in air, as opposed to a gas-filled evacuated chamber. For example, U.S. Pat. No. 5,633,424 relates to a method of sterilizing items using water vapor-based plasma. The items to be sterilized are placed in a chamber, which is then evacuated. Water vapor is introduced into the chamber and is allowed to uniformly disperse throughout the chamber. Electromagnetic radiation energy is then applied to the chamber, fractionating the water molecules into reactive radicals. These radicals then combine with the microorganisms on the items, effectively vaporizing the microorganisms. The by-product gases are exhausted from the chamber, and the now-sterilized items can be removed from the chamber.
U.S. Pat. No. 5,700,327 recites a method for removing organic compounds from hollow containers, thereby cleaning the containers. The container is placed into a vacuum chamber, and an oxidizing gas is introduced into the chamber. An electric field is then applied to the chamber, converting the oxidizing gas into low temperature plasma, which then oxidizes substantially all of the organic compounds within the container.
U.S. Pat. No. 6,059,935 discloses two methods and corresponding electrode designs for the generation of a plasma, for example, at or about one atmosphere. Using the disclosed methods, various webs, films and three-dimensional objects are beneficially treated in a reduced amount of time. A first method utilizes a repetitive, asymmetric voltage pulse to generate a plasma discharge between two electrodes. An asymmetric voltage pulse is used to generate a discharge in which a substrate can be exposed predominately to either positive or negative plasma species depending on the voltage polarity used. A second method uses the gap capacitance of an electrode pair and an external inductor in shunt to form a resonant IC circuit. The circuit is driven by a high power radio frequency source operating at 1 to 30 MHz to generate a uniform discharge between the electrode pair. Both methods have temperature controlled discharge surfaces with supply gas temperature, humidity and flow rate control. The gas flow is typically sufficient to cause a turbulent flow field in the discharge region where materials are treated. Electrode pairs implement these methods and include a metal faced electrode and a dielectric covered electrode, one or both of which have a series of holes extending through the electrode face for supply gas flow. The second of the above-described methods will also operate with paired, metal faced electrodes, but under more restricted operating conditions.
U.S. Pat. No. 6,132,813 discloses a method for modifying a substrate surface, including the step of applying a high density plasma to the substrate surface in the presence of a hydrofluorocarbon gas and a carrier gas to form an antiwetting layer on

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