Patent application number | Description | Published |
20100022030 | DRY ETCH STOP PROCESS FOR ELIMINATING ELECTRICAL SHORTING IN MRAM DEVICE STRUCTURES - The present invention relates generally to semiconductor fabrication and particularly to fabricating magnetic tunnel junction devices. In particular, this invention relates to a method for using the dielectric layer in tunnel junctions as an etch stop layer to eliminate electrical shorting that can result from the patterning process. | 01-28-2010 |
20100285237 | NANOLAYER DEPOSITION USING BIAS POWER TREATMENT - A hybrid deposition process of CVD and ALD, called NanoLayer Deposition (NLD) is provided. The NLD process is a cyclic sequential deposition process, comprising introducing a first plurality of precursors to deposit a thin layer with the deposition process not self limiting, followed by introducing a second plurality of precursors for plasma treating the thin deposited layer. The plasma can be isotropic, anisotropic, or a combination of isotropic and anisotropic to optimize the effectiveness of the treatment of the thin deposited layers. | 11-11-2010 |
20120021138 | NANOLAYER DEPOSITION PROCESS FOR COMPOSITE FILMS - A NanoLayer Deposition (NLD) process for depositing composite films of tertiary, quaternary, pentanary, and hexary stoichiometric films is provided. The inventive deposition process is a cyclic process consisting of a sequence of thin film deposition and treatment steps to obtain a desired film stoichiometry. The deposition steps are not self-limiting as in atomic layer deposition. In one embodiment for depositing a compound oxide film, the deposition process comprises a first deposition, followed by a hydrogen-containing plasma treatment, a second deposition followed by a hydrogen-containing plasma treatment, and then a third deposition followed by a hydrogen-containing plasma and then an oxygen-containing plasma treatment to produce a stoichiometric quaternary film. The cyclic process is repeated until the desired overall film thickness is achieved. The inventive process is used to fabricate high k dielectric films, ferroelectric films, piezoelectric films, and other complex oxides. | 01-26-2012 |
20120202353 | NANOLAYER DEPOSITION USING PLASMA TREATMENT - A process to deposit a thin film by chemical vapor deposition includes evacuating a chamber of gases; exposing a device to a gaseous first reactant, wherein the first reactant deposits on the device to form the thin film having a plurality of monolayers in thickness; evacuating the chamber of gases; exposing the device, coated with the first reactant, to a gaseous second reactant under a plasma treatment, wherein the thin film is treated by the first reactant; and repeating the previous steps. | 08-09-2012 |
Patent application number | Description | Published |
20090035388 | ANTIMICROBIAL PHOTO-STABLE COATING COMPOSITION - The invention is an antimicrobial photo-stable coating composition that deters photo-induced discoloration, does not stain tissue and can be applied to the surface of a variety of medical materials. The composition comprises in an aspect silver-PCA complex and dye. | 02-05-2009 |
20110100293 | SYSTEM AND METHOD FOR COATING MEDICAL DEVICES - A system and method for photo-grafting a coating polymer onto the surface of a medical device are provided. The system comprises a plurality of stations including a novel grafting station. The system and method of the invention are both time- and resource-efficient. The system includes several stations, each station including a dipping tank. The system allows for the automated, semi-automated, or manual dipping of medical devices into the dipping tanks in a specified order, as desired, wherein at least one of the stations is a grafting station for photo-grafting the coating polymer onto the surface of the medical device. The system is modular, which allows for modification of the process as required, depending on the needs of the user. The system may comprise stations for incorporating an antimicrobial agent into the coating, and/or for rendering the coating lubricious. | 05-05-2011 |
20110100294 | SYSTEM AND METHOD FOR COATING MEDICAL DEVICES - A system and method for photo-grafting a coating polymer onto the surface of a medical device are provided. The system comprises a plurality of stations including a novel grafting station. The system and method of the invention are both time- and resource-efficient. The system includes several stations, each station including a dipping tank. The system allows for the automated, semi-automated, or manual dipping of medical devices into the dipping tanks in a specified order, as desired, wherein at least one of the stations is a grafting station for photo-grafting the coating polymer onto the surface of the medical device. The system is modular, which allows for modification of the process as required, depending on the needs of the user. The system may comprise stations for incorporating an antimicrobial agent into the coating, and/or for rendering the coating lubricious. | 05-05-2011 |
20110104390 | SYSTEM AND METHOD FOR COATING MEDICAL DEVICES - A system and method for photo-grafting a coating polymer onto the surface of a medical device are provided. The system comprises a plurality of stations including a novel grafting station. The system and method of the invention are both time- and resource-efficient. The system includes several stations, each station including a dipping tank. The system allows for the automated, semi-automated, or manual dipping of medical devices into the dipping tanks in a specified order, as desired, wherein at least one of the stations is a grafting station for photo-grafting the coating polymer onto the surface of the medical device. The system is modular, which allows for modification of the process as required, depending on the needs of the user. The system may comprise stations for incorporating an antimicrobial agent into the coating, and/or for rendering the coating lubricious. | 05-05-2011 |
20110212152 | MODIFIED ANTI-MICROBIAL SURFACES, DEVICES AND METHODS - Methods for making modified surfaces and in particular, surfaces that may be lubricious and may be further treated to be anti-microbial are disclosed. Devices comprising modified surfaces prepared by the methods are also disclosed. An exemplary method comprises incubating a photo-initiator-coated substrate in an aqueous monomer solution that is capable of free radical polymerization, exposing the incubating substrate to ultraviolet (UV) light creating a modified surface on the substrate. An anti-microbial agent may be added to the modified surface. | 09-01-2011 |
20110256185 | REINFORCED TISSUE SHIELDS - Self-reinforced tissue shields are useful as ophthalmic shields, wound dressings, wound barriers, nerve repair, therapeutic drug delivery devices and the like. The self-reinforced tissue protective shields comprise gelatin, chitosan and reinforce and are made by a method comprising forming inter-molecular locking within a solution through electrostatic forces, eliminating the use of extra cross-linking methods, the solution mainly comprising natural existing polymers that are biodegradable and biocompatible. | 10-20-2011 |
20110313048 | ANTIMICROBIAL SILICONE-BASED WOUND DRESSINGS - Antimicrobial silicone-based dressings, such as wound dressings, are disclosed. An example dressing comprises a transparent and self-adhesive gel sheet cured from a liquid containing silicone, the sheet having dispersed therein (i) particulates of a chlorhexidine compound that is not soluble in the liquid; and (ii) at least one other antimicrobial. Methods of making the silicone-based dressings and methods of use are also disclosed. | 12-22-2011 |
20120330210 | ANTIMICROBIAL SILICONE-BASED WOUND DRESSINGS - Antimicrobial silicone-based dressings, such as wound dressings, are disclosed. An example dressing comprises a transparent and self-adhesive gel sheet cured from a liquid containing silicone, the sheet having dispersed therein (i) particulates of a chlorhexidine compound that is not soluble in the liquid; and (ii) at least one other antimicrobial. Methods of making the silicone-based dressings and methods of use are also disclosed. | 12-27-2012 |
20130039953 | METHOD FOR TREATING A SURFACE WITH A COATING COMPRISING A THERAPEUTIC AGENT AND DEVICE WITH TREATED SURFACE - A method for treating a surface with a therapeutic agent is disclosed. The method comprises precipitating a therapeutic agent from a hydrophilic polymeric base layer with which the therapeutic agent has been complexed, to form a layer comprising microparticles of the therapeutic agent on the hydrophilic polymeric base layer, the hydrophilic polymeric base layer being grafted to the surface. Devices comprising a surface having a hydrophilic polymeric base layer comprising a hydrophilic polymer grafted to the surface and a layer comprising microparticles of a therapeutic agent disposed on and complexed with the hydrophilic polymeric base layer are also disclosed. | 02-14-2013 |
20130137780 | NON-ADHESIVE ELASTIC GELATIN MATRICES - The present invention is a substantially non-adhesive elastic gelatin matrix. The matrix is both non-adhesive to wounds, tissues and organs and is also elastic such that it is flexible. The matrix is a lyophilized mixture of protein(s), polymer(s), cross-linking agent(s) and optional plasticizer(s). The invention also provides methods for making the non-adhesive elastic gelatin matrix. | 05-30-2013 |