The present application relates to cellulose nanocrystals and other anionic carbohydrates and methods of preparation thereof. Specifically, in certain embodiments, the cellulose nanocrystals are modified using ion exchange technology to yield thermally stable or task-specific, dispersible cellulose nanocrystals.

The present invention provides a support for temporary bonding a workpiece such as a thick device wafer. The support comprises a carrier having a supporting surface and an isolation film. A first side of the isolation film is bonded to the supporting surface with a peeling strength of from 0.01 to 50.0 g/cm. The invention also provides a method of using the support to e.g. grind the workpiece in making thinned products such as thin silicon wafer, optical lens, thin LCD glass, and thin rock crystal wafer, among others.

The present invention provides a support for temporary bonding a workpiece such as a thick device wafer. The support comprises a carrier having a supporting surface and an isolation film. A first side of the isolation film is bonded to the supporting surface with a peeling strength of from 0.01 to 50.0 g/cm. The invention also provides a method of using the support to e.g. grind the workpiece in making thinned products such as thin silicon wafer, optical lens, thin LCD glass, and thin rock crystal wafer, among others.

Methods and processes for depositing a fire resistant barrier on a construction material involve coating exposed webbing of, for instance, an I-joist with a fire-resistant material using a wetting layer and a thickening layer. A time period between depositing the wetting layer and thickening layer is controlled to facilitate complete wetting of the exposed webbing. Filler such as fiberglass may be included in the thickening layer. The wetting and thickening layers may be deposited on the webbing in the same application. The construction material, such as the I-joist, may then be subjected to a curing treatment and additional curing period followed by coating the second side using a similar methodology.

An in-line coating machine adapted to coat food products with a particulate coating material has a food products conveyor; a coating device; an excess coating material separation station; an excess coating material recovery conveyor; and a particulate coating material elevator device. An elevator device fill assembly along the recovery conveyor is configured to fill the elevator device with recovered excess coating material. An adjustable discharge opening device controls a discharge opening in the recovered excess coating material bed support. An adjustable upper layer diverter device engages an upper layer of the recovered excess coating material bed passing over the recovered excess coating material bed support and diverts at least a portion of the upper layer at an adjustable rate into the particulate coating material elevator device.

An in-line coating machine adapted to coat food products with a particulate coating material has a food products conveyor; a coating device; an excess coating material separation station; an excess coating material recovery conveyor; and a particulate coating material elevator device. An elevator device fill assembly along the recovery conveyor is configured to fill the elevator device with recovered excess coating material. An adjustable discharge opening device controls a discharge opening in the recovered excess coating material bed support. An adjustable upper layer diverter device engages an upper layer of the recovered excess coating material bed passing over the recovered excess coating material bed support and diverts at least a portion of the upper layer at an adjustable rate into the particulate coating material elevator device.

A staple cartridge assembly for use with a surgical stapling instrument includes a staple cartridge including a plurality of staples and a cartridge deck. The staple cartridge assembly also includes a compressible adjunct positionable against the cartridge deck, wherein the staples are deployable into tissue captured against the compressible adjunct, and wherein the compressible adjunct comprises a first biocompatible layer comprising a first portion, a second biocompatible layer comprising a second portion, and crossed spacer fibers extending between the first portion and the second portion.

A staple cartridge assembly for use with a surgical stapling instrument includes a staple cartridge including a plurality of staples and a cartridge deck. The staple cartridge assembly also includes a compressible adjunct positionable against the cartridge deck, wherein the staples are deployable into tissue captured against the compressible adjunct, and wherein the compressible adjunct comprises a first biocompatible layer comprising a first portion, a second biocompatible layer comprising a second portion, and crossed spacer fibers extending between the first portion and the second portion.

A method for preparing a ratiometric electrochemical miR3123 aptasensor based on a copper-based metal-organic framework (Cu-MOF) composite doped with black phosphorus nanosheets (BPNSs) and thionine (TH) is provided. TH/Cu-MOF is prepared by reacting TH with Cu-MOF precursor, and BPNSs/TH/Cu-MOF is prepared by drop coating the BPNSs and drop coated onto an electrode. A ferrocene (Fc)-labeled single-stranded DNA aptamer is adsorbed on the BPNSs to prepare aptamer-BPNSs/TH/Cu-MOF. Target molecule miR3123 is bonded with the single-stranded DNA aptamer Fc-DNA, Fc-DNA is forced to escape from the BPNSs. Electrochemical signals of Fc are, therefore, weakened while TH signals are slightly affected. The ratiometric electrochemical miR3123 aptasensor is constructed by fitting a linear relationship between peak current intensity ratios I.sub.Fc/I.sub.TH and concentrations of the miR3123.

Inside a heating space of a heating chamber, a first heating treatment of moving a substrate along a substrate moving direction is performed by a first conveyor. After that, first conveyance processing of moving the substrate along a conveying direction is performed by a second conveyor. At this time, source mist is sprayed on the substrate by first thin film forming nozzles. Subsequently, second heating treatment is performed by a third conveyor. After that, second conveyance processing is performed by a fourth conveyor. At this time, source mist is sprayed on the substrate by second thin film forming nozzles.