An object of the present invention is to provide an analysis apparatus in which local analysis of a substrate with ICP-MS is automated. The present invention relates to an automatic analysis apparatus for a local region of a substrate, including: a nozzle for local analysis having: analysis-liquid supply means that ejects analysis liquid onto a substrate; analysis-liquid discharge means that takes the analysis liquid including an object to be analyzed from the substrate into the nozzle to feed the analysis liquid to a nebulizer; and exhaust means including an exhaust channel in the nozzle; automatic liquid-feed means that automatically feeds the collected analysis liquid to ICP-MS; flow adjustment means that adjusts the flow of the analysis liquid; and automatic control means that simultaneously performs local analysis and analysis of the object to be analyzed with the ICP-MS to perform automatic analysis to a plurality of adjacent predetermined regions, successively.

The invention generally relates to microfluidic devices that include channels that are slidable relative to each other and methods of use thereof. In certain embodiments, the invention provides a microfluidic device that includes a first channel having an open end, and a second channel having an open end. The first and second channels are slidable relative to each other such that when the open end of the first channel and the open end of the second channel are aligned with each other, fluid flows from the first channel into the second channel.

The invention provides mechanical devices that can be used to combine reagents and discover their effects on living cells. A device of the invention holds liquids in open-ended channels and transfers liquids from one channel to another by bringing a second channel into proximity and alignment with an open end of a first channel. Channels of the device can include fluid partitions (e.g., water-oil-water emulsions) that include living cells. The device includes a mechanical system the operation of which causes a receiving channel to pass among supply channels, aligning with each in turn, to pick up chemicals from those channels and make new combinations within the receiving channel. The device then presents those new chemical combinations to the living cells within their respective partitions, thereby allowing for the determination of the effects of those combinations on living cells.

Methods and apparatuses for mechanically controlling microfluidic movement using a force applicator and an elastically deformable sheet are described herein. These apparatuses may include a mechanical microfluidics apparatus and a cartridge. A microfluidic droplet may be moved or displaced within an air gap of the cartridge by applying a compressive force locally and selectively reduce the gap width of the air gap near the microfluidic droplet causing the microfluidic droplet to move toward the reduced gap. Compressive forces may also be used to divide, join, mix or perform other operations on the microfluidic droplets.