A microfluidic device for storing a reagent includes a single unit includes a first portion having a reagent storage chamber configured to hold a reagent. The device also includes a second portion having a reaction chamber configured to support the reagent during a reaction process to form a product. The device also includes a valve configured to isolate the reagent storage compartment from the reaction chamber when the valve is in a closed state.

A test method and test apparatus is provided that employs a microfluidic device to characterize properties of a fluid. The microfluidic device has a first inlet port, an outlet port, and a microchannel as part of a fluid path between the first inlet port and the outlet port. While generating a flow of the fluid through the microchannel of the microfluidic device, fluid pressure at the first inlet port of the microfluidic device is measured and recorded in conjunction with varying the controlled temperature of the microchannel of the microfluidic device to characterize the properties of the fluid that flows through the microchannel of the microfluidic device. The properties of the fluid can relate to the clathrate hydrate formation condition of the fluid at the pressure of the flow through the microchannel of the microfluidic device.

Embodiments described herein provide micro-fluidic systems and devices for use in performing various diagnostic and analytical tests. According to one embodiment, the micro-fluidic device includes a sample chamber for receiving a sample, and a reaction chamber for performing a chemical reaction. A bubble jet pump is structured on the device to control delivery of a fluid from the sample chamber to the reaction chamber. The pump is fluidically coupled to one or more chambers of the device using a fluidic channel such as a capillary. A valve may be coupled to one or more chambers to control flow into and out of those chambers. Also, a sensor may be positioned in one or more of the chambers, such as the reactant chamber, for sensing a property of the fluid within the chamber as well as the presence of a chemical within the chamber.

The present invention relates to an automated radiosynthesis device adapted for enhanced automatic disconnection of a disposable kit once a radiosynthesis has been carried out. The automated radiosynthesis device of the invention therefore reduces the time to remove the disposable kit from the radiosynthesis device and reduces radiation exposure to the operator.

A closed system for rehydrating powder and delivering the rehydrated powder to a reactor, may include a liquid reservoir for containing liquid; a syringe configured to contain powder to be rehydrated; a reactor; a controller for controlling operation of the syringe; and a conduit fluidically linking the liquid reservoir to a port of the syringe, fluidically linking the port to the reactor. The controller is configured to operate the syringe so as to draw liquid from the liquid reservoir into the syringe and rehydrate the powder, or to drive the rehydrated powder into the reactor.

Systems and methods are disclosed for synthesizing one or more simple alcohols from mixtures including organic acids, water, and a superparamagnetic catalyst exposed to fluctuating magnetic fields under ambient conditions.

A general-purpose software-reconfigurable chemical process system useful in a wide range of applications is disclosed. Embodiments may include software control of internal processes, automated provisions for cleaning internal elements with solvents, provisions for clearing and drying gasses, and multitasking operation. In one family of embodiments, a flexible software-reconfigurable multipurpose reusable Lab-on-a-Chip or embedded chemical processor is realized that can facilitate a wide range of applications, instruments, and appliances. Through use of a general architecture, a single design can be economically manufactured in large scale and readily adapted to diverse specialized applications. Clearing and cleaning provisions may be used to facilitate reuse of the device, or may be used for decontamination prior to recycling or non-reclaimed disposal. In other embodiments, a flexible software-reconfigurable multipurpose reusable laboratory glassware setup may be realized, sparing talented laboratory staff from repetitive, complex, or low-level tasks occurring in analysis, synthesis, or small-scale chemical manufacturing.

Embodiments described herein provide micro-fluidic systems and devices for use in performing various diagnostic and analytical tests. According to one embodiment, the micro-fluidic device includes a sample chamber for receiving a sample, and a reaction chamber for performing a chemical reaction. A bubble jet pump is structured on the device to control delivery of a fluid from the sample chamber to the reaction chamber. The pump is fluidically coupled to one or more chambers of the device using a fluidic channel such as a capillary. A valve may be coupled to one or more chambers to control flow into and out of those chambers. Also, a sensor may be positioned in one or more of the chambers, such as the reactant chamber, for sensing a property of the fluid within the chamber as well as the presence of a chemical within the chamber.

Provided is a method for producing a nanoparticle having a uniform particle diameter. A method for producing a nanoparticle comprising an amphiphilic block polymer, the method comprising: with use of a nanoparticle production device that includes: a polymer solution supply channel Cp; an aqueous liquid supply channel Cw1, Cw2; a junction J of the channels; a nanoparticle formation channel Cn; and a nanoparticle-containing liquid outlet On, supplying a solution of a polymer and an aqueous liquid to the junction J; forming a nanoparticle while bringing a laminar flow of the polymer solution and a laminar flow of the aqueous liquid into contact with each other; obtaining a liquid containing the formed nanoparticle from the nanoparticle-containing liquid outlet; and controlling a particle diameter of the nanoparticle by measuring a statistic of the particle diameter of the formed nanoparticle in real time, and by controlling at least one of an amount of the polymer solution supplied to the junction and an amount of the aqueous liquid supplied to the junction such that the statistic becomes a desired value.

A method of controlling the temperature of autothermal microchannel reactors is disclosed. A hierarchical control structure employs a distributed temperature controller including a phase change material and a supervisory control system including the control of one or more inputs into the reactor. The phase change material acts as a fast, distributed controller, and the supervisory controller acts over a longer time horizon to mitigate persistent disturbances. A stochastic optimization method for selecting the phase change layer thickness is employed.