The present invention relates to sample-to-answer systems, devices, cartridges, and method of using the same for detecting the presence of microorganisms in a sample, such as bacteria.

Devices, systems, and methods for en masse patterning of nucleic acid molecule structures are disclosed. The devices can include microchannels and nanoslits. The microchannels and nanoslits can be connected by parking chambers. The systems and methods can utilize the geometry of the devices in coordination with a voltage application routine to park nucleic acid molecules in the parking chambers and subsequently inject the nucleic acid molecules into the nanoslits. The methods can be utilized to present nucleic acid molecules in a fashion suitable for genomic analysis. The methods can also be utilized to provide size selection of the nucleic acid molecules.

Devices, systems, and methods for en masse patterning of nucleic acid molecule structures are disclosed. The devices can include microchannels and nanoslits. The microchannels and nanoslits can be connected by parking chambers. The systems and methods can utilize the geometry of the devices in coordination with a voltage application routine to park nucleic acid molecules in the parking chambers and subsequently inject the nucleic acid molecules into the nanoslits. The methods can be utilized to present nucleic acid molecules in a fashion suitable for genomic analysis. The methods can also be utilized to provide size selection of the nucleic acid molecules.

3D nanochannel interleaved devices for molecular manipulation are provided. In one aspect, a method of forming a device includes: forming a pattern on a substrate of alternating mandrels and spacers alongside the mandrels; selectively removing the mandrels from a front portion of the pattern forming gaps between the spacers; selectively removing the spacers from a back portion of the pattern forming gaps between the mandrels; filling i) the gaps between the spacers with a conductor to form first electrodes and ii) the gaps between the mandrels with the conductor to form second electrodes; and etching the mandrels and the spacers in a central portion of the pattern to form a channel (e.g., a nanochannel) between the first electrodes and the second electrodes, wherein the first electrodes and the second electrodes are offset from one another across the channel, i.e., interleaved. A device formed by the method is also provided.

An example of a flow cell includes a substrate and a cured, patterned resin on the substrate. The cured, patterned resin has nano-depressions separated by interstitial regions. Each nano-depression has a largest opening dimension ranging from about 10 nm to about 1000 nm. The cured, patterned resin also includes an interpenetrating polymer network. The interpenetrating polymer network of the cured, patterned resin includes an epoxy-based polymer and a (meth)acryloyl-based polymer.

An apparatus includes a plate and a microheater. The plate defines a sample reservoir, component reservoirs, an outlet, a microfluidic channel, and branches. The sample reservoir is configured to hold a specified sample volume of a hydrocarbon sample. Each component reservoir is configured to hold a respective specified component volume of a different one of the hydrocarbons. The microfluidic channel extends from the sample reservoir to the outlet. Each branch connects a different one of the component reservoirs to the microfluidic channel. The microheater is an electrical resistor that is configured to provide heat to the hydrocarbon sample held in the sample reservoir. The hydrocarbon sample fractionates into the hydrocarbons, which are distributed across the component reservoirs, as the hydrocarbon sample flows from the sample reservoir to the outlet in response to receiving the heat from the microheater.

Methods for producing engineered exosomes and other vesicle-like biological targets, including allowing a target vesicle-like structure to react and bind with immunomagnetic particles; capturing the immunomagnetic particle/vesicle complex by applying a magnetic field; further engineering the captured vesicles by surface modifying with additional active moieties or internally loading with active agents; and releasing the engineered vesicle-like structures, such as by photolytically cleaving a linkage between the particle and engineered vesicle-like structures, thereby releasing intact vesicle-like structures which can act as delivery vehicles for therapeutic treatments.

The particle trapping device according to the present invention comprises: a lead-in channel; a flattened channel disposed on the downstream side of the lead-in channel; a rectangular channel disposed on the downstream side of the flattened channel; and a particle pit trap disposed at least on a first inner wall face of the rectangular channel, wherein the lead-in channel has a channel cross-section larger than a channel cross-section of the flattened channel; the flattened channel has a flat channel cross-section whose the width is longer than its height; the rectangular channel has a rectangular channel cross-section, and is provided with the first inner wall face, a second inner wall face opposed to the first inner wall face, a third inner wall face, and a fourth inner wall face opposed to the third inner wall face; and the lead-in channel, the flattened channel, the rectangular channel, and the particle pit trap are characterized by being configured in such a way that a portion of liquid containing target particles and flowing through the lead-in channel flows into the flattened channel; the target particles contained in the liquid that had flowed through the flattened channel flow into the rectangular channel; and the target particle that had flowed through the rectangular channel enters into the particle pit trap and is trapped therein.

A method of obtaining a numerical model is disclosed. The numerical model correlates estimated line width values to minimum pressure for gas bubble generation (MPGBG) values. An MPGBG value of each capillary tube in the reference group is measured for a liquid. A nanoparticle composition is deposited, under standard conditions, on substrate(s) from each respective reference capillary tube, to form nanoparticle lines. A line width of each of the nanoparticle lines deposited using each respective reference capillary tube is measured by a microscope apparatus. A numerical model that correlates estimated line width values to MPGBG values for the liquid is calculated.

Techniques relate to forming a sorting device. A mesh is formed on top of a substrate. Metal assisted chemical etching is performed to remove substrate material of the substrate at locations of the mesh. Pillars are formed in the substrate by removal of the substrate material. The mesh is removed to leave the pillars in a nanopillar array. The pillars in the nanopillar array are designed with a spacing to sort particles of different sizes such that the particles at or above a predetermined dimension are sorted in a first direction and the particles below the predetermined dimension are sorted in a second direction.