Aspects of the subject disclosure may include, for example, an apparatus comprising: a membrane, wherein the membrane has a first side and a second side, wherein the membrane has a first pore disposed therein, wherein the first pore extends through the membrane from the first side of the membrane to the second side of the membrane, wherein the membrane has a second pore disposed therein, and wherein the second pore extends through the membrane from the first side of the membrane to the second side of the membrane; a first channel disposed on the first side of the membrane, wherein the first channel is along a first longitudinal axis; a second channel disposed on the first side of the membrane, wherein the second channel is along a second longitudinal axis, and wherein the first channel and the second channel are disposed side by side adjacent to each other; a third channel disposed on the second side of the membrane, wherein the third channel is along a third longitudinal axis, wherein the third channel is in first fluid communication with the first channel via the first pore, and wherein the third channel is in second fluid communication with the second channel via the second pore; and one or more sensors disposed at one or more locations to facilitate sequencing of a molecule that extends from the first channel, through the first pore across at least a portion of the third channel, and through the second pore into the second channel. Additional embodiments are disclosed.

Disclosed herein are ruthenium-containing materials, such as ruthenium containing materials having a double layer capacitance ranging from between about 180 pF/um.sup.2 to about 320 pF/um.sup.2. In some embodiments, the ruthenium-containing materials are suitable for use in electrodes. In some embodiments, the ruthenium-containing materials are suitable for use in nanopore sequencing devices.

The present invention relates to a device comprising a biomolecular processor. Each biomolecular processor has one or more bioreactor chambers defined by a solid substrate; a support structure within each bioreactor; a cleaving enzyme immobilized to the support structure and operatively positioned within the bioreactor chamber to cleave monomer or multimer units of a biopolymer molecule operatively engaged by the cleaving enzyme; and one or more time-of-flight channels formed in the solid substrate and fluidically coupled to said one or more bioreactor chambers. Each of the time-of-flight channels have two or more sensors including at least (i) a first sensor contacting the time-of-flight channel proximate to the input end of the channel and (ii) a second sensor contacting the time-of-flight channel proximate to the output end of channel. The present invention further relates to methods of sequencing and identifying biopolymer molecules using the device.

Among others, the present invention provides apparatus for interacting with a biological subject to detect circulating tumor cells therein, comprising one device for sending a signal to the biological subject and optionally receiving a response to the signal from the biological entity.

Methods of analyzing features such as the physical size of macromolecules or biomarkers along large genomic DNA molecules were disclosed as wen as the devices for carrying out such high throughput analysis in a massively parallel fashion. Methods of fabricating such devices are also disclosed.

At least one exemplary embodiment of the invention is directed to a molecular diagnostic device that comprises a cartridge configured to eject samples comprising genomic material into a microfluidic chip that comprises an amplification area, a detection area, and a matrix analysis area.

Methods of forming a chip with fluidic channels include forming (e.g., milling) at least one nanofunnel with a wide end and a narrow end into a planar substrate, the nanofunnel having a length, with width and depth dimensions that both vary over its length and forming (e.g., milling) at least one nanochannel into the planar substrate at an interface adjacent the narrow end of the nanofunnel.

Provided herein are methods and devices for single object detection. The methods and devices can be used to identify a plurality of epigenetic markers on a genetic material, or a chromatin, encompassing fragments thereof. The invention provides for the characterization of the genetic material flowing through a channel in a continuous body of fluid based on detection of one or more properties of the genetic material. The methods and systems provided herein allow genome-wide, high-throughput epigenetic analysis and overcome a variety of limitations common to bulk analysis techniques.

A device for passing a biopolymer molecule includes a nanochannel formed between a surface relief structure, a patterned layer forming sidewalls of the nanochannel and a sealing layer formed over the patterned layer to encapsulate the nanochannel. The surface relief structure includes a three-dimensionally rounded surface that reduces a channel dimension of the nanochannel at a portion of nanochannel and gradually increases the dimension along the nanochannel toward an opening position, which is configured to receive a biopolymer.

A delivery system for a sensor chip includes a plurality of selectable ports and a two-way pump port selectively connectable to each of the selectable ports. The two-way pump port is configured to allow material to be drawn or delivered from or to the two-way pump port. The delivery system also includes a chamber and a bypass waste channel that is selectively connectable to the two-way pump port. The plurality of selectable ports includes a selectable chamber port connected to the chamber and the chamber has a chamber waste exit. Material may selectively flow through the chamber to a waste collection via the chamber waste exit or flow to the waste collection via the bypass waste channel that bypasses the chamber waste exit.