The present invention relates to methods, devices, instruments, processes, and systems for the highly specific, targeted molecular analysis of regions of human genomes and transcriptomes from the blood, i.e. from cell free circulating DNA, exosomes, microRNA, IncRNA, circulating tumor cells, or total blood cells. The technology enables highly sensitive identification and enumeration of mutation, expression, copy number, translocation, alternative splicing, and methylation changes using spatial multiplexing and combined nuclease, ligation, polymerase, and sequencing reactions. Such technology may be used for non-invasive early detection of cancer, non-invasive cancer prognosis, and monitoring both treatment efficacy and disease recurrence of cancer.

A system for filling multiple sterile containers includes a filter with an inlet port and multiple outlet ports, the outlet ports being pre-attached to sterile containers by respective filling lines of each container. Each container has an interior and each of the respective filling lines are connected to a respective container interior. The respective filling lines are sealed to the outlet ports and the containers such that the container interiors are isolated from an external environment except the inlet port, via the filter, forming a combined interior volume which is sterile. A container that is connectable to an outlet port the system has a bladder, a first tube and a second tube connected to the bladder, and a sterilizing filter. The container, the first tube and the second tube, and the sterilizing filter are sterile before water is flowed through the sterilizing filter into the bladder.

A novel microfluidic chip is proposed for performing a chemical or biochemical test in a metered reaction volume. The microfluidic chip has a body which defines an inner flow volume. An inlet has been provided to the body for connecting the inner flow volume to the ambient space. A waste channel forms part of the inner flow volume and is in fluid communication with the inlet. A sample channel also forms part of the inner flow volume and is in fluid communication with the inlet. The sample channel includes a first hydrophobic stop and a second hydrophobic stop at a distance from the first hydrophobic stop so as to provide a metered reaction volume there between. An expelling channel is in fluid communication with the metered reaction volume of the sample channel through the first hydrophobic stop. A sample reservoir is in fluid communication with the metered reaction volume of the sample channel through the second hydrophobic stop.

In some aspects, the present disclose provides methods for amplifying and quantifying nucleic acids. Methods for amplifying and quantifying nucleic acids comprise isolating a sample comprising nucleic acid molecules into a plurality of microchambers, performing a polymerase chain reaction on the plurality of microchambers, and analyzing the results of the polymerase chain reaction. In some aspects, the present disclosure provides devices consistent with the methods herein.

Microfluidic devices are provided for separating particulates that have a major dimension above a predetermined threshold value from a fluid, the device comprising an inlet, an inlet channel, a curved channel, a separation chamber, a first outlet and a second outlet; the inlet being connected to the inlet channel, the inlet channel is connected to the curved channel, the curved channel is connected to the separation chamber and the separation chamber is connected to the first outlet by a first outlet channel, and the separation chamber is connected to the second outlet by a second outlet channel; the first outlet channel comprises a serpentine portion; wherein the second outlet channel branches from the separation chamber substantially perpendicular to the first outlet channel.

A sequencing device has at least one sequencing channel configured to fluidically connect a first gap with a second gap. The sequencing channel is formed as a cavity in the region of the first gap and is formed as a pore in the region of the second gap. The pore has a smaller cross section than the cavity.

A microchamber array device having built-in reaction microchambers, in which the dilution ratio can be greatly increased at the same time as dramatically raising cell recovery efficiency, and an inspection object analysis method using said device are provided. This microchamber array device is provided with: a microchamber array 1 for cell capture by electrophoresis comprising an arrangement of a substrate 2, electrodes 3 and photoresists 4; and a reaction microchamber array 6 which is separated from the capture microchamber array 1, and which is formed from reaction microchamber 8 comprising micro channels 7 arranged so as to be opposite of the aforementioned microchamber array 1.

Multistage deterministic lateral displacement devices, methods of forming the devices, and methods of separating a fluid mixture including particles having three or more particle sizes generally include a first module and at least one additional module. Each module includes a condenser portion and a separate portion. The condenser portion is generally configured to focus a streamline of all particles to a center of a channel whereas the separator separates the streamline of all particles into two different streamlines. One of the streamlines focuses the largest particles in the fluid mixture along a sidewall of the channel and the other streamline of smaller particles is between opposing sidewalls that define the channel. Each additional module can be used to further separate the largest particles remaining in the fluid mixture from the smaller particles.

A platform and method for conducting multi-variable combinational interactions are provided. An array of multiplexing chambers in formed in a body. The body also includes a common well communicating with each multiplexing chamber of the array of multiplexing chambers and a plurality of variable wells. Each of variable wells communicates with at least one multiplexing chamber of the array of multiplexing chambers. The common well is loaded with a first variable and different variables are loaded in each of the plurality of variable wells. The interaction of the first variable with at least one of the different variables in each multiplexing chamber of the array of multiplexing chambers is observed.

Among others, the present invention provides micro-devices for detecting or treating a disease, each comprising a first micro sensor for detecting a property of the biological sample at the microscopic level, and an interior wall defining a channel, wherein the micro sensor is located in the interior wall of the micro-device and detects the property of the biological sample in the microscopic level, and the biological sample is transported within the channel.