There is provided a microfluidic chip for sensing an analyte in a sample by colorimetry. The microfluidic chip comprises: an inlet adapted to receive the sample; an incubation chamber having an incubation chamber inlet fluidly connected to the inlet downstream thereof, to incubate the analyte in the sample; a filter barrier fluidly connected to the incubation chamber, downstream of the incubation chamber inlet; a sensing chamber fluidly connected to the incubation chamber, downstream of the filter barrier, the sensing chamber having a plasmonic nanosurface, the plasmonic nanosurface including nanostructures protruding from the plasmonic nanosurface, the nanostructures having a size that is smaller than that of the diffraction limit of light, the nanostructures having a metallic layer that is plasmon-supported on top of a back reflector layer; and an outlet fluidly connected to the sensing chamber downstream thereof.

Sub-millimeter scale three-dimensional (3D) structures are disclosed with customizable chemical properties and/or functionality. The 3D structures are referred to as drop-carrier particles. The drop-carrier particles allow the selective association of one solution (i.e., a dispersed phased) with an interior portion of each of the drop-carrier particles, while a second non-miscible solution (i.e., a continuous phase) associates with an exterior portion of each of the drop-carrier particles due to the specific chemical and/or physical properties of the interior and exterior regions of the drop-carrier particles. The combined drop-carrier particle with the dispersed phase contained therein is referred to as a particle-drop. The selective association results in compartmentalization of the dispersed phase solution into sub-microliter-sized volumes contained in the drop-carrier particles. The compartmentalized volumes can be used for single-molecule assays as well as single-cell, and other single-entity assays.

The present disclosure pertains to a microfluidic platform. The microfluidic platform includes a top layer having a top inlet and outlet, a center layer having a center inlet and outlet, and a bottom layer having a bottom inlet and outlet. The microfluidic platform further includes a first porous membrane between the top and center layer, a second porous membrane between the center and bottom layer, a first electrode disposed on at least one of the top and bottom layers, and a second electrode disposed on at least one of the top and bottom layers. Additionally, the present disclosure pertains to a method for selective isolation. The method includes flowing a sample through a microfluidic platform, isolating a first component from the sample in a top layer, isolating a second component from the sample in a center layer, and isolating a third component from the sample in a bottom layer.

A force sensing probe (100) for sensing snap-in and/or pull-off force of a liquid droplet (111) brought into and/or separated from contact with a hydrophobic sample surface (151), respectively, comprises: a sensing tip (101); a sensor element (102) connected to the sensing tip, capable of sensing sub-micronewton forces acting on the sensing tip in a measurement direction; and a droplet holding plate (104) having a first main surface (105) and a hydrophilic second main surface (106) connected via a peripheral edge surface (107), and being attached via the first main surface to the sensing tip (101) perpendicularly relative to the measurement direction for receiving and holding a liquid droplet (111) as attached to the second main surface; the droplet holding plate comprising an electrically conductive surface layer (115), the first and the second main surfaces and the peripheral edge surface being defined by the surface layer.

A method of manipulating microdroplets having an average volume in the range 0.5 femtolitres to 10 nanolitres comprised of at least one biological component and a first aqueous medium having a water activity of a.sub.w1 of less than 1 is provided. It is characterised by the step of maintaining the microdroplets in a water-immiscible carrier fluid which further includes secondary droplets having an average volume less than 25% of the average volume of the microdroplets up to and including a maximum of 4 femtolitres and wherein the volume ratio of carrier fluid to total volume of microdroplets per unit volume of the total is greater than 2:1. The method may be employed for example with microdroplets containing biological cells or with microdroplets containing single nucleoside phosphate such as are prepared in a droplet-based nucleic acid sequencer. The method is suitable

An apparatus for biological reactions is provided. The apparatus includes a substrate and a plurality of reaction sites within the substrate. A surface of the substrate is configured to have a first hydrophilicity and each surface of the plurality of reaction sites is configured to have a second hydrophilicity to load a substantial number of reaction sites with a sample volume. The sample volume of each loaded reaction site is substantially confined to its respective reaction site. The sample volume is configured to undergo a biological reaction within the reaction site.

An apparatus and method for performing analysis and identification of molecules have been presented. In one embodiment, a portable molecule analyzer includes a sample input/output connection to receive a sample, a nanopore-based sequencing chip to perform analysis on the sample substantially in real-time, and an output interface to output result of the analysis.

Provided herein is a method of loading wells with a liquid droplet, or a portion thereof, wherein each liquid droplet comprises solid supports and a detergent or surfactant, such that the detergent or surfactant reduces the contact angle between the liquid droplet and the wells. Also provided is a method of detecting and quantifying an analyte of interest in a sample, which involves loading wells in an array with a liquid droplet according to aforementioned method, wherein the liquid droplet comprises an analyte captured on a solid support.

The present disclosure provides a device for separating biomolecules comprising a substrate having a planar surface, nanowires disposed on at least a portion of the planar surface, and a fluid chamber formed to include at least a portion of the nanowires.

An apparatus for biological reactions is provided. The apparatus includes a substrate and a plurality of reaction sites within the substrate. A surface of the substrate is configured to have a first hydrophilicity and each surface of the plurality of reaction sites is configured to have a second hydrophilicity to load a substantial number of reaction sites with a sample volume. The sample volume of each loaded reaction site is substantially confined to its respective reaction site. The sample volume is configured to undergo a biological reaction within the reaction site.