Systems, methods, and devices for analyzing small volumes of fluidic samples, as a non-limiting example, less than twenty microliters are provided. The devices are configured to make a first sample reading, for example, measure an energy property of the fluid sample, for example, osmolality, make a second sample reading, for example, detecting the presence or concentration of one or more analytes in the fluid sample, or make both the first sample reading and the second sample reading, for example, measuring the energy property of the fluid sample as well as detecting the presence or concentration of one or more analytes in the fluid sample.

A fluidic device (10) is described. The fluidic device (10) comprises the first part (110) and the second part (120). The first part (110) comprises a first inlet (111) and a first outlet (112), mutually spaced apart. The second part (120) comprises a first chamber (121) arranged to contain a predetermined first amount A1 of a first fluid F1 therein and a first wall portion (122) arranged to contain, at least in part, the first fluid F1 in the first chamber (121). The fluidic device (10) is arrangeable in a first configuration, wherein the first part (110) is fluidically isolated from the first chamber (121). The fluidic device (10) is arrangeable in a second configuration, wherein the first inlet (111) and the first outlet (112) are fluidically coupled via the first chamber (121), whereby increasing a first pressure P1 in the first chamber (121) via the first inlet (111) urges at least a part of the predetermined first amount A1 of the first fluid F1 through the first outlet (112).

A microfluidic device comprises upper and lower spaced apart substrates defining a fluid chamber therebetween; an aperture for introducing fluid into the fluid chamber; a plurality of independently addressable array elements, each array element defining a respective region of the fluid chamber; and control means for addressing the array elements. The control means are configured to: determine that a working fluid has been introduced into a first region of the fluid chamber; and provide an output to a user to indicate that the working fluid is present in the first region. Once the working fluid is in the first region, the fluid applicator used to dispense the fluid can be removed without any risk of accidentally withdrawing dispensed working fluid from the microfluidic device. In the case of manual loading of the working fluid the output may inform a user that it is safe to remove the applicator, or in the case of automatic or robotic loading the output signal may be provided to the system controlling the automatic or robotic loading of fluid so that the system can remove the fluid applicator.

A solid reagent containment unit is formed by a support; a frame body fixed to the support and delimiting internally, together with the support, an analysis volume; a reagent-adhesion structure within the analysis volume; and at least one reagent cavity, which extends within the reagent-adhesion structure. The reagent-adhesion structure is of an adhesion material embossable at temperatures lower by 6-8° C. than its own melting point and has a melting point such as not to interfere with the analysis. The reagent cavity forms a retention wall, laterally surrounding the reagent cavity, and houses dried reagents. The adhesion material is chosen among wax, such as paraffin, a polymer, such as polycaprolactone, a solid fat, such as cocoa butter, and a gel, such as hydrogel or organogel.

A capillary driven microfluidic system and a biosensing device including the capillary driven microfluidic system are provided. The capillary driven microfluidic system includes: a first substrate comprising at least one microfluidic channel ending in an opening, and having, adjacent to the opening, a protruding element; and a second substrate comprising at least one open cavity. The at least one protruding element and the at least one cavity include at least one hydrophilic surface. In addition, the at least one protruding element and the at least one cavity may be adapted for engaging with one another for providing transfer of a fluid between the first substrate and the second substrate. A space between the at least one hydrophilic surface of the at least one protruding element and the at least one hydrophilic surface of the at least one cavity is provided, where the separation between said surfaces is such that capillary forces are generated on the fluid upon entering inside the space.

A solid reagent containment unit is formed by a support; a frame body fixed to the support and delimiting internally, together with the support, an analysis volume; a reagent-adhesion structure within the analysis volume; and at least one reagent cavity, which extends within the reagent-adhesion structure. The reagent-adhesion structure is of an adhesion material embossable at temperatures lower by 6-8° C. than its own melting point and has a melting point such as not to interfere with the analysis. The reagent cavity forms a retention wall, laterally surrounding the reagent cavity, and houses dried reagents. The adhesion material is chosen among wax, such as paraffin, a polymer, such as polycaprolactone, a solid fat, such as cocoa butter, and a gel, such as hydrogel or organogel.

A sampling structure, a sealing structure and a detection assembly are provided. The sampling structure includes a first main body, a second main body and a third main body. The first main body includes a first channel, the first channel includes a first opening that is exposed. The second main body is connected to the first main body and includes a second channel and at least one partition column located in the second channel, the second channel is linked with the first channel, and a first gap is between the partition column and a channel wall of the second channel. The third main body is connected to the second main body and includes a chamber, the chamber is linked with the second channel and is capable of containing a sample.

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.

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.

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.