A blood sample collection and/or storage device includes a two-piece housing that encompasses a port at which a fingertip blood sample is collected at a sample port. After the sample is taken, the two-piece housing is moved to a closed position deposit the sample onto a storage membrane Embodiments of the device include a one or more capillaries with movable plungers that dispense fluid from the sample port onto the membrane as the housing is closed. A desiccant, which may be held in place by a backbone structure within the housing, is positioned adjacent the membrane. The housing may also be opened to access the stored sample for further processing.

Various apparatus, systems, and methods for measuring a solution characteristic of a sample comprising microorganisms are disclosed. In one embodiment, a sensor apparatus is disclosed comprising a sample container comprising a sample chamber configured to receive the sample and a reference sensor component comprising a reference conduit having a reference conduit cavity defined therein. The reference conduit cavity can be at least partially filled with a reference buffer gel, buffer solution, or wicking component. A segment of the reference conduit can extend into the sample chamber. A reference electrode material can be positioned at a proximal end of the wicking component or extend partially into the reference conduit cavity. The sensor apparatus can also comprise an active sensor component having an active electrode in fluid contact with the sample. The sample in the sample chamber can be aerated through an aeration port defined along a surface of the sample container.

The present invention discloses a method for preparing a micro-channel array plate, comprising the steps of : (1) arranging a first optical fiber glass rod and a second optical fiber glass rod closely, melting the two glass rods into a whole at a high temperature to obtain a melted glass rod, drawing the melted glass rod at least one time into a longer and thinner glass rod than the melted glass rod, and cutting the drawn glass rod into small pieces to obtain a micro-channel array plate blank, wherein the corrosion resistance of the first optical fiber glass rod and the second optical fiber glass rod to the same corrosive liquid is different; (2) corroding the micro-channel array plate blank by a corrosive liquid to obtain a micro-channel array plate crude product with through holes; and (3) conducting hydrophobic treatment on the micro-channel array plate crude product to obtain the micro-channel array plate.

The invention relates to a method for producing at least one pattern (2) on a carrier surface (7) of a carrier (3), wherein the method comprises the following steps: a. adding a first fluid (4) to the carrier surface (7) and b. adding a second fluid (5), wherein the second fluid (5) is immiscible with the first fluid (4) and at least partially covers the first fluid (4) and c. adding at least one object (6) above the carrier surface (7), d. generating the pattern (2) by a relative movement between the object (6) and the carrier (3) in which a force is exerted on the object (6) from a force generating means (28), wherein the force transmission from the force generating means (28) on the object (6) is contactless and the pattern (2) is generated by a portion of the second fluid (15) wetting the carrier surface (7).

Described herein are systems relating to a continuous-flow instrument that includes all necessary components for digital droplet quantification without the need to introduce key reagents or collect and transfer droplets between stages of instrument operation. Digital quantification can proceed without any additional fluid or consumable handling and without exposing fluids to risk of external contamination.

Disclosed herein are methods for quantifying contact lens deposition. An example method may comprise disposing a contact lens sample in a fluid well. The example method may comprise disposing a volume of tear fluid in the well with the contact lens sample. The example method may comprise capturing pre-rinse images of the contact lens sample. The example method may comprise rinsing the contact lens sample. The example method may comprise capturing post-rinse images of the contact lens after the rinsing. The example method may comprise determining, using one or more of the tear images or the post-rinse images, a deposition metric. The example method may comprise outputting the deposition metric.

Disclosed in one aspect is a method for performing a complete blood count (CBC) on a sample of whole blood by metering a predetermined amount of the whole blood and mixing it with a predetermined amount of diluent and stain and transferring a portion thereof to an imaging chamber of fixed dimensions and utilizing an automated microscope with digital camera and cell counting and recognition software to count every white blood cell and red blood corpuscle and platelet in the sample diluent/stain mixture to determine the number of red cells, white cells, and platelets per unit volume, and analyzing the white cells with cell recognition software to classify them.

An apparatus and method to detect disease-specific antigens assists in disease diagnosis. Point-of-care (POC) micro biochip incorporates at least one hydrophilic microchannel for controlled and self-driven flow of body fluid. Metallic nano-interdigitated electrodes disposed within the channels give enhanced sensitivity detection. Microchannel controls flow and amplifies a capillary effect. Electrodes are fabricated on microchannel surface to detect biomolecular interactions. When a sample flows through microchannel, disease-specific antigens from the sample form antigen-antibody complex with antibodies immobilized on electrodes. Antigen-antibody interaction is detected via an electrical change in the biochip's nano circuit. Each electrode may include a different antibody to detect different antigens. Capacitance during antigen-antibody interaction without microfluidic flow is higher than with microfluidic flow due to immobilized antibodies instability on sensing surface caused by shear stress. POC biochip provides nano level detection of many disease-specific antigens of any type based on micro volume or single drop sized sample.

A microfluidic component used for measuring electrical impedance across a biological object, the component including a microfluidic space including a zone referred to as measurement zone, at least two electrodes arranged facing one another on each side of the measurement zone, the component being formed by assembling, along a longitudinal junction plane, at least two superposed layers referred to as lower layer and upper layer, the two layers each having at least one cavity, the two layers being assembled with one another in such a way as to position the two cavities facing one another in order to form the microfluidic space.

In some embodiments, the present invention is a device, including: a swab including an absorptive component attached to a stem, an extraction chamber configured to receive the swab and position the absorptive component of the swab configured to be in fluid communication with an extraction reagent, a test strip configured to be brought in fluid communication with the extraction reagent following extraction of the analyte from the biological sample, including: a sample receiving portion configured to accept a sample, a site on the strip where the analyte-specific labeled reagent has been incorporated, such reagent configured to bind the analyte from the biological sample, a capture portion configured to receive: the analyte from the biological sample and the analyte-specific labeled reagent so as to result in displaying a positive or negative result at the completion of the assay, and an adsorbent pad attached to the test strip.