The invention provides methods for identifying a patient as likely to have an onset of massive hemorrhage. In one embodiment, the invention provides a method for identifying a patient as likely to have an onset of massive hemorrhage, the method comprising measuring at least one of first coagulation characteristic parameter reflective of a clotting time in a sample of blood of the patient, a second coagulation characteristic parameter reflective of clot formation in a sample of blood of the patient using the viscoelastic assay to obtain a second result; a third coagulation characteristic parameter reflective of clot strength in a sample of blood of the patient using the viscoelastic assay to obtain a third result; and a fourth coagulation characteristic parameter reflective of clot lysis in a sample of blood of the patient using the viscoelastic assay to obtain a fourth result; wherein, a positive for at least one of the first result, second result, third result and fourth result identifies the patient as likely to have an onset of massive hemorrhage.

Systems and methods for analysis of a whole blood sample from an individual to determine the platelet function and coagulation status of the individual in a substantially automated and efficient matter. Also provided here are systems, reagent kits, and methods for concurrent assessment of platelet function and coagulation as they interact during hemostasis.

Machine learning analysis for classifying agglutination of fluid samples. A method includes scanning a unique scannable code printed on a test card, wherein the test card comprises a negative control fluid sample, a positive control fluid sample, and a test fluid sample. The method includes capturing an image of the test card and providing the image of the test card to a machine learning algorithm configured to assess agglutination of the test fluid sample based on the image. The method includes receiving from the machine learning algorithm one or more of a qualitative analysis or a quantitative analysis of the agglutination of the test fluid sample.

This invention provides a method that enables determining the fibrinogen concentration in plasma of a sample. The method comprises: computing the fibrinogen concentration in whole blood of the sample using magnetic particles; computing the waveform-based hematocrit value based on the peak value of the movement signal of the magnetic particles; subjecting the fibrinogen concentration in whole blood to hematocrit correction using the waveform-based hematocrit value; and computing the fibrinogen concentration in plasma of the sample.

The present invention provides a pipette tip, which can be used in in-vitro diagnostics, in particular in the diagnostic testing of body fluids, such as in coagulation testing. The Pipette tip contains two constituents in a spatially separated manner. The present invention furthermore provides a method of performing such diagnostics, e.g. coagulation analysis, and to the use of the pipette tip in such diagnostic testing.

Provided is a method for accurately measuring coagulation time of blood specimens showing various coagulation reactions. The method for measuring blood coagulation time includes acquiring coagulation reaction P(i) of a subject specimen and reaction velocity V(i); calculating a calculation start point Te by using the ratio of the V(i) to maximum reaction velocity as an index; and calculating time Tc giving P(Tc)=P(Te)×N % (0<N<100) and determining the Tc as the blood coagulation time.

The present invention relates to a platelet testing device using blockage phenomenon, comprising: a sample chamber containing blood sample; a microfluidic tube which is in fluid communication with the sample chamber and through which the blood sample flows; and a microbead packing arranged on a flow path of the blood sample of the microfluidic tube; wherein the microbead packing comprises: a packing pipe which constitutes a part of the flow path of the blood sample; and a plurality of microbeads contained in the packing pipe and arranged to be in close contact with each other so as to form voids between the microbeads, whereby function of the platelet is tested by blockage phenomenon of the voids due to the platelet in the blood sample which flows through the microfluidic tube from the sample chamber according to the present invention.

A method of determining the result of an assay in a microfluidic device includes the steps of: dispensing a sample droplet onto a first portion of an electrode array of the microfluidic device; dispensing a reagent droplet onto a second portion of the electrode array of the microfluidic device; controlling actuation voltages applied to the electrode array to mix the sample droplet and the reagent droplet into a product droplet; sensing a dynamic property of the product droplet; and determining an assay of the sample droplet based on the sensed dynamic property. The dynamic property is a physical property of the product droplet that influences a transport property of the product droplet on the electrode array. Example dynamic properties of the product droplet include the moveable state, split-able state, and viscosity based on droplet properties. The method may be used to perform an amoebocyte lysate (LAL) assay.

This invention relates to a method and apparatus for determining the activity of coagulation factors in dilute capillary whole blood, citrated whole blood and citrated plasma. It also includes the detection of the hemoglobin amount in a whole blood sample so a correction of the clotting time can be performed thereby making the clotting time values independent of hemoglobin and hematocrit effect.

A medical analyzer and coagulation profiler performs various interrogations on specimens. A motor with reduction gearing moves and a video camera observes the samples, the cartridges or parts thereof. Changes in images are compared and recorded with a central processor that controls a display. Power supply, temperature controller, motor and gearing are mounted in a box which attaches to a smartphone. The smartphone provides the video camera, illumination and central processor that control the movement, temperature and display. The device makes testing simpler for small hospitals, clinics, ambulances, remote locations and individuals and controls a number of parallel or serial devices operating simultaneously or sequentially. A cartridge insertion actuates a circular motion to generate a blood profile based on changes. Change is analyzed with a video camera and processor such as in a smartphone and is plotted to show an amplitude and time. A smartphone provides a specific movement pattern.