Abstract: Systems and methods for characterizing immune response to infection using cellular analysis, such as a hematological cellular analyzer. In some instances, the immune response may be characterized as normal or abnormal based on one or more blood cell population parameters. In some instances, abnormal characterization may be used to identify patients with sepsis or at elevated risk of developing sepsis.

Abstract: Systems and methods for characterizing immune response to infection using cellular analysis, such as a hematological cellular analyzer. In some instances, the immune response may be characterized as normal or abnormal based on one or more blood cell population parameters. In some instances, abnormal characterization may be used to identify patients with sepsis or at elevated risk of developing sepsis.

Abstract: Systems and methods of assessing a probability that an individual will develop sepsis are provided. The systems and methods can include obtaining a set of parameters associated with the individual including white blood cell count (WBC) and monocyte distribution width (MDW) value, and determining whether the set of parameters provides an elevated risk status by comparing at least the WBC and the MDW value with respective predetermined criteria. In the event that the set of parameters is determined to provide the elevated risk status, the systems and methods can further include obtaining a secondary parameter associated with the individual; and providing the probability that the individual will develop sepsis.

Abstract: Systems and methods for providing clinical decision support information including one or more clinical acuity recommendations to a clinician is provided. The systems and methods can include obtaining one or more parameters associated with a blood sample obtained from an individual, the one or more parameters can include a monocyte distribution width (MDW) value. The systems and methods can also include comparing the MDW value with one or more predetermined criteria; and providing a clinical acuity recommendation at least partly in response to the comparing the MDW value with the one or more predetermined criteria.

Abstract: Systems and methods of assessing a probability that an individual will develop sepsis are provided. The systems and methods can include obtaining a set of parameters associated with the individual including white blood cell count (WBC) and monocyte distribution width (MDW) value, and determining whether the set of parameters provides an elevated risk status by comparing at least the WBC and the MDW value with respective predetermined criteria. In the event that the set of parameters is determined to provide the elevated risk status, the systems and methods can further include obtaining a secondary parameter associated with the individual; and providing the probability that the individual will develop sepsis.

Abstract: Using vital sign measurements, such as systolic blood pressure (SBP), when combined with hematology parameters such as White Blood Cell Count (WBC) and Monocyte Distribution Width (MDW), has been identified as an improved method for detecting sepsis. The probability of having or developing sepsis is determined when each measurement is compared to a predetermined criteria and the combination of measurements that are within a reference range determines this probability.

Abstract: Systems and methods for characterizing immune response to infection using cellular analysis, such as a hematological cellular analyzer. In some instances, the immune response may be characterized as normal or abnormal based on one or more blood cell population parameters. In some instances, abnormal characterization may be used to identify patients with sepsis or at elevated risk of developing sepsis.

Abstract: Systems and methods for characterizing immune response to infection using cellular analysis, such as a hematological cellular analyzer. In some instances, the immune response may be characterized as normal or abnormal based on one or more blood cell population parameters. In some instances, abnormal characterization may be used to identify patients with sepsis or at elevated risk of developing sepsis.

Abstract: A method for diagnosing and monitoring subjects for hemostatic dysfunction, severe infection and systematic inflammatory response syndrome is provided whereby lipoproteins are examined for abnormalities, particularly for prothrominase enhancement, through quantitative and qualitative analysis.

Abstract: A method for diagnosing a condition of a patient involves the steps of (a) adding one or more reagents to a test sample from a patient, the test samples comprising at least part of a blood sample from the patient, in order to cause formation of a complex comprising at least one acute phase protein at at least one human lipoprotein, while causing substantially no fiber polymerization; (b) measuring the formation of the complex over time so as to derive a time-dependent measurement profile, and (c) determining a slope and/or total change in the time-dependent measurement profile, so as to diagnose a condition of the patient. A greater formation of the complex is correlated to increased probability of death of the patient.

Abstract: A method for diagnosing a condition of a patient involves the steps of (a) adding one or more reagents to a test sample from a patient, the test samples comprising at least part of a blood sample from the patient, in order to cause formation of a complex comprising at least one acute phase protein and at least one human lipoprotein, while causing substantially no fiber polymerization; (b) measuring the formation of the complex over time so as to derive a time-dependent measurement profile, and (c) determining a slope and/or total change in the time-dependent measurement profile, so as to diagnose a condition of the patient. A greater formation of the complex is correlated to increased probability of death of the patient.

Abstract: A method for assessing coagulation in a test sample is provided wherein an activator is added to a test sample in an amount sufficient to trigger a thrombin explosion dependent on propagation phase and amplification pathways but said amount insufficient to result in complete fibrin polymerization, followed by measuring the amount of fibrin polymerization due to the thrombin explosion and assessing the patient's coagulation based on the measurement of the fibrin polymerization. The method also provides a means for detecting defects in the propagation and amplification phases of coagulation.

Abstract: A reagent and kit are disclosed for determining if a patient is hypercoagulable, hypocoagulable or normal. The test involves providing a test sample from the patient and initiating coagulation in the sample in the presence of an activator, which is added to the sample in an amount which will result in intrinsic tenase-dependent fibrin. Then the formation of the intrinsic tenase-dependent fibrin polymerization is monitored over time so as to derive a time-dependent profile, with the results of the fibrin polymerization monitoring determining whether the patient is hypercoagulable, normal or hypocoagulable. The coagulation activator is added in an amount that triggers a thrombin explosion that is dependent on the propagation phase and amplification pathways. In this way, a single assay can assess the hemostatic potential of a sample.

Abstract: A method is disclosed for determining if a patient is hypercoagulable, hypocoagulable or normal. The test involves providing a test sample from the patient and initiating coagulation in the sample in the presence of an activator, which is added to the sample in an amount which will result in intrinsic tenase-dependent fibrin. Then the formation of the intrinsic tenase-dependent fibrin polymerization is monitored over time so as to derive a time-dependent profile, with the results of the fibrin polymerization monitoring determining whether the patient is hypercoagulable, normal or hypocoagulable. The coagulation activator is added in an amount that triggers a thrombin explosion that is dependent on the propagation phase and amplification pathways. In this way, a single assay can assess the hemostatic potential of a sample.

Abstract: A method is disclosed for determining if a patient is hypercoagulable, hypocoagulable or normal. The test involves providing a test sample from the patient and initiating coagulation in the sample in the presence of an activator, which is added to the sample in an amount which will result in intrinsic tenase-dependent fibrin. Then the formation of the intrinsic tenase-dependent fibrin polymerization is monitored over time so as to derive a time-dependent profile, with the results of the fibrin polymerization monitoring determining whether the patient is hypercoagulable, normal or hypocoagulable. The coagulation activator is added in an amount that triggers a thrombin explosion that is dependent on the propagation phase and amplification pathways. In this way, a single assay can assess the hemostatic potential of a sample.

Abstract: A method for diagnosing and monitoring subjects for hemostatic dysfunction, severe infection and systematic inflammatory response syndrome is provided whereby lipoproteins are examined for abnormalities, particularly for prothrominase enhancement, through quantitative and qualitative analysis.

Abstract: A reagent and kit are disclosed for determining if a patient is hypercoagulable, hypocoagulable or normal. The test involves providing a test sample from the patient and initiating coagulation in the sample in the presence of an activator, which is added to the sample in an amount which will result in intrinsic tenase-dependent fibrin. Then the formation of the intrinsic tenase-dependent fibrin polymerization is monitored over time so as to derive a time-dependent profile, with the results of the fibrin polymerization monitoring determining whether the patient is hypercoagulable, normal or hypocoagulable. The coagulation activator is added in an amount that triggers a thrombin explosion that is dependent on the propagation phase and amplification pathways. In this way, a single assay can assess the hemostatic potential of a sample.

Abstract: A method for predicting that an individual has antiphospholipid syndrome or an increased likelihood of having antiphospholipid syndrome, includes: a) providing a test sample from an individual; b) combining the test sample with phospholipids; c) directing a light beam at the test sample and monitoring light scattering or transmittance over time so as to provide a time-dependent measurement profile; d) determining if a value or a slope at or over a particular time in the time-dependent measurement profile is beyond a corresponding predetermined value or slope threshold; and if the value or slope in the time-dependent measurement profile is beyond the predetermined threshold, then determining that the individual has antiphospholipid syndrome or an increased risk of antiphospholipid syndrome. The phospholipids can be provided as part of a coagulation reagent, or as part of a reagent where coagulation is not activated.

Abstract: A method for diagnosing a condition of a patient involves the steps of (a) adding one or more reagents to a test sample from a patient, the test samples comprising at least part of a blood sample from the patient, in order to cause formation of a complex comprising at least one acute phase protein at at least one human lipoprotein, while causing substantially no fiber polymerization; (b) measuring the formation of the complex over time so as to derive a time-dependent measurement profile, and (c) determining a slope and/or total change in the time-dependent measurement profile, so as to diagnose a condition of the patient. A greater formation of the complex is correlated to increased probability of death of the patient.

Abstract: A prothrombin time reagent is disclosed for use in a prothrombin time test. The reagent utilizes recombinant human tissue factor, phospholipids of a natural or synthetic origin, a buffer composition and calcium ion. Stabilizers and salts may also be utilized in the reagent. In addition, a method for creating lipid micelles containing tissue factor is also disclosed.