LogoFDA 510(k) Search
Search Filters

Search Results

Found 1 results

510(k) Data Aggregation

    K Number
    K212183
    Device Name
    STA R Max 3, STA Compact Max 3
    Manufacturer
    Diagnostica Stago SAS
    Date Cleared
    2023-06-07

    (694 days)

    Product Code
    JPA
    Regulation Number
    864.5425
    Type
    Traditional
    Panel
    Hematology
    Reference & Predicate Devices
    K983460,K082675,K093001,K151867,K130090,K961579,K093167
    Why did this record match?
    Reference Devices :

    K983460, K082675, K093001, K151867, K130090, K961579, K093167

    AI/MLSaMDIVD (In Vitro Diagnostic)TherapeuticDiagnosticis PCCP AuthorizedThirdpartyExpeditedreview
    Intended Use

    The STA R Max 3® and STA Compact Max 3® are fully automatic clinical analyzers designed to be used by professional laboratory personnel and to perform tests on human venous plasmas (in 3.2% trisodium citrate tubes) the results of which aid in the diagnosis of coagulation abnormalities or in monitoring anticoagulant therapy.

    Device Description

    The STA R Max 3® and STA Compact Max 3® are fully automatic clinical analyzers designed to be used by professional laboratory personnel and to perform tests on human venous plasmas (in 3.2% trisodium citrate tubes) the results of which aid in the diagnosis of coagulation abnormalities or in monitoring anticoagulant therapy.
    The technological characteristics are the same for all STA R Max® Family and STA Compact Max® family analyzers, including STA R Max 30 and STA Compact Max 30, which is based on two measurement principles: Chronometric measurement principle and Photometry measurement principle.
    The analyzers use Diagnostica Stago reagents in addition to open adaptation of other available reagents. The instrument performs multiple test methodologies in random access, as selected by the user. These include clotting time or clot-based tests (i.e. chronometric measures) and photometric assays on plasma samples.
    Changes include a redesigned PSR module to replace the Hamilton syringes and Valcor pump of the fluidic circuit and the addition of the HIL module for estimating interferences (Hemoglobin, Icterus, Lipemia).

    AI/ML Overview

    The provided text describes the performance data for laboratory instruments (STA R Max 3® and STA Compact Max 3®) used for in vitro coagulation studies, not for an AI/ML-driven medical device for which the acceptance criteria would typically focus on diagnostic accuracy metrics like sensitivity, specificity, or AUC as evaluated by expert readers.

    Therefore, the requested information regarding acceptance criteria and study design elements specific to AI/ML devices (e.g., sample size for test set with provenance, number of experts for ground truth, adjudication methods, MRMC study, standalone performance, training set details) is largely not applicable to the content of this FDA 510(k) summary, as it pertains to traditional in vitro diagnostic instruments and their analytical performance.

    The document focuses on:

    • Method Comparison: Comparing the new devices' measurements against predicate devices using standard regression analysis (Passing & Bablok, Deming) and correlation coefficients (Spearman's r).
    • Precision/Reproducibility: Assessing the variability of measurements within a run, between runs, between days, and between instruments/sites using standard deviation (SD) and coefficient of variation (CV%).
    • Interference Testing (HIL): Testing the impact of hemoglobin, icterus, and lipemia on results.

    Below is a reinterpretation of the request based on the provided document, focusing on the analytical performance acceptance criteria and study details for these in vitro diagnostic instruments.

    Acceptance Criteria and Device Performance for Coagulation Analyzers (STA R Max 3® and STA Compact Max 3®)

    The provided document details the analytical performance of the STA R Max 3® and STA Compact Max 3® coagulation analyzers, demonstrating their substantial equivalence to predicate devices (STA R Max® and STA Compact Max®). The acceptance criteria are implicit in the presented method comparison and precision data, aiming to show comparable performance to the legally marketed predicates.

    1. Table of Acceptance Criteria and Reported Device Performance

    Since this is an in vitro diagnostic (IVD) device (a laboratory instrument) and not an AI/ML-driven diagnostic algorithm, the "acceptance criteria" are defined differently than for radiological AI tools. Here, they relate to statistical comparability (method comparison) and measurement reproducibility (precision). The specific quantitative "acceptance criteria" values (e.g., maximum allowable bias, maximum CV%) are not explicitly stated as discrete numbers in the document's summary tables, but rather are implied by the presentation of regression analysis results (slopes, intercepts, correlation coefficients) and precision statistics (SD, CV%). The expectation is that these values demonstrate strong agreement with the predicate devices and sufficient reproducibility for clinical use.

    Performance Data Summary (Representing "Met Acceptance Criteria")

    Test/CharacteristicAcceptance Criteria (Implicit from comparability with predicate and clinical utility based on CLSI guidelines)Reported Device Performance (Summary)
    Method Comparison STA R Max 3® vs. STA R Max®Slope near 1.00, Intercept near 0, High Spearman's r (close to 1.00) indicating strong correlation and minimal bias.STA - Neoplastine CI Plus: Slope: 0.98, Intercept: 0.20 sec, rSpearman: 0.997
    STA - PTTA: Slope: 1.00, Intercept: -0.32, rSpearman: 0.997
    STA - Fibrinogen: Slope: 1.01, Intercept: 4.26 mg/dL, rSpearman: 0.996
    STA - Stachrom® ATIII: Slope: 1.03, Intercept: -1.03%, rSpearman: 0.980
    STA - Liatest D-Di: Slope: 1.02, Intercept: -0.02 µg/mL, rSpearman: 0.998
    Method Comparison STA Compact Max 3® vs. STA Compact Max®Slope near 1.00, Intercept near 0, High Spearman's r (close to 1.00) indicating strong correlation and minimal bias.STA - Neoplastine CI Plus: Slope: 0.99, Intercept: 0.20 sec, rSpearman: 0.994
    STA - PTTA: Slope: 0.99, Intercept: 0.06 sec, rSpearman: 0.996
    STA - Fibrinogen: Slope: 1.01, Intercept: 4.94 mg/dL, rSpearman: 0.995
    STA - Stachrom® ATIII: Slope: 1.00, Intercept: 0.00%, rSpearman: 0.981
    STA - Liatest D-Di: Slope: 1.02, Intercept: -0.01 µg/mL, rSpearman: 0.997
    Method Comparison HIL vs. Reference (cobas® 8000/spectrophotometer)Strong correlation coefficients (r or rSpearman) and acceptable slopes/intercepts.Hemolysis: Slope: 1.12 (with outliers), 1.11 (without outliers), rSpearman: 0.954 (with outliers), 0.948 (without outliers)
    Icterus: Slope: 0.99, Intercept: 0.26 mg/dL, rSpearman: 0.956
    Lipemia: Linear Regression (vs. Spectrophotometer) r = 0.91; (vs. cobas® 8000) r = 0.97.
    Precision/ReproducibilityLow CV% for within-run, between-run, between-day, between-instrument/site, and total precision. Specific acceptable CV% ranges are not explicitly stated, but the values provided are generally low indicating high precision. The summary states: "The acceptance criteria were met for all samples in the studies."Detailed tables are provided for 5 different assays (PT, APTT, FIB, AT, D-Dimer) across up to 5 samples per assay, showing SD and CV% for various precision components. For example, for STA R Max 3, combined total precision CV% ranges from 1.1% (PT) to 10.6% (D-Dimer). For STA Compact Max 3, combined total precision CV% ranges from 1.5% (PT) to 9.2% (AT).

    2. Sample Size Used for the Test Set and Data Provenance

    • Sample Size:
      • Method Comparison: For each assay and each instrument (STA R Max 3 and STA Compact Max 3), samples were "selected in order to cover the entire measuring range." The exact number of samples (patients) for each method comparison is not explicitly stated as a single number but would be consistent with CLSI EP09c recommendations. For example, the precision data tables indicate 80 replicates per sample per analyzer for single-site precision (e.g., 240 N for "All instruments combined" across 3 analyzers), and 90 N per sample for multi-site precision (across 3 sites) for a total of 270 replicates per sample per parameter across all sites and analyzers.
      • HIL Method Comparison: Not explicitly stated, but samples were "spiked plasma" to create various concentrations across designated indices.
    • Data Provenance: The method comparison studies were conducted at "three external sites." Precision studies were conducted at "one external site" (single-site precision) and "three external sites" (multi-site precision). The country of origin is not specified but is implicitly within a region where FDA regulatory standards are applicable.
    • Retrospective or Prospective: Not explicitly stated, but given the nature of instrument validation studies, they are typically purpose-generated (prospective) for the study rather than utilizing historical patient data. Spiked plasma for HIL analysis indicates prospective sample preparation.

    3. Number of Experts Used to Establish the Ground Truth for the Test Set and Qualifications of those Experts

    • Not applicable in the context of this IVD device. For an in vitro diagnostic instrument like a coagulation analyzer, "ground truth" is established by the analytical method itself, often by comparison to a well-established reference method or the predicate device that has established analytical accuracy. There are no human "experts" establishing a diagnostic ground truth from images or clinical data in the way an AI/ML diagnostic device would require. The "truth" is the measured concentration or clotting time.

    4. Adjudication Method for the Test Set

    • Not applicable. As there are no human interpretations or classifications that require adjudication for this type of IVD instrument validation.

    5. If a Multi-Reader Multi-Case (MRMC) Comparative Effectiveness Study was done, If so, what was the effect size of how much human readers improve with AI vs without AI assistance

    • Not applicable. This study pertains to the analytical performance of a laboratory instrument, not an AI-assisted diagnostic tool that aids human readers.

    6. If a Standalone (i.e. algorithm only without human-in-the loop performance) was done

    • Yes, in the context of an IVD analyzer. The "standalone" performance here refers to the analytical performance of the instrument itself when measuring samples. The entire document describes this "standalone" performance through method comparison and precision studies. The device measures various coagulation parameters directly from plasma samples.

    7. The Type of Ground Truth Used

    • Analytical Ground Truth: The ground truth for this device's performance is established by:
      • Comparison to a Legally Marketed Predicate Device: The performance of the new devices (STA R Max 3 and STA Compact Max 3) is compared directly to the established performance of their previous versions (STA R Max and STA Compact Max) using patient samples. This is the primary method for demonstrating substantial equivalence.
      • Reference Methods (for HIL): For the HIL interferences, the device's readings were compared against "reference methods, cobas® 8000 modular analyzer (Hemolysis, Icterus, and Lipemia) and spectrophotometer (Lipemia)."
      • Theoretical/Expected Values (for HIL spiking): For HIL, "spiked plasmas were prepared" to provide known concentrations of interfering substances, and the results "matched the index determination for the subject devices and the theoretical index."
      • Repeated Measurements (for Precision): For precision, repeated measurements demonstrating low variability around a mean value for different samples serve as the internal "ground truth" for reproducibility.

    8. The Sample Size for the Training Set

    • Not applicable for this type of conventional IVD instrument. These are not AI/ML devices that undergo "training" on a data set. Their "training" or calibration involves standard laboratory procedures and calibration materials according to manufacturer protocols.

    9. How the Ground Truth for the Training Set Was Established

    • Not applicable. As stated above, there is no "training set" in the AI/ML sense for this traditional laboratory instrument.
    Ask a Question

    Ask a specific question about this device

    Page 1 of 1