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510(k) Data Aggregation

    K Number
    K143673
    Device Name
    CMOS Video Nasopharyngoscope System
    Manufacturer
    Schoelly Fiberoptic Gmbh
    Date Cleared
    2015-03-04

    (70 days)

    Product Code
    EOB
    Regulation Number
    874.4760
    Type
    Special
    Panel
    Ear Nose & Throat
    Reference & Predicate Devices
    K132009
    Predicate For
    K232015
    AI/MLSaMDIVD (In Vitro Diagnostic)TherapeuticDiagnosticis PCCP AuthorizedThirdpartyExpeditedreview
    Intended Use

    The Schoelly CMOS Video Nasopharyngoscope System may only be used by persons with an appropriate medical qualification and who are acquainted with the rhino/laryngoscopic technique. The endoscopic diagnosis within the nasal lumens and airway and is intended to provide visualization via a video monitor.

    Device Description

    The Schoelly CMOS Video Nasopharyngoscope System consists of a flexible and steerable endoscope and a camera control unit (CCU) for regulation of light intensity and connection to a monitor, PC, medical video recorder or printer for image display or image documentation.

    The endoscope has outer surfaces mainly made from plastic. The endoscope handle incorporates a control lever to bend the distal tip and an integrated LED light source. Light is transmitted through fiberoptic bundles illuminating the anatomy under investigation. The video signal is captured by a CMOS imaging sensor located at the tip of the endoscope shaft and transferred to the CCU.

    The endoscope further incorporates a ventilation system to protect the shaust valve at the endoscope handle can further be used for leakage testing. For this purpose the system is accompanied by a leakage tester and accessories.

    The Schoelly CMOS Video Nasopharyngoscope System is delivered in a non-sterile condition.

    AI/ML Overview

    This document is a 510(k) summary for a Special 510(k) submission, meaning the changes described are limited to a modification of an already cleared device. In this specific case, the only change is an update to the Instructions for Use to add a validated method for high-level disinfection.

    Therefore, the "device performance" described is specifically the performance of the High-Level Disinfection (HLD) process, not the overall performance of the nasopharyngoscope system for its intended diagnostic use. The study proves the HLD process meets the acceptance criteria for disinfection efficacy.

    Here's the breakdown of the acceptance criteria and study information:

    1. Table of Acceptance Criteria and Reported Device Performance

    Acceptance CriteriaReported Device Performance (HLD Efficacy)
    Minimum 6-log reduction of an appropriate indicator organism (Mycobacterium terrae)Successfully achieved a 7.5-log reduction.
    No significant adverse effects on the endoscope from HLD processNo damage or material degradation observed after multiple, extended HLD cycles.
    No residual disinfectant material that could adversely affect test results by obscuring residual indicator organisms.Cytotoxicity testing confirmed no such residual material.

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

    • Sample Size for HLD Efficacy Test: "In total, five results for microbial reduction by HLD and three inoculation control results were obtained as part of the efficacy study." This refers to the number of test devices and control devices used in the disinfection validation.
    • Data Provenance: The devices used for validation had "previously been in clinical use to ensure 'real life' conditions." This suggests the data provenance is retrospective clinical use, but the validation itself was a prospective laboratory study performed on these used devices. The country of origin for the data is not explicitly stated, but the manufacturer is based in Germany.

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

    This information is not applicable to this specific study. The "ground truth" for the HLD efficacy study was established through laboratory methods (culturing viable indicator organisms to determine log reduction), not through expert clinical consensus or interpretation of images.

    4. Adjudication Method for the Test Set

    This is not applicable. The HLD efficacy test involved quantitative microbiological culturing and functional/material testing, not human interpretation that would require adjudication.

    5. If a multi-reader multi-case (MRMC) comparative effectiveness study was done

    No, a multi-reader multi-case (MRMC) comparative effectiveness study was not done. This type of study involves human readers evaluating cases with and without AI assistance and is relevant for evaluating diagnostic accuracy, which is not the focus of this specific 510(k) submission (which only concerns HLD validation).

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

    This concept is not applicable. There is no "algorithm" or AI in the context of high-level disinfection validation. The study evaluated the mechanical and chemical process of disinfection.

    7. The type of ground truth used

    The ground truth used for the HLD efficacy study was laboratory-derived quantitative microbiological counts. Specifically, the number of viable indicator organisms (Mycobacterium terrae) remaining after disinfection, determined by culturing.

    8. The sample size for the training set

    This is not applicable. There is no "training set" in the context of validating a high-level disinfection process. This is a laboratory validation, not a machine learning model.

    9. How the ground truth for the training set was established

    This is not applicable for the reasons stated above.

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