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510(k) Data Aggregation
(406 days)
uWS-MR is a software solution intended to be used for viewing, manipulation, and storage of medical images. It supports interpretation and evaluations within healthcare institutions. It has the following additional indications:
The MR Stitching is intended to create full-format images from overlapping MR volume data sets acquired at multiple stages.
The Dynamic application is intended to provide a general post-processing tool for time course studies.
The Image Fusion application is intended to combine two different image series so that the displayed anatomical structures match in both series.
MRS (MR Spectroscopy) is intended to evaluate the molecule constitution and spatial distribution of cell metabolism. It provides a set of tools to view, process, and analyze the complex MRS data. This application supports the analysis for both SVS (Single Voxel Spectroscopy) and CSI (Chemical Shift Imaging) data.
The MAPs application is intended to provide a number of arithmetic and statistical functions for evaluating dynamic processes and images. These functions are applied to the grayscale values of medical images.
The MR Breast Evaluation application provides the user a tool to calculate parameter maps from contrast-enhanced timecourse images.
The Brain Perfusion application is intended to allow the visualizations in the dynamic susceptibility time series of MR datasets.
MR Vessel Analysis is intended to provide a tool for viewing, manipulating MR vascular images. The Inner view application is intended to perform a virtual camera view through hollow structures (cavities), such as vessels.
uWS-MR is a comprehensive software solution designed to process, review and analyze MR (Magnetic Resonance Imaging) studies. It can transfer images in DICOM 3.0 format over a medical imaging network or import images from external storage devices such as CD/DVDs or flash drives. These images can be functional data, as well as anatomical datasets. It can be at one or more time-points or include one or more time-frames. Multiple display formats including MIP and volume rendering and multiple statistical analysis including mean, maximum and minimum over a user-defined region is supported. A trained, licensed physician can interpret these displayed images as well as the statistics as per standard practice.
The provided document is a 510(k) premarket notification for the uWS-MR software. It focuses on demonstrating substantial equivalence to predicate devices, rather than presenting a standalone study with detailed acceptance criteria and performance metrics for a novel AI-powered diagnostic device.
Therefore, much of the requested information regarding specific acceptance criteria, detailed study design for proving the device meets those criteria, sample sizes for test and training sets, expert qualifications, and ground truth establishment cannot be fully extracted from this document.
Here's what can be inferred and stated based on the provided text:
1. Table of Acceptance Criteria and Reported Device Performance
The document does not explicitly list quantitative acceptance criteria in a pass/fail format nor provide specific, measurable performance metrics for the proposed device (uWS-MR) in comparison to such criteria. Instead, it relies on demonstrating substantial equivalence to predicate devices by comparing their features and functionalities. The "Remark" column consistently states "Same," indicating that the proposed device's features align with its predicates, implying it meets comparable performance.
| Feature Type (Category) | Proposed Device (uWS-MR) Performance (Inferred) | Predicate Device (syngo.via/Reference Devices) Performance (Inferred to be matched) | Remark/Acceptance (Inferred) |
|---|---|---|---|
| General | |||
| Device Classification Name | Picture Archiving and Communications System | Picture Archiving and Communications System | Same (Acceptable) |
| Product Code | LLZ | LLZ | Same (Acceptable) |
| Regulation Number | 21 CFR 892.2050 | 21 CFR 892.2050 | Same (Acceptable) |
| Device Class | II | II | Same (Acceptable) |
| Classification Panel | Radiology | Radiology | Same (Acceptable) |
| Specification | |||
| Image communication | Standard network protocols like TCP/IP and DICOM. Additional fast image. | Standard network protocols like TCP/IP and DICOM. Additional fast image. | Same (Acceptable) |
| Hardware / OS | Windows 7 | Windows 7 | Same (Acceptable) |
| Patient Administration | Display and manage image data information of all patients stored in the database. | Display and manage image data information of all patients stored in the database. | Same (Acceptable) |
| Review 2D | Basic processing of 2D images (rotation, scaling, translation, windowing, measurements). | Basic processing of 2D images (rotation, scaling, translation, windowing, measurements). | Same (Acceptable) |
| Review 3D | Functionalities for displaying and processing image in 3D form (VR, CPR, MPR, MIP, VOI analysis). | Functionalities for displaying and processing image in 3D form (VR, CPR, MPR, MIP, VOI analysis). | Same (Acceptable) |
| Filming | Dedicated for image printing, layout editing for single images and series. | Dedicated for image printing, layout editing for single images and series. | Same (Acceptable) |
| Fusion | Auto registration, Manual registration, Spot registration. | Auto registration, Manual registration, Spot registration. | Same (Acceptable) |
| Inner View | Inner view of vessel, colon, trachea. | Inner view of vessel, colon, trachea. | Same (Acceptable) |
| Visibility | User-defined display property of fused image: Adjustment of preset of T/B value; Adjustment of the fused. | User-defined display property of fused image: Adjustment of preset of T/B value; Adjustment of the fused. | Same (Acceptable) |
| ROI/VOI | Plotting ROI/VOI, obtaining max/min/mean activity value, volume/area, max diameter, peak activity value. | Plotting ROI/VOI, obtaining max/min/mean activity value, volume/area, max diameter, peak activity value. | Same (Acceptable) |
| MIP Display | Image can be displayed as MIP and rotating play. | Image can be displayed as MIP and rotating play. | Same (Acceptable) |
| Compare | Load two studies to compare. | Load two studies to compare. | Same (Acceptable) |
| Advanced Applications (Examples) | |||
| MR Brain Perfusion: Type of imaging scans | MRI | MRI | Same (Acceptable) |
| MR Breast Evaluation: Automatic Subtraction | Yes | Yes | Same (Acceptable) |
| MR Stitching: Automatic Stitching | Yes | Yes | Same (Acceptable) |
| MR Vessel Analysis: Automatic blood vessel center lines extraction | Yes | Yes | Same (Acceptable) |
| MRS: Single-voxel Spectrum Data Analysis | Yes | Yes | Same (Acceptable) |
| MR Dynamic/MAPS: ADC and eADC Calculate | Yes | Yes | Same (Acceptable) |
2. Sample Size Used for the Test Set and the Data Provenance
The document states: "Software verification and validation testing was provided to demonstrate safety and efficacy of the proposed device." and lists "Performance Verification" for various applications. However, it does not specify the sample size used for these performance tests (test set) or the data provenance (e.g., country of origin, retrospective/prospective nature).
3. Number of Experts Used to Establish the Ground Truth for the Test Set and the Qualifications of Those Experts
This information is not provided in the document. The filing focuses on technical and functional equivalence, not on clinical performance evaluated against expert ground truth.
4. Adjudication Method
This information is not provided in the document.
5. Multi-Reader Multi-Case (MRMC) Comparative Effectiveness Study
A multi-reader multi-case (MRMC) comparative effectiveness study was not explicitly mentioned as being performed or required. The submission is a 510(k) for substantial equivalence, which often relies more on technical verification and comparison to predicate devices rather than new clinical effectiveness studies.
6. Standalone Performance
The document clearly states: "Not Applicable to the proposed device, because the device is stand-alone software." This implies that the device is intended to perform its functions (viewing, manipulation, post-processing) as a standalone software, and its performance was evaluated in this standalone context during verification and validation, aligning with the predicates which are also software solutions. However, no specific standalone performance metrics are provided.
7. Type of Ground Truth Used
The document does not explicitly state the "type of ground truth" used for performance verification. Given the nature of the device (image post-processing software) and the 510(k) pathway, performance verification likely involved:
- Technical validation: Comparing outputs of uWS-MR's features (e.g., image stitching, parameter maps, ROI measurements) against known good results, simulated data, or outputs from the predicate devices.
- Functional testing: Ensuring features operate as intended (e.g., if a rotation function rotates the image correctly).
Pathology or outcomes data are typically used for diagnostic devices with novel clinical claims, which is not the primary focus here.
8. Sample Size for the Training Set
The concept of a "training set" typically applies to machine learning or AI models that learn from data. While the uWS-MR is post-processing software, and could potentially incorporate AI elements (though not explicitly stated beyond general "post-processing"), the document does not mention a training set size. This strongly suggests that a machine learning or deep learning model with a distinct training phase, as commonly understood, was not a primary component evaluated in this filing or, if present, its training data details were not part of this summary.
9. How the Ground Truth for the Training Set Was Established
As no training set is mentioned (see point 8), the establishment of its ground truth is not applicable and therefore not described in the document.
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