Search Results
Found 1 results
510(k) Data Aggregation
(87 days)
The FONAR 360° Magnetic Resonance Imaging System is indicated for use in producing images of multiple planes in the head and body. These images correspond to the distribution of hydrogen nuclei exhibiting nuclear magnetic resonance (NMR) and depend for their contrast upon NMR parameters [hydrogen nuclei concentration and flow velocity, T1 (spinlattice relaxation time) and T2 (spin-spin relaxation time)]. As a result of the acquisition and processing of the NMR data, these images display the internal structure of the head and body, and when interpreted by a trained physician, can yield diagnostically useful information.
The FONAR 360° magnet follows the same basic design, operating and physical principles, and construction methods and materials of the predicate magnets. The field strength of this magnet is 6000 gauss (0.6T). This magnet configuration is essentially a combination of basic structural elements of Fonar's previously approved magnets. The two pole assemblies of the vertical-field iron-core electromagnet are separated and supported by steel supports that form the "walls", "ceiling" and "floor" of the room-sized magnet. This provides an unimpeded 360° access to the magnet's imaging gap. The electromagnet coil elements are windings of multiple turns of epoxy-insulated copper installed around the poles of the magnet frame, connected to a regulated power source, and chilled via the closed loop chiller system.
During operation, the poles of the magnet establish a vertical magnet field with a limited fringe field. The magnetic field is created by passing a regulated DC current through the coil windings surrounding the magnet poles. The field strength is proportional to the amount of current in the coils. In this magnet the current supplied will result in a magnetic field of 6000 gauss, ± 5% (0.6T ± 5%), operating at frequencies between 24.27 and 26.92 MHz. This magnet functions with all imaging sequences available in the current software releases. All other non-magnet related equipment and procedures used are as previously reviewed by the FDA in PMA 830076, its supplements, and the 510(k) submissions K910839 and K951681.
The transmitter coil for the Fonar 360° is modified from the coil used in the Quad 12000 magnet to accommodate the openness of the gap and the removal of the vertical posts of the Quad magnet construction. The resulting transmitter coil is configured as a quadrature coil instead of the linear coil used in the Quad. While the construction methods are different, the resulting field after application of the RF power produces the same level of excitation as the previously approved coils, and results in images that are equivalent to those produced by the predicate devices.
The provided text describes the FONAR 360° Magnetic Resonance Imaging Scanner and its substantial equivalence to previously approved FONAR MRI magnets. The document focuses on non-clinical and clinical testing to demonstrate safety and effectiveness primarily through comparison to NEMA standards and predicate devices.
1. Table of Acceptance Criteria and Reported Device Performance
The acceptance criteria for the FONAR 360° MRI scanner are primarily based on demonstrating substantial equivalence to predicate devices (Fonar B3000 and Quad 12000) and adherence to NEMA standards. The reported device performance is presented in comparison to these benchmarks.
| Parameter | Acceptance Criteria (Predicate/NEMA Standards) | Reported Device Performance (FONAR 360°) |
|---|---|---|
| Static Field Strength | Quad 12000: 0.6T ± 5% | 0.6T ± 5% |
| Peak A-Weighted Acoustic Noise | Not explicitly stated as a numerical criterion for the predicate, but NEMA standards are followed. | 88.2 ± 0.8 dBA |
| Operational Modes | Not explicitly stated as a numerical criterion for the predicate, but implied to be normal operation. | Normal mode only |
| Max SAR for Transmitter | Quad 12000: 0.76 W/kg (Calculated) | <0.1 W/kg measured (NEMA); 0.76 W/kg calculated |
| Max dB/dt | Not explicitly stated as a numerical criterion for the predicate, but NEMA standards are followed. | 16.53 T/s ± 0.31 |
| Emergency Shutdown | Implied existence of a shutdown mechanism in predicate devices. | Switch on console |
| Biocompatibility | Implied no new materials or invasive uses from predicate devices. | No new materials or invasive uses |
| Signal-to-Noise (SNR) | Not explicitly stated as a numerical criterion for the predicate, but expected to be comparable. | Body: 41 ± 3.5%; Head: 104 ± 3.1% |
| Geometric Distortion | Not explicitly stated as a numerical criterion for the predicate, but expected to be comparable. | Body: 0.53% to 3.94%; Head: 0.49% to 1.78% |
| Image Uniformity | Not explicitly stated as a numerical criterion for the predicate, but expected to be comparable. | Body Average: ± 46.67%; Head Average: ± 26.3% |
| Slice Thickness Accuracy | Not explicitly stated as a numerical criterion for the predicate, but expected to be comparable. | se20 Avg. Error: ± 0.21 mm; se30 Avg. Error: ± 0.22 mm |
| Spatial Resolution | Not explicitly stated as a numerical criterion for the predicate, but expected to be comparable. | Min. pixel dimension: 0.5 mm; Min. phantom resolution element: 0.46 mm |
| Other Magnet Specifications | * (Numerous specifications from the table in section 1 like Field Strength, Calculated SAR, Power Consumption, Cooling, Stability, Field Homogeneity, Shimming, Open Gap Configuration, Fringe Field, Pole Cap Eddy Current Compensation, Outer Dimensions, Weight)* Including but not limited to: Field Strength, Stability (long-term < 2 ppm/hr, short term < .3 ppm/min), Field Homogeneity (3 ppm within 30 cm DSV, 1 ppm within 20 cm DSV). | * (Demonstrates substantial equivalence to predicate devices for all listed magnet specifications in the table in section 1)* Including but not limited to: Field Strength: 0.6T ± 5%, Stability: long-term < 2 ppm/hr, short term < .3 ppm/min, Field Homogeneity: 3 ppm within 30 cm DSV, 1 ppm within 20 cm DSV. |
| Image Quality (Clinical) | Images equivalent to those produced by predicate devices; high-quality images with good signal intensity and image uniformity. | Verification that the FONAR 360° magnet is effective in producing high-quality images with good signal intensity and image uniformity. |
| Safety (Clinical) | No serious malfunctions or adverse effects to patient health or safety reported from predicate devices. | No serious malfunctions or adverse effects to patient health or safety reported. |
2. Sample Size Used for the Test Set and Data Provenance
- Sample Size for Test Set: The document mentions "a period of human imaging" for clinical testing, however, it does not specify the number of human participants or images included in this test set.
- Data Provenance: The document states "A period of human imaging was performed." It does not specify the country of origin, but given the submission to the FDA (U.S. Federal law), it's highly probable the data was collected in the United States. The study appears to be prospective for the clinical imaging mentioned, as it was specifically performed for the purpose of demonstrating safety and effectiveness of the new device.
3. Number of Experts Used to Establish the Ground Truth for the Test Set and Qualifications of Those Experts
The document states that images "when interpreted by a trained physician, can yield diagnostically useful information." For the clinical testing, it focuses on image quality and safety. However, it does not specify the number of experts used to interpret the images in the clinical test set, nor does it detail their specific qualifications (e.g., "radiologist with 10 years of experience").
4. Adjudication Method for the Test Set
The document does not specify any particular adjudication method (e.g., 2+1, 3+1) for the clinical interpretation of images. The focus is on the overall quality and diagnostic utility, rather than a specific consensus process for individual findings.
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
The document does not describe a multi-reader multi-case (MRMC) comparative effectiveness study. This submission is for a new MRI scanner and focuses on demonstrating its safety and equivalence to existing MRI technology, not on the performance of an AI algorithm or its impact on human reader performance. Therefore, there is no information on the effect size of human readers improving with AI vs. without AI assistance.
6. If a Standalone (i.e., algorithm only without human-in-the-loop performance) was done
This submission is for an MRI scanner, a hardware device, not an AI algorithm. Therefore, a "standalone algorithm only" performance study is not applicable and was not done. The primary focus is on the physical and performance characteristics of the magnetic resonance imaging system itself.
7. The Type of Ground Truth Used
For the non-clinical tests, the ground truth was based on NEMA standards and direct physical measurements of the device's performance parameters (e.g., field strength, acoustic noise, SAR, dB/dt, SNR, geometric distortion, image uniformity, slice thickness, spatial resolution).
For the clinical testing, the "ground truth" for demonstrating effectiveness seems to be based on the qualitative assessment of "high-quality images with good signal intensity and image uniformity" by trained physicians, implying a clinical judgment rather than a specific external pathology or outcomes data for each case. The comparison is also made implicitly to images produced by the predicate devices.
8. The Sample Size for the Training Set
The document does not mention a training set in the context of an AI algorithm, as this submission is for a physical medical device (MRI scanner) and its hardware/physical performance characteristics.
9. How the Ground Truth for the Training Set Was Established
As no training set is discussed or implied for an AI algorithm, this question is not applicable.
Ask a specific question about this device
Page 1 of 1