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510(k) Data Aggregation
(217 days)
The Incisive CT is a Computed Tomography X-Ray System intended to produce images of the head and body by computer reconstruction of x-ray transmission data taken at different angles and planes. These devices may include signal analysis and display equipment, patient and equipments and accessories. The Incisive CT is indicated for head, whole body, cardiac and vascular X-ray Computed Tomography applications in patients of all ages.
These scanners are intended to be used for diagnostic imaging and for low dose CT lung cancer screening for the early detection of lung nodules that may represent cancer*. The screening must be performed within the established inclusion criteria of programs / protocols that have been approved and published by either a governmental body or professional medical society.
Besides installed in hospital, the proposed Philips Incisive CT may also be installed on trailer and be transported to designated locations for use. And Incisive CT installed on trailer has the same intended use as installed in hospital.
The proposed Philips Incisive CT on Trailer is a whole-body computed tomography (CT) X-Ray System featuring a continuously rotating x-ray tube, detectors, and gantry with multi-slice capability. The acquired x-ray transmission data is reconstructed by computer into cross-sectional images of the body taken at different angles and planes. This system also includes signal analysis and display equipment, patient and equipment support, components, and accessories. The Philips Incisive CT has a 72cm bore and includes a detector array that provides 50cm scan field of view (FOV).
Besides installed in hospital, Philips Incisive CT can also be installed on trailer and be transported to designated locations.
The main components (detection system, the reconstruction algorithm, and the x-ray system) that are used in the proposed Philips Incisive CT on trailer are identical to the currently marketed and predicate Philips Incisive CT (K180015, 20/March/2018).
The components of the proposed Philips Incisive CT on trailer include the following:
- Gantry. The Gantry consists of 4 main internal units:
a. Stator – a fixed mechanical frame that carries HW and SW
b. Rotor – A rotating circular stiff frame that is mounted in and supported by the stator
c. X-Ray Tube (XRT) and Generator, - fixed to the Rotor frame
d. Data Measurement System (DMS) - a detectors array, fixed to the Rotor frame - Patient Support (Couch) - carries the patient in and out through the Gantry bore synchronized with the scan.
- Console - Containing a Host computer and display that is the primary user interface.
- CT on Trailer Kit - Modified Incisive CT installed and secured on trailer requires locking motion parts during trailer transportation and unlocking motion parts before CT operations.
In addition to the above components and the software operating them, each system includes hardware and software for data acquisition, display, manipulation, storage and filming as well as post-processing into views other than the original axial images. Patient supports (positioning aids) are used to position the patient.
The provided document is a 510(k) premarket notification for the Philips Incisive CT on Trailer. It seeks to demonstrate substantial equivalence to a predicate device, the Philips Incisive CT (K180015). This type of submission focuses on showing that the new device is as safe and effective as a legally marketed predicate device, rather than on providing extensive clinical performance data for an AI algorithm.
Therefore, the document does not contain the detailed information necessary to answer all parts of your request, especially those pertaining to AI/algorithm-specific studies. The device described is a CT scanner, not an AI algorithm for image analysis.
However, I can extract the relevant information regarding the device's performance criteria based on the context provided for a traditional 510(k) submission for an imaging device.
Here's an analysis based on the document:
1. Table of Acceptance Criteria and Reported Device Performance
The document details that the "Philips Incisive CT on Trailer" is essentially the predicate "Philips Incisive CT" (K180015) installed on a trailer. The justification for substantial equivalence relies heavily on the fact that the core CT system (detection system, reconstruction algorithm, x-ray system) is identical to the predicate.
The primary performance evaluation mentioned, specifically for the "on Trailer" aspect, relates to robustness and image quality after transportation.
| Acceptance Criteria (for Incisive CT on Trailer vs. Predicate) | Reported Device Performance |
|---|---|
| Mechanical/Transport Robustness: Withstand vibration exposure simulating 10 years or 120,690 km lifetime. (MIL-STD-810F, Method 514.5: Composite wheeled vehicle vibration exposures) | The Philips Incisive CT on Trailer has passed the vibration test of 300 hours to simulate a 10 years or 120,690 kM lifetime. |
| Image Quality Performance QA Test: Maintain image quality performance identical to the predicate device after transportation (MeanCT, Uniformity, Noise, Spatial Resolution, Slice Thickness, Linearity, and Low Contrast Resolution). | QA test (including MeanCT, Uniformity, Noise, Spatial Resolution, Slice Thickness, Linearity and Low Contrast Resolution) was conducted. The QA test process and acceptance criteria are same as the predicate device, which is stated to "demonstrate the Philips Incisive CT on Trailer performs as well as the predicate device." |
2. Sample Size Used for the Test Set and Data Provenance
- Test Set Sample Size: Not explicitly stated as a number of patient cases. The "test set" in this context refers to the physical device undergoing vibration and QA tests. The tests were performed on "the proposed Philips Incisive CT on Trailer." This likely refers to one or more physical units of the device.
- Data Provenance: The testing was conducted by Philips Healthcare (Suzhou) Co., Ltd. within their development/validation process in China. The data is prospective in the sense that it's generated from testing the new "on Trailer" configuration.
3. Number of Experts Used to Establish Ground Truth for the Test Set and Their Qualifications
- This question is not applicable in the context of this 510(k) submission. This filing is for a physical CT device (mobile CT scanner) and its ability to maintain performance after transport, not for an AI algorithm that generates a "ground truth" often established by expert readers. The "ground truth" here is the physical performance of the CT scanner measured by established imaging quality metrics.
4. Adjudication Method for the Test Set
- Not applicable for this type of device submission. Adjudication generally refers to expert consensus in interpreting medical images or data. The performance of the CT scanner is measured objectively (e.g., noise levels, spatial resolution) against pre-defined engineering and image quality specifications.
5. If a Multi-Reader Multi-Case (MRMC) Comparative Effectiveness Study was done, and its effect size
- No, an MRMC study was not done. This type of study is relevant for AI algorithms intended to assist human readers in diagnostic tasks. The device in focus is the CT scanner itself, not an AI software for image interpretation.
6. If a Standalone (i.e., algorithm only without human-in-the-loop performance) was done
- No, a standalone AI algorithm performance study was not done. This 510(k) is for the CT imaging system, not an AI diagnostic algorithm.
7. The Type of Ground Truth Used
- For the physical performance of the CT scanner (MeanCT, Uniformity, Noise, Spatial Resolution, Slice Thickness, Linearity, Low Contrast Resolution), the "ground truth" is established by engineering specifications and phantoms/test objects yielding objective physical measurements, rather than clinical outcomes or expert consensus on patient images. The claim is that these measurements are "same as the predicate device," implying the predicate's performance serves as the benchmark.
8. The Sample Size for the Training Set
- Not applicable. This document is for a CT scanner hardware device (with integrated software for image acquisition and reconstruction), not a machine learning model that requires a "training set" of data.
9. How the Ground Truth for the Training Set was Established
- Not applicable. See point 8.
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(91 days)
The Access CT scanner system can be used as a Whole Body (except cardiac) Computed Tomography X-ray System featuring a continuously rotating X-ray tube and detector array with multislice capability up to 6/16 slices simultaneously. The acquired X-ray transmission data is reconstructed by computer into cross-sectional images of the same axial plane taken at different angles. The system is suitable for all patients.
The proposed Access CT is currently available in two system configurations, 6 slices and 16 slices.
The Access CT system is used clinically as a diagnostic patient imaging device that produces images that correspond to tissue density. The quality of the images depends on the level and amount of X-ray energy delivered to the tissue. CT imaging displays both high-density tissue, such as bone, and soft tissue. When interpreted by a trained physician, CT images yield useful diagnostic information. The system is intended for use in the head and whole body.
The main components (detection system, the reconstruction algorithm, and the x-ray system) that are used in the Access CT have the same fundamental design characteristics and are based on comparable technologies as the predicate.
The main system modules and functionalities are:
- Gantry. The Gantry consists of 4 main internal units:
a. Stator – a fixed mechanical frame that carries HW and SW.
b. Rotor – A rotating circular stiff frame that is mounted in and supported by the stator.
c. X-Ray Tube (XRT) and Generator – fixed to the Rotor frame.
d. Data Measurement System (DMS) – a detectors array, fixed to the Rotor frame. - Patient Support (Couch) – carries the patient in and out through the Gantry bore synchronized with the scan.
- Console - Containing a Host computer and display that is the primary user interface.
In addition to the above components and the software operating them, each system includes hardware and software for data acquisition, display, manipulation, storage and filming as well as post-processing into views other than the original axial images. Patient supports (positioning aids) are used to position the patient.
Here's an analysis of the provided text regarding the acceptance criteria and study proving the device meets those criteria:
This document is a 510(k) Premarket Notification for the Philips Access CT system. It does not present a clinical study for proving the device meets specific acceptance criteria in the context of diagnostic accuracy or AI performance. Instead, it focuses on demonstrating substantial equivalence to predicate devices based on technical specifications, performance standards, and non-clinical testing.
The "acceptance criteria" here relate to engineering and performance specifications for a CT scanner, rather than diagnostic performance of an AI algorithm. The "study" described is primarily non-clinical verification and validation testing, ensuring the device meets its design requirements and complies with relevant safety and performance standards.
Therefore, many of the requested points regarding AI performance, human-in-the-loop studies, ground truth establishment for AI, and expert adjudication are not applicable to this document as it describes a non-AI medical device (a CT scanner).
Acceptance Criteria and Device Performance (as presented in the document)
The document outlines acceptance criteria as technical specifications that the device must meet to be considered substantially equivalent to predicate devices. The "reported device performance" are the actual specifications of the Access CT that are compared against these criteria and the predicate device's specifications.
1. Table of Acceptance Criteria and Reported Device Performance
The closest representation of "acceptance criteria" and "reported device performance" in this document is found in the "Table 5-1 Design/fundamental scientific technologies Comparison" on page 8. The "Acceptance Criteria" are implicitly the values or characteristics of the "Predicate Device Philips MX 16-slice (K091195)", and the "Reported Device Performance" are the values for the "Proposed Access CT".
| Characteristic | Acceptance Criteria (Predicate: Philips MX 16-slice K091195) | Reported Device Performance (Proposed: Access CT) | Conclusion (Meeting Criteria) |
|---|---|---|---|
| Application | Head/Body | Head/Body | Identical / Substantially Equivalent |
| Scan Regime | Continuous Rotation | Continuous Rotation | Identical / Substantially Equivalent |
| No. of Slices | 16 | 6/16 | Access CT 6 and Access CT 16 use the same Detector and other hardware configuration, by software control, 6 slices is implemented by combining different detecting units to achieve different slice thickness configuration. This does not affect the safety or effectiveness. Therefore, demonstrating substantial equivalence. |
| Scan Modes | Surview, Axial Scan, Helical Scan | Surview, Axial Scan, Helical Scan | Identical / Substantially Equivalent |
| Minimum Scan Time | 0.5 sec for 360° rotation | 0.75 sec for 360° rotation | Increasing the Minimum scan time from 0.5 to 0.75 sec on the proposed Access CT does not affect the safety or effectiveness. Therefore, demonstrating substantial equivalence. |
| Image (Spatial) Resolution | High resolution mode: 15 lp/cm | High resolution mode: 15 ± 10% lp/cm @ 0% | Identical / Substantially Equivalent |
| Image Noise | ≤0.35% | ≤0.35% | Identical / Substantially Equivalent |
| Image Matrix | 512x512. | 512x512. | Identical |
| Display | 768x768, 1024x1024, 1024x1280 | 768x768, 1024x1024, 1024x1280 | Substantially Equivalent (for all three resolutions, listed together) |
| Host Infrastructure | Windows XP | Windows 7 | Changing the Windows platform from Windows XP to Windows 7 does not affect the safety or effectiveness of the device. Therefore demonstrating substantial equivalence. |
| Communication | Compliance with DICOM | Compliance with DICOM | Identical / Substantially Equivalent |
| Dose Reporting and Management | None (for predicate) | Compliance with NEMA XR25, XR28 and XR29 | Subject device compliant with NEMA standards. There is no impact on safety or effectiveness. |
| Generator and Tube Power (kW Output) | 50 kW | 28 kW | The difference of power output from 50 KW to 28KW does not have an impact on the functionality / performance and/or safety or effectiveness of the device. Therefore, demonstrating substantial equivalence. |
| mA Range | 30mA-420mA | 10mA-233mA | The impact of decreasing the tube power is an extended lower limit of mA range and decreased upper limit of mA range, difference in range does not affect safety or effectiveness. Therefore, demonstrating substantial equivalence. |
| kV Settings | 90kV, 120kV, 140kV | 70kV, 80kV, 100kV, 120kV, 140kV | The impact of decreasing the tube power is an extended kV range, difference in range does not affect safety or effectiveness. Therefore, demonstrating substantial equivalence. |
| Tube Type | CTR 2150 CEPN | CTR1735 | Identical tube technology, and same tube supplier, does not affect safety or effectiveness. Therefore, demonstrating substantial equivalence. |
| Detector Type | NanoPanel Elite | NanoPanel Elite | Identical / Substantially Equivalent |
| Scan Field of View (SFOV) | 500 mm | 450 mm | The difference of SFOV impact on the scan field, does not affect safety or effectiveness. Therefore, substantially equivalent. |
| Detector Type (Detail) | Single layer ceramic scintillator plus a photodiode | Single layer ceramic scintillator plus a photodiode | Identical / Substantially Equivalent |
| Detector Material | GOS solid | GOS solid | Identical / Substantially Equivalent |
| Gantry Tilt capability | ± 30° | No physical tilt (digital tilt for images) | Both are available for axial scans. The difference does not affect safety or effectiveness. Therefore, substantially equivalent. |
| Gantry Rotation Speed | 120 RPM | 80 RPM | Identical transmission design with lower rotation speed. Safety and effectiveness are not affected. Therefore, substantially equivalent. |
| Bore Size | 700mm | 650mm | Bore Size decreasing does not affect safety or effectiveness. Therefore, substantially equivalent. |
| Maximum Scannable Range | 1,500 mm | Fixed height couch: ≤ 1200mm; Vertical moveable couch: ≤1380mm | Maximum scannable range decreasing does not affect safety or effectiveness. Therefore, substantially equivalent. |
| Z-position Accuracy | +/- 0.25 mm | +/- 0.25 mm | Identical / Substantially Equivalent |
| Lowest Table Height | 579mm | Fixed height couch: 815mm; Vertical movement couch: 480mm | The difference of table height does not affect safety or effectiveness. Therefore, substantially equivalent. |
| Maximum Load Capacity | 200kg | Fixed height couch: 150kg; Vertical movement couch: 200kg | Both are compliant with IEC60601 series standards. The difference does not affect safety or effectiveness. Therefore, substantially equivalent. |
| Clinical Features (e.g., 2D Viewer, MPR, 3D, VE, Filming, MAR, Dose Modulation, Bolus Tracking, Worklist, MPPS, Reporting, CCT, Brain Perfusion, Dental, VA) | Yes (for all listed) | Yes (for all listed) | Identical / Substantially Equivalent (for each feature) |
The document also compares against two other reference devices (Philips Ingenuity CT and Philips Incisive CT) for specific "clinical features" (Iterative recon, CTC, LNA, iPlanning, Batch image processing (iBatch)), concluding they are "Identical".
Study Details (as presented in the document, primarily non-clinical)
2. Sample Size Used for the Test Set and the Data Provenance
- Test Set Description: The document refers to "Design Verification planning and testing" and "Design validation of user needs and intended use" with "simulated use testing with production equivalent Access CT Systems."
- Sample Size: The document does not specify a sample size in terms of patient data or scanned images for non-clinical verification. It focuses on testing the system's compliance with engineering requirements and standards.
- Data Provenance: The testing was conducted internally by Philips Healthcare (Suzhou) Co., Ltd. in China ("Philips Healthcare (Suzhou) Co., Ltd., No. 258, Zhongyuan Road, Suzhou Industrial Park, Suzhou Jiangsu, CHINA, 215024"). The data stems from design verification and validation activities rather than a clinical study. The type of data is technical performance measurements, rather than patient scans with clinical findings. The document states: "The proposed Access CT System did not require any external clinical site testing."
- Retrospective or Prospective: Not applicable in the context of clinical data. The verification and validation testing would have been "prospective" in the sense that it was planned and executed for the purpose of demonstrating compliance.
3. Number of Experts Used to Establish the Ground Truth for the Test Set and the Qualifications of Those Experts
- Not Applicable: This is a submission for a CT scanner itself, not an AI algorithm that requires expert ground truth for diagnostic accuracy. The "ground truth" for the device's performance is adherence to technical specifications and safety standards, as measured by engineering tests.
4. Adjudication Method for the Test Set
- Not Applicable: There is no clinical test set requiring adjudication in this document. Adjudication methods are relevant for clinical studies where multiple human readers interpret medical images or data.
5. If a Multi Reader Multi Case (MRMC) Comparative Effectiveness Study was done
- No: The document explicitly states: "The proposed Access CT System did not require any external clinical site testing. Clinical evaluation of workflow was conducted via simulated use testing and is accounted for in the Summary of Non-Clinical Testing section of the summary."
- This also means there is no effect size given for human readers improving with AI vs. without AI assistance, as AI assistance is not the subject of this 510(k).
6. If a Standalone (i.e., algorithm only without human-in-the-loop performance) was done
- Not Applicable: This device is a CT scanner, not a standalone algorithm.
7. The Type of Ground Truth Used
- For the technical and safety performance of the CT scanner, the "ground truth" is established by international and FDA-recognized consensus standards (listed in the "Summary of Non-Clinical Performance Data" section on pages 4-5) and system design requirements. The device's performance is measured against these established standards and requirements. Examples of standards cited include AAMI / ANSI ES60601-1, IEC 60601-1-2, IEC 60601-1-3, IEC 60601-2-44, IEC 62304, IEC 62366-1, ISO14971, NEMA XR 25-2011, NEMA XR 28-2013, and NEMA XR 29-2013.
8. The Sample Size for the Training Set
- Not Applicable: This is not an AI/machine learning device submission. There is no "training set" in the context of model development.
9. How the Ground Truth for the Training Set was Established
- Not Applicable: As there is no training set for an AI model, this question is not relevant to the content of the document.
In summary, the provided document details the 510(k) submission for a CT scanner, demonstrating its substantial equivalence to previously cleared predicate devices through comparisons of technical specifications and compliance with established safety and performance standards via non-clinical verification and validation. It is not an application for an AI-powered diagnostic device, and thus, many of the questions related to AI study design, clinical efficacy, and human reader performance are not addressed.
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