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Digital Dental Intra Oral Sensor is intended to collect dental x-ray photons and convert them into electronic impulses that may be stored, viewed and manipulated for diagnostic use by dentists.

Device Description

Digital Dental Intra Oral Sensor is a device which acquires digital intra-oral images. Direct digital systems acquire images with a sensor that is connected to a computer to produce an image almost instantaneously following exposure. The primary advantage of direct sensor systems is the speed with which images are acquired. For patient comfort, the ergonomic design is based on human intraoral anatomy.

Excellent image quality based on advanced CMOS technology
More comfortable sensor ergonomic shape for the human oral structure
Lower dose exposure (Compared to film sensor)
Enhanced durability
Easy-to-use USB interface

AI/ML Overview

The provided document is a 510(k) summary for the Rayence Co., Ltd. Digital Dental Intra Oral Sensor. This type of submission focuses on demonstrating substantial equivalence to a predicate device rather than providing detailed clinical study results designed to prove device performance against specific acceptance criteria.

Therefore, the document does not contain the information requested for acceptance criteria and a study proving the device meets those criteria in the typical sense of a clinical trial. Instead, it relies on demonstrating similar performance to a legally marketed predicate device through non-clinical testing.

Here's what can be extracted and what is missing based on your request:

1. Table of Acceptance Criteria and Reported Device Performance

The document measures performance characteristics like DQE, MTF, Pixel Pitch, and Sensor Dimensions against those of a predicate device. It doesn't explicitly state "acceptance criteria" but rather demonstrates "equivalence" to the predicate.

Characteristic	Acceptance Criteria (Implicit: Equivalent to Predicate)	Reported Device Performance (Proposed Device)	Predicate Device Performance
Sensor Dimension (mm) (±10%)	Equivalent to Predicate or justified differences	Size 1.0: 36.8 x 25.4
Size 1.5: 39.5 x 29.2
Size 2.0: 42.9 x 31.3	Size 1.0: 37.6 x 25.4
Size 1.5: 39.5 x 29.2
Sensor Thickness (mm)	Equivalent to Predicate	4.8	4.8
Active Area (mm)	Equivalent to Predicate or justified differences	Size 1.0: 30.01 x 20.01
Size 1.5: 33.00 x 23.98
Size 2.0: 35.99 x 25.99	Size 1.0: 30.01 x 20.00
Size 1.5: 33.00 x 23.98
Pixel Pitch (µm) (Full Resolution)	Equivalent to Predicate	14.8	14.8
Pixel Pitch (µm) (Binning mode)	Equivalent to Predicate	29.6	29.6
DQE (6 lp/mm) (Full Resolution)	Equivalent to Predicate	0.38	0.38
DQE (6 lp/mm) (Binning mode)	Equivalent to Predicate	0.34	0.34
MTF (3 lp/mm) (Full Resolution)	Equivalent to Predicate	0.642	0.642
MTF (3 lp/mm) (Binning mode)	Equivalent to Predicate	0.630	0.630
Electrical, Mechanical, Environmental Safety	Compliance with IEC 60601-1: 2005 + CORR.1(2006) + CORR(2007)	Performed and Compliant	(Not explicitly stated for predicate in summary, but assumed compliant)
EMC Testing	Compliance with IEC 60601-1-2:2007	Performed and Compliant	(Not explicitly stated for predicate in summary, but assumed compliant)
Dynamic Range	Same as predicate device	Same dynamic range	(Not explicitly stated with a value, but equivalence claimed)

2. Sample size used for the test set and the data provenance:

The document explicitly states: "Clinical images were not necessary to establish substantial equivalence based on the modifications to the device. The laboratory performance data shows that the subject device operates similar to the predicate device." Therefore, there was no clinical test set in the traditional sense with human patient data.
The comparison was done with laboratory performance data. The provenance of this laboratory data (e.g., specific lab, country) is not detailed. It's an internal test report.

3. Number of experts used to establish the ground truth for the test set and the qualifications of those experts:

Not applicable, as no clinical test set with human data and expert ground truth was used.

4. Adjudication method (e.g., 2+1, 3+1, none) for the test set:

Not applicable, as no clinical test set with human data and associated adjudication was used.

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:

No MRMC study was done, nor is this device described as an AI-assisted device. The device is a digital intra-oral sensor for image acquisition.

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

The device itself is a standalone hardware component (sensor). The "performance" being evaluated is its technical characteristics (DQE, MTF, etc.) demonstrating equivalence to a predicate, not an algorithmic diagnostic output. The document states that "The DQE, MTF and linear response to X-ray exposure test demonstrated that the subject sensor performed equivalently compared to the predicate device with the same dynamic range." This is a standalone device performance evaluation, but not in the context of an AI algorithm's diagnostic accuracy.

7. The type of ground truth used (expert consensus, pathology, outcomes data, etc.):

Not applicable, as the evaluation was based on non-clinical, laboratory performance measurements (e.g., DQE, MTF values, physical dimensions) compared to a predicate device's specifications. The ground truth for these measurements would be the reference standards and protocols used in the laboratory setting to measure these physical properties.

8. The sample size for the training set:

Not applicable. This is a 510(k) submission for a hardware device (digital x-ray sensor) demonstrating substantial equivalence to a predicate through non-clinical bench testing. It does not involve machine learning or AI models with training sets.

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

Not applicable, as there is no training set for an AI model mentioned.

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K Number

K150797

Device Name

Digital Dental Intra Oral Sensor, EzSensor Smart

Manufacturer

Rayence Co., Ltd

Date Cleared

2015-05-01

(36 days)

Product Code

Regulation Number

Type

Panel

Reference & Predicate Devices

K131594,K143753,K090526

Intended Use

Digital Dental Intra Oral Sensor is intended to collect dental x-ray photons and convert them into electronic impulses that may be stored, viewed and manipulated for diagnostic use by dentists.

Device Description

AI/ML Overview

Here's a breakdown of the acceptance criteria and study information for the "Digital Dental Intra Oral Sensor, EzSensor Smart" device, based on the provided text:

Important Note: The provided text is a 510(k) summary, which focuses on demonstrating substantial equivalence to a predicate device rather than a comprehensive standalone performance study with detailed acceptance criteria and ground truth validation as one might find for a novel AI device. Therefore, some information, particularly regarding specific numerical acceptance criteria and a detailed multi-reader multi-case (MRMC) study, is not present.

1. Table of Acceptance Criteria and Reported Device Performance

The document doesn't explicitly state numerical acceptance criteria in a pass/fail format for diagnostic performance. Instead, it focuses on demonstrating superiority or substantial equivalence to a predicate device (EzSensor) through various technical characteristics and a comparative image review.

Characteristic	Acceptance Criteria (Implied)	Reported Device Performance (Proposed Device)
Diagnostic Image Quality	Produce images allowing for correct diagnosis of a range of anatomic structures while minimizing radiation exposure to patients. Ideally, equivalent or superior to the predicate device.	Images produced by the proposed device (IOS-U15VF AND 11MODELS, both Binning Mode and Full Resolution Mode) were consistently better than the predicate device (EzSensor) in terms of diagnostic quality in most cases. Negligible difference between Binning Mode and Full Resolution Mode. All images from both devices presented no significant difficulty in evaluating a range of anatomic structures necessary for a correct diagnosis.
Pixel Pitch ($\mu$m)	Improved (smaller) pixel pitch compared to predicate for better resolution.	Full Resolution: 14.8 $\mu$m; Binning mode: 29.6 $\mu$m (Predicate: 35 $\mu$m)
DQE (6 lp/mm)	Improved DQE compared to predicate for better dose efficiency.	Full Resolution: 0.38; Binning mode: 0.34 (Predicate: 0.123) - Consistently performed better.
MTF (6 lp/mm)	Improved MTF compared to predicate for better resolution.	Full Resolution: 0.642; Binning mode: 0.630 (Predicate: 0.382) - Consistently performed better.
Linear Response to X-ray Exposure	Improved linearity (closer to 1) compared to predicate.	Very linear response, closer to 1, than the predicate device in the same dynamic range.
Electrical, Mechanical, Environmental Safety	Compliance with IEC/EN 60601-1 and IEC 60601-1-2 EMC standards.	Electrical, mechanical, environmental safety and performance testing according to IEC 60601-1: 2005 + CORR.1(2006) + CORR(2007) and EMC testing according to IEC 60601-1-2:2007 were performed. (Implied compliance, as the conclusion states the device is safe and effective).
Risk Mitigation	All identified risks successfully mitigated and accepted.	Risks analyzed with FMEA method; specific risk control measures implemented. Overall assessment concluded all risks from design change successfully mitigated and accepted.

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

Sample Size: "Total 30 sets of radiographic image samples" were reviewed for diagnostic image quality.
Data Provenance: The document does not specify the country of origin. It also does not explicitly state whether the data was retrospective or prospective, but given it's an evaluation of image samples, it's most likely retrospective image data captured using the devices.

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

Number of Experts: "a licensed dentist." (Singular)
Qualifications: "licensed dentist." (No specific years of experience or subspecialty beyond general dentistry is mentioned).

4. Adjudication Method for the Test Set

Adjudication Method: "Based on the reviewer's conclusion..." The use of a single licensed dentist for review indicates none in terms of formal adjudication (e.g., 2+1 or 3+1 consensus). The assessment relies on a single expert opinion.

5. If a Multi-Reader Multi-Case (MRMC) Comparative Effectiveness Study was Done

MRMC Study: No, a formal MRMC comparative effectiveness study was not done. The evaluation of diagnostic image quality was conducted by a single licensed dentist reviewing 30 image sets.
Effect Size: Not applicable, as no MRMC study was performed. The comparison was qualitative by a single reviewer ("superior to EzSensor in terms of diagnostic quality in most cases").

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

This device is a digital intra-oral sensor, a hardware device that captures X-ray images, not an AI algorithm. Therefore, the concept of a "standalone (algorithm only)" performance study is not applicable. The performance tests described relate to the sensor's physical and technical image acquisition capabilities (e.g., DQE, MTF, pixel pitch) and how the images are perceived by a human reader.

7. The Type of Ground Truth Used

Type of Ground Truth: For the diagnostic image quality assessment, the ground truth was expert opinion/consensus by a single "licensed dentist." It's an assessment of whether the images facilitate correct diagnosis, rather than being linked to independent pathology or patient outcomes data.
For technical characteristics (pixel pitch, DQE, MTF, linearity), the "ground truth" is derived from laboratory measurements using standardized testing methods.

8. The Sample Size for the Training Set

The document describes a hardware device (intra-oral sensor) and its associated viewing software. It does not mention any machine learning or AI components that would require a "training set." Therefore, this question is not applicable to this device submission.

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

As there is no mention of a training set for an AI algorithm, this question is not applicable.

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K Number

K143753

Device Name

Digital Dental Intra Oral Sensor, EzSensor Soft, EzSensor Bio

Manufacturer

Rayence Co., Ltd

Date Cleared

2015-03-10

(69 days)

Product Code

Regulation Number

Type

Panel

Reference & Predicate Devices

K131594,K090526

Intended Use

EzSensor Soft [Alternative name : EzSensor Bio] Digital Dental Intra Oral Sensor is intended to collect dental x-ray photons and convert them into electronic impulses that may be stored, viewed and manipulated for diagnostic use by dentists.

Device Description

EzSensor Soft[Alternative name : EzSensor Bio] Digital Dental Intra Oral Sensor is a device which acquires digital intra oral images. Direct digital systems acquire images with a flexible sensor that is connected to a computer to produce an image almost instantaneously following exposure. The primary advantage of direct sensor systems is the speed with which images are acquired. For patient comfort, the ergonomic design is based on human intraoral anatomy.

AI/ML Overview

The provided document is a 510(k) premarket notification for a dental imaging device, "EzSensor Soft [Alternative name : EzSensor Bio] digital dental image processing system". It compares the new device to a predicate device, "EzSensor". The study primarily focuses on technical performance comparisons and a small-scale image review, rather than a clinical effectiveness study with strict acceptance criteria often seen in AI/CAD device approvals.

Here's an analysis of the acceptance criteria and study findings based on the provided text, while noting the limitations in terms of typical AI/CAD device study requirements:

1. A table of acceptance criteria and the reported device performance

The document does not explicitly state formal acceptance criteria in the manner of quantifiable metrics for diagnostic performance (e.g., sensitivity, specificity, AUC targets). Instead, the performance comparison focuses on technical image quality metrics and a qualitative review by a dentist.

Here's a table based on the provided technical characteristics and the stated comparative performance:

Characteristic	Acceptance Criteria (Implied / Comparator)	Reported Device Performance (EzSensor Soft / EzSensor Bio)
Image Quality	At least equivalent to the predicate device (EzSensor) in DQE, MTF, NPS.	- DQE (6 lp/mm): 0.199 (Full Resolution & Binning Mode) vs. 0.123 (Predicate). Better performance.

MTF (6 lp/mm): 0.436 (Full Resolution) / 0.464 (Binning Mode) vs. 0.382 (Predicate). Better performance.
NPS: Not explicitly quantified, but stated "outperformed EzSensor". Better performance. |
| Linearity | At least equivalent to the predicate device (EzSensor). | "Very linear and has better linearity than EzSensor in the same dynamic range." Better performance. |
| Contrast-to-Noise Ratio (CNR) | At least equivalent to the predicate device (EzSensor). | "Superior CNR characteristics compared to EzSensor... direct result of Noise improvement." Better performance. |
| Resolution/Sharpness | Images should be similar or moderately superior to EzSensor, presenting no difficulty in evaluating anatomical structures. | "Final images generated by both new and predicate sensors are similar or moderately superior to existing EzSensor (Predicate)." "Images of EzSensor Soft [Alternative name : EzSensor Bio] in full resolution mode is generally more sharper and clearer than EzSensor Soft [Alternative name : EzSensor Bio] in binning mode." |
| Clinical Acceptability | Images present no difficulty in evaluating anatomical structures necessary for correct diagnosis. | "All images present no difficulty in evaluating a range of anatomic structures necessary to provide a correct conclusion..." (based on review by one dentist). |
| Risk Assessment | All risks and hazardous conditions mitigated to acceptable limits. | "All risks and hazardous conditions identified arising from the design change were successfully mitigated and accepted." Risks identified (electronic shock, device failure, misdiagnosis, tissue damage, serious leakage current, sensor fracture/breakage, cable disconnection) analyzed via FMEA and verified with IEC/EN 60601-1 and drop & vibration tests. |
| Software Functionality | Easydent and EzDent i have same functionality and performance. | "Easydent and EzDent i image viewing software have the same functionality and performance." Main difference is UI design and new consulting simulation tool for EzDent i. |

2. Sample size used for the test set and the data provenance (e.g. country of origin of the data, retrospective or prospective)

Test Set Sample Size: "Total 30 sets of radiographic images were reviewed."
Data Provenance: Not explicitly stated, but the submission is from Rayence Co. Ltd. in Korea. The context of a premarket notification for a new device suggests these would likely be newly acquired images for testing, making them prospective to the submission. However, this is an inference; it is not explicitly stated. The country of origin for the images is not specified.

3. Number of experts used to establish the ground truth for the test set and the qualifications of those experts (e.g. radiologist with 10 years of experience)

Number of Experts: "a licensed dentist" (singular).
Qualifications: "a licensed dentist." No information on years of experience or specialization is provided.

4. Adjudication method (e.g. 2+1, 3+1, none) for the test set

Adjudication Method: "none". The document states "Based on the reviewer's conclusion," indicating a single reviewer's assessment without a consensus or adjudication process.

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

MRMC Study: No. This document describes a medical device (digital dental x-ray sensor), not an AI/CAD system. Therefore, an MRMC study comparing human readers with and without AI assistance is not applicable and was not performed. The study described is a technical comparison of the image sensor and a qualitative review of images by a single dentist.

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

Standalone Study: Not applicable. This is not an AI/CAD algorithm. The device is an image acquisition sensor. There is no algorithm operating standalone on diagnostic tasks.

7. The type of ground truth used (expert consensus, pathology, outcomes data, etc)

Type of Ground Truth: The "ground truth" for the image review consisted of the qualitative assessment by a single "licensed dentist" regarding the difficulty in evaluating anatomical structures and the sharpness/clearness of images. This is best characterized as expert opinion/review by a single expert. It is not objective ground truth like pathology or outcomes data.

8. The sample size for the training set

Training Set Sample Size: Not applicable. As this is an image acquisition hardware device (sensor) and not an AI/machine learning algorithm, there is no "training set" in the context of AI. The device's performance is based on its physical and electronic design and confirmed through bench testing.

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

Ground Truth for Training Set: Not applicable, as there is no training set for an AI algorithm.

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K Number

K140060

Device Name

DIGITAL DENTAL INTRA ORAL SENSOR, HDI 2000, HDI 2000A

Manufacturer

RAYENCE CO., LTD

Date Cleared

2014-05-13

(123 days)

Product Code

Regulation Number

Type

Panel

Reference & Predicate Devices

K131594,K121132

Intended Use

HDI 2000 / HDI 2000A, an Intra-Oral Intended to collect dental x-ray photons and convert them into electronic impulses that may be stored, viewed, and manipulated for diagnostic use by dentists.

Device Description

The HDI 2000 / HDI 2000A Intra-oral imaging system is a device which acquires digital image. Direct digital systems acquire images with a solid-state sensor that is connected to a computer to produce an image almost instantaneously following exposure. The primary advantage of direct sensor systems is the speed with which images are acquired. The sensor is connected by a wire to an analog-to-digital USB box, which is connected to the computer. Images are produced within seconds of sensor exposure. The wire length from a direct sensor is about 3 meters and less. The USB box connects to the USB 2.0 port of the computer.

AI/ML Overview

Here's an analysis of the provided text regarding the acceptance criteria and study for the HDI 2000 / HDI 2000A device:

This 510(k) submission primarily focuses on demonstrating substantial equivalence to a predicate device (EzSensor P) rather than presenting a de novo clinical study with explicit acceptance criteria for diagnostic performance. Therefore, many of the typical clinical study details are not present.

1. Table of Acceptance Criteria and Reported Device Performance

Because this is a 510(k) submission for substantial equivalence based on technological characteristics, explicit numerical diagnostic performance acceptance criteria (e.g., sensitivity, specificity, AUC) are not defined or reported for diagnostic accuracy. The acceptance criteria revolve around meeting established safety and performance standards for medical electrical equipment and X-ray imaging devices, and demonstrating that the new device does not raise new questions of safety or effectiveness compared to the predicate.

Acceptance Criteria Category	Specific Standard/Guidance	Reported Device Performance / Compliance
Electrical, Mechanical, Environmental Safety & Performance	IEC 60601-1:2005 + CORR.I(2006) + CORR(2007)	"All test results were satisfactory."
Electromagnetic Compatibility (EMC)	IEC 60601-1-2:2007	"EMC testing were conducted in accordance with standard IEC 60601-1-2:2007."
Non-clinical & Clinical Considerations for Solid State X-ray Imaging Devices	FDA Guidance for the Submissions of 510(k)'s for Solid State X-ray Imaging Devices	"Non-clinical & Clinical considerations... was performed."
Technological Equivalence (Primary justification)	Comparison to predicate device (EzSensor P)	"The indications for use, material, form factor, performance, and safety characteristics of HDI 2000 / HDI 2000A described in this 510(k) are the same as that of the predicate device... The difference in the physical dimension of the sensor does not present any new concerns in terms of safety and effectiveness."
Software Risk Analysis	Not explicitly stated, but implied by "design control risk analysis for ProraView"	"All risks are mitigated and any residual risks are determined acceptable."

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

The document does not describe a clinical test set in the traditional sense of a clinical trial for diagnostic performance. The testing described is primarily for engineering standards compliance (safety, EMC) and performance characteristics relevant to sensor operation, rather than a clinical evaluation of diagnostic accuracy using a test dataset of patient images.

Sample Size for Test Set: Not applicable in the context of diagnostic performance. The document refers to "test results" for electrical, mechanical, environmental, and EMC testing, which would involve laboratory testing of device units.
Data Provenance: Not applicable for diagnostic performance as no clinical diagnostic test set is described. The engineering tests would be performed in a controlled laboratory environment.

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

Not applicable. As no clinical test set for diagnostic performance is described, there's no mention of experts establishing a ground truth for such a set.

4. Adjudication Method for the Test Set

Not applicable. No clinical test set or adjudication process for diagnostic interpretations is described.

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 or reported in this 510(k) submission. The submission focuses on demonstrating substantial equivalence based on technological characteristics and engineering tests, not a clinical comparison of diagnostic efficacy.

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

This device is an intra-oral imaging system (sensor and software), not an AI algorithm designed to interpret images independently. Therefore, the concept of "standalone performance" for an AI algorithm without human-in-the-loop is not applicable to this submission. The device's function is to acquire and display images for diagnostic use by dentists.

7. The Type of Ground Truth Used

The concept of "ground truth" for diagnostic accuracy (e.g., pathology, outcomes data) is not applicable in this submission, as no diagnostic performance study is described. The "truth" being evaluated relates to the device's adherence to engineering standards and its functional performance as an imaging system (e.g., image capture, viewing) being equivalent to the predicate device.

8. The Sample Size for the Training Set

Not applicable. This device is an imaging sensor and viewer software; it is not an artificial intelligence (AI) or machine learning (ML) algorithm that requires a "training set" of data for learning diagnostic patterns.

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

Not applicable, as there is no training set for an AI/ML algorithm described.

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K Number

K140056

Device Name

DIGITAL DENTAL INTRA ORAL SENSOR; HDI 1000, HDI 1000A

Manufacturer

RAYENCE CO., LTD

Date Cleared

2014-05-13

(123 days)

Product Code

Regulation Number

Type

Panel

Reference & Predicate Devices

K131594,K090526

Intended Use

HDI 1000 / HDI 1000A, an Intra-oral Imaging System, is used to collect dental x-rays photons and convert them into electronic impulses that may be stored, viewed, and manipulated for diagnostic use by dentists.

Device Description

The HDI 1000 / HDI 1000A intra-oral imaging system is a device which acquires digital intra oral images. Direct digital systems acquire images with a solid-state sensor that is connected to a computer to produce an image almost instantaneously following exposure. The primary advantage of direct sensor systems is the speed with which images are acquired. The sensor is connected by a wire to an analog-to-digital converter box, which is connected to the computer. Images are produced within seconds of sensor exposure. The wire length from a direct sensor is about 3 meters and less. This wire plugs into an analogto-digital converter box. The converter box connects to the computer with a USB cable.

AI/ML Overview

The provided text does not contain information about specific acceptance criteria or a study that proves the device meets those criteria with detailed performance metrics. The submission is a 510(k) summary for a digital dental intra-oral sensor (HDI 1000, HDI 1000A), which primarily focuses on demonstrating substantial equivalence to a predicate device.

The document states: "The indications for use, material, form factor, performance, and safety characteristics of HDI 1000 / HDI 1000A described in this 510(k) are the same as that of the predicate device, EzSensor of Rayence Co., Ltd." This indicates that the device is deemed acceptable because it performs similarly to an already approved device.

The "Summary for any testing in the submission" section mentions:

Electrical, mechanical, environmental safety and performance testing according to standard IEC 60601-1: 2005 + CORR.1(2006) + CORR(2007).
EMC testing conducted in accordance with standard IEC 60601-1-2:2007.
Non-clinical & Clinical considerations according to FDA Guidance "Guidance for the Submissions of 510(k)'s for Solid State X-ray Imaging Devices" was performed.

It concludes that "All test results were satisfactory" and the device is "safe and effective and substantially equivalent to predicate device." However, specific quantitative acceptance criteria or detailed results from these tests are not provided in this summary.

Therefore, most of the requested information regarding detailed acceptance criteria, device performance, sample sizes, ground truth establishment, expert involvement, and comparative effectiveness studies are not present in this 510(k) summary.

Here's a breakdown of what can be extracted and what is missing:

1. A table of acceptance criteria and the reported device performance

Acceptance Criteria	Reported Device Performance
Substantial Equivalence to predicate device (EzSensor) in terms of:	- Device determined to be substantially equivalent to EzSensor (K090526).

Indications for use, material, form factor, performance, and safety characteristics are the same. |
| Electrical, mechanical, environmental safety and performance according to IEC 60601-1: 2005 + CORR.1(2006) + CORR(2007) |- All test results were satisfactory. |
| EMC compliance according to IEC 60601-1-2:2007 |- All test results were satisfactory. |
| Non-clinical & Clinical considerations according to FDA Guidance "Guidance for the Submissions of 510(k)'s for Solid State X-ray Imaging Devices" |- All test results were satisfactory. |

2. Sample size used for the test set and the data provenance

Missing: The document does not specify any sample sizes for test sets or data provenance (e.g., country of origin, retrospective/prospective). The testing mentioned seems to be primarily engineering and regulatory compliance, not clinical performance studies with patient data to establish diagnostic accuracy.

3. Number of experts used to establish the ground truth for the test set and the qualifications of those experts

Missing: This information is not provided as there is no mention of a clinical study involving experts establishing ground truth for diagnostic accuracy.

4. Adjudication method for the test set

Missing: Not applicable, as no clinical test set requiring adjudication is described.

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

Missing: This is not an AI or CAD device. It's an imaging acquisition device. No MRMC study was conducted or is relevant based on the provided information.

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

Missing: Not applicable. This is an imaging sensor, not an algorithm.

7. The type of ground truth used

Missing: As no clinical performance study for diagnostic accuracy is described, there's no mention of ground truth established through expert consensus, pathology, or outcomes data. The "ground truth" for this device's acceptance is its ability to meet safety and performance standards (e.g., IEC standards) and demonstrate substantial equivalence to a predicate device.

8. The sample size for the training set

Missing: Not applicable. This is an imaging sensor, not a machine learning model, so there is no "training set."

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

Missing: Not applicable.

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