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The Angioslide PROTEUS™ Percutaneous Transluminal Angioplasty (PTA) Balloon Catheter with Embolic Capture Feature is indicated for peripheral transluminal angioplasty and for capture and removal of embolic material (e.g. debris, thrombus) during angioplasty, for the femoral, iliac, ilio-femoral, popliteal, tibial, peroneal, and profunda arteries.

The Angioslide PROTEUS™ PTA Balloon Catheter with Embolic Capture is not intended for use in the renal, cerebral, coronary or carotid vasculature.

Device Description

One lumen is used for inflation of the balloon and is accessed via the inflation port (2). The other lumen, starting at the guidewire port (10), allows access to the distal tip for guidewire insertion (max. 0.035"). The balloon has two radiopaque markers (8) for positioning the balloon relative to stenosis. The radiopaque markers indicate the dilating section of the balloon and help in balloon placement. The balloon is designed to provide an inflatable segment of known diameter and length at specified pressure.

The shaft (4) comprises the outer shaft (6) and the inner shaft (7). The distal end of the balloon (A) is connected to the inner shaft and the proximal end of the balloon (B) is connected to the outer shaft. The inner shaft is connected to the proximal hub (10) which is connected to the pulling knob (1) and the outer shaft is connected to the handle grip (3). The pulling knob lock (11) locks the handle grip and the pulling knob together. The distal end of the balloon is folded inwards towards the proximal end of the balloon, by pressing on pulling knob lock (11) and pulling the pulling knob away from the handle (1). The inward-folding of the balloon forms a cavity and allows for collection and removal of embolic material.

AI/ML Overview

The provided document describes the Angioslide PROTEUS™ PTA Balloon Catheter with Embolic Capture Feature. It is a medical device designed for peripheral transluminal angioplasty and for capturing embolic material during angioplasty in various peripheral arteries. The document is a 510(k) summary, demonstrating substantial equivalence to a predicate device (K133043).

Here's an analysis of the acceptance criteria and study information:

1. Table of Acceptance Criteria and Reported Device Performance

The document presents a comprehensive table of non-clinical bench tests. All tests passed, indicating the device met its acceptance criteria. Below is a summarized version of the table provided in the document:

Test	Acceptance Criteria (Example)	Reported Device Performance
Visual inspection - external surface	Free from extraneous matter and surface defects (<0.2mm² TAPPI). 90% Confidence, 90% Reliability	PASS
Visual inspection - distal tip	Smooth, rounded, tapered, or similarly finished. 90% Confidence, 90% Reliability	PASS
Distal Bond Outer Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Wrapped Balloon Outer Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Guide Wire Lumen Inner Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Minimum Balloon Burst Pressure (RBP)	RBP 12atm. 95% Confidence, 99.9% Reliability	PASS
Balloon Fatigue (Repeated Inflation/Deflations)	Inflation/Deflation Cycles 10 at 12atm. No leakage, rupture, and/or herniation. 95% Confidence, 90% Reliability (Up to max 20 cycles)	PASS
Tensile Strength- Distal Balloon to Inner Tube (Peel/Shear)	10N. 90% Confidence, 95% Reliability	PASS
Liquid Leakage	No leakage. 90% Confidence, 90% Reliability	PASS
Balloon Inflation/Deflation Testing	Inflation Time: ≤ 14.0s; Deflation Time: ≤ 30.6s. No leakage on Inflation. 90% Confidence, 90% Reliability	PASS
Balloon Compliance	Compliance: ≤ 13%; Nominal Pressure: 8atm; RBP: 12atm. 90% Confidence, 90% Reliability	PASS
Stress & Strain	Passed (implied by overall performance for intended use)	PASS
Flow Characteristics (Straight & Extreme Angle Configuration)	Distal flow observed in uninflated/deflated state, occlusion of distal flow in inflated state. 90% Confidence, 90% Reliability	PASS
Stroke Length	Minimum 70% of Balloon Working Length; Max: Balloon deflatable after reaching stroke limit. 90% Confidence / 90% Reliability	PASS
Simulated Use in Tortuous Anatomy (Guidewire Compatibility)	Catheter can be mounted over a 0.035" guide wire. 90% Confidence, 90% Reliability	PASS
Simulated Use in Tortuous Anatomy (Sheath Compatibility)	Completely folded balloon passes through identified Introducer Sheath at the end of procedure. 90% Confidence, 90% Reliability	PASS
Simulated Use in Tortuous Anatomy (Kink Resistance)	No permanent deformations (kinks) once removed from the tortuous anatomy model. 90% Confidence, 90% Reliability	PASS

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

Sample Size: "Sample sizes used for the testing were based on required confidence/reliability levels as per FDA Guidance... and the results of the risk analysis (DFMEA). The number of units utilized for each test depends on whether the data to be collected was variable data or attribute data, therefore the number of units tested varies from test to test. However, in all cases, the number utilized for testing met the required number of units based on the risk analysis, and the required confidence/reliability levels."
Data Provenance: The studies are described as "In vitro bench testing" and "Design Verification and Validation," performed in accordance with Angioslide's Risk Analysis and applicable FDA Guidance documents and ISO standards. This indicates the testing was conducted in a laboratory setting, likely at the manufacturer's facility in Israel. The data is prospective, generated specifically for this submission.

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

This device is not an AI/imaging device requiring expert interpretation of medical images to establish ground truth. The acceptance criteria are based on objective, quantifiable physical and mechanical properties of the device, measured using standardized engineering and material science tests. Therefore, there are no "experts" in the traditional sense of medical image interpretation for a test set, nor are there qualifications of such experts relevant to the type of testing performed. The "ground truth" is established by the specifications defined in the design and validated through these bench tests against established industry standards (ISO, FDA guidance).

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

Not applicable. This is not a study involving human readers or subjective interpretations requiring adjudication. The tests conducted are objective, measurable physical and mechanical tests of the device's components and functionality.

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

Not applicable. This device is a physical medical device (a balloon catheter), not an artificial intelligence (AI) or imaging diagnostic tool that would involve human readers or AI assistance in interpretation.

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

Not applicable. This device is a physical medical device, not an algorithm. The testing described is for the physical and functional aspects of the catheter itself.

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

The "ground truth" for this device's performance is established by engineering specifications, industry standards (ISO), and FDA guidance documents. For example, the definition of "In Tolerance" for dimensions or "No leakage" for liquid leakage comes from predetermined, objective criteria. For the purpose of substantial equivalence, the performance is compared against these predefined physical and functional benchmarks, rather than clinical outcomes or expert consensus on medical findings.

8. The sample size for the training set

Not applicable. This is not an AI device that requires a training set. The device is a physical medical instrument.

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

Not applicable. As there is no training set for an algorithm, there is no ground truth to be established for it.

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K Number

K133043

Device Name

PROTEUS PTA BALLOON CATHETER WITH EMBOLIC CAPTURE FEATURE

Manufacturer

ANGIOSLIDE, LTD

Date Cleared

2013-12-06

(71 days)

Product Code

Regulation Number

Type

Panel

Reference & Predicate Devices

K090364,K120805

Predicate For

K172494

Intended Use

The Angioslide PROTEUS™ PTA Balloon Catheter with Embolic Capture Feature is not intended for use in the renal, cerebral, coronary or carotid vasculature.

Device Description

The Angioslide PROTEUS™ Percutaneous Transluminal Angioplasty (PTA) Balloon Catheter with Embolic Capture Feature is an over the wire dual lumen catheter with a foldable balloon (S) located near the distal atraumatic soft tip (9).

The shaft (4) comprises the outer shaft (6) and the inner shaft (7). The distal end of the balloon (A) is connected to the inner shaft and the proximal end of the balloon (B) is connected to the outer shaft. The inner shaft is connected to the proximal hub (10) which is connected to the pulling knob (1) and the outer shaft is connected to the handle grip (3). The pulling knob lock ( 1 ) locks the handle grip and the pulling knob together. The distal end of the balloon is folded inwards towards the proximal end of the balloon, by pressing on pulling knob lock (11) and pulling the pulling knob away from the handle (1). The inward-folding of the balloon forms a cavity and allows for collection and removal of embolic material.

The balloon size and diameter are printed on the strain relief (12). Refer also to the package label for information about catheter length, balloon nominal and rated burst pressure, balloon size, balloon compliance, guidewire compatibility and sheath compatibility.

AI/ML Overview

The PROTEUS™ PTA Balloon Catheter with Embolic Capture Feature underwent non-clinical bench testing to demonstrate its performance and safety, particularly regarding its use within a stent environment.

1. Acceptance Criteria and Reported Device Performance:

Test	Acceptance Criteria	Reported Device Performance
Post-Dilatation, Minimum Balloon Burst Pressure (RBP)	RBP ≥ 14atm (3x100 only), 12atm for all other sizes with 95% Confidence, 99.9% Reliability	PASS
Post-Dilatation, Balloon Fatigue (Repeated Inflation/Deflations)	Inflation/Deflation Cycles ≥ 10 at 14atm (for 3x100 only), 12atm for all other sizes. No leakage, rupture, and/or herniation. Up to max 40 cycles with 95% Confidence, 90% Reliability	PASS
Post Dilatation Balloon Inflation/Deflation Testing	Inflation time: ≤ 14.0 sec, Deflation time: ≤ 30.6 sec. No leakage upon inflation with 90% Confidence, 90% Reliability	PASS
Post Dilatation, Simulated Use in Tortuous Anatomy Model - Guide Wire Compatibility	Catheter can be mounted over a 0.014" guide wire (3x100 only), 0.035" guide wire for all other sizes with 90% Confidence, 90% Reliability	PASS
Post Dilatation Simulated Use in Tortuous Anatomy Model - Introducer Sheath Compatibility	Completely folded balloon passes through identified Introducer Sheath (5F, 6F, 7F) at the end of procedure with 90% Confidence, 90% Reliability	PASS
Post Dilatation Simulated Use in Tortuous Anatomy Model – Kink Resistance	No permanent deformations (kinks) are present once removed from the tortuous anatomy model with 90% Confidence, 90% Reliability	PASS
Post-Dilatation Capture Efficiency	N/A - Characterization only	PASS (Overall CE consistent with previously tested device sizes without multiple overlapping stents, despite slight increase in particulate generation with stents.)

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

Sample Size: The document states that "Sample sizes used for Design Verification and Validation testing were based on required confidence / reliability levels as a result of risk analysis performed for the PROTEUS™ PTA Balloon Catheter, or per recommendations within the FDA Guidance "Non-Clinical Tests and Recommended Labeling for Intravascular Stents and Associated Delivery Systems." Specifically, the number of samples utilized for each test depended on whether the data to be collected was variable data or attribute data in nature." Specific numerical sample sizes for each test are not explicitly provided in the text.
Data Provenance: The tests were non-clinical in vitro bench tests conducted by Angioslide, Ltd. No patient data (retrospective or prospective) from specific countries was used for these tests.

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

Not applicable. The study involved non-clinical bench testing, not human expert evaluation of clinical data to establish ground truth.

4. Adjudication Method for the Test Set:

Not applicable. The study involved non-clinical bench testing, not human expert review with adjudication.

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

No. This was a non-clinical bench test. No human readers or AI assistance were involved in evaluating efficacy.

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

Not applicable. This device is a physical medical device (catheter), not an algorithm or AI system.

7. The Type of Ground Truth Used:

In a non-clinical bench study for a physical device, "ground truth" is established by the specifications and measurable outcomes of the device's physical performance against predefined engineering and regulatory standards (e.g., burst pressure, inflation/deflation times, absence of leakage, ability to pass through a tortuous model). The "ground truth" is essentially the expected physical behavior and integrity of the device under simulated conditions.

8. The Sample Size for the Training Set:

Not applicable. This device is a physical medical device undergoing performance testing, not an AI model that requires a training set.

9. How the Ground Truth for the Training Set Was Established:

Not applicable. As this is not an AI model, there is no training set or ground truth for a training set in this context.

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K Number

K120164

Device Name

PROTEUS PTA BALLOON CATHETER WITH EMBOLIC CAPTURE FEATURE

Manufacturer

ANGIOSLIDE, LTD

Date Cleared

2012-06-08

(141 days)

Product Code

Regulation Number

Type

Panel

Reference & Predicate Devices

K111750

Predicate For

N/A

Intended Use

The Angioslide PROTEUS™ Percutaneous Transluminal Angioplasty (PTA) Balloon Catheter with Embolic Capture Feature is indicated for peripheral transluminal angioplasty and for capture and containment of embolic material during angioplasty, for the femoral, iliac, ilio-femoral, popliteal, tibial, peroneal, and profunda arteries.

The Angioslide PROTEUS™ PTA Balloon Catheter with Embolic Capture Feature is not intended for use in the renal, cerebral, coronary or carotid vasculature.

Device Description

The Angioslide PROTEUSTM Percutaneous Transluminal Angioplasty (PTA) Balloon Catheter with Embolic Capture Feature is an over the wire dual lumen catheter with a foldable balloon (5) located near the distal atraumatic soft tip (9). One lumen is used for inflation of the balloon and is accessed via the inflation port (2). The other lumen, starting at the guidewire port (10), allows access to the distal tip for guidewire insertion (max. 0.035"). The balloon has two radiopaque markers (8) for positioning the balloon relative to stenosis. The radiopaque markers indicate the dilating section of the balloon and help in balloon placement. The balloon is designed to provide an inflatable segment of known diameter and length at specified pressure. The shaft (4) comprises the outer shaft (6) and the inner shaft (7). The distal end of the balloon (A) is connected to the inner shaft and the proximal end of the balloon (B) is connected to the outer shaft. The inner shaft is connected to the proximal hub (10) which is connected to the pulling knob (1) and the outer shaft is connected to the handle grip (3). The pulling knob lock (11) locks the handle grip and the pulling knob together. The distal end of the balloon is folded inwards towards the proximal end of the balloon, by pressing on pulling knob lock ( 1 l ) and pulling the pulling knob away from the handle (1). The embolic capture feature involves a single-use suction mechanism that works through inward folding of the balloon, which creates negative pressure within the capture cavity for debris capture and removal. The reduced pressure in the capture cavity causes some of the particles that are released during the procedure to flow into the cavity for containment and removal. The balloon size and diameter are printed on the strain relief (12). Refer also to the package label for information about catheter length, balloon nominal and rated burst pressure, balloon size, balloon compliance, guidewire compatibility and sheath compatibility.

AI/ML Overview

Here's a breakdown of the acceptance criteria and the study information for the PROTEUS™ PTA Catheter with Embolic Capture Feature, based on the provided text:

Acceptance Criteria and Device Performance

The device underwent extensive non-clinical bench testing, sterilization, packaging, and shelf-life testing to demonstrate conformance. The table below summarizes the acceptance criteria and reported device performance for these non-clinical tests.

Note: The provided document is a 510(k) summary for a submission that claims substantial equivalence to a predicate device (K111750), implying that the new device has identical technological characteristics for both PTA balloon function and embolic capture. Therefore, the "study" described here is a suite of design verification and validation tests rather than a comparative clinical trial.

Test Description	Acceptance Criteria	Reported Device Performance
Visual Inspection - External Surface	External surface of catheter effective length, including the distal end, is free from extraneous matter and surface defects (90% Confidence, 90% Reliability)	PASS
Visual Inspection - Distal Tip	Distal tip is smooth, rounded, tapered, or similarly finished. (90% Confidence, 90% Reliability)	PASS
Dimensional Inspection - Distal Bond O.D.	In Tolerance (90% Confidence, 90% Reliability)	PASS
Dimensional Inspection - Soft Tip Length	In Tolerance (90% Confidence, 90% Reliability)	PASS
Dimensional Inspection - Guidewire Inner Lumen	In Tolerance (90% Confidence, 90% Reliability)	PASS
Dimensional Inspection - Wrapped Balloon O.D.	The balloon must pass aperture < 2.00mm at 37deg C (90% Confidence, 90% Reliability)	PASS
Dimensional Inspection - Catheter Overall Length	In tolerance (90% Confidence, 90% Reliability)	PASS
Dimensional Inspection - Catheter Overall Effective Length	In tolerance (90% Confidence, 90% Reliability)	PASS
Dimensional Inspection - Knob Height	In tolerance (90% Confidence, 90% Reliability)	PASS
Handle Assembly Burst	Burst Pressure ≥ 12 atm (90% Confidence, 90% Reliability)	PASS
Handle Assembly Fatigue	≥ 10 Inflation/Deflation Cycles to RBP (95% Confidence, 90% Reliability)	PASS
Handle Assembly Leakage	No Leakage	PASS
Balloon Inflation and Deflation Time	90% Confidence, 90% Reliability; No leakage during inflation; Inflation Time: ≤ 14.0 sec, Deflation Time: ≤ 30.6 sec	PASS
Tensile Strength - Distal Balloon to Inner Shaft (Peel)	90% Confidence, 90% Reliability; Force at Break ≥ 10N	PASS
Tensile Strength - Distal Balloon to Inner Shaft (Shear)	90% Confidence, 95% Reliability; Force at Break ≥ 10N	PASS
Tensile Strength - Outer Shaft to T Connector	90% Confidence, 95% Reliability; Force at Break ≥ 10N	PASS
Tensile Strength - Inflation Tube to T Connector	90% Confidence, 90% Reliability; Force at Break ≥ 15N	PASS
Tensile Strength – Inflation Tube to Inflation Luer	90% Confidence, 90% Reliability; Force at Break ≥ 15N	PASS
Tensile Strength - Cylinder to T Connector	90% Confidence, 90% Reliability; Force at Break ≥ 15N	PASS
Tensile Strength - Inner Shaft to Pulling Rod	90% Confidence, 90% Reliability; Force at Break ≥ 10N	PASS
Tensile Strength - Pulling Rod to Proximal Luer	90% Confidence, 95% Reliability; Force at Break ≥ 15N	PASS
Tensile Strength - Pulling Rod to Knob Base	90% Confidence, 90% Reliability; Force at Break ≥ 15N	PASS
Tensile Strength - Distal Cap to Shells	90% Confidence, 90% Reliability; Force at Break ≥ 15N	PASS
Tensile Strength - Proximal Cap to Shells	90% Confidence, 90% Reliability; Force at Break ≥ 15N	PASS
Tensile Strength - Knob Base to Knob Cover	Force at Break ≥ 15N (90% Confidence, 90% Reliability)	PASS
Corrosion Resistance	No signs of corrosion after treatment	PASS
Stroke Length	Minimum Stroke Length: ≥ 70% of the associated Balloon Working Length; Maximum Stroke Length: Balloon can be deflated after reaching stroke limit.	PASS
Simulated Use in Tortuous Anatomy Model - guidewire compatibility	90% Confidence / 90% Reliability; Catheter can be mounted over a .035” guidewire	PASS
Simulated Use in Tortuous Anatomy Model - Advance/Retract/Deploy/Fold Balloon/Withdraw after Procedure	90% Confidence, 90% Reliability; Completely folded balloon passes through identified Introducer Sheath at the end of procedure.	PASS
Simulated Use in Tortuous Anatomy Model - Kink Resistance	90% Confidence, 90% Reliability; No permanent deformations (kinks) are present once removed from the tortuous anatomy model.	PASS
Flow Characteristics	90% Confidence, 90% Reliability; Distal flow observed in uninflated and deflated state, occlusion of distal flow in inflated state (straight and bend configurations)	PASS
Labeling Validation	90% Confidence, 90% Reliability; Instructions for performing type 1 and type 2 recovery methods can be performed successfully per instructions.	PASS
Packaging Validation - Pouch Label Visual Inspection	Label is securely attached to the pouch surface. Across entire label, details/print is legible and free of smudging or creasing (90% Confidence, 90% Reliability)	PASS
Packaging Validation - Pouch Seal Visual Inspection	Pouch Seals at locations A, B, and C are visibly free of wrinkles, channels, visible bubbles, foreign material, transparent areas, and non-uniform seal width. (90% Confidence, 90% Reliability)	PASS
Packaging Validation - Bubble Leak Testing	No leaks are observed from seals or surface of the pouch. (90% Confidence, 90% Reliability)	PASS
Packaging Validation - Seal Strength Testing	Contract Manufacturer and Supplier Seal: Peel Force ≥ 5.0N (90% Confidence, 90% Reliability)	PASS
Pyrogenicity (LAL Test)	Must meet spec of 0.5 EU/ml for general blood contacting medical devices	Met (successful completion)
EtO Residuals	Within the ISO 10993-7 standard specification	Met
Sterility Assurance Level (SAL)	1x10^-6	Met
Shelf Life (Device Function and Performance)	All functional and performance specifications met after sterilization and accelerated aging (3-year shelf life)	Met

Study Details for PROTEUS™ PTA Catheter

Based on the provided K120164 510(k) summary, the "study" refers to a series of non-clinical bench tests for design verification and validation, as well as tests for biocompatibility, sterilization, packaging, pyrogenicity, and shelf life. This is a 510(k) submission, which typically relies on demonstrating substantial equivalence to a legally marketed predicate device rather than conducting new clinical trials for effectiveness.

Sample size used for the test set and the data provenance (e.g. country of origin of the data, retrospective or prospective):
- Sample Size: The sample sizes for Design Verification and Validation testing "were based on required confidence/reliability levels as a result of risk analysis performed for the PROTEUS™ PTA Balloon Catheter, or per recommendations within the FDA Guidance 'Non-Clinical Tests and Recommended Labeling for Intravascular Stents and Associated Delivery Systems.'" Specifically, the number of samples utilized varied depending on whether the data was variable or attribute.
  - For the "four corners" approach, at least four sizes (largest/smallest diameters and lengths) plus a middle catheter size were tested for robustness.
  - Many tests specify a confidence/reliability level (e.g., 90% Conf., 90% Rel. or 95% Conf., 90% Rel.), which dictates the minimum sample size for attribute or variable data.
- Data Provenance: The tests were "in vitro bench testing" conducted by Angioslide, Ltd., an Israeli company. The data is prospective, generated specifically for this submission. The origin of the data itself is from laboratory bench tests.
Number of experts used to establish the ground truth for the test set and the qualifications of those experts:
- This document describes bench testing of a medical device's physical and functional characteristics, not an AI or diagnostic device that requires expert ground truth. Therefore, no experts (e.g., radiologists) were used to establish ground truth in the traditional sense of medical image interpretation or diagnosis. The "ground truth" for these tests are the pre-defined engineering specifications and performance standards outlined in the acceptance criteria.
Adjudication method (e.g. 2+1, 3+1, none) for the test set:
- Not applicable. This is not a study requiring adjudication of clinical or image-based findings. The results of the bench tests (e.g., whether a dimension is "in tolerance" or if "no leakage" is observed) are direct physical measurements and observations against pre-defined criteria.
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. This is a medical device (PTA Catheter) and not an AI or diagnostic imaging device. Therefore, no MRMC study, human readers, or AI assistance was involved.
If a standalone (i.e. algorithm only without human-in-the loop performance) was done:
- Not applicable. This is a physical medical device, not an algorithm or AI system.
The type of ground truth used (expert consensus, pathology, outcomes data, etc.):
- For the bench tests, the "ground truth" is defined by engineering specifications, regulatory standards (e.g., ISO, FDA guidance documents), and internal design requirements. For example, "In Tolerance" for a dimension, "No Leakage" for a seal, "Force at Break ≥ 10N" for tensile strength. For pyrogenicity, it's a specific endotoxin limit (0.5 EU/ml).
The sample size for the training set:
- Not applicable. This is not an AI or machine learning device that requires a training set. The "training" for this device would be its manufacturing process and design iterations, not data sets for an algorithm.
How the ground truth for the training set was established:
- Not applicable, as there is no training set mentioned or implied for this type of device.

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K Number

K120805

Device Name

PROTEUS PTA BALLOON CATHETER WITH EMBOLIC CAPTURE FEATURE

Manufacturer

ANGIOSLIDE, LTD

Date Cleared

2012-04-13

(28 days)

Product Code

Regulation Number

Type

Panel

Reference & Predicate Devices

K111750,K093720

Predicate For

K133043

Intended Use

The Angioslide PROTEUS™ Percutaneous Transluminal Angioplasty (PTA) Balloon Catheter with Embolic Capture Feature is indicated for peripheral transluminal angroplasty and for capture and containment of embolic material during angioplasty, for the femoral, iliac, ilio-femoral, popliteal, tibial, peroneal, and profunda arteries.

The Angioslide PROTEUS™ PTA Balloon Catheter with Embolic Capture is not intended for use in the renal, cerebral, coronary or carotid vasculature.

Device Description

The Angioslide PROTEUS™ Percutaneous Transluminal Angioplasty (PTA) Balloon Catheter with Embolic Capture Feature is an over the wire dual lumen catheter with a foldable balloon (5) located near the distal atraumatic soft tip (9).

AI/ML Overview

Acceptance Criteria and Device Performance for PROTEUS™ PTA Catheter with Embolic Capture Feature

This submission describes the non-clinical testing performed to demonstrate the substantial equivalence of the modified PROTEUS™ PTA Catheter with Embolic Capture Feature. The testing followed Angioslide's Risk Analysis, applicable FDA Guidance documents, and ISO standards.

1. Table of Acceptance Criteria and Reported Device Performance

Test	Acceptance Criteria	Reported Device Performance
Visual inspection - external surface	External surface of catheter effective length, including the distal end, is free from extraneous matter and surface defects (<0.2mm² TAPPI). 90% Confidence, 90% Reliability	PASS
Visual inspection - distal tip	Distal tip is smooth, rounded, tapered, or similarly finished. 90% Confidence, 90% Reliability	PASS
Distal Bond Outer Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Distal Balloon Cone to Distal Tip	In Tolerance. 90% Confidence, 90% Reliability	PASS
Distal Tip to Proximal Outer Tube Tip Length	In Tolerance. 90% Confidence, 90% Reliability	PASS
Soft Tip Length	In Tolerance. 90% Confidence, 90% Reliability	PASS
Wrapped Balloon Outer Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Guide Wire Lumen Inner Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Proximal Bond Outer Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Marker Band Spacing	In Tolerance. 90% Confidence, 90% Reliability	PASS
Balloon Working Length	In Tolerance. 90% Confidence, 90% Reliability	PASS
Balloon Outer Diameter	In Tolerance. 90% Confidence, 90% Reliability	PASS
Catheter Overall Effective Length	In Tolerance. 90% Confidence, 90% Reliability	PASS
Catheter Overall Length	In Tolerance. 90% Confidence, 90% Reliability	PASS
Minimum Balloon Burst Pressure (RBP)	RBP ≥ 14atm. 95% Confidence, 99.9% Reliability	PASS
Balloon Fatigue (Repeated Inflation/Deflations)	Inflation/Deflation Cycles ≥ 10 at 14atm (for 3x100). No leakage, rupture, and/or herniation up to max 40 cycles. 95% Confidence, 90% Reliability	PASS
Tensile Strength- Distal Balloon to Inner Tube (Peel)	≥ 5N. 90% Confidence, 95% Reliability	PASS
Tensile Strength- Distal Balloon to Inner Tube (Shear)	≥ 5N. 90% Confidence, 95% Reliability	PASS
Tensile Strength- Proximal Balloon to Outer Tube	≥ 10N. 90% Confidence, 95% Reliability	PASS
Tensile Strength- Cylinder to T-Connector	≥ 15N. 90% Confidence, 90% Reliability	PASS
Tensile Strength- Inflation Tube to T-Connector	≥ 15N. 90% Confidence, 90% Reliability	PASS
Tensile Strength- Outer Tube to T-Connector	≥ 15N. 90% Confidence, 90% Reliability	PASS
Tensile Strength- Inner Shaft to Pulling Rod	≥ 10N. 90% Confidence, 95% Reliability	PASS
Tensile Strength- Pulling Rod to Proximal Luer	≥ 15N. 90% Confidence, 90% Reliability	PASS
Tensile Strength- Pulling Rod to Knob Base	≥ 15N. 90% Confidence, 90% Reliability	PASS
Tensile Strength- Cylinder to O-ring Cap	≥ 15N. 90% Confidence, 90% Reliability	PASS
Liquid Leakage	No leakage. 90% Confidence, 90% Reliability	PASS
Balloon Inflation/Deflation Testing	Inflation Time: ≤ 14.0s. Deflation Time: ≤ 30.6s. 90% Confidence, 90% Reliability	PASS
Balloon Compliance	Compliance: ≤ 13%. Nominal Pressure: 8atm. RBP: 14atm. 90% Confidence, 90% Reliability	PASS
Flow Characteristics- Straight Configuration	Distal flow observed in uninflated and deflated state, occlusion of distal flow in inflated state. 90% Confidence, 90% Reliability	PASS
Flow Characteristics- Extreme Angle Configuration	Distal flow observed in uninflated and deflated state, occlusion of distal flow in inflated state. 90% Confidence, 90% Reliability	PASS
Stroke Length	Minimum Stroke Length: ≥ 70% of the associated Balloon Working Length. Maximum Stroke Length: Balloon can be deflated after reaching stroke limit.	PASS
Simulated Use in Tortuous Anatomy Model - guide wire compatibility	90% Confidence / 90% Reliability. Catheter can be mounted over a 0.014" guide wire. 90% Confidence, 90% Reliability	PASS
Simulated Use in Tortuous Anatomy Model - Introducer Sheath Compatibility	90% Confidence, 90% Reliability. Completely folded balloon passes through identified Introducer Sheath at the end of procedure. 90% Confidence, 90% Reliability	PASS
Simulated Use in Tortuous Anatomy Model - Kink Resistance	90% Confidence, 90% Reliability. No permanent deformations (kinks) are present once removed from the tortuous anatomy model. 90% Confidence, 90% Reliability	PASS
Simulated Use in Tortuous Anatomy Model - Max Advancement Force	N/A - Characterization only	N/A
Simulated Use in Tortuous Anatomy Model - Max Collapse Force	N/A - Characterization only	N/A
Simulated Use in Tortuous Anatomy Model - Max Anatomy Retraction Force	N/A - Characterization only	N/A
Simulated Use in Tortuous Anatomy Model - Max Removal Retraction Force	N/A - Characterization only	N/A
Capture Efficiency Comparison	N/A - Characterization only	N/A

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

The sample sizes for testing varied depending on whether the data collected was variable or attribute data, which was determined by the risk analysis (DFMEA) performed for the PROTEUS™ PTA catheter and required confidence/reliability levels as per FDA Guidance "Non-Clinical Tests and Recommended Labeling for Intravascular Stents and Associated Delivery Systems." The documentation does not specify the exact number of units tested for each individual test but states that the number met the required statistical confidence and reliability levels.

The data provenance is from in vitro bench testing conducted by Angioslide, Ltd. and is thus not from a specific country of origin in a clinical context (e.g., patient data). It is prospective in the sense that the tests were designed and conducted specifically for this submission.

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

Not applicable. The tests described are non-clinical (bench testing) of the physical and mechanical properties of the device, not an evaluation requiring expert interpretation of clinical ground truth.

4. Adjudication Method for the Test Set

Not applicable. This was bench testing, not an evaluation relying on expert consensus for clinical interpretations. The results are objective measurements against defined criteria.

5. Multi-Reader Multi-Case (MRMC) Comparative Effectiveness Study

No, a multi-reader multi-case (MRMC) comparative effectiveness study was not conducted as this is a device performance evaluation (bench testing) and not an AI-based diagnostic device.

6. Standalone Performance Study

This document details standalone performance testing of the device itself (hardware), not an algorithm or AI without human interaction. The results demonstrate the device's ability to meet its specifications.

7. Type of Ground Truth Used

The "ground truth" for these tests was established by engineering specifications, regulatory standards (ISO), and defined acceptance criteria for the physical and mechanical properties of the device, such as dimensions, tensile strength, burst pressure, and flow characteristics.

8. Sample Size for the Training Set

Not applicable. This is a medical device (catheter) and not an AI/Machine Learning algorithm, therefore, there is no "training set."

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

Not applicable, as there is no training set for a physical medical device.

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