Implementing and conducting a robust and efficient in vitro test validation protocol for transcatheter heart valve devices is complex. This article proposes a method to reduce cost and to optimise the development cycle of these products.
Lack of dedicated guidanceTests and their limitations
| FIGURE 1: Example of a dual activation chamber duplicator and its measurement capabilities:9 3D velocity contours within the left atrium using multi-plane stereoscopic particle image velocimetry (PIV) (top left), 3D echocardiograpghy of a mitral valve prosthesis (top middle) and 2D velocity map within the left ventricle using PIV. |
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Guidance on how to assess the hydro-dynamic performance of heart valves under steady and pulsatile flow conditions is provided in ISO 5840 (Table I). Parameters such as pressure drop,5 effective orifice area, leakage rate, regurgitant volumes6,7 and velocity flow fields can be obtained using a dual chamber pulsatile tester with transparent anatomical models of ventricular and atrial chambers.8,9 Dual chamber pulse duplicators are particularly well suited to assess the hydrodynamic performance of aortic and mitral artificial heart valves because they offer the possibility of simulating ventricle and atrial muscle contractions and relaxation with independent hydraulic activation systems. For example, they allow the simulation of pulmonary hypertension and/or atrial fibrillation following mitral valve replacement, or the concomitant effect of aortic valve replacement with a low compliance aorta. Unlike single activation testers, comparative studies9 have shown that dual chamber pulse duplicator simulated volume and pressure waveforms, as well as pressure-volume loops, are found to be accurate and similar to in vivo physiological cardiac haemodynamic. As required in ISO 5840, particle image velocimetry can be conducted to characterise complex three-dimensional (3D) flow dynamics inside realistic aorta, left ventricle and atrium geometries of the dual chamber pulse duplicators (Figure 1).9 If not executed and controlled properly, hydro-dynamic heart valve test results may exhibit significant variability, which is not inherent to the samples, but to the test bench and/or test procedure themselves. False negative or false positive results could lead to costly research and development (R&D) design decisions.
| FIGURE 2: Cardiac cavities within a dual activation chamber duplicator. Left ventricle is in yellow and left atrium is in pale red. |
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Hydrodynamic heart valve test results are often affected by stent, leaflets and delivery systems interactions. Positioning errors, deployment accuracy, migration and conformability to the native valve with various heterogeneous shapes and degree of calcification and stenosis, can affect heart valve performance. For example, transcatheter valves with low outward radial force would not properly comply with a highly calcified noncircular annulus. This could induce detrimental paravalvular leaks. In this context, in vitro hydrodynamic tests must carefully consider the diseased native valve model that is used. Orifice shape, rigidity and the cross-sectional area used to support the native valve in the tester are therefore of major importance when testing transcatheter heart valves. To reduce the paravalvular leakage flow, stent oversizing is generally employed. Thus, valve oversizing has to be taken into consideration during assessment of valve hydrodynamic performance.
| TABLE I: Critical heart valves hydrodynamic tests outlined in ISO 5840: 2005, Cardiovascular Implants, Cardiac Valve Prostheses. | ||
| Static, pulsatile, durability testing equipment | ||
| Bench test | Description | Reference standard: ISO 5840 |
| Steady forward-flow testing | Measurement of the pressure difference and valve effective orifice area across the test valve and the standard nozzle over a flow range of 5 to 30 L/min in 5 L/min increments | Clause 7.2.3 + Annex L.2 |
| Steady back-flow leakage testing | Measurement of the static leakage across the closed test valve and the standard nozzle at five equidistant back pressures in the range of 40 to 200 mmHg | Clause 7.2.3 + Annex L.3 |
| Pulsatile-flow testing |
Measurement of the pressure difference and effective orifice area across the valve at four simulated cardiac outputs (2, 3.5, 5, 7 L/min) at a single simulated normal heart rate (70 cycles/min). Measurement of the regurgitant volumes and regurgitant fraction at three different mean back pressures (80, 120 and 160 mmHg), at three simulated heart rates (45, 70 and 120 cycles/min) at a normal cardiac output (5 L/min). Assessment of the flow fields (velocity and shear stress) in the immediate vicinity of the heart valve substitute using particle image velocimetry, laser doppler velocimetry or computational fluid dynamics |
Clause 7.2.3 + Annex L.4 |
| Valve durability testing |
Durability assessment of heart valves in blood analogue for 400 millions cycles (mechanical valve) or 200 millions cycles (biological valve). Test frequency may vary on system response (usually between 8 and15 Hz). Test performed at a target differential pressure consistent with normotensive conditions (> 100 mmHg in the aortic position) Durability shall be demonstrated based on measurement of pressure difference/regurgitant volume and by visual inspection at 5x magnification of cyclic loaded. |
Clause 7.2.4.2 + Annex M |
| FIGURE 3: Hysteresis curve of a NiTi stent during three successive radial compression/expansion using a radial expansion force gauge tester. |
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Durability testing is critical to assess the long-term performance of the device during prolonged physiological loading conditions. Dual designs as in trans-catheter heart valves systems add significant complexity to fatigue resistance studies because both the valve and stent components need to be tested. Standard valve fatigue testers must be fitted with a special chamber to host stented valves with high struts. Heart valve fatigue testers will only test valve leaflets opening or closing, leaflet sutures (commissures) and stent strut resistance in the axial direction for 200 million cycles.2 Test frequencies rarely exceed 15 Hz, and lead to prolonged test time that can last six months or more. Cyclic radial fatigue testing requires a different approach using accelerated conditions to simulate 10 years of a real-life metallic stent.3 If the natural frequency of the device permits it, the stent can be tested at approximately 50 Hz by avoiding detrimental resonance effect.10 Testers that eliminate dependence and rigorous control of tube compliance are preferred for fatigue studies. Online high-resolution optical inspections should be conducted periodically to detect early onset of failure and avoid prolonging studies unnecessarily. However, these two independent tests do not cover the effect of radial loading on leaflets and suture fatigue and integrity. High stress fields that are generated within the stent during accelerated fatigue testing can cause stent failure modes that may induce valve performance deficiency. Combining both tests would seem relevant to avoid critical and premature failure as a result of the dual effect of stent and valve interactions.
Mastering both stent and heart valve testing appears to be generally accessible to some companies with existing heart valve and interventional business. Yet, there are a significant number of companies that cannot claim this dual expertise and do not have the resource capabilities to test heart valve and stent device combinations. Investment limitations could force small companies to overlook testing strategy in their development plans. Prior successful experience with disassociated stent and catheter development programmes leads companies to undertake complete heart valve validation testing and undermines basic design performance studies. In turn, this risky choice brings significant complexity to companies’ overall development plans and leads to unnecessarily lengthy and costly validation programmes.
| TABLE II: Critical push, track, torque and miscellaneous tests outlined in ISO 25539-2:2008, Cardiovascular Implants, Endovascular Devices, Part 2, Vascular Stents; in CDRH guidance for industry and FDA staff: 2005, Nonclinical Tests and Recommended Labelling for Intravascular Stents and Associated Delivery Systems; in ASTM WK 14950, Working Group guide for endovascular devices. Trackability and pushability; in ASTM F2394: 2007, Standard guide for measuring securement of balloon-expandable vascular stent mounted on delivery system; in ASTM WK 6315, Working Group guide for assessing acute coating durability of polymer-coated drug-eluting vascular stents. | ||
| Interventional device testing equipment | ||
| Bench test | Description | Referenced standards |
| Trackability | Uses the proximal load cell to measure the force to advance the device through a tortuous anatomy with or without the aid of a guiding accessory such as a guidewire or guiding catheter | ISO 25539-2 (2008), Clause 8.5.1.12 CDRH guidance Stents (2005), Clause C.1 ASTM WK 14950 |
| Pushability | Uses the proximal and distal load cells to measure the amount of force the distal tip of the device experiences when a known force is being applied to the product on the proximal end. | ISO 25539-2 (2008), Clause 8.5.1.8 CDRH guidance Stents (2005), Clause C.1 ASTM WK 14950 |
| Dislodgment force | Uses the proximal load cell and the encoder to measure the force required to dislodge the premounted stent from the crimped position on the nonexpanded balloon and to completely separate the stent from the nonexpanded balloon during clinical use through a tortuous path | ISO 25539-2 (2008), Clauses 8.5.1.5, 8.5.2.9 CDRH guidance Stents (2005), Clause C.8 ASTM F2394 (2007) |
| Flexibility/kink | Uses the proximal load cell to measure the ability of the device to advance and withdraw, with no loss of function or damage to the tortuous anatomy, over a clinically relevant bend. The roller system and the camera allow the smallest radius of curvature that the stent can withstand without kinking to be determined | ISO 25539-2 (2008), Clauses 8.5.1.6, 8.5.3.6, 8.6.5.4 CDRH guidance Stents (2005), Clause B.15 |
| Torquability | Uses the proximal and distal torque sensors to measure the amount of torque transmitted through the device by rotating the device at a more proximal location and fixing the distal end while the device is outed through tortuous anatomy | ISO 25539-2 (2008), Clause 8.5.1.10 |
| Simulated use | Uses the roller system and the camera to qualitatively evaluate the performance of the device using a tortuous path that simulates the intended use conditions | ISO 25539-2 (2008), Clauses 8.5.1.9, 8.5.2.12, 8.5.3.7, 8.6.1.4, 8.6.2.8, 8.6.4.5, 8.6.5.7 |
| Torsional bond strength | Uses rotation motor and torque sensor to determine the rotation/ torque required to break joints and/or materials in the appropriate delivery system components, if appropriate for the intended clinical use; the results shall be evaluated in relation to the torque necessary to access the system (torquability) | ISO 25539-2 (2008), Clauses 8.5.1.11, 8.5.3.8 |
| Profile effect/flaring | Uses camera to determine the change in distance between the external diameter of the stent and the external diameter of the balloon while tracking through a tortuous path | ISO 25539-2 (2008) Clause 8.6.1.3 |
| Conformability to vessel wall | Uses camera to evaluate the ability of the device to contact adequately the vessel wall on deployment | ISO 25539-2 (2008) Clause 8.6.2.2 |
| Acute coating integrity | Uses roller system to perform a simulated use of the device (access, deployment, withdrawal). Cumulative particulates released from the stent(s), stent(s) coating and stent system(s) during the procedure are continuously monitored, counted and classified according to size ranges | ISO 25539-2 (2008) Clause 8.6.3.2 CDRH guidance Stents (2005) Clause B.13 ASTM WK 6315 |
References
1. M. Thompson et al., “Heart Valve Market PAVR Poised for Growth,” Medical Technology Market Intelligence, MEDTECH Insight, 11, 1 (2009).
2. ISO 5840: 2005, Cardiovascular Implants, Cardiac Valve Prostheses.
3. ISO 25539-2:2008, Cardiovascular Implants, Endovascular Devices, Part 2, Vascular Stents.
4. ISO 7198: 1998, Cardiovascular Implants, Tubular Vascular Prostheses.
5. V. Garitey et al., “Pressure Drop Measurements of Prosthetic Heart Valves Influence of the Test Chamber Size,” J. Clinical Engineering, 23, 6, 409-415 (1998).
6. F. Mouret et al., “In Vitro Measurements of the Regurgitation of Mechanical Mitral Heart Valve Prostheses in Case of Atrial Fibrillation,” J. Heart Valve Disease, 10, 2, 264–9 (2001).
7. F. Mouret et al., “Mitral Valve Prosthesis Regurgitation: Normal Conditions Versus Atrial Fibrillation,” Cardiovascular Engineering: An International Journal, 2, 4, 139–148 (2002).
8. F. Mouret et al., A New Dual Activation Simulator of the Left Heart which Reproduces Physiological and Pathological Conditions,” Medical and Biological Engineering and Computing, 38, 558–561 (2000).
9. D. Tanné et al., “Assessment of Left Heart and Pulmonary Circulation Flow Dynamics by a New Pulsed Mock Circulatory System,” Experiments in Fluids DOI 10.1007/s00348-009-0771-x (online publication - Springer) (2009). www.springerlink.com/content/100416/ [5]
10. J.M. Stankiewicz et al., “Fatigue-Crack Growth Properties of Thin-Walled Superelastic Austenitic Nitinol Tube for Endovascular Stents, J. Biomedical Material Research, Part A, 81, 3, 685–91 (2007).
Karim Mouneimné is Chief Business Development Officer, Vincent Garitey
is Chief Technical Officer, and David Tanné, PhD, is Test Engineer all at Protomed SA, Faculté de Médecine, Secteur Nord, 51 Blvd Dramard, F-13916 Marseille Cedex 20, France, tel. +33 486 686 810
e-mail: k.mouneimne@protomed.fr [6]
www.protomed.fr [7]