Don’t abandon cerebral protection devices
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The largest randomized clinical trial to assess the safety and efficacy of cerebral embolic protection systems during transcatheter aortic valve replacement yielded puzzling and somewhat contradictory results, according to a report presented at the Transcatheter Cardiovascular Therapeutics annual meeting and published simultaneously in the Journal of the American College of Cardiology.

Virtually every device in this industry-sponsored study involving 363 elderly patients (mean age, 83.4 years) with severe aortic stenosis trapped particulate debris as intended, the mean volume of new lesions in the protected areas of the brain was reduced by 42%, and the number and volume of new lesions correlated with neurocognitive outcomes at 30 days.

However, the reduction in lesion volume did not achieve statistical significance, and the improvement in neurocognitive function also did not reach statistical significance.

In addition, “the sample size was clearly too low to assess clinical outcomes, and in retrospect, was also too low to evaluate follow-up MRI findings or neurocognitive outcomes.” Nevertheless, the trial “provides reassuring evidence of device safety,” said Samir R. Kapadia, MD, of the Cleveland Clinic (J Am Coll Cardiol. 2016 Nov 1. doi: 10.1016/j.jacc.2016.10.023).

In this prospective study, the investigators assessed patients at 17 medical centers in the United States and 2 in Germany. In addition to being elderly, the study patients were at high risk because of frequent comorbidities, including atrial fibrillation (31.7%) and prior stroke (5.8%).

Dr. Samir R. Kapadia
In all, 121 patients were randomly assigned to undergo TAVR with a cerebral embolic protective device and 119 to TAVR without a protective device. New brain lesions were then assessed via MRI at 2-7 days post procedure, and neurocognitive function was assessed at 30 days.

The remaining 123 patients underwent TAVR but not MRI in a safety arm of the trial.

The protection devices were placed “without safety concerns” in most patients. The rate of major adverse events with the device was 7.3%, markedly less than the 18.3% prespecified performance goal for this outcome. Total procedure time was lengthened by only 13 minutes when the device was used, and total fluoroscopy time was increased by only 3 minutes. These findings demonstrate the overall safety of using the device, Dr. Kapadia said.

Debris including thrombus with tissue elements, artery wall particles, calcifications, valve tissue, and foreign materials was retrieved from the filters in 99% of patients.

The mean volume of new cerebral lesions in areas of the brain protected by the device was reduced by 42%, compared with that in patients who underwent TAVR without the protection device. However, this reduction was not statistically significant, so the primary efficacy endpoint of the study was not met.

Similarly, neurocognitive testing at 30 days showed that the volume of new lesions correlated with poorer outcomes. However, the difference in neurocognitive function between the intervention group and the control group did not reach statistical significance.

Several limitations likely contributed to this lack of statistical significance, Dr. Kapadia said.

First, the 5-day “window” for MRI assessment was too long. Both the number and the volume of new lesions rapidly changed over time, which led to marked variance in MRI findings depending on when the images were taken.

In addition, only one TAVR device was available at the time the trial was designed, so the study wasn’t stratified by type of valve device. But several new devices became available during the study, and the study investigators were permitted to use any of them. Both pre- and postimplantation techniques differ among these TAVR devices, but these differences could not be accounted for, given the study design.

Also, certain risk factors for stroke, especially certain findings on baseline MRI, were not understood when the trial was designed, and those factors also were not accounted for, Dr. Kapadia said.

Claret Medical funded the study. Dr. Kapadia reported having no relevant financial disclosures; his associates reported numerous ties to industry sources. The meeting was sponsored by the Cardiovascular Research Foundation.

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From a logical standpoint, a device that collects cerebral embolic material in 99% of cases should prevent ischemic brain injury, yet the findings from this randomized trial don’t appear to support the routine use of such devices. But it would be inappropriate and unfair to close the book on cerebral protection after this chapter.

The authors acknowledge that an MRI “window” of 5 days creates too much heterogeneity in the data, that multiple TAVR devices requiring different implantation techniques further muddy the picture, and that in retrospect the sample size was inadequate and the study was underpowered. In addition, rigorous neurocognitive assessment can be challenging in elderly, recovering patients, and results can depend on the time of day and the patient’s alertness.

Despite the negative findings regarding both primary and secondary endpoints, the data do show the overall safety of embolic protection devices. We are dealing with a potential benefit that cannot be ignored as TAVR shifts to younger and lower-risk patients.
 

Azeem Latib, MD, is in the interventional cardiology unit at San Raffaele Scientific Institute in Milan. Matteo Pagnesi, MD, is in the interventional cardiology unit at EMO-GVM Centro Cuore Columbus in Milan. San Raffaele Scientific Institute has been involved in clinical studies of embolic protection devices made by Claret Medical, Innovative Cardiovascular Solutions, and Keystone Heart. Dr. Latib and Dr. Pagnesi reported having no other relevant financial disclosures. They made these remarks in an editorial accompanying Dr. Kapadia’s report (J Am Coll Cardiol. 2016 Nov 1. doi: 10.1016/j.jacc.2016.10.036).

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From a logical standpoint, a device that collects cerebral embolic material in 99% of cases should prevent ischemic brain injury, yet the findings from this randomized trial don’t appear to support the routine use of such devices. But it would be inappropriate and unfair to close the book on cerebral protection after this chapter.

The authors acknowledge that an MRI “window” of 5 days creates too much heterogeneity in the data, that multiple TAVR devices requiring different implantation techniques further muddy the picture, and that in retrospect the sample size was inadequate and the study was underpowered. In addition, rigorous neurocognitive assessment can be challenging in elderly, recovering patients, and results can depend on the time of day and the patient’s alertness.

Despite the negative findings regarding both primary and secondary endpoints, the data do show the overall safety of embolic protection devices. We are dealing with a potential benefit that cannot be ignored as TAVR shifts to younger and lower-risk patients.
 

Azeem Latib, MD, is in the interventional cardiology unit at San Raffaele Scientific Institute in Milan. Matteo Pagnesi, MD, is in the interventional cardiology unit at EMO-GVM Centro Cuore Columbus in Milan. San Raffaele Scientific Institute has been involved in clinical studies of embolic protection devices made by Claret Medical, Innovative Cardiovascular Solutions, and Keystone Heart. Dr. Latib and Dr. Pagnesi reported having no other relevant financial disclosures. They made these remarks in an editorial accompanying Dr. Kapadia’s report (J Am Coll Cardiol. 2016 Nov 1. doi: 10.1016/j.jacc.2016.10.036).

Body

 

From a logical standpoint, a device that collects cerebral embolic material in 99% of cases should prevent ischemic brain injury, yet the findings from this randomized trial don’t appear to support the routine use of such devices. But it would be inappropriate and unfair to close the book on cerebral protection after this chapter.

The authors acknowledge that an MRI “window” of 5 days creates too much heterogeneity in the data, that multiple TAVR devices requiring different implantation techniques further muddy the picture, and that in retrospect the sample size was inadequate and the study was underpowered. In addition, rigorous neurocognitive assessment can be challenging in elderly, recovering patients, and results can depend on the time of day and the patient’s alertness.

Despite the negative findings regarding both primary and secondary endpoints, the data do show the overall safety of embolic protection devices. We are dealing with a potential benefit that cannot be ignored as TAVR shifts to younger and lower-risk patients.
 

Azeem Latib, MD, is in the interventional cardiology unit at San Raffaele Scientific Institute in Milan. Matteo Pagnesi, MD, is in the interventional cardiology unit at EMO-GVM Centro Cuore Columbus in Milan. San Raffaele Scientific Institute has been involved in clinical studies of embolic protection devices made by Claret Medical, Innovative Cardiovascular Solutions, and Keystone Heart. Dr. Latib and Dr. Pagnesi reported having no other relevant financial disclosures. They made these remarks in an editorial accompanying Dr. Kapadia’s report (J Am Coll Cardiol. 2016 Nov 1. doi: 10.1016/j.jacc.2016.10.036).

Title
Don’t abandon cerebral protection devices
Don’t abandon cerebral protection devices

 

The largest randomized clinical trial to assess the safety and efficacy of cerebral embolic protection systems during transcatheter aortic valve replacement yielded puzzling and somewhat contradictory results, according to a report presented at the Transcatheter Cardiovascular Therapeutics annual meeting and published simultaneously in the Journal of the American College of Cardiology.

Virtually every device in this industry-sponsored study involving 363 elderly patients (mean age, 83.4 years) with severe aortic stenosis trapped particulate debris as intended, the mean volume of new lesions in the protected areas of the brain was reduced by 42%, and the number and volume of new lesions correlated with neurocognitive outcomes at 30 days.

However, the reduction in lesion volume did not achieve statistical significance, and the improvement in neurocognitive function also did not reach statistical significance.

In addition, “the sample size was clearly too low to assess clinical outcomes, and in retrospect, was also too low to evaluate follow-up MRI findings or neurocognitive outcomes.” Nevertheless, the trial “provides reassuring evidence of device safety,” said Samir R. Kapadia, MD, of the Cleveland Clinic (J Am Coll Cardiol. 2016 Nov 1. doi: 10.1016/j.jacc.2016.10.023).

In this prospective study, the investigators assessed patients at 17 medical centers in the United States and 2 in Germany. In addition to being elderly, the study patients were at high risk because of frequent comorbidities, including atrial fibrillation (31.7%) and prior stroke (5.8%).

Dr. Samir R. Kapadia
In all, 121 patients were randomly assigned to undergo TAVR with a cerebral embolic protective device and 119 to TAVR without a protective device. New brain lesions were then assessed via MRI at 2-7 days post procedure, and neurocognitive function was assessed at 30 days.

The remaining 123 patients underwent TAVR but not MRI in a safety arm of the trial.

The protection devices were placed “without safety concerns” in most patients. The rate of major adverse events with the device was 7.3%, markedly less than the 18.3% prespecified performance goal for this outcome. Total procedure time was lengthened by only 13 minutes when the device was used, and total fluoroscopy time was increased by only 3 minutes. These findings demonstrate the overall safety of using the device, Dr. Kapadia said.

Debris including thrombus with tissue elements, artery wall particles, calcifications, valve tissue, and foreign materials was retrieved from the filters in 99% of patients.

The mean volume of new cerebral lesions in areas of the brain protected by the device was reduced by 42%, compared with that in patients who underwent TAVR without the protection device. However, this reduction was not statistically significant, so the primary efficacy endpoint of the study was not met.

Similarly, neurocognitive testing at 30 days showed that the volume of new lesions correlated with poorer outcomes. However, the difference in neurocognitive function between the intervention group and the control group did not reach statistical significance.

Several limitations likely contributed to this lack of statistical significance, Dr. Kapadia said.

First, the 5-day “window” for MRI assessment was too long. Both the number and the volume of new lesions rapidly changed over time, which led to marked variance in MRI findings depending on when the images were taken.

In addition, only one TAVR device was available at the time the trial was designed, so the study wasn’t stratified by type of valve device. But several new devices became available during the study, and the study investigators were permitted to use any of them. Both pre- and postimplantation techniques differ among these TAVR devices, but these differences could not be accounted for, given the study design.

Also, certain risk factors for stroke, especially certain findings on baseline MRI, were not understood when the trial was designed, and those factors also were not accounted for, Dr. Kapadia said.

Claret Medical funded the study. Dr. Kapadia reported having no relevant financial disclosures; his associates reported numerous ties to industry sources. The meeting was sponsored by the Cardiovascular Research Foundation.

 

The largest randomized clinical trial to assess the safety and efficacy of cerebral embolic protection systems during transcatheter aortic valve replacement yielded puzzling and somewhat contradictory results, according to a report presented at the Transcatheter Cardiovascular Therapeutics annual meeting and published simultaneously in the Journal of the American College of Cardiology.

Virtually every device in this industry-sponsored study involving 363 elderly patients (mean age, 83.4 years) with severe aortic stenosis trapped particulate debris as intended, the mean volume of new lesions in the protected areas of the brain was reduced by 42%, and the number and volume of new lesions correlated with neurocognitive outcomes at 30 days.

However, the reduction in lesion volume did not achieve statistical significance, and the improvement in neurocognitive function also did not reach statistical significance.

In addition, “the sample size was clearly too low to assess clinical outcomes, and in retrospect, was also too low to evaluate follow-up MRI findings or neurocognitive outcomes.” Nevertheless, the trial “provides reassuring evidence of device safety,” said Samir R. Kapadia, MD, of the Cleveland Clinic (J Am Coll Cardiol. 2016 Nov 1. doi: 10.1016/j.jacc.2016.10.023).

In this prospective study, the investigators assessed patients at 17 medical centers in the United States and 2 in Germany. In addition to being elderly, the study patients were at high risk because of frequent comorbidities, including atrial fibrillation (31.7%) and prior stroke (5.8%).

Dr. Samir R. Kapadia
In all, 121 patients were randomly assigned to undergo TAVR with a cerebral embolic protective device and 119 to TAVR without a protective device. New brain lesions were then assessed via MRI at 2-7 days post procedure, and neurocognitive function was assessed at 30 days.

The remaining 123 patients underwent TAVR but not MRI in a safety arm of the trial.

The protection devices were placed “without safety concerns” in most patients. The rate of major adverse events with the device was 7.3%, markedly less than the 18.3% prespecified performance goal for this outcome. Total procedure time was lengthened by only 13 minutes when the device was used, and total fluoroscopy time was increased by only 3 minutes. These findings demonstrate the overall safety of using the device, Dr. Kapadia said.

Debris including thrombus with tissue elements, artery wall particles, calcifications, valve tissue, and foreign materials was retrieved from the filters in 99% of patients.

The mean volume of new cerebral lesions in areas of the brain protected by the device was reduced by 42%, compared with that in patients who underwent TAVR without the protection device. However, this reduction was not statistically significant, so the primary efficacy endpoint of the study was not met.

Similarly, neurocognitive testing at 30 days showed that the volume of new lesions correlated with poorer outcomes. However, the difference in neurocognitive function between the intervention group and the control group did not reach statistical significance.

Several limitations likely contributed to this lack of statistical significance, Dr. Kapadia said.

First, the 5-day “window” for MRI assessment was too long. Both the number and the volume of new lesions rapidly changed over time, which led to marked variance in MRI findings depending on when the images were taken.

In addition, only one TAVR device was available at the time the trial was designed, so the study wasn’t stratified by type of valve device. But several new devices became available during the study, and the study investigators were permitted to use any of them. Both pre- and postimplantation techniques differ among these TAVR devices, but these differences could not be accounted for, given the study design.

Also, certain risk factors for stroke, especially certain findings on baseline MRI, were not understood when the trial was designed, and those factors also were not accounted for, Dr. Kapadia said.

Claret Medical funded the study. Dr. Kapadia reported having no relevant financial disclosures; his associates reported numerous ties to industry sources. The meeting was sponsored by the Cardiovascular Research Foundation.

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Key clinical point: The largest randomized clinical trial to assess the safety and efficacy of cerebral embolic protection systems during TAVR yielded puzzling and contradictory results.

Major finding: Debris including thrombus with tissue elements, artery wall particles, calcifications, valve tissue, and foreign materials was retrieved from the cerebral protection filters in 99% of patients.

Data source: A prospective, international, randomized trial involving 363 elderly patients undergoing TAVR for severe aortic stenosis.

Disclosures: Claret Medical funded the study. Dr. Kapadia reported having no relevant financial disclosures; his associates reported numerous ties to industry sources.