Intravascular Ultrasound for the Evaluation of Malperfusion Syndrome in the Setting of Acute Aortic Dissection

Not Applicable

• Conditions: Perfusion; Complications; Aortic Dissection
• Interventions: Device: Intravascular ultrasound 0.035 PV IVUS catheter (Volcano Therapeutics, Rancho Cordova, CA)

• Registration Number: NCT04907071
• Lead Sponsor: London Health Sciences Centre

Brief Summary

Aortic dissection is a life-threatening condition caused by a tear in the internal layer of major artery wall (aorta) that carries blood to all body organs, resulting in separation of the aortic wall layers (dissection). The dissected aorta compromises blood flow to any organ, and eventually leads to organ damage (Malperfusion Syndrome).

Our goal in this project is to use Intravascular Ultrasound (IVUS) to have real time assessment and confirm any evidence of malperfusion syndrome in the setting of aortic dissection after repairing the original aortic tear. IVUS is a small ultrasound (sound waves) wand that is attached to the top of a thin tube. This tube is inserted into the aorta from the groin. This device takes pictures of the aorta and its major branches, to identify problems with blood flow. Having this real-time and dynamic assessment will help to identify any malperfused organs before leaving the operating room and allow us to address the malperfusion syndrome as quickly as possible to limit complications. Without this technique, identifying the problem can take several days after surgery at which point there can be irreversible complications.

Detailed Description

Acute Type A Aortic Dissection

A Debakey acute type A aortic dissection (ATAAD) represents a lethal condition with a risk of mortality of 1% per hour and up to nearly 50% in first 48 hours if left untreated.1, 2 Traditional surgical teaching has always involved emergent repair of the proximal aortic with resection and replacement of the intima entry tear and aneurysmal tissue within the ascending aorta. This approach addresses obviates the risk of aortic rupture, proximal extension into the coronary arteries, cardiac tamponade and aortic valve insufficiency, all of which lead to mortality. However, as expertise in the field progress evidence is emerging that dealing with only the proximal extent of the dissection may still leave a significant portion of patients at risk for complications from an inability to identify and treat end-organ malperfusion.3 At Western University and London Health Sciences center our mortality rate for patients presenting the ATAAD has been reporter at 20.0%4, and is similar to that reported by the International Registry of Acute aortic Dissection (IRAD) database, with mortality rates between 16.2 and 27.4%.5,6

Malperfusion Syndrome and Aortic Rupture In the 2018 Circulation paper published by Yang et al. the University of Michigan group outline the treatment strategy for ATAAD.

In this study, all patients with an ATAAD presenting with malperfusion, but without signs of aortic rupture or cardiac tamponade, were treated first with endovascular revascularization followed by delayed open aortic repair.3 The authors report that in the second decade of their experience with this treatment model, the overall mortality dropped to 10.7%.3 When compared to our local data and that published by the IRAD group, it would appear that there are significant improvements that can be made for the treatment of these individuals. The authors report that roughly 1/3 of all patients presented with some form of malperfusion syndrome and that in this group, 87% of the deaths were attributed to organ failure from malperfusion even after fenestration and stenting. Conversely there was only a 4% risk of aortic rupture following fenestration and stenting prior to open surgical repair in this group.3 This would indicate that malperfusion is a significant cause of morbidity and mortality in these patients maybe even more so than the risk of aortic rupture in selective patients but in order to improve our outcomes, we need a better way to assess static and dynamic changes that cause malperfusion as early as possible.

Static and Dynamic Arterial Malperfusion

The concept of static and dynamic obstructions in regards to aortic blood flow, indicates the phenomenon where disruption of laminar flow due to interruption of the intimal layer in and aortic dissection, results in gradients between the true and false lumen which can shear a dissection flap over a branching vessel causing collapse of the true lumen (dynamic), or the development of thrombus within the false lumen resulting in obstruction of a branch vessel (static). Most emergent AAD repairs will involve a baseline CT scan of the chest, abdomen and pelvis, which may identify malperfusion of distal arteries shown by a lack of contrast opacification. However, this is done prior to surgical repair and not an accurate representation of perfusion after proximal surgical repair is completed. Frist of all, at the time of the initial CT scan the intimal tear is still present and flow may not be directed into the true lumen, patients blood pressures may not be controlled which can cause dynamic shifts in the intimal flap favouring either true or false lumen flow, and lastly multiple distal re-entry tears can form throughout the remaining aorta after surgical repair which also have the capability of altering arterial flow. Transesophageal echocardiogram is usually present at the time of open surgical repair, but it is limited to the ascending, arch and descending thoracic aorta and provides little information regarding flow to the visceral segments, kidneys and legs.

Intravascular Ultrasound (IVUS)

Intravascular Ultrasound (IVUS) has been used over the past several decades for the real-time assessment of vascular anatomy in a variety of clinical settings.7 Standard IVUS catheters typically use a 9-French delivery sheath and are run over a 0.035-inch guidewire. The device transducer emits and receives signals at varying frequencies to produce a 360̊ axial image. As surgeons are becoming more familiar with this technology and developing the skill set necessary to use the equipment, including the real-time acquisition and interpretation of images, it permits the full evaluation of the thoracoabdominal aorta including size, tortuosity, and calcification. In the setting of an AAD, IVUS can provide real-time data under physiologic conditions following open proximal repair to indicate the presence of distal re-entry tears, compression of the true lumen and malperfusion to aortic branches. It also, can be used intraoperatively to confirm resolution of malperfusion to the visceral segments and legs after proximal flow is reinsituted into the true lumen.

Study Rationale

As noted above, AAD is a lethal condition that every cardiovascular surgeon is faced with at some point in their career. Although the outcomes at LHSC have been historically very good and are on par with or better than the existing IRAD data, looking at other institutions who have more advanced approaches, there appears to be some room to improve our outcomes even further. We believe that emergent repair of the proximal extent of the AAD, which is the current standard at LHSC, results in stabilization of the aortic valve, protects coronary flow, relieves cardiac tamponade and reduces the risk of aortic rupture. However, this approach leaves patients at risk for distal malperfusion due to distal re-entry tears, patent false lumens and thrombus formation, creating both dynamic and static obstruction. Intraoperative IVUS evaluation would therefore allow for the assessment of distal perfusion immediately following proximal repair in order to identify malperfusion and adjust treatment accordingly to prevent damage from prolonged end-organ ischemia. The purpose of this study is to test the safety and efficacy of intraoperative IVUS immediately following open surgical repair.

Device Description

The study devices are intended to improve outcomes for patients presenting with malperfusion syndrome in the setting of ATAAD. Every subject in the cohort must be deemed treatable with an 8Fr IVUS from an anatomy and clinical safety perspective.

Intravascular ultrasound 0.035 PV catheter system

The investigational 0.035 PV IVUS catheter (Volcano Therapeutics, Rancho Cordova, CA) is an over the wire catheter-based ultrasound with an 8.2-French profile at the transducer end and 7.0-French shaft diameter. This is run through a 9-French place under surface ultrasound guidance in the common femoral artery. The working length of this catheter is 90 cm, with the ability to imaging a diameter up to 60 mm.7

Study Timeline

• Study First Submitted: 2021-05-25
• Study First Submitted QC: 2021-05-27
• Study First Posted: 2021-05-28
• Status Verified: 2022-02
• Last Update Submitted: 2022-02-13
• Study Start: 2022-03-01
• Last Update Posted: 2022-03-02
• Primary Completion: 2023-08-01
• Study Completion: 2023-08-01

Recruitment & Eligibility

• Status: UNKNOWN
• Sex: All
• Target Recruitment: 50

Inclusion Criteria

• Patients diagnosed with an AAD or acute on chronic aortic dissection, with a new diagnosis of malperfusion syndrome (Malperfusion Primary Cohort), by meeting both of the following criteria:

  • Imaging findings indicating reduced flow to the Celiac Trunk, Superior mesenteric artery, either renal artery or either iliac artery
  • Clinical stigmata of end organ ischemia (abdominal pain, distended abdomen, oliguria/anuria, reduced pulses, signs of limb ischemia) correlating with imaging findings

• OR

  o Laboratory findings suggestive of end organ ischemia (lactic acidosis, elevated LFTs, Elevated Creatinine, Rhabdomyolysis, Electrolyte abnormalities) correlating with imaging findings

• Patients diagnosed with an AAD undergoing surgical repair without evidence of malperfusion syndrome preoperatively, but who develop malperfusion syndrome due to dynamic flow changes after true lumen flow is reinstituted intraoperatively as indicated by new clinical signs or new laboratory results meeting the following criteria (Malperfusion Secondary Cohort):

  • New Clinical signs include: Loss of femoral pulses, distended abdomen, reduced urine output, dusky/cold extremities
  • New Laboratory results include: Rising lactate (>50% above baseline), Rising Creatinine, Metabolic Acidosis, Rising LFTs

• Patients diagnosed with an AAD undergoing surgical repair without evidence of malperfusion syndrome preoperatively and postoperatively (No Malperfusion Cohort).

Exclusion Criteria

• Subject has not been diagnosed with AAD, or acute on chronic aortic dissection
• Subject is not hemodynamically stable to undergo IVUS evaluation
• Subject has anatomy or pre-existing condition precluding safe use of IVUS evaluation
• Subject has a pre-existing condition that may explain evidence of malperfusion (i.e. Dialysis patient with severe renal stenosis).
• Subject or substitute decision maker has language barrier and no translator available at the time of obtaining informed consent to participate in the study.

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: SINGLE_GROUP

Arm && Interventions

Group	Intervention	Description
Malperfusion Primary Cohort	Intravascular ultrasound 0.035 PV IVUS catheter (Volcano Therapeutics, Rancho Cordova, CA)	Patients presenting to hospital with AAD meeting criteria for malperfusion syndrome preoperatively which includes both components: * Imaging findings indicating reduced flow to the Celiac Trunk, Superior mesenteric artery, either renal artery or either iliac artery * Clinical stigmata of end organ ischemia (abdominal pain, distended abdomen, oliguria/anuria, reduced pulses, signs of limb ischemia) OR Laboratory findings suggestive of end organ ischemia (lactic acidosis, elevated LFTs, Elevated Creatinine, Rhabdomyolysis, Electrolyte abnormalities)
No Malperfusion Cohort	Intravascular ultrasound 0.035 PV IVUS catheter (Volcano Therapeutics, Rancho Cordova, CA)	Patients presenting with AAD with no evidence of malperfusion syndrome preoperatively and postoperatively.
Malperfusion Secondary Cohort:	Intravascular ultrasound 0.035 PV IVUS catheter (Volcano Therapeutics, Rancho Cordova, CA)	Patients who develop new clinical signs or laboratory results indicating distal malperfusion after proximal repair of the AAD is complete and proximal blood flow is redirected into the true lumen. * New Clinical signs include: Loss of femoral pulses, distended abdomen, reduced urine output, dusky extremities * New Laboratory signs include: Rising lactate (\>50% above baseline), Rising Creatinine, Metabolic Acidosis, Rising LFTs

Primary Outcome Measures

Name	Time	Method
Primary Safety Endpoint	30 days	Composite of all-cause in hospital mortality, acute kidney injury requiring new dialysis, mesenteric ischemia requiring intervention and major vascular complications.
Primary Effectiveness Endpoint	30 days	Composite of all-cause in hospital mortality, acute kidney injury requiring dialysis, mesenteric ischemia requiring surgical resection and major vascular complications.

Secondary Outcome Measures

Name	Time	Method
Secondary Effectiveness Endpoint	30 days	Composite of length of ICU stay and length of hospitalization.