Endovascular management of ascending aortic pathology

3296
Ralf Kolvenbach

By Ralf Kolvenbach 

 

The incidence of thoracic aortic aneurysms is estimated to be as high as six cases per 100,000 person-years, and replacement of the ascending aorta accounts for the majority of cardiothoracic aortic procedures.  

Aneurysms and dissections of the ascending aorta are still mainly treated operatively with cardiopulmonary bypass. Ascending aortic aneurysms with normal sinuses and aortic annulus require only replacement of the ascending aorta from the sinotubular ridge to the origin of the innominate artery with a Dacron tube graft.

Due to the significant morbidity and mortality of these procedures high-risk patients are not considered for cardiac surgery. There are a number of anecdotal reports describing endovascular stent grafting of various pathologies including deployment of a fenestrated stent graft in a case of an ascending aortic rupture.

Endovascular treatment of the ascending aorta is particularly challenging because of the anatomical features of this aortic segment. Acute and chronic Type A dissections can be treated with a tubular endograft when the aortic valve and the coronary arteries are not involved. An analysis in our clinic of 30 consecutive patients admitted with ascending aortic pathology showed that in 75% ascending aneurysms had a conical shape without a proximal landing zone. Only in a few cases the ascending aorta had a tubular configuration with a long proximal landing zone of at least 2cm. This makes over-sizing and an optimal graft configuration particularly important. Only patients without connective tissue disorders, clinically relevant aortic incompetence, stenosis or concomitant coronary artery disease can be considered for an endovascular procedure.  


Material and methods

So far only patients with ascending aortic pathology who were considered unfit for open surgery were treated with an endograft. We also excluded patients with malperfusion or any preoperative unstable clinical condition after Type A dissection. Also excluded were patients with severe aortic valvular disease including aortic valvular incompetence as a consequence of an acute Type A dissection, coronary artery disease requiring surgery, and any kind of connective tissue disorder. Included in our ongoing study are patients with intramural hematoma, floating thrombus after chronic Type A dissection and penetrating aortic ulcers. Also included are aneurysm patients without aortic valve incompetence or significant dilatation of the aortic annulus requiring composite graft replacement of the aortic valve and the ascending aorta.

Patients with asymptomatic penetrating aortic ulcers (PAU) were initially managed conservatively. If symptoms did not resolve, or patients continued complaining about chest pain, endovascular exclusion was discussed with the patient.

Threshold for aneurysm patients is an aortic diameter of 6cm or larger and an adequate landing zone proximal to the coronary arteries.  Patients were excluded if they were good candidates for open surgery. In cases without a good landing zone an aortic banding procedure using a mini sternotomy was performed prior to stent graft deployment as originally described by the Zurich group of Lachat.

The length of the stent graft was depending on the length of the outer curve of the ascending aorta which was regularly longer than the distance determined by center line measurement.

All operations were performed under general anesthesia. In addition to our monitoring protocol for TEVAR transoesophageal ultrasound was performed to control cardiac and valvular function. Cardiac arrest was induced with adenosine administration when required. A temporary ventricular pacemaker was placed through the jugular vein.

After road map angiography selective coronary angiography was performed to outline the origin of the coronary arteries.

An ultra stiff guide wire (Lunderquist, Cook) was placed into the left ventricle after passage of the aortic valve with a vertebral catheter over a 0.035 guide wire. The endograft (Cook custom made ascending endograft) was carefully placed across the aortic valve into the left ventricle. The kind of graft used depended on the size required.

Tracking of the stiff wire all the time during the procedure was essential to avoid ventricular perforation. At the end of the procedure ventriculography was performed to rule out any damage to the left ventricle or the valve apparatus. In case of any ECG changes coronary angiography was added before removing the catheter and sheaths. Before discharge a contrast enhanced angio CT was performed as well as cardiac ultrasound examination.

Ascending aortic dilatation may be caused by intrinsic pathology of the aortic wall, or hemodynamic factors caused by a stenotic aortic valve: High velocity and turbulent flow downstream of the stenosis place mechanical stress on the aortic wall.

The thin wall of the ascending aorta does not permit aggressive over dilatation. The graft was deployed in most cases without any additional balloon dilatation. The walls of the aortic sinus (sinus of Valsalva) are considerably thinner than the wall of the aorta. Hooks or bear springs should therefore be deployed in a safe distance from the sinus and the origin of the coronary arteries to avoid erosion and perforation. One of our first patients suffered from a stroke postoperatively.

Calcifications and thrombus lining of the ascending aorta and aortic arch were the main parameters for increased stroke risk

Access can be a problem since in most aneurysm cases a 24F access sheath was required.  In two cases with sever calcification of the iliac vessels we had to use the left carotid artery as an access which proved to be uneventful. Alternatively using a small thoracotomy the endograft can be deployed through the apex of the heart.

There is so far only one dedicated graft for the ascending aorta (Cook). Since most aneurysms have conical shape a stent graft designed for Type a dissection cases is not necessarily suitable for aneurysm patients. So far the anchoring zone of a few millimeters only, requires fixation with hooks, significant over sizing and coil deployment into the sac of the aneurysm if necessary. Banding of the ascending aorta is an option to increase the landing zone in aneurysm patients with conical aneurysm morphology.

The aortic impulse which is directly proportional to the mean blood pressure, the cross sectional area of the aorta and the duration during systole varies inversely with the distance from the aortic valve. In stent grafting of the aortic arch and the descending aorta high aortic impulses can cause significant pulsate motion of the arch and inadvertent movement of the stent graft. In the future more active fixation with a stapler would probably permit safer deployment, less Type I leaks and better long term performance. Especially when treating more advanced stages of aortic pathology a valve bearing conduit with fenestrations for the coronary arteries will be necessary.

Before a routine use can be advocated outside of studies several issues must be addressed. There should be dedicated grafts for ascending aneurysms and for acute dissections like the one available so far. Precise deployment of the graft adjacent to the coronary arteries is essential in aneurysm patients. In most cases there is a landing zone of a few millimeters only, deployment too distal from the sinotubular junction results in kinking of the graft and subsequently a type I leak.

We can conclude that stent grafting of the ascending aorta is technically feasible but should be reserved to selected high risk patients only, preferably in centers where vascular specialists cooperate closely with interventional cardiologists. Cardiac surgery with cardiopulmonary bypass and if necessary deep hypothermia is still the gold standard when treating ascending aortic aneurysms  though still associated with significant morbidity and mortality. Stent graft exclusion of more advanced and complex ascending aortic aneurysms should be reserved for high risk patients only in centers with the necessary skills to perform transvalvular cardiac procedures. This may change in the future when more dedicated grafts become available. The future will and has to show valve bearing endovascular conduits which will permit minimal invasive treatment of most aortic aneurysms. The grafts available so far already permit emergency endovascular treatment of type A dissections. Yet in aneurysm patients compromises are still necessary.