Management of Coarctation of The Aorta in Adult Patients: State of The Art

• 1. Resection with end-to-end anastomosis. The first surgical therapy documented for CoA was performed through a lateral thoracotomy and involved resection of the coarcted segment followed by a direct suture anastomosis of the transected ends. High re-CoA rates complicated this approach due to the circumferential suture lines particularly when performed in neonates.

• 2. Patch aortoplasty. To minimize the concerns of re-CoA, patch augmentation, initially with Dacron, was used where the aorta was incised longitudinally through the coarcted segment on the lateral wall of the aorta and a prosthetic patch is sutured across the incision which enlarges the vessel diameter. This technique initially resulted in less frequent re-CoA compared to the end-to-end repair but it fell out of avour when aneurysms formed in 20–40% of cases on the opposite wall of the patch augmentation. Changing the patch material to polytetrafluoroethylene (PTFE) reduced the aneurysm formation to about 7% but still demonstrated a 25% risk of re-CoA. Patch aortoplasty is still being used but only in the context of complex arch reconstruction.18)

• 3. Subclavian flap aortoplasty. In this technique the subclavian artery (SCA) is ligated close to the origin of the left vertebral artery. The flap is generated by an incision of the SCA that is extended down onto the aortic isthmus and across the coarcted segment. The re-CoA rate of this technique seems to be relatively low when performed in older children up to 3%. However, when applied to neonates, re-CoA may occur in up to 23%.19) Although sacrificing the SCA does not result in left arm ischemia, it may cause claudication of the affected arm in the long term.

• 4. Extended end-to-end anastomosis. In contrast to a direct end-to-end anastomosis, the proximal clamp is placed across the aortic arch including the SCA or even the left carotid artery including the aortic arch. Distally, the aorta is clamped below the coarcted segment. After ligation and division of the ductus arteriosus, the coarcted segment is resected and the aortic arch is opened on its inferior aspect, followed by end-to-end anastomosis of the opened arch and the descending aorta. The procedure can be performed with low peri-operative mortality and reports show relatively low re-CoA rates of 4% to 13%.20)

• 5. Interposition graft. This technique has been reserved for patients in whom outgrowth of the graft is not a concern, or in patients with long-segment CoA. After the aorta is cross-clamped and the obstructive tissue resected, a tube graft of either aortic homograft or Dacron is sewn into the aorta, creating an unobstructed path for blood. The main disadvantage of this technique is that it requires a longer cross-clamp time for two surgical anastomoses to be sewn, and the tube graft will not grow with the patient. Yet, for adult-sized patients presenting with long-segment CoA, this technique may be preferable at many centers.

Balloon angioplasty

Balloon angioplasty (BA) for CoA was first reported in 1982,24) with use having become widespread over the past two decades. The mechanism of BA involves controlled tearing of the intimal and medial walls of the aorta and there is concern that this damage to the aortic wall predisposes to later aneurysm formation especially when treating native CoA with this technique. A relatively high incidence of re-stenosis is also reported for BA alone.25) In order to overcome these concerns, stenting of CoA was introduced in 1991.26)

Stenting

Stenting is considered advantageous when compared to BA alone; it improves luminal diameter, results in minimal residual PPG, and sustained hemodynamic benefit. It also can tack intimal flaps to the aortic wall potentially allowing healing to occur this way reducing the risk of dissection and aneurysm formation. Furthermore, stent implantation does prevent vascular recoil resulting in re-CoA.27) Nowadays, BA with simultaneous stenting is considered to be the preferred treatment option for adolescent and adult patients with native or re-CoA. Stent implantation in young children remains controversial due to the need for frequent re-dilation to accommodate the growing aorta. In our practice, we consider stent placement only in patients who are large enough (usually over 15 kg in weight) to receive a stent that can be expanded to an adult size. However very few stents are expandable to the average diameter of a large adult aorta (21.1+3.2 mm for women, 26.1+4.3 mm for men).

Stent technology has evolved in recent years and there is now a wide variety of stents available to treat CoA which all vary in the degree of flexibility, profile, foreshortening on expansion, maximal expansion diameter, and radial strength. The choice of stent depends on the CoA anatomy, size of the patient, the preference of the operator and availability.

1) Stent types

The most commonly implanted type of stent, and the only one with Food and Drug Administration and CE mark approval for this use, is the Cheatham Platinum (CP) stent (NuMED Inc., Hopkinton, NY, USA). Other stent types are used off-label. They include Palmaz series (Johnson & Johnson Interventional Systems Co., Warren, NJ, USA), Genesis XD (Cordis Corp., Miami, FL, USA), Atrium Advanta V12 (Maquet, Rastatt, Germany), IntraStent (Medtronic, Minneapolis, MN, USA), Formula (Cook Medical, Bloomington, IN, USA), and AndraStent (Andramed GmbH, Reutlingen, Germany). In small children and in bail-out situations, coronary stents have been used as well, because of the small diameter of the aorta. Stents vary both in material and architecture. There are 3 commonly used designs, namely closed-cell, open-cell, and a hybrid design. In closed-cell design all internal inflection points of the structural components are connected (fixed points), thereby creating small closed cells. Therefore, it is less flexible and conformable compared with stents with an open-cell design. In the open-cell designs some of the internal inflection points of the structural components are not connected. The absence of connections allows more longitudinal flexibility of the cells preferred for treatment of transverse aortic arch narrowing, because they adapt better to the arch shape. Furthermore, separate BA through the cell into the aortic branches can be performed when using an open-cell design. Stents with hybrid design, closed-cell and open-cell designs are combined. Another architectural difference is the use of single wires welded together (for instance in the case of the CP stent) versus a single tube that is slotted without junctions between components. Welds represent weak points in the structure of the stent; thus, in the newer CP stents, gold soldering was added to reinforce the welds. One of the other important differences between the stents is the metal made of, namely, stainless steel, platinum-iridium alloy, and chromium-cobalt alloy. The chromium-cobalt alloy is stronger than stainless steel. Stents can be bare or covered. The most commonly used material for the cover is PTFE, which makes the stent impermeable. Conventionally, covered stents were solely used to treat aortic wall complications. However, currently, covered stents are implanted as the primary treatment of CoA in patients at risk of complications. Risk factors for lesions to the aortic wall include narrow CoA, tortuous aorta, genetic aortic pathologies, and aneurysms/pseudoaneurysms derived from previous interventions. The characteristics of each type of stent are summarized in Table 1.

Table 1
Characteristics of the different types of stents

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2) Procedural steps

At our institution, we elected to perform all procedures that involve BA or stent implantation for CoA under general anesthesia. The procedure incites pain at the time of dilatation and this may result in patient movement which may compromise the success of the procedure. Trans-femoral artery (FA) approach is the standard access, if crossing of the CoA segment is impossible from the descending aorta, a secondary arterial access via the radial or brachial artery allows for an antegrade catheterization of the CoA. Subsequently, the wire has to be exteriorized through the FA sheath. Some operators may prefer the second access from a transseptal puncture. We also obtain venous access to perform full hemodynamic study and for the possibility of rapid right ventricular pacing during stent deployment. Intravenous heparin is administered achieving an activated clotting time (ACT) greater than 200 seconds. A straight-tip catheter (multipurpose) or a right judkins catheter is then advanced into the descending aorta followed by advancing a soft-tipped wire (e.g., Glide wire) through the CoA site. Once the catheter is advanced into the ascending aorta, it is replaced over the wire by a pigtail catheter or multitrack catheter followed by careful pullback to obtain PPG across the CoA. Biplane angiography is then performed using a calibrated pigtail catheter positioned just proximal to the CoA. Good angiographic visualization of the aortic arch in a lateral and shallow left or right anterior oblique projection view is essential. The angiogram needs to show the entire transverse aortic arch, including brachiocephalic vessel location, isthmus, CoA segment, and the aorta down to the level of the diaphragm. Following angiography, measurements are made at different points of the aorta in order to select the size of balloon or stent to be used. The decision on the maximal diameter of the balloon on which the stent is mounted is based on the diameter of the transverse or distal arch and isthmus with the diameter not exceeding the size of aorta at the level of the diaphragm. It is important to note that post-stenotic dilatation is common and this should not be used as reference for balloon size selection. A soft tipped wire is initially used to cross the CoA. Thereafter, it is exchanged for a stiffer wire (usually an Amplatz super or extra stiff exchange guidewire) which is secured in the ascending aorta or the right SCA. A long Mullins sheath (at least 75-cm) (Cook Medical) is advanced from the FA site and placed across the CoA segment for deployment of the stent. The stent is hand-crimped on the balloon catheter. We use an umbilical tape to finish crimping on to the balloon if available. A guidewire is inserted into the distal end of the balloon catheter while crimping the stent onto the balloon in order to avoid compromising the lumen of the catheter. Variety of balloons such as the BIB and Z-Med (NuMEM Corp., Hopkinton, NY, USA), and Cristal (Balt, Montmorency, France) balloons are used. The BIB balloon catheter is the most commonly used balloon in our practice. This balloon has an inner balloon and a 1-cm longer outer balloon which is double the diameter of the inner balloon. They are available in outer balloon diameters of 12 to 30 mm, requiring sheaths from 8 to 16 Fr. Because the inner balloon is usually shorter than the stent, the balloon expands the stent uniformly without flaring the ends of the stent, thus decreasing the risk of balloon perforation or wall injury. The expanded inner balloon provides a better anchoring mechanism, which results in more precise control during inflation of the outer balloon. As such it provides controlled stent expansion and the ability to adjust stent position following inner balloon expansion. The single large diameter balloon catheters can be used, but as these balloons first expand at the ends, they carry the risk of wall injury by the edges of the stent especially in small anatomy. The already mounted bare and mounted covered CP Stents are available. The stent is pre-mounted on a BIB balloon catheter. This already pre-mounted system will save time and reduces the risk of dislodgement. It is ready to be introduced through the delivery sheath over the stiff wire. Recently introduced is the NuDEL™ (NuMED Inc.) which is all-in-one stent delivery system designed for the efficient and effective treatment of CoA. It includes the covered CP stent, mounted on a BIB balloon catheter, which is then covered by a sheath (stent, balloon, sheath: all-in-one system). Pre-loaded system saves time and allows for quick actions in emergency situations.

The stent/balloon assembly is advanced through the Mullins sheath over the stiff wire and the stent is positioned across the CoA site before the sheath is withdrawn gently to uncover the stent/balloon completely. Prior to full uncovering, repeated injections can be made from the other access line or via the side-arm of the delivery sheath. Once position of the stent is confirmed to be at the right location, expansion of the stent follows. If the coarcted segment is very tight, no need for right ventricular pacing. However, if the CoA is mild or the segment is in the transverse arch, we recommend rapid RV pacing to ensure no stent movement. We usually like to see mean aortic pressure about 50 mmHg during pacing while expanding the stent. Pacing is turned off after the outer balloon is fully deflated. The various steps of CoA stenting are demonstrated in Figure 6.

Figure 6
Angiogram in the transverse arch in left anterior oblique 30° (A) and straight lateral 90° (B) in a 28 years female patient with severe coarctation of the aorta, with a gradient of 30 mmHg. (A) The coarctation ridge (arrow). (B) Ductal diverticulum (long arrow) and the coarctation juxta ductal (shorter arrow). Note, there is a pacing catheter in the right ventricle. (C, D) Angiogram via side arm of delivery sheath (covered stent [Bentley 14 mm×39 mm] is uncovered half way). (C) Origin of the left subclavian artery (long arrow) and proximal tip of the stent (short arrow). (E, F) Angiogram via side arm of sheath after uncovering the stent completely. Note, origin of the left subclavian artery (arrow). (G, H) Angiogram via pigtail catheter in transverse arch after complete stent deployment showing good position (arrows) and remodelling of the area of coarctation. Residual gradient was 0 mmHg.

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We advise against pre-stent BA unless the CoA is very tight to allow the delivery sheath passage as this approach is associated with more complications than primary direct stenting.28) If a BIB balloon catheter is used, the inner balloon is inflated first and the stent repositioned, if needed, before inflation of the outer diameter. Both balloons are then deflated and the balloon catheter is removed over the wire while keeping the sheath in position. Following stent deployment, another PPG across the CoA is documented with pullback or simultaneous pressure measurement using the catheter above the CoA and the sheath positioned below the CoA. A final angiogram is performed to assess the result and to look for any complication (aortic wall injury). Stent implantation is considered successful if a PPG <10 mmHg and improvement in vessel calibre >80% of the normal adjacent aortic arch is achieved.29) Post-dilatation of the stent with a larger balloon can be performed if CoA relief or stent apposition to the aortic wall is deemed suboptimal. However, we recommend against full expansion of the stent at the site of CoA. In adults with tight CoA, we are satisfied with a diameter of 12–14 mm at the site. Above and below can be gently expanded making sure not to expand the narrow area to that diameter. Some operators, specially using covered stents they try to achieve full expansion to the diameter of isthmus. At the end of the procedure we remove the sheath manually (ACT <160 seconds). A perclose proglide suture mediated closure system (Abbot Vascular, Abbott Park, IL, USA) has been used to close the access site. However, it needs to be inserted in the common FA prior to the introduction of the large sheath and the diameter of the vessel to be at least 5–6 mm.

Procedure related complications are not common, and these may include: vascular access related complications and aortic wall injury. Aortic dissection and aortic rupture may occur in 0.9% and 0.4%, respectively. Stent migration/embolization may occur in 2.4% of the cases. Occlusion of aortic side branches and stroke may occur, and death is uncommon (0.4%).30)

Patients are usually discharged home next day on aspirin 81 mg daily and are instructed to avoid contact sports for 6 months. A chest radiograph, ECG, TTE are obtained prior to discharge.

Success

Since the first cases of CoA stenting were reported in the 1990s, the encouraging outcome of this procedure has been described in considerable numbers of individual series reporting both short-term and intermediate-term results.31), 32), 33), 34) In 2007, a large multi-center retrospective series was reported by the Congenital Cardiovascular Interventional Study Consortium (CCISC) on 565 procedures of stent implantation performed in 555 patients with CoA between 1989 and 2005.28) The success rate of reducing PPG to less than 20 mmHg was 98%. There was a mean±standard deviation (SD) reduction of the PPG from 31.6±16 to 2.7±4.2 mmHg and an increase in diameter from 7.4±3.0 to 14.3±3.2 mm. These results showed high degree of success rates which were similar to those reported in other smaller series.31), 32), 33), 34) These series and the CCISC in a follow-up study reported that the relief of the PPG persisted in the majority of patients at medium-term follow-up.31) Recently, Hartman et al.30) reviewed reports published between 1990 and 2014 after stenting CoA involving 1,612 patients with some reports included in this review had long follow-up reaching up to 45 months.30) The CoA diameter increased from 6.43±0.86 mm to 15.1±0.6 mm, PPG deceased from 38.58±3.66 mmHg to 3.93±1.3 mmHg, and systolic blood pressure from 153±9.3 mmHg to 132±10.8 mmHg. In another recent meta-analysis by Yang et al.35) for the reports published between 1991 and 2015 including 561 CoA patients after stenting. The procedures success rate was 98%, the CoA diameter increased from 5.1± 5.4 mm to 14.4±7.7 mm, PPG deceased from 47.4±13.4 mmHg to 3.6±3.6 mmHg (all CoA diameter and PPG values are presented as mean±SD.).

Long term complication

Recently, the results of the Coarctation of the Aorta Stent Trial (COAST) trial, a study that aimed to assess the safety and efficacy of CP stents in children and adults with native or re-CoA were published.36) During the two-year follow-up no deaths, serious adverse events or surgical interventions were reported. All patients experienced satisfactory post procedural results with low rates of complications including aneurysms (5.7%) and stent fracture (11% at 2 year) without loss of stent integrity, stent embolization, aortic wall injury, or re-obstruction. Re-interventions (8.7%) that occurred during the two-year follow-up period were for stent re-dilatation in order to account for the patients' somatic growth and address of aneurysms. Of note, there was evidence of fracture progression and additional reinterventions occurred after 2 years. In the review by Hartman et al.30) the rate of aneurysms was 1.5%, stent fracture 1.6%, and reintervention 11%. Relatively similar findings were obtained by Yang et al.35) in his meta-analysis.

Covered stent versus bare stent

It has been proposed that the use of covered stents reduces the risk of aneurysms, dissection, and rupture. The recently published, COAST II trial which is a multi-center, single arm trial using the covered CP stent for the treatment and/or prevention of acute wall injury (AWI) in native or re-CoA associated with one or more of the following: acute or chronic aortic wall injury, nearly atretic descending aorta to 3 mm or less in diameter, genetic syndromes associated with aortic wall weakening (e.g., Marfan syndrome, Turner syndrome, familial BAV with ascending aortic aneurysm), or advanced age (60 years or older). A total of 158 patients were involved. The PPG decreased from 27 mmHg to 4 mmHg. The overall success rate was 92%. There was no AWI, repeat intervention or death.37) However, in a randomized trial of 120 patients with severe native CoA, there was no difference in the rate of re-CoA and pseudoaneurysm formation after 31 months of follow-up between patients who underwent implantation using a bare metal stent and those with a covered stent and this result was similar to what previously has been published in case reports and small series.38) Nevertheless, covered stents offer the advantage of excluding any stretch-induced wall trauma from the endoluminal aspect of the aorta, particularly in the catastrophic event of aortic rupture as revealed by COAST II trial.

Surgery versus transcatheter intervention

Forbes et al.39) published the results of a multi-center observational study comparing the safety and efficacy of surgical repair (72 patients), stent (217 patients), and BA (67 patients) as treatment of native CoA acutely and at follow-up. All 3 treatment modalities showed significant improvement in systolic blood pressure and PPG. The rate of acute complications was lower after stent implantation compared to BA or surgery. However, planned re-intervention was more likely in the group of stented patients. Stent implantation and surgery achieved superior hemodynamic results than BA. This finding was relatively consistent with the previously reported results by Carr et al.40)

Hypertension

Chronic hypertension remains present in 35–68% of the patients with CoA, even in the presence of an anatomically satisfactory repair.41), 42), 43) Furthermore, exercise-induced hypertension occurs in over one-third of the normotensive patients.44) Prevalence of systemic hypertension is significantly lower in patients treated in the neonatal period or infancy and in patients who underwent CoA resection with end-to-end anastomosis.42) The exact pathophysiology of late-onset hypertension after CoA-repair remains to be elucidated. Reduced aortic compliance and an abnormal baroreceptor function may explain this.41) Hypertension is also associated with an abnormal geometry of the aortic arch.42) Mild residual morphological obstruction and a disturbed renin–angiotensin–aldosterone system appear to play no major role in late-onset hypertension.45) Post-treatment hypertension is a risk factor for premature death and requires aggressive treatment. Follow-up should include ambulatory 24 hours blood pressure measurement and exercise testing, as exercise-induced hypertension can predict future systemic hypertension.41)

Exercise/sports

Patients without residual obstruction who are normotensive at rest and with exercise can usually lead normally active lives without restriction, except for extensive static sports at a competition level. Patients with arterial hypertension, residual obstruction, or other complications should avoid heavy isometric exercises, in proportion to the severity of their problem.14), 15)

Pregnancy

After successful treatment of CoA, many women tolerate pregnancy without major problems. In particular, women with unrepaired CoA, but also those after repair with arterial hypertension, residual CoA, or aortic aneurysms have an increased risk of aortic rupture and rupture of a cerebral aneurysm during pregnancy and delivery. An excess of miscarriages and hypertensive disorders is reported.14), 15)