- Thank you Mr. Chairman, good morning ladies and gentlemen. So that was a great setting of the stage for understanding that we need to prevent reinterventions of course. So we looked at the data from the DREAM trial. We're all aware that we can try
to predict secondary interventions using preoperative CT parameters of EVAR patients. This is from the EVAR one trial, from Thomas Wyss. We can look at the aortic neck, greater angulation and more calcification.
And the common iliac artery, thrombus or tortuosity, are all features that are associated with the likelihood of reinterventions. We also know that we can use postoperative CT scans to predict reinterventions. But, as a matter of fact, of course,
secondary sac growth is a reason for reintervention, so that is really too late to predict it. There are a lot of reinterventions. This is from our long term analysis from DREAM, and as you can see the freedom, survival freedom of reinterventions in the endovascular repair group
is around 62% at 12 years. So one in three patients do get confronted with some sort of reintervention. Now what can be predicted? We thought that the proximal neck reinterventions would possibly be predicted
by type 1a Endoleaks and migration and iliac thrombosis by configurational changes, stenosis and kinks. So the hypothesis was: The increase of the neck diameter predicts proximal type 1 Endoleak and migration, not farfetched.
And aneurysm shrinkage maybe predicts iliac limb occlusion. Now in the DREAM trial, we had a pretty solid follow-up and all patients had CT scans for the first 24 months, so the idea was really to use
those case record forms to try to predict the longer term reinterventions after four, five, six years. These are all the measurements that we had. For this little study, and it is preliminary analysis now,
but I will be presenting the maximal neck diameter at the proximal anastomosis. The aneurysm diameter, the sac diameter, and the length of the remaining sac after EVAR. Baseline characteristics. And these are the re-interventions.
For any indications, we had 143 secondary interventions. 99 of those were following EVAR in 54 patients. By further breaking it down, we found 18 reinterventions for proximal neck complications, and 19 reinterventions
for thrombo-occlusive limb complications. So those are the complications we are trying to predict. So when you put everything in a graph, like the graphs from the EVAR 1 trial, you get these curves,
and this is the neck diameter in patients without neck reintervention, zero, one month, six months, 12, 18, and 24 months. There's a general increase of the diameter that we know.
But notice it, there are a lot of patients that have an increase here, and never had any reintervention. We had a couple of reinterventions in the long run, and all of these spaces seem to be staying relatively stable,
so that's not helping much. This is the same information for the aortic length reinterventions. So statistical analysis of these amounts of data and longitudinal measures is not that easy. So here we are looking at
the neck diameters compared for all patients with 12 month full follow-up, 18 and 24. You see there's really nothing happening. The only thing is that we found the sac diameter after EVAR seems to be decreasing more for patients who have had reinterventions
at their iliac limbs for thrombo-occlusive disease. That is something we recognize from the literature, and especially from these stent grafts in the early 2000s. So conclusion, Mr. Chairman, ladies and gentlemen, CT changes in the first two months after EVAR
predict not a lot. Neck diameter was not predictive for neck-reinterventions. Sac diameter seems to be associated with iliac limb reinterventions, and aneurysm length was not predictive
of iliac limb reinterventions. Thank you very much.
- Thank you for introduction. Thanks to Frank Veith for the kind invitation to present here our really primarily single-center experience on this new technique. This is my disclosure. So what you really want
in the thromboembolic acute events is a quick flow restoration, avoid lytic therapies, and reduce the risk of bleeding. And this can be achieved by surgery. However, causal directed local thrombolysis
is much less invasive and also give us a panoramic view and topographic view that is very useful in these cases. But it takes time and is statistically implied
and increases risk of bleeding. So theoretically percutaneous thrombectomy can accomplish all these tasks including a shorter hospital stay. So among the percutaneous thrombectomy devices the Indigo System is based on a really simple
aspiration mechanism and it has shown high success in ischemic stroke. This is one of my first cases with the Indigo System using a 5 MAX needle intervention
adapted to this condition. And it's very easy to understand how is fast and effective this approach to treat intraprocedural distal embolization avoiding potential dramatic clinical consequences, especially in cases like this,
the only one foot vessel. This is also confirmed by this technical note published in 2015 from an Italian group. More recently, other papers came up. This, for example, tell us that
there has been 85% below-the-knee primary endpoint achievement and 54% in above-the-knee lesions. The TIMI score after VAT significantly higher for BTK lesions and for ATK lesions
a necessity of a concomitant endovascular therapy. And James Benenati has already told us the results of the PRISM trials. Looking into our case data very quickly and very superficially we can summarize that we had 78% full revascularization.
In 42% of cases, we did not perform any lytic therapy or very short lytic therapy within three hours. And in 36% a long lytic therapy was necessary, however within 24 hours. We had also 22% failure
with three surgery necessary and one amputation. I must say that among this group of patients, twenty patients, there were also patients like this with extended thrombosis from the groin to the ankle
and through an antegrade approach, that I strongly recommend whenever possible, we were able to lower the aspiration of the clots also in the vessel, in the tibial vessels, leaving only this region, thrombosis
needed for additional three hour infusion of TPA achieving at the end a beautiful result and the patient was discharged a day after. However not every case had similar brilliant result. This patient went to surgery and he went eventually to amputation.
Why this? And why VAT perform better in BTK than in ATK? Just hypotheses. For ATK we can have unknown underlying chronic pathology. And the mismatch between the vessel and the catheter can be a problem.
In BTK, the thrombus is usually soft and short because it is an acute iatrogenic event. Most importantly is the thrombotic load. If it is light, no short, no lytic or short lytic therapy is necessary. Say if heavy, a longer lytic therapy and a failure,
regardless of the location of the thrombosis, must be expected. So moving to the other topic, venous occlusive thrombosis. This is a paper from a German group. The most exciting, a high success rate
without any adjunctive therapy and nine vessels half of them prosthetic branch. The only caution is about the excessive blood loss as a main potential complication to be checked during and after the procedure. This is a case at my cath lab.
An acute aortic renal thrombosis after a open repair. We were able to find the proximate thrombosis in this flush occlusion to aspirate close to fix the distal stenosis
and the distal stenosis here and to obtain two-thirds of the kidney parenchyma on both sides. And this is another patient presenting with acute mesenteric ischemia from vein thrombosis.
This device can be used also transsympatically. We were able to aspirate thrombi but after initial improvement, the patient condition worsened overnight. And the CT scan showed us a re-thrombosis of the vein. Probably we need to learn more
in the management of these patients especially under the pharmacology point of view. And this is a rapid overview on our out-of-lower-limb case series. We had good results in reimplanted renal artery, renal artery, and the pulmonary artery as well.
But poor results in brachial artery, fistula, and superior mesenteric vein. So in conclusion, this technology is an option for quick thromboembolic treatment. It's very effective for BTK intraprocedural embolic events.
The main advantage is a speeding up the blood flow and reestablishing without prolonged thrombolysis or reducing the dosage of the thrombolysis. Completely cleaning up extensive thromobosed vessels is impossible without local lytic therapies. This must be said very clearly.
Indigo technology is promising and effective for treatment of acute renovisceral artery occlusion and sub massive pulmonary embolism. Thank you for your attention. I apologize for not being able to stay for the discussion
because I have a flight in a few hours. Thank you very much.
- Rifampin-soaked endografts for treating prosthetic graf y work? I have no conflicts of interest. Open surgery for mycotic aneurysms is not perfect. We know it's logical, but it has a morbidity mortality of at least 40% in the abdomen and higher in the chest.
Sick, old, infected patients do poorly with major open operations so endografts sound logical. However, the theoretical reasons not to use them is putting a prosthetic endograft in an infected aorta immediately gets infected. Not removing infected tissue creates
an abcess in the aorta outside the endgraft and of course you have to replace the aorta in aorto-enteric fistulas. So, case in point, saccular aneurysm treated with a TEVAR and two weeks later as fever and abdominal pain.
You start out like this, you put an EVAR inside you get an abcess. Ended up with an open ilio-celiac open thoraco with left heart bypass. Had to sew two arches together. But what about cases where you can't
or you shouldn't do open? For example, 44 year old IV drug user, recurrent staph aureus endocarditis, bacteremia, had a previous aorto-bifem which was occluded, iliac stents, many many laparotomies ending in short bowel syndrome and an ileostomy.
CT scan and a positive tag white cell scan shows this. It's two centimeters, it's okay, treat it with antibiotics. Unfortunately, 10 days later it looks like this, so open repair. So, we tried for hours to get into the abdomen. The abdomen was frozen and, ultimately,
we ended up going to endografts so I added rifampin to it, did an aorta union and a fem fem and it looked like this and I said well, we'll see what happens. She's going to die. Amazingly, at a year the sac had totally shrunk. I remind you she was on continuous treatment.
She had her heart replaced again for the second time and notice the difference between the stent at one year to the sac size. So adding rifampin to prosthetic Dacron was first described in the late 1980's and inhibits growth in vivo and in vitro.
So I used the same concentration of 60 milligrams per milliliter. That's three amps of 600, 30 CC's water injected into the sheath. We published this awhile back. You can go straight into the sheath in a Cook.
Looks like this, or you can pre deploy a bit of little Medtronic and sort of trickle it in with an angiocatheter. So the idea that endografts in infected aortas immediately become infected, make it worse. I don't think it's true.
It may be false. What about aorto-enteric fistulas? This person showed up 63 year old hemorrhagic shock, previous Dacron patch, angioplasty to the aorta a few years ago, aorto-duodenal fistula not subtle. Nice little Hiroshima sign
and occluded bilateral external iliac arteries. Her abdomen looked like this. Multiple abdominal hernias, bowel resections, and had a skin graft on the bowel. Clearly this was the option. I'm not going to tell you how I magically got in there
but let's just leave it at that I got an endograft in there, rifampin soaked, sealed the hole and then I put her on TPN. So the idea that you have to resect and bypass, I'll get back to her soon, I think it's false. You don't necessarily have to do it every time. What about aorto-esophageal hemorrhagic shock, hematemesis?
Notice the laryng and esophageus of the contrast, real deal fistula. Put some TEVARs in there, and the idea was to temporize and to do a definitive repair knowing that we wouldn't get away with it. On post update nine, we did a cervical esophagostomy
and diverted the esophagus with the idea that maybe he could heal for a little while. He went home, we were going to repair him later, but of course he came back with fever, malaise, and of course gas around the aneurysm and we ended up having to fix him open.
So the problem with aorto-enteric fistulas is when you put an endograft in them it's sort of like a little boomerang. You get to throw them out and it's nice and it sails around but in the end you have to catch it. So, in the long term the lady I showed you before,
a year and a half later she came back with a retroperitoneal abscess. However, she was in much better shape. She wasn't bleeding to death, she'd lost weight, she'd quit smoking. She got an ax-bi-fem, open resection,
gastrojejunostomy and she's at home. So, I think the idea's, I think it's false but maybe realistically what it is, is that eventually if you do aorto-enteric fistulas you're going to have to do something and maybe if you don't remove the infection
it may make it worse. So in conclusion, endografts for mycotic aneurysms, they do save lives. I think you should use them liberally for bad cases. It could be a bad patient, a bad aorta, or bad presentation. Treat it with antibiotics as long as possible
before you put the endograft in and here's the voodoo, 60 milligrams per mil of rifampin. Don't just put in there, put it in with some semblance of science behind it, put it on Dacron, it may even lead to complete resolution. And I've also added trans-lumbar thoracic pigtail drains
in patients that I literally cannot ever want to go back in. Put 'em in for ten days wash it out. TPN on aorto-enterics for a month, voodoo, I agree, and I use antibiotics for life. Have a good plan B because it may come back in two weeks or two years, deploy them low
or cut out the super renal fixations so you can take them out a little easier. Thank you.
- We are talking about the current management of bleeding hemodialysis fistulas. I have no relevant disclosures. And as we can see there with bleeding fistulas, they can occur, you can imagine that the patient is getting access three times a week so ulcerations can't develop
and if they are not checked, the scab falls out and you get subsequent bleeding that can be fatal and lead to some significant morbidity. So fatal vascular access hemorrhage. What are the causes? So number one is thinking about
the excessive anticoagulation during dialysis, specifically Heparin during the dialysis circuit as well as with cumin and Xarelto. Intentional patient manipulati we always think of that when they move,
the needles can come out and then you get subsequent bleeding. But more specifically for us, we look at more the compromising integrity of the vascular access. Looking at stenosis, thrombosis, ulceration and infection. Ellingson and others in 2012 looked at the experience
in the US specifically in Maryland. Between the years of 2000/2006, they had a total of sixteen hundred roughly dialysis death, due to fatal vascular access hemorrhage, which only accounted for about .4% of all HD or hemodialysis death but the majority did come
from AV grafts less so from central venous catheters. But interestingly that around 78% really had this hemorrhage at home so it wasn't really done or they had experienced this at the dialysis centers. At the New Zealand experience and Australia, they had over a 14 year period which
they reviewed their fatal vascular access hemorrhage and what was interesting to see that around four weeks there was an inciting infection preceding the actual event. That was more than half the patients there. There was some other patients who had decoags and revisional surgery prior to the inciting event.
So can the access be salvaged. Well, the first thing obviously is direct pressure. Try to avoid tourniquet specifically for the patients at home. If they are in the emergency department, there is obviously something that can be done.
Just to decrease the morbidity that might be associated with potential limb loss. Suture repairs is kind of the main stay when you have a patient in the emergency department. And then depending on that, you decide to go to the operating room.
Perera and others 2013 and this is an emergency department review and emergency medicine, they use cyanoacrylate to control the bleeding for very small ulcerations. They had around 10 patients and they said that they had pretty good results.
But they did not look at the long term patency of these fistulas or recurrence. An interesting way to kind of manage an ulcerated bleeding fistula is the Limberg skin flap by Pirozzi and others in 2013 where they used an adjacent skin flap, a rhomboid skin flap
and they would get that approximal distal vascular control, rotate the flap over the ulcerated lesion after excising and repairing the venotomy and doing the closure. This was limited to only ulcerations that were less than 20mm.
When you look at the results, they have around 25 AV fistulas, around 15 AV grafts. The majority of the patients were treated with percutaneous angioplasty at least within a week of surgery. Within a month, their primary patency was running 96% for those fistulas and around 80% for AV grafts.
If you look at the six months patency, 76% were still opened and the fistula group and around 40% in the AV grafts. But interesting, you would think that rotating an adjacent skin flap may lead to necrosis but they had very little necrosis
of those flaps. Inui and others at the UC San Diego looked at their experience at dialysis access hemorrhage, they had a total 26 patients, interesting the majority of those patients were AV grafts patients that had either bovine graft
or PTFE and then aneurysmal fistulas being the rest. 18 were actually seen in the ED with active bleeding and were suture control. A minor amount of patients that did require tourniquet for a shock. This is kind of the algorithm when they look at
how they approach it, you know, obviously secure your proximal di they would do a Duplex ultrasound in the OR to assess hat type of procedure
they were going to do. You know, there were inciting events were always infection so they were very concerned by that. And they would obviously excise out the skin lesion and if they needed interposition graft replacement they would use a Rifampin soak PTFE
as well as Acuseal for immediate cannulation. Irrigation of the infected site were also done and using an impregnated antibiotic Vitagel was also done for the PTFE grafts. They were really successful in salvaging these fistulas and grafts at 85% success rate with 19 interposition
a patency was around 14 months for these patients. At UCS, my kind of approach to dealing with these ulcerated fistulas. Specifically if they bleed is to use
the bovine carotid artery graft. There's a paper that'll be coming out next month in JVS, but we looked at just in general our experience with aneurysmal and primary fistula creation with an AV with the carotid graft and we tried to approach these with early access so imagine with
a bleeding patient, you try to avoid using catheter if possible and placing the Artegraft gives us an opportunity to do that and with our data, there was no significant difference in the patency between early access and the standardized view of ten days on the Artegraft.
Prevention of the Fatal Vascular Access Hemorrhages. Important physical exam on a routine basis by the dialysis centers is imperative. If there is any scabbing or frank infection they should notify the surgeon immediately. Button Hole technique should be abandoned
even though it might be easier for the patient and decreased pain, it does increase infection because of that tract The rope ladder technique is more preferred way to avoid this. In the KDOQI guidelines of how else can we prevent this,
well, we know that aneurysmal fistulas can ulcerate so we look for any skin that might be compromised, we look for any risk of rupture of these aneurysms which rarely occur but it still needs to taken care of. Pseudoaneurysms we look at the diameter if it's twice the area of the graft.
If there is any difficulty in achieving hemostasis and then any obviously spontaneous bleeding from the sites. And the endovascular approach would be to put a stent graft across the pseudoaneurysms. Shah and others in 2012 had 100% immediate technical success They were able to have immediate access to the fistula
but they did have around 18.5% failure rate due to infection and thrombosis. So in conclusion, bleeding to hemodialysis access is rarely fatal but there are various ways to salvage this and we tried to keep the access viable for these patients.
Prevention is vital and educating our patients and dialysis centers is key. Thank you.
- This is from some work in collaboration with my good friend, Mike Dake. And, a couple of years of experience at Stanford now. First described by Kazy? years ago. This technical note of using multiple main-body endographs in a sandwich formation.
Up at the top but, then yielding multiple branches to get out to the visceral vessels and leaving one branch for a bifurcated graft. We've sort of modified it a little bit and generally either use multiple
grafts in order to create a branch the celiac and SMA. Left the celiac sometimes for a chimney, but the strategy really has been in one of the limbs to share both renals and the limb that goes down to the legs. We noticed early on that this really was not for
non-operative candidates, only for urgent cases and we recognize that the visceral branches were the most important to be in their own limb. I'll just walk you through a case. 6.8 centimeter stent for foraco above
the prior opened repair. The plan drawn out here with multiple main bodies and a second main body inside in order to create the multiple branches. The first piece goes in. It's balloon molded at the level of pulmonary
vein with enough length so that the ipsalateral limb is right next to the celiac. And we then, from above get into that limb and down into the celiac vessel and extend with either a limb or a viabahn. Next, we deploy a second main body inside
of the gate, thus creating now another two limbs to work through. And then through that, extend in its own branch a limb to the SMA. This was an eight by 79 vbx. Then we've got a third limb to go through.
We put a cuff that measures about 14. This is the math so that the double renal snorkle plus the main body fills up this hole. Now, double sheath access from above, looking for both renals. Sheaths out into both renals with viabahns
inside of that. Deployment of the bottom device and then a final angiogram with a little bit of a gutter that we often see when we have any kind of parallel graft configuration. Here's the post-op CT scan wherein
that limb is the two shared renals with the leg. This is the one year post-op with no endo leaks, successful exclusion of this. Here's another example of one of an eight and a half centimeter stent three thorico similar strategy, already with an occluded
celiac. Makes it a little bit easier. One limb goes down to the superior mesenteric artery and then the other limb then is shared again bilateral renals in the lower main body. Notice in this configuration you can get all the way up to the top then by putting a thoracic component
inside of the bifurcated subabdominal component. There's the final CT scan for that. We've spent some time looking at the different combinations of how these things will fill up to minimize the gutters through some more work. In collaboration with some friends in Kampala.
So we've treated 21 patients over the last couple of years. 73 years of age, 48 percent female usual comorbid factors. Oh, I thought I had more data there to show you. O.K. I thought this was a four minute talk.
Look at that. I'm on time. Octopus endovascular strategy is a feasible off the shelf solution for high risk patients that can't undergo open repair. You know obviously, sort of in this forum and coming to this meeting we see what's
available outside of the U.S. and I certainly am awaiting clinical trial devices that will have purpose specific teacher bi-graphs. The end hospital morbidity has still been high, at four percent. The one year survival of 71 percent in this select
group of 21 patients is acceptable. Paraplegia is still an issue even when we stage them and in this strategy you can stage them by just doing the top part plus the viscerals first and leaving the renals for another day. And branch patency thus far has been
in the short term similar to the purpose specific graft as well as with the parallel graft data. Thank you.
- Thank you and thanks again Frank for the kind invitation to be here another year. So there's several anatomic considerations for complex aortic repair. I wanted to choose between fenestrations or branches,
both with regards to that phenotype and the mating stent and we'll go into those. There are limitations to total endovascular approaches such as visceral anatomy, severe angulations,
and renal issues, as well as shaggy aortas where endo solutions are less favorable. This paper out of the Mayo Clinic showing that about 20% of the cases of thoracodynia aneurysms
non-suitable due to renal issues alone, and if we look at the subset that are then suitable, the anatomy of the renal arteries in this case obviously differs so they might be more or less suitable for branches
versus fenestration and the aneurysm extent proximally impacts that renal angle. So when do we use branches and when do we use fenestrations? Well, overall, it seems to be, to most people,
that branches are easier to use. They're easier to orient. There's more room for error. There's much more branch overlap securing those mating stents. But a branch device does require
more aortic coverage than a fenestrated equivalent. So if we extrapolate that to juxtarenal or pararenal repair a branched device will allow for much more proximal coverage
than in a fenestrated device which has, in this series from Dr. Chuter's group, shows that there is significant incidence of lower extremity weakness if you use an all-branch approach. And this was, of course, not biased
due to Crawford extent because the graft always looks the same. So does a target vessel anatomy and branch phenotype matter in of itself? Well of course, as we've discussed, the different anatomic situations
impact which type of branch or fenestration you use. Again going back to Tim Chuter's paper, and Tim who only used branches for all of the anatomical situations, there was a significant incidence of renal branch occlusion
during follow up in these cases. And this has been reproduced. This is from the Munster group showing that tortuosity is a significant factor, a predictive factor, for renal branch occlusion
after branched endovascular repair, and then repeated from Mario Stella's group showing that upward-facing renal arteries have immediate technical problems when using branches, and if you have the combination of downward and then upward facing
the long term outcome is impaired if you use a branched approach. And we know for the renals that using a fenestrated phenotype seems to improve the outcomes, and this has been shown in multiple trials
where fenestrations for renals do better than branches. So then moving away from the phenotype to the mating stent. Does the type of mating stent matter? In branch repairs we looked at this
from these five major European centers in about 500 patients to see if the type of mating stent used for branch phenotype grafts mattered. It was very difficult to evaluate and you can see in this rather busy graph
that there was a combination used of self-expanding and balloon expandable covered stents in these situations. And in fact almost 2/3 of the patients had combinations in their grafts, so combining balloon expandable covered stents
with self expanding stents, and vice versa, making these analyses very very difficult. But what we could replicate, of course, was the earlier findings that the event rates with using branches for celiac and SMA were very low,
whereas they were significant for left renal arteries and if you saw the last session then in similar situations after open repair, although this includes not only occlusions but re-interventions of course.
And we know when we use fenestrations that where we have wall contact that using covered stents is generally better than using bare stents which we started out with but the type of covered stent
also seems to matter and this might be due to the stiffness of the stent or how far it protrudes into the target vessel. There is a multitude of new bridging stents available for BEVAR and FEVAR: Covera, Viabahn, VBX, and Bentley plus,
and they all seem to have better flexibility, better profile, and better radial force so they're easier to use, but there's no long-term data evaluating these devices. The technical success rate is already quite high for all of these.
So this is a summary. We've talked using branches versus fenestration and often a combination to design the device to the specific patient anatomy is the best. So in summary,
always use covered stents even when you do fenestrated grafts. At present, mix and match seems to be beneficial both with regards to the phenotype and the mating stent. Short term results seem to be good.
Technical results good and reproducible but long term results are lacking and there is very limited comparative data. Thank you. (audience applauding)
- So I'd like to thank Dr. Ascher, Dr. Sidawy, Dr. Veith, and the organizers for allowing us to present some data. We have no disclosures. The cephalic arch is defined as two centimeters from the confluence of the cephalic vein to either the auxiliary/subclavian vein. Stenosis in this area occurs about 39%
in brachiocephalic fistulas and about 2% in radiocephalic fistulas. Several pre-existing diseases can lead to the stenosis. High flows have been documented to lead to the stenosis. Acute angles. And also there is a valve within the area.
They're generally short, focal in nature, and they're associated with a high rate of thrombosis after intervention. They have been associated with turbulent flow. Associated with pre-existing thickening.
If you do anatomic analysis, about 20% of all the cephalic veins will have that. This tight anatomical angle linked to the muscle that surrounds it associated with this one particular peculiar valve, about three millimeters from the confluence.
And it's interesting, it's common in non-diabetics. Predictors if you are looking for it, other than ultrasound which may not find it, is calcium-phosphate product, platelet count that's high, and access flow.
If one looks at interventions that have commonly been reported, one will find that both angioplasty and stenting of this area has a relatively low primary patency with no really discrimination between using just the balloon or stent.
The cumulative patency is higher, but really again, deployment of an angioplasty balloon or deployment of a stent makes really no significant difference. This has been associated with residual stenosis
greater than 30% as one reason it fails, and also the presence of diabetes. And so there is this sort of conundrum where it's present in more non-diabetics, but yet diabetics have more of a problem. This has led to people looking to other alternatives,
including stent grafts. And in this particular paper, they did not look at primary stent grafting for a cephalic arch stenosis, but mainly treating the recurrent stenosis. And you can see clearly that the top line in the graph,
the stent graft has a superior outcome. And this is from their paper, showing as all good paper figures should show, a perfect outcome for the intervention. Another paper looked at a randomized trial in this area and also found that stent grafts,
at least in the short period of time, just given the numbers at risk in this study, which was out after months, also had a significant change in the patency. And in their own words, they changed their practice and now stent graft
rather than use either angioplasty or bare-metal stents. I will tell you that cutting balloons have been used. And I will tell you that drug-eluting balloons have been used. The data is too small and inconclusive to make a difference. We chose a different view.
We asked a simple question. Whether or not these stenoses could be best treated with angioplasty, bare-metal stenting, or two other adjuncts that are certainly related, which is either a transposition or a bypass.
And what we found is that the surgical results definitely give greater long-term patency and greater functional results. And you can see that whether you choose either a transposition or a bypass, you will get superior primary results.
And you will also get superior secondary results. And this is gladly also associated with less recurrent interventions in the ongoing period. So in conclusion, cephalic arch remains a significant cause of brachiocephalic AV malfunction.
Angioplasty, across the literature, has poor outcomes. Stent grafting offers the best outcomes rather than bare-metal stenting. We have insufficient data with other modalities, drug-eluting stents, drug-eluting balloons,
cutting balloons. In the correct patient, surgical options will offer superior long-term results and functional results. And thus, in the good, well-selected patient, surgical interventions should be considered
earlier in this treatment rather than moving ahead with angioplasty stent and then stent graft. Thank you so much.
- These are my disclosures, as it pertains to this talk. FEVAR has become increasingly common treatment for juxtarenal aneurysm in the United States since it's commercial release in 2012. Controversy remains, however, with regard to stenting the SMA when it is treated with a single-wide, 10 mm scallop in the device.
You see here, things can look very similar. You see SMA treated with an unstented scallop on the left and one treated with the stented SMA on the right. It has been previously reported by Jason Lee that shuttering can happen with single-wide scallops of the SMA and in their experience
the SMA shuttering happens to different degree in patients, but is there in approximately 50% of the patients. But in his experience, the learning curve suggests that it decreases over time. At UNC, we use a selective criteria for stenting in the SMA. We will do a balloon test in the SMA,
as you see in the indication, and if the graft is not moved, then our SMA scallop is appropriate in line. If we have one scallop and one renal stent, its a high likelihood that SMA scallop will shift and change over time. So all those patients get stented.
If there is presence of pre-existing visceral stenosis we will stent the SMA through that scallop and in all of our plans, we generally place a 2 mm buffer, between the bottom edge of the scallop and the SMA. We looked over our results and 61 Zenith fenestrated devices performed over a short period of time.
We looked at the follow-up out up to 240 days and 40 patients in this group had at least one single wide scallop, which represented 2/3 of the group. Our most common configuration as in most practices is too small renal fenestrations and one SMA scallop.
Technically, devices were implanted in all patients. There were 27 patients that had scallops that were unstented. And 13 of the patients received stented scallops. Hospital mortality was one out of 40, from a ruptured hepatic artery aneurysm post-op.
No patients had aneurysm-related mortality to the intended treated aneurysm. If you look at this group, complications happen in one of the patients with stented SMA from a dissection which was treated with a bare metal stent extension at the time
of the initial procedure. And in the unstented patients, we had one patient with post-op nausea, elevated velocities, found to have shuttering of the graft and underwent subsequent stenting. The second patient had elevated velocities
and 20-pound weight loss at a year after his treatment, but was otherwise asymptomatic. There is no significant difference between these two groups with respect to complication risk. Dr. Veith in the group asked me to talk about stenting choice
In general, we use the atrium stent and a self-expanding stent for extension when needed and a fenestrated component. But, we have no data on how we treat the scallops. Most of those in our group are treated with atrium. We do not use VBX in our fenestrated cases
due to some concern about the seal around the supported fenestration. So Tips, we generally calculate the distance to the first branch of the SMA if we're going to stent it. We need to know the SMA diameter, generally its origin where its the largest.
We need to position the imaging intensifier orthogonal position. And we placed the stent 5-6 mm into the aortic lumen. And subsequently flare it to a 10-12 mm balloon. Many times if its a longer stent than 22, we will extend that SMA stent with a self-expanding stent.
So in conclusion, selective stenting of visceral vessels in single wide scallops is safe in fenestrated cases during this short and midterm follow-up if patients are carefully monitored. Stenting all single wide scallops is not without risk and further validation is needed
with multi-institution trial and longer follow-up
- Thank you. Here are my disclosures. Our preferred method for zone one TAVR has evolved to a carotid/carotid transposition and left subclavian retro-sandwich. The technique begins with a low transverse collar incision. The incision is deepened through the platysma
and subplatysmal flaps are then elevated. The dissection is continued along the anterior border of the sternocleidomastoid entering the carotid sheath anteromedial to the jugular vein. The common carotid artery is exposed
and controlled with a vessel loop. (mumbling) The exposure's repeated for the left common carotid artery and extended as far proximal to the omohyoid muscle as possible. A retropharyngeal plane is created using blunt dissection
along the anterior border of the cervical vertebra. A tunneling clamp is then utilized to preserve the plane with umbilical tape. Additional vessel loops are placed in the distal and mid right common carotid artery and the patient is systemically anticoagulated.
The proximal and distal vessel loops are tightened and a transverse arteriotomy is created between the middle and distal vessel loops. A flexible shunt is inserted and initially secured with the proximal and middle vessel loops. (whistling)
It is then advanced beyond the proximal vessel loop and secured into that position. The left common carotid artery is then clamped proximally and distally, suture ligated, clipped and then transected. (mumbling)
The proximal end is then brought through the retropharyngeal tunnel. - [Surgeon] It's found to have (mumbles). - An end-to-side carotid anastomosis is then created between the proximal and middle vessel loops. If preferred the right carotid arteriotomy
can be made ovoid with scissors or a punch to provide a better shape match with the recipient vessel. The complete anastomosis is back-bled and carefully flushed out the distal right carotid arteriotomy.
Flow is then restored to the left carotid artery, I mean to the right carotid artery or to the left carotid artery by tightening the middle vessel loop and loosening the proximal vessel loop. The shunt can then be removed
and the right common carotid artery safely clamped distal to the transposition. The distal arteriotomy is then closed in standard fashion and flow is restored to the right common carotid artery. This technique avoids a prosthetic graft
and the retropharyngeal space while maintaining flow in at least one carotid system at all times. Once, and here's a view of the vessels, once hemostasis is assured the platysma is reapproximated with a running suture followed by a subcuticular stitch
for an excellent cosmetic result. Our preferred method for left subclavian preservation is the retro-sandwich technique which involves deploying an initial endograft just distal to the left subclavian followed by both proximal aortic extension
and a left subclavian covered stent in parallel fashion. We prefer this configuration because it provides a second source of cerebral blood flow independent of the innominate artery
and maintains ready access to the renovisceral vessels if further aortic intervention is required in the future. Thank you.
- [Presenter] Thank you very much, Mr. Chairman, and ladies and gentlemen, and Frank Veith for this opportunity. Before I start my talk, actually, I can better sit down, because Hans and I worked together. We studied in the same city, we finished our medical study there, we also specialized in surgery
in the same city, we worked together at the same University Hospital, so what should I tell you? Anyway, the question is sac enlargement always benign has been answered. Can we always detect an endoleak, that is nice. No, because there are those hidden type II's,
but as Hans mentioned, there's also a I a and b, position dependent, possible. Hidden type III, fabric porosity, combination of the above. Detection, ladies and gentlemen, is limited by the tools we have, and CTA, even in the delayed phase
and Duplex-scan with contrast might not always be good enough to detect these lesions, these endoleaks. This looks like a nice paper, and what we tried to do is to use contrast-enhanced agents in combination with MRI. And here you see the pictures. And on the top you see the CTA, with contrast,
and also in the delayed phase. And below, you see this weak albumin contrast agent in an MRI and shows clearly where the leak is present. So without this tool, we were never able to detect an endoleak with the usual agents. So, at this moment, we don't know always whether contrast
in the Aneurysm Sac is only due to a type II. I think this is an important message that Hans pushed upon it. Detection is limited by the tools we have, but the choice and the success of the treatment is dependent on the kind of endoleak, let that be clear.
So this paper has been mentioned and is using not these advanced tools. It is only using very simple methods, so are they really detecting type II endoleaks, all of them. No, of course not, because it's not the golden standard. So, nevertheless, it has been published in the JVS,
it's totally worthless, from a scientific point of view. Skip it, don't read it. The clinical revelance of the type II endoleak. It's low pressure, Hans pointed it out. It works, also in ruptured aneurysms, but you have to be sure that the type II is the only cause
of Aneurysm Sac Expansion. So, is unlimited Sac Expansion harmless. I agree with Hans that it is not directly life threatening, but it ultimately can lead to dislodgement and widening of the neck and this will lead to an increasing risk for morbidity and even mortality.
So, the treatment of persistent type II in combination with Sac Expansion, and we will hear more about this during the rest of the session, is Selective Coil-Embolisation being preferred for a durable solution. I'm not so much a fan of filling the Sac, because as was shown by Stephan Haulan, we live below the dikes
and if we fill below the dikes behind the dikes, it's not the solution to prevent rupture, you have to put something in front of the dike, a Coil-Embolisation. So classic catheterisation of the SMA or Hypogastric, Trans Caval approach is now also popular,
and access from the distal stent-graft landing zone is our current favorite situation. Shows you quickly a movie where we go between the two stent-grafts in the iliacs, enter the Sac, and do the coiling. So, prevention of the type II during EVAR
might be a next step. Coil embolisation during EVAR has been shown, has been published. EVAS, is a lot of talks about this during this Veith meeting and the follow-up will tell us what is best. In conclusions, the approach to sac enlargement
without evident endoleak. I think unlimited Sac expansion is not harmless, even quality of life is involved. What should your patient do with an 11-centimeter bilp in his belly. Meticulous investigation of the cause of the Aneurysm Sac
Expansion is mandatory to achieve a, between quote, durable treatment, because follow-up is crucial to make that final conclusion. And unfortunately, after treatment, surveillance remains necessary in 2017, at least. And this is Hans Brinker, who put his finger in the dike,
to save our country from a type II endoleak, and I thank you for your attention.
- Thank you very much, Frank, ladies and gentlemen. Thank you, Mr. Chairman. I have no disclosure. Standard carotid endarterectomy patch-plasty and eversion remain the gold standard of treatment of symptomatic and asymptomatic patient with significant stenosis. One important lesson we learn in the last 50 years
of trial and tribulation is the majority of perioperative and post-perioperative stroke are related to technical imperfection rather than clamping ischemia. And so the importance of the technical accuracy of doing the endarterectomy. In ideal world the endarterectomy shouldn't be (mumbling).
It should contain embolic material. Shouldn't be too thin. While this is feasible in the majority of the patient, we know that when in clinical practice some patient with long plaque or transmural lesion, or when we're operating a lesion post-radiation,
it could be very challenging. Carotid bypass, very popular in the '80s, has been advocated as an alternative of carotid endarterectomy, and it doesn't matter if you use a vein or a PTFE graft. The result are quite durable. (mumbling) showing this in 198 consecutive cases
that the patency, primary patency rate was 97.9% in 10 years, so is quite a durable procedure. Nowadays we are treating carotid lesion with stinting, and the stinting has been also advocated as a complementary treatment, but not for a bail out, but immediately after a completion study where it
was unsatisfactory. Gore hybrid graft has been introduced in the market five years ago, and it was the natural evolution of the vortec technique that (mumbling) published a few years before, and it's a technique of a non-suture anastomosis.
And this basically a heparin-bounded bypass with the Nitinol section then expand. At King's we are very busy at the center, but we did 40 bypass for bail out procedure. The technique with the Gore hybrid graft is quite stressful where the constrained natural stint is inserted
inside internal carotid artery. It's got the same size of a (mumbling) shunt, and then the plumbing line is pulled, and than anastomosis is done. The proximal anastomosis is performed in the usual fashion with six (mumbling), and the (mumbling) was reimplanted
selectively. This one is what look like in the real life the patient with the personal degradation, the carotid hybrid bypass inserted and the external carotid artery were implanted. Initially we very, very enthusiastic, so we did the first cases with excellent result.
In total since November 19, 2014 we perform 19 procedure. All the patient would follow up with duplex scan and the CT angiogram post operation. During the follow up four cases block. The last two were really the two very high degree stenosis. And the common denominator was that all the patients
stop one of the dual anti-platelet treatment. They were stenosis wise around 40%, but only 13% the significant one. This one is one of the patient that developed significant stenosis after two years, and you can see in the typical position at the end of the stint.
This one is another patient who develop a quite high stenosis at proximal end. Our patency rate is much lower than the one report by Rico. So in conclusion, ladies and gentlemen, the carotid endarterectomy remain still the gold standard,
and (mumbling) carotid is usually an afterthought. Carotid bypass is a durable procedure. It should be in the repertoire of every vascular surgeon undertaking carotid endarterectomy. Gore hybrid was a promising technology because unfortunate it's been just not produced by Gore anymore,
and unfortunately it carried quite high rate of restenosis that probably we should start to treat it in the future. Thank you very much for your attention.
- So, I'm going to probably echo many of the themes that Gary just touched upon here. These are my disclosures. So, if we look at the CHEST guidelines on who should get pharmacomechanical techniques, it is very very very sobering, and I apologize if the previous speakers have shown this slide,
but essentially, what's right now being disseminated to the American College of CHEST Physicians is that nobody should get catheter-directed thrombolysis, the concept of pharmacomechanical technique should really only reserved as a last-ditch effort if nothing else works, if you happen to have somebody
with extraordinary expertise in your institution, it could not be more of a damning recommendation for what I'm about to talk to you about for the next eight or nine minutes or so. So, then the question is, what is the rationale? What are we talking about here?
And again, I'm going to say that Gary and I, I think are sort of kindred spirits in recognizing that we really do need to mature this concept of the catheter-based technique for pulmonary embolism. So, I'm going to put out a hypothetical question, what if there was a single session/single device therapy
for acute PE, Gary showed one, that could avoid high dose lytics, avoid an overnight infusion, acutely on the table lower the PA pressure, acutely improve the function of the right ventricle, rapidly remove, you know, by angiography,
thrombus and clot from the pulmonary artery, and it was extremely safe, what if we had that? Would that change practice? And I would respectfully say, yes it would. And then what if this concept has already been realized, and we're actually using this across the world
for STEMI, for stroke, for acute DVT, and so why not acute pulmonary embolism? What is limiting our ability to perform single session, rapid thrombus removal and
patient stabilization on the table? Gary showed this slide, there's this whole litany of different devices, and I would argue none of them is exactly perfect yet, but I'm going to try and sort of walk you through what has been developed in an attempt
to reach the concept of single session therapy. When we talk about pharmacomechanical thrombectomy or thrombo-aspiration, it really is just one line item on the menu of all the different things that we can offer patients that present with acutely symptomatic PE, but it is important to recognize
what the potential benefits of this technology are and, of course, what the limitations are. When we look at this in distinction to stroke or STEMI or certainly DVT, it's important to recognize that during a surgical pulmonary embolectomy case, the clot that's able to be extracted is quite impressive,
and this is a very very very sobering amount of material that is typically removed from the patient's right heart and their pulmonary circulation, so, in order to innovate and iterate a percutaneous technology based on existing concepts,
it really does demand significant disruption to achieve the goals, we have not tackled this yet in terms of our endovascular tool kit. So, what is the role? Well, it's potentially able to debulk in acute PE, in an intermediate risk patient which would
ideally eliminate the need for overnight lysis, as Gary alluded to, but what if it could actually replace surgical embolectomy in high risk patients? I think many of us have had the conversation where we, we sort of don't know that's there a
experienced, comfortable surgeon to do an embolectomy within the building or within immediate access to the patient that we see crashing in front of our eyes. I'm very very lucky here in New York that I've incredible cardiovascular surgeons that are able to perform this procedure very very safely 24/7,
but I know that's not the case across the country. So, one of our surgeons who actually came from the Brigham and Women's Hospital in Boston developed this concept, which was the sort of first bridge between surgical embolectomy and percutaneous therapy, which is a large bore aspiration catheter,
it's a 22 French cannula that was originally designed to be placed through a cutdown but can now be placed percutaneously, and I think many of us in the room are familiar with this technology, but essentially you advance this under fluoroscopy into the right heart,
place the patient on venous-venous bypass, and a trap, which is outside the patient, is demonstrated in the lower left portion of the screen here, is able to capture any thrombotic material and then restore the circulation via the contralateral femoral vein,
any blood that is aspirated. Very very scant data on this, here's the experience from Michael and Kenny up in Boston where they tried this technology in just a handful of cases, this was followed by John Moriarty's experience from UCLA, where he actually argued a little bit of caution
using this technology, largely related to its inability to safely and reliably deliver it to the pulmonary circulation. To that end, AngieDynamics is funding a prospective registry really looking at safety and efficacy at delivering this device to the pulmonary circulation
and its ability to treat acute pulmonary embolism as well as any right heart clot, but that data's not commercially available yet. This is just one case that we did recently of a clot in transit, which I would argue could not be treated with any other technology
and the patient was able to be discharged the same day, I personally think this is a wonderful application of this technology and is our default strategy right now for a very large clot in transit. The second entrance to the space is the Inari FlowTriever device, which is a 20 French cannula,
it does not require a perfusion team in vein-vein bypass, the concept is simple, a 20 French guide catheter is advanced into the pulmonary circulation and these trilobed disks, which function like a stentriever for stroke are deployed in the pulmonary circulation, retracted to allow the clot to be delivered to the guide cath,
and then using manual aspiration, the clot is retrieved from the patient. Just a few case reports in small series describing this, this one in JACC two years ago, showing quite robust ability to extract a clot, this company which is a relatively small company funded a
single-arm prospective trial enrolling 168 patients, and not only did they complete enrollment last year, but they actually received FDA approval, now there is no peer-reviewed literature on this, it has undergone public presentation, but we, we really don't know exactly which patients were treated,
and so we really can't dissect this, I think there is a learning curve to this technology, and it's not, certainly, ready for broad dissemination yet, we just don't know which patients are ideal for it currently. Another technology, the Penumbra CAT8 system,
a market reduction in the size, an 8 French catheter based technology, this is exact same technology that's used for thrombo-aspiration for acute ischemic stroke, currently just in a slightly different size, and then a number of cases demonstrating its efficacy at
alleviating the acute nonperfusion of an entire lobe, as Gary was referring to previously, and this is one of our cases from our own lab, where you see there's no perfusion of the right, middle and lower lobe, I'm not sure if I can get these movies to play here, oh here it goes,
and so using sort of a handmade separator, we were able to restore perfusion again to the right, middle and lower lobe here, so just one example where, I think there is a potential benefit of thrombo-aspiration in a completely occluded segment.
There has been a wealth of literature about this technology, mostly demonstrating safety and efficacy, the most recent one on the bottom right in CVIR demonstrates the ability to acutely reduce the PA pressures on the table with the use of this technology, and to that end,
Akhi Sista, our faculty here this morning, is the national principal investigator of a US multicenter prospective study looking at exactly that, to try and prove that this technology is safe and effective in the treatment of submassive pulmonary embolism, so more to come on that.
Lastly, the AngioJet System, probably the most reported and studied technology, this is a 6 French technology by default, a wealth of literature here showing safety and efficacy, however, due to adverse event reporting, this technology currently has black box label warnings
in the treatment of acute pulmonary embolism, so clearly this technology should not be used by the novice, and there are significant safety concerns largely related to bradyarrhythmias and hypotension, that being said, again, it is a quite experienced technology for this. So where do we currently stand?
I think we clearly see there are several attributes for thrombo-aspiration including just suction aspiration, a mechanical stent-triever technology, and the ability to not just insanguinate the patient but actually restore circulation and not make the patient anemic, here,
you can see where these technologies are going in terms of very very large bore and very small bore, I placed the question marked right in the center which is where I think this technology needs to converge in order to lead to the disruption for the broad adoption of a single session technology.
So, numerous devices exist, all the devices have been used clinically and have demonstrated the ability to be delivered in aspirary pulmonary embolus, at present, unfortunately there is no consensus regarding which device should be used for which patients and in which clinical presentations,
we need many prospective studies to demonstrate the safety and clinical benefit for our patients, we desperately do need a single session therapy, again, I completely agree with Gary on this, but there is a lot of work yet to do. Thank you for your attention.
- Thanks (mumbles) I have no disclosures. So when were talking about treating thoracoabdominal aortic aneurysms in patients with chronic aortic dissections, these are some of the most difficult patients to treat. I thought it would be interesting
to just show you a case that we did. This is a patient, you can see the CT scrolling through, Type B dissection starts pretty much at the left subclavian, aneurysmal. It's extensive dissection that involves the thoracic aorta, abdominal aorta,
basically goes down to the iliac arteries. You can see the celiac, SMA, renals at least partially coming off the true and continues all the way down. It's just an M2S reconstruction. You can see again the extent of this disease and what makes this so difficult in that it extends
from the entire aorta, up proximally and distally. So what we do for this patient, we did a left carotid subclavian bypass, a left external to internal iliac artery bypass. We use a bunch of thoracic stent grafts and extended that distally.
You can see we tapered down more distally. We used an EVAR device to come from below. And then a bunch of parallel grafts to perfuse our renals and SMA. I think a couple take-home messages from this is that clearly you want to preserve the branches
up in the arch. The internal iliac arteries are, I think, very critical for perfusing the spinal cord, especially when you are going to cover this much. And when you are dealing with these dissections, you have to realize that the true lumens
can become quite small and sometimes you have to accommodate for that by using smaller thoracic endografts. So this is just what it looks like in completion. You can see how much metal we have in here. It's a full metal jacket of the aorta, oops.
We, uh, it's not advancing. Oops, is it 'cause I'm pressing in it or? All right, here we go. And then two years post-op, two years post-op, you can see what this looks like. The false lumen is completely thrombosed and excluded.
You can see the parallel grafts are all open. The aneurysm sac is regressing and this patient was successfully treated. So what are some of the tips and tricks of doing these types of procedures. Well we like to come in from the axillary artery.
We don't perform any conduits. We just stick the axillary artery separately in an offset manner and place purse-string sutures. You have to be weary of manipulating around the aortic arch, especially if its a more difficult arch, as well as any thoracic aortic tortuosity.
Cannulating of vessels, SMA is usually pretty easy, as you heard earlier. The renals and celiac can be more difficult, depending upon the angles, how they come off, and the projection. You want to make sure you maintain a stiff wire,
when you do get into these vessels. Using a Coda balloon can be helpful, as sometimes when you're coming from above, the wires and catheters will want to reflux into that infrarenal aorta. And the Coda balloon can help bounce that up.
What we do in situations where the Coda doesn't work is we will come in from below and a place a small balloon in the distal renal artery to pin the catheters, wires and then be able to get the stents in subsequently. In terms of the celiac artery,
if you're going to stent it, you want to make sure, your wire is in the common hepatic artery, so you don't exclude that by accident. I find that it is just simpler to cover, if the collaterals are intact. If there is a patent GDA on CT scan,
we will almost always cover it. You can see here that robust collateral pathway through the GDA. One thing to be aware of is that you are going to, if you're not going to revascularize the celiac artery you may need to embolize it.
If its, if the endograft is not going to oppose the origin of the celiac artery in the aorta because its aneurysmal in that segment. In terms of the snorkel extent, you want to make sure, you get enough distal purchase. This is a patient intra-procedurally.
We didn't get far enough and it pulled out and you can see we're perfusing the sac. It's critical that the snorkel or parallel grafts extend above the most proximal extent of your aortic endograft or going to go down. And so we take a lot of care looking at high resolution
pictures to make sure that our snorkel and parallel grafts are above the aortic endograft. This is just a patient just about a year or two out. You can see that the SMA stent is pulling out into the sac. She developed a endoleak from the SMA,
so we had to come in and re-extend it more distally. Just some other things I mentioned a little earlier, you want to consider true lumen space preserve the internals, and then need to sandwich technique to shorten the parallel grafts. Looking at a little bit of literature,
you can see this is the PERCLES Registry. There is a number of type four thoracos that are performed here with good results. This is a paper looking at parallel grafting and 31 thoracoabdominal repairs. And you can see freedom from endoleaks,
chimney graft patency, as well as survival is excellent. This was one looking purely at thoracoabdominal aneurysm repairs. There are 32 altogether and the success rates and results were good as well. And this was one looking at ruptures,
where they found that there was a mean 20% sac shrinkage rate and all endografts remained patent. So conclusion I think that these are quite difficult to do, but with good techniques, they can be done successfully. Thank you.
- The only disclosure is the device I'm about to talk to you about this morning, is investigation in the United States. What we can say about Arch Branch Technology is it is not novel or particularly new. Hundreds of these procedures have been performed worldwide, most of the experiences have been dominated by a cook device
and the Terumo-Aortic formerly known as Bolton Medical devices. There is mattering of other experience through Medtronic and Gore devices. As of July of 2018 over 340 device implants have been performed,
and this series has been dominated by the dual branch device but actually three branch constructions have been performed in 25 cases. For the Terumo-Aortic Arch Branch device the experience is slightly less but still significant over 160 device implants have been performed as of November of this year.
A small number of single branch and large majority of 150 cases of the double branch repairs and only two cases of the three branch repairs both of them, I will discuss today and I performed. The Aortic 3-branch Arch Devices is based on the relay MBS platform with two antegrade branches and
a third retrograde branch which is not illustrated here, pointing downwards towards descending thoracic Aorta. The first case is a 59 year old intensivist who presented to me in 2009 with uncomplicated type B aortic dissection. This was being medically managed until 2014 when he sustained a second dissection at this time.
An acute ruptured type A dissection and sustaining emergent repair with an ascending graft. Serial imaging shortly thereafter demonstrated a very rapid growth of the Distal arch to 5.7 cm. This is side by side comparison of the pre type A dissection and the post type A repair dissection.
What you can see is the enlargement of the distal arch and especially the complex septal anatomy that has transformed as initial type B dissection after the type A repair. So, under FDA Compassion Use provision, as well as other other regulatory conditions
that had to be met. A Terumo or formerly Bolton, Aortic 3-branch Arch Branch device was constructed and in December 2014 this was performed. As you can see in this illustration, the two antegrade branches and a third branch
pointing this way for the for the left subclavian artery. And this is the images, the pre-deployment, post-deployment, and the three branches being inserted. At the one month follow up you can see the three arch branches widely patent and complete thrombosis of the
proximal dissection. Approximately a year later he presented with some symptoms of mild claudication and significant left and right arm gradient. What we noted on the CT Angiogram was there was a kink in the participially
supported segment of the mid portion of this 3-branch graft. There was also progressive enlargement of the distal thoracoabdominal segment. Our plan was to perform the, to repair the proximal segment with a custom made cuff as well as repair the thoracoabdominal segment
with this cook CMD thoracoabdominal device. As a 4 year follow up he's working full time. He's arm pressures are symmetric. Serum creatinine is normal. Complete false lumen thrombosis. All arch branches patent.
The second case I'll go over really quickly. 68 year old man, again with acute type A dissection. 6.1 cm aortic arch. Initial plan was a left carotid-subclavian bypass with a TEVAR using a chimney technique. We changed that plan to employ a 3-branch branch repair.
Can you advance this? And you can see this photo. In this particular case because the pre-operative left carotid-subclavian bypass and the extension of the dissection in to the innominate artery we elected to...
utilize the two antegrade branches for the bi-lateral carotid branches and actually utilize the downgoing branch through the- for the right subclavian artery for later access to the thoracoabdominal aorta. On post op day one once again he presented with
an affective co arctation secondary to a kink within the previous surgical graft, sustaining a secondary intervention and a placement of a balloon expandable stent. Current status. On Unfortunately the result is not as fortunate
as the first case. In 15 months he presented with recurrent fevers, multi-focal CVAs from septic emboli. Essentially bacteria endocarditis and he was deemed inoperable and he died. So in conclusion.
Repair of complex arch pathologies is feasible with the 3-branch Relay arch branch device. Experience obviously is very limited. Proper patient selection important. And the third antegrade branch is useful for later thoracoabdominal access.
- Thank you Professor Veith. Thank you for giving me the opportunity to present on behalf of my chief the results of the IRONGUARD 2 study. A study on the use of the C-Guard mesh covered stent in carotid artery stenting. The IRONGUARD 1 study performed in Italy,
enrolled 200 patients to the technical success of 100%. No major cardiovascular event. Those good results were maintained at one year followup, because we had no major neurologic adverse event, no stent thrombosis, and no external carotid occlusion. This is why we decided to continue to collect data
on this experience on the use of C-Guard stent in a new registry called the IRONGUARD 2. And up to August 2018, we recruited 342 patients in 15 Italian centers. Demographic of patients were a common demographic of at-risk carotid patients.
And 50 out of 342 patients were symptomatic, with 36 carotid with TIA and 14 with minor stroke. Stenosis percentage mean was 84%, and the high-risk carotid plaque composition was observed in 28% of patients, and respectively, the majority of patients presented
this homogenous composition. All aortic arch morphologies were enrolled into the study, as you can see here. And one third of enrolled patients presented significant supra-aortic vessel tortuosity. So this was no commerce registry.
Almost in all cases a transfemoral approach was chosen, while also brachial and transcervical approach were reported. And the Embolic Protection Device was used in 99.7% of patients, with a proximal occlusion device in 50 patients.
Pre-dilatation was used in 89 patients, and looking at results at 24 hours we reported five TIAs and one minor stroke, with a combined incidence rate of 1.75%. We had no myocardial infection, and no death. But we had two external carotid occlusion.
At one month, we had data available on 255 patients, with two additional neurological events, one more TIA and one more minor stroke, but we had no stent thrombosis. At one month, the cumulative results rate were a minor stroke rate of 0.58%,
and the TIA rate of 1.72%, with a cumulative neurological event rate of 2.33%. At one year, results were available on 57 patients, with one new major event, it was a myocardial infarction. And unfortunately, we had two deaths, one from suicide. To conclude, this is an ongoing trial with ongoing analysis,
and so we are still recruiting patients. I want to thank on behalf of my chief all the collaborators of this registry. I want to invite you to join us next May in Rome, thank you.
- Thank you (mumbles) and thank you Dr. Veith for the kind invitation to participate in this amazing meeting. This is work from Hamburg mainly and we all know that TEVAR is the first endovascular treatment of choice but a third of our patients will fail to remodel and that's due to the consistent and persistent
flow in the false lumen over the re-entrance in the thoracoabdominal aorta. Therefore it makes sense to try to divide the compartments of the aorta and try to occlude flow in the false lumen and this can be tried by several means as coils, plug and glue
but also iliac occluders but they all have the disadvantage that they don't get over 24 mm which is usually not enough to occlude the false lumen. Therefore my colleague, Tilo Kolbel came up with this first idea with using
a pre-bulged stent graft at the midportion which after ballooning disrupts the dissection membrane and opposes the outer wall and therefore occludes backflow into the aneurysm sac in the thoracic segment, but the most convenient
and easy to use tool is the candy-plug which is a double tapered endograft with a midsegment that is 18 mm and once implanted in the false lumen at the level of the supraceliac aorta it occludes the backflow in the false lumen in the thoracic aorta
and we have seen very good remodeling with this approach. You see here a patient who completely regressed over three years and it also answers the question how it behaves with respect to true and false lumen. The true lumen always wins and because once
the false lumen thrombosis and the true lumen also has the arterial pressure it does prevail. These are the results from Hamburg with an experience of 33 patients and also the international experience with the CMD device that has been implanted in more than 20 cases worldwide
and we can see that the interprocedural technical success is extremely high, 100% with no irrelevant complications and also a complete false lumen that is very high, up to 95%. This is the evolvement of the candy-plug
over the years. It started as a surgeon modified graft just making a tie around one of the stents evolving to a CMD and then the last generation candy-plug II that came up 2017 and the difference, or the new aspect
of the candy-plug II is that it has a sleeve inside and therefore you can retrieve the dilator without having to put another central occluder or a plug in the central portion. Therefore when the dilator is outside of the sleeve the backflow occludes the sleeve
and you don't have to do anything else, but you have to be careful not to dislodge the whole stent graft while retrieving the dilator. This is a case of a patient with post (mumbles) dissection.
This is the technique of how we do it, access to the false lumen and deployment of the stent graft in the false lumen next to the true lumen stent graft being conscious of the fact that you don't go below the edge of the true lumen endograft
to avoid (mumbles) and the final angiography showing no backflow in the aneurysm. This is how we measure and it's quite simple. You just need about a centimeter in the supraceliac aorta where it's not massively dilated and then you just do an over-sizing
in the false lumen according to the Croissant technique as Ste-phan He-lo-sa has described by 10 to 30% and what is very important is that in these cases you don't burn any bridges. You can still have a good treatment
of the thoracic component and come back and do the fenestrated branch repair for the thoracoabdominal aorta if you have to. Thank you very much for your attention. (applause)
- Thank you, Dr. Ascher. Great to be part of this session this morning. These are my disclosures. The risk factors for chronic ischemia of the hand are similar to those for chronic ischemia of the lower extremity with the added risk factors of vasculitides, scleroderma,
other connective tissue disorders, Buerger's disease, and prior trauma. Also, hemodialysis access accounts for a exacerbating factor in approximately 80% of patients that we treat in our center with chronic hand ischemia. On the right is a algorithm from a recent meta-analysis
from the plastic surgery literature, and what's interesting to note is that, although sympathectomy, open surgical bypass, and venous arterialization were all recommended for patients who were refractory to best medical therapy, endovascular therapy is conspicuously absent
from this algorithm, so I just want to take you through this morning and submit that endovascular therapy does have a role in these patients with digit loss, intractable pain or delayed healing after digit resection. Physical examination is similar to that of lower extremity, with the added brachial finger pressures,
and then of course MRA and CTA can be particularly helpful. The goal of endovascular therapy is similar with the angiosome concept to establish in-line flow to the superficial and deep palmar arches. You can use an existing hemodialysis access to gain access transvenously to get into the artery for therapy,
or an antegrade brachial, distal brachial puncture, enabling you treat all three vessels. Additionally, you can use a retrograde radial approach, which allows you to treat both the radial artery, which is typically the main player in these patients, or go up the radial and then back over
and down the ulnar artery. These patients have to be very well heparinized. You're also giving antispasmodic agents with calcium channel blockers and nitroglycerin. A four French sheath is preferable. You're using typically 014, occasionally 018 wires
with balloon diameters 2.3 to three millimeters most common and long balloon lengths as these patients harbor long and tandem stenoses. Here's an example of a patient with intractable hand pain. Initial angiogram both radial and ulnar artery occlusions. We've gone down and wired the radial artery,
performed a long segment angioplasty, done the same to the ulnar artery, and then in doing so reestablished in-line flow with relief of this patient's hand pain. Here's a patient with a non-healing index finger ulcer that's already had
the distal phalanx resected and is going to lose the rest of the finger, so we've gone in via a brachial approach here and with long segment angioplasty to the radial ulnar arteries, we've obtained this flow to the hand
and preserved the digit. Another patient, a diabetic, middle finger ulcer. I think you're getting the theme here. Wiring the vessels distally, long segment radial and ulnar artery angioplasty, and reestablishing an in-line flow to the hand.
Just by way of an extreme example, here's a patient with a vascular malformation with a chronically occluded radial artery at its origin, but a distal, just proximal to the palmar arch distal radial artery reconstitution, so that served as a target for us to come in
as we could not engage the proximal radial artery, so in this patient we're able to come in from a retrograde direction and use the dedicated reentry device to gain reentry and reestablish in-line flow to this patient with intractable hand pain and digit ulcer from the loss of in-line flow to the hand.
And this patient now, two years out, remains patent. Our outcomes at the University of Pennsylvania, typically these have been steal symptoms and/or ulceration and high rates of technical success. Clinical success, 70% with long rates of primary patency comparing very favorably
to the relatively sparse literature in this area. In summary, endovascular therapy can achieve high rates of technical, more importantly, clinical success with low rates of major complications, durable primary patency, and wound healing achieved in the majority of these patients.
- Mister Chairman, ladies and gentlemen. Good morning. I am excited to present some of the data on the new device here. These are my disclosure. There are opportunities to improve current TEVAR devices. One of that is to have a smaller device,
is a rapid deployment that is precise, and wider possibilities to have multiple size matrix to adapt to single patient anatomy. The Valiant device actually tried to meet all these unmet needs, and nowadays the Navion has been designed on the platform
of the Valiant Captivia device with a completely different solution. First of all, it's four French smaller than the Valiant Captivia, and now it's 18 French in outer diameter for the smallest sizes available.
The device has been redesigned with a shorter tip and longer length of the shaft to approach more proximal diseases, and the delivery system deploys the graft in one step that is very easy to accomplish and precise.
The fabric has been changed with nowadays the Navion having the multi-filament weave of the Endurant that already demonstrates conformability, flexibility, and long-term durability of the material. It's coming with a wide matrix of options available. In terms of length, up to 225 mm.
Diameters as small as 20 mm, and tapered device to treat particular anatomical needs. But probably the most important innovation is the possibility to have two proximal configuration options: the FreeFlo and the CoveredSeal.
Both tied to the tip of the device with the tip-capture mechanism that ensures proximal deployment of the graft that is very accurate. This graft is being under trial in a global trial
that included 100 patients all over the world. The first 87 patients have been submitted for primary endpoint analysis. 40% of the patients were females. High risk patients showed here by the ASA class III and IV. Most of the patients presented
with a fusiform or saccular aneurysm, and the baseline anatomy is quite typical for these kinds of patients, but most of the patients have the very tortuous indices, both at the level of the access artery tortuosity and the thoracic aorta tortuosity.
Three-fourths of the patients had been treated with a FreeFlo proximal end of the graft, while one-fourth with the CoveredSeal. Complete coverage of the left subclavian occurred in one-fifth of the patients. Almost all had been revascularized.
Procedure was quite short, less than one and half hour, percutaneous access in the majority of cases. There were no access or deployment failures in this series. And coming to the key clinical endpoints, there were two mortality reported out of 87 patients.
One was due to the retrograde type A dissection at day one, and one was not device related almost at the end of the first month. Secondary procedures were again two. One was in the case of retrograde type A dissection, and the second one in a patient
that had an arch rupture due to septicemia. Type 1a endoleak was reported in only one case, and it was felt to be no adverse event associated so was kept under surveillance without any intervention. Major Adverse Events occurred in 28% of the cases. Notably four patients had a stroke
that was mild and not disabling, regressing in two weeks. Only one case of spinal cord ischaemia that resolved by drainage and therapy in 20 days. In summary, we can say that the design enhancement of Valiant Navion improved upon current generation TEVAR.
Acute performance is quite encouraging: no access or deployment failure, low procedural and fluoro times, low rate of endoleaks, Major Adverse Events in the range expected for this procedure.
Nowadays the graft is USA FDA approved as well as in Europe CE mark. And of course we have to wait the five years results.
- Thank you for the opportunity to present this arch device. This is a two module arch device. The main model comes from the innominated to the descending thoracic aorta and has a large fenestration for the ascending model that is fixed with hooks and three centimeters overlapping with the main one.
The beginning fenestration for the left carotid artery was projected but was abandoned for technical issue. The delivery system is precurved, preshaped and this allows an easy positioning of the graft that runs on a through-and-through wire from the
brachial to the femoral axis and you see here how the graft, the main model is deployed with the blood that supported the supraortic vessels. The ascending model is deployed after under rapid pacing.
And this is the compilation angiogram. This is a case from our experience is 6.6 centimeters arch and descending aneurysm. This is the planning we had with the Gore Tag. at the bottom of the implantation and these are the measures.
The plan was a two-stage procedure. First the hemiarch the branching, and then the endovascular procedure. Here the main measure for the graph, the BCT origin, 21 millimeters, the BCT bifurcation, 20 millimeters,
length, 30 millimeters, and the distal landing zone was 35 millimeters. And these are the measures that we choose, because this is supposed to be an off-the-shelf device. Then the measure for the ascending, distal ascending, 35 millimeters,
proximal ascending, 36, length of the outer curve of 9 centimeters, on the inner curve of 5 centimeters, and the ascending model is precurved and we choose a length between the two I cited before. This is the implantation of the graft you see,
the graft in the BCT. Here, the angiography to visualize the bifurcation of the BCT, and the release of the first part of the graft in the BCT. Then the angiography to check the position. And the release of the graft by pushing the graft
to well open the fenestration for the ascending and the ascending model that is released under cardiac pacing. After the orientation of the beat marker. And finally, a kissing angioplasty and this is the completion and geography.
Generally we perform a percutaneous access at auxiliary level and we close it with a progolide checking the closure with sheet that comes from the groin to verify the good occlusion of the auxiliary artery. And this is the completion, the CT post-operative.
Okay. Seven arch aneurysm patients. These are the co-morbidities. We had only one minor stroke in the only patient we treated with the fenestration for the left carotid and symptomology regressed completely.
In the global study, we had 46 implantations, 37 single branch device in the BCT, 18 in the first in men, 19 compassionate. These are the co-morbidities and indications for treatment. All the procedures were successful.
All the patients survived the procedure. 10 patients had a periscope performed to perfuse the left auxiliary artery after a carotid to subclavian bypass instead of a hemiarch, the branching. The mean follow up for 25 patients is now 12 months.
Good technical success and patency. We had two cases of aneurysmal growth and nine re-interventions, mainly for type II and the leak for the LSA and from gutters. The capilomiar shows a survival of 88% at three years.
There were three non-disabling stroke and one major stroke during follow up, and three patients died for unrelated reasons. The re-intervention were mainly due to endo leak, so the first experience was quite good in our experience and thanks a lot.
- So thank you to the organizers and to Dr. Veith, and thank you to Dr. Ouriel for giving me the introduction of the expense of an unsuitable procedure for pain patients. We have no disclosures.
I think when you look at MRV or Venous interventions, you can look at it as providing you a primary diagnosis, confirming a diagnosis if there's confusion. Procedural planning, you can use it as a procedural adjunct,
or you can use it as a primary procedural modality. In general, flow-dependent MRI has a low sensitivity and a slow acquisition time, making it practically impractical. Flow-independent MRI has become more popular, with sensitivity and specificities
rounding at 95 to 100%. There's a great deal of data on contrast-enhanced MRI, avoiding adanalenum using the iron compounds, and you'll hear later from Dr. Black about Direct Thrombus Imaging. There has been significant work on Thrombus Imaging,
but I will leave it up to him to talk about it. MR you can diagnose a DVT, either in both modalities, and you can see here with the arrows. It will also provide you data on the least inaccessible areas for duplex and other modalities,
such as the iliac veins and the IVC, as can be seen here. It is also perhaps easier to use than CTV, because at least in my institution CTV always comes out as a CTA, and I can't help that no matter what happens.
MR can also show you collaterals, which may be very important as you are trying to diagnose a patient. And in essence it may show you the smaller vein that you're more interested in, particularly in pelvic congestion syndrome,
such as this patient with an occluded internal iliac vein. It can also demonstrate, for those of you who deal with dialysis access, or it's central line problems, central venous stenosis and Thrombus. But equally importantly
it may show you that a stenosis is not intrinsic to the wall, but it's actually intrinsic to extravascular inflammation, as in this patient with mediastinal fibrosis, and which will give you a different way of what you wish to do and treat.
The European guidelines have addressed MR in it's future with chronic venous disease and they give it a 1C rating, and they recommend that if doesn't work you should proceed to Ibes. It can be used for the diagnoses of pulmonary embolism,
it can eliminate the use of ECHO, one can diagnose both the presence of the Thrombus, the dilatation of the ventricul, and if one is using Dynamic MR Imaging one can also see mcconnell sign or the equivalent on the septum between the two ventricles.
More interestingly it can also be used now in the chronic thrombuc, pulmonary hypertension, where it can show both the legions that are treatable and untreatable, as some of you may have heard from Dr. Roosevelt
earlier in the day, where they're now treating the outlying lesions with balloon angioplasty serial sessions. It can also look at the ventricul and give you some idea of where the ventricul stands with regard to it's performance,
we're looking at and linking this to the lungs. It can also show you the unusual, such as atresia of the IVC or it can help with you the diagnosis of Pelvic Congestion Syndrome. And it is extremely valuable
in dealing with AVM's, although it may take one, two, or three sessions with differing contrast bulosus to identify both the arterial, the intrinsic lesion, and the outflow lesions,
but a very valuable adjunct. In renal carcinoma it has two values, one is that it can may diagnosis venous invasion, and it may also let you understand whether or not you are dealing with bland thrombus or tumor thrombus,
which can change the staging for the patient and also change the actual intervention that you may perform. If you use flash imaging one will get at least an 89% sensitivity of the nature of thrombus,
whether it's bland or tumor thrombus, which may change what you need to do during the procedure. It could also tell you whether there's actual true wall invasion, which will require excision of the IVC
as opposed to the simple thromboendarterectomy. And this can run up to a specificity of 88% to exclude it. In the brain it's commonly used to diagnose the intra tumor vasculature. Diagnosing between veins and arterial systems, which can be helpful
particularly if one is considering percutaneous or other interventions. With regard to central venous stenosis there is some data and most people are now using an onlay technique where they take the MRI,
they develop the lines for the vessels and then use that as guide in one or two dimensions with fusion imaging to achieve access with a wire, catheter and balloon, as opposed to a blind stick technique.
There is data to show that you can image with the correct catheter balloons within the vessels and do serial MR's to show that it works. And finally with guidance catheters EP is now able to guide the catheter further and further in to achieve from the,
either the jugular or the venous access across the septum and to burn the entrium as appropriate. And finally, one can use MR to actually gain access, burn, and then actually use the MR to look at the specific tissue,
to show that you've achieved a burn at the appropriate area within the cardiac system and thus prove that your modality has achieved it. So in summary, we can use it for primary diagnosis, confirmatory diagnosis,
procedural planning, and procedural adjunct, but we're only still learning how to use it as a primary procedural modality. Thank you so much.
- Mr. Chairman, ladies and gentlemen, good morning. I'd like to thank Dr. Veith for the opportunity to present at this great meeting. I have nothing to disclose. Since Dr. DeBakey published the first paper 60 years ago, the surgical importance of deep femoral artery has been well investigated and documented.
It can be used as a reliable inflow for low extremity bypass in certain circumstances. To revascularize the disease, the deep femoral artery can improve rest pain, prevent or delay the amputation, and help to heal amputation stump.
So, in this slide, the group patient that they used deep femoral artery as a inflow for infrainguinal bypass. And 10-year limb salvage was achieved in over 90% of patients. So, different techniques and configurations
of deep femoral artery angioplasty have been well described, and we've been using this in a daily basis. So, there's really not much new to discuss about this. Next couple minutes, I'd like to focus on endovascular invention 'cause I lot I think is still unclear.
Dr. Bath did a systemic review, which included 20 articles. Nearly total 900 limbs were treated with balloon angioplasty with or without the stenting. At two years, the primary patency was greater than 70%. And as you can see here, limb salvage at two years, close to, or is over 98% with very low re-intervention rate.
So, those great outcomes was based on combined common femoral and deep femoral intervention. So what about isolated deep femoral artery percutaneous intervention? Does that work or not? So, this study include 15 patient
who were high risk to have open surgery, underwent isolated percutaneous deep femoral artery intervention. As you can see, at three years, limb salvage was greater than 95%. The study also showed isolated percutaneous transluminal
angioplasty of deep femoral artery can convert ischemic rest pain to claudication. It can also help heal the stump wound to prevent hip disarticulation. Here's one of my patient. As you can see, tes-tee-lee-shun with near
or total occlusion of proximal deep femoral artery presented with extreme low-extremity rest pain. We did a balloon angioplasty. And her ABI was increased from 0.8 to 0.53, and rest pain disappeared. Another patient transferred from outside the facility
was not healing stump wound on the left side with significant disease as you can see based on the angiogram. We did a hybrid procedure including stenting of the iliac artery and the open angioplasty of common femoral artery and the profunda femoral artery.
Significantly improved the perfusion to the stump and healed wound. The indications for isolated or combined deep femoral artery revascularization. For those patient presented with disabling claudication or rest pain with a proximal
or treatable deep femoral artery stenosis greater than 50% if their SFA or femoral popliteal artery disease is unsuitable for open or endovascular treatment, they're a high risk for open surgery. And had the previous history of multiple groin exploration, groin wound complications with seroma or a fungal infection
or had a muscle flap coverage, et cetera. And that this patient should go to have intervascular intervention. Or patient had a failed femoral pop or femoral-distal bypass like this patient had, and we should treat this patient.
So in summary, open profundaplasty remains the gold standard treatment. Isolated endovascular deep femoral artery intervention is sufficient for rest pain. May not be good enough for major wound healing, but it will help heal the amputation stump
to prevent hip disarticulation. Thank you for much for your attention.
- Thank you. Thank you again for the invitation, and also my talk concerns the use of new Terumo Aortic stent graft for the arch. And it's the experience of three different countries in Europe. There's no disclosure for this topic.
Just to remind what we have seen, that there is some complication after surgery, with mortality and the stroke rate relatively high. So we try to find some solution. We have seen that we have different options, it could be debranching, but also
we know that there are some complications with this technique, with the type A aortic dissection by retrograde way. And also there's a way popular now, frozen elephant trunk. And you can see on the slide the principle.
But all the patients are not fit for this type of surgery. So different techniques have been developed for endovascular options. And we have seen before the principle of Terumo arch branch endograft.
One of the main advantages is a large window to put the branches in the different carotid and brachiocephalic trunk. And one of the benefit is small, so off-the-shelf technique, with one size for the branch and different size
for the different carotids. This is a more recent experience, it's concerning 15 patients. And you can see the right column that it is. All the patients was considered unfit for conventional surgery.
If we look about more into these for indication, we can see four cases was for zone one, seven cases for zone two, and also four cases for zone three. You can see that the diameter of the ascending aorta, the min is 38,
and for the innominate artery was 15, and then for left carotid was eight. This is one example of what we can obtain with this type of handling of the arch with a complete exclusion of the lesion, and we exclude the left sonography by plyf.
This is another, more complex lesion. It's actually a dissection and the placement of a stent graft in this area. So what are the outcomes of patients? We don't have mortality, one case of hospital mortality.
We don't have any, sorry, we have one stroke, and we can see the different deaths during the follow-up. If we look about the endoleaks, we have one case of type three endoleak started by endovascular technique,
and we have late endoleaks with type one endoleaks. In this situation, it could be very difficult to treat the patient. This is the example of what we can observe at six months with no endoleak and with complete exclusion of the lesion.
But we have seen at one year with some proximal type one endoleak. In this situation, it could be very difficult to exclude this lesion. We cannot propose this for this patient for conventional surgery, so we tried
to find some option. First of all, we tried to fix the other prosthesis to the aortic wall by adjusted technique with a screw, and we can see the fixation of the graft. And later, we go through the,
an arrangement inside the sac, and we put a lot of colors inside so we can see the final results with complete exclusion. So to conclude, I think that this technique is very useful and we can have good success with this option, and there's a very low
rate of disabling stroke and endoleaks. But, of course, we need more information, more data. Thank you very much for your attention.
- Now I want to talk about, as Chrissy mentioned AVM Classification System and it's treatment implication to achieve cure. How do I put forward? Okay, no disclosures. So there are already AVM Classification Systems. One is the well-known Houdart classification
for CNS lesions, and the other one is quite similar to the description to the Houdart lesion, the Cho Do classification of peripheral AVM's. But what do we expect from a good classification system? We expect that it gives us also a guide how to treat with a high rate of cure,
also for complex lesions. So the Yakes Classification System was introduced in 2014, and it's basically a further refinement of the previous classification systems, but it adds other features. As for example, a new description of
a new entity, Type IV AVM's with a new angioarchitecture, it defines the nidus, and especially a value is that it shows you the treatment strategy that should be applied according to angioarchitecture to treat the lesion. It's based on the use of ethanol and coils,
and it's also based on the long experience of his describer, Wayne Yakes. So the Yakes Classification System is also applicable to the very complex lesions, and we start with the Type I AVM, which is the most simple, direct
arterial to venous connection without nidus. So Type I is the simplest lesion and it's very common in the lung or in the kidney. Here we have a Type I AVM come from the aortic bifurcation draining into the paralumbar venous plexus,
and to get access, selective cauterization of the AVM is needed to define the transition point from the arterial side to the venous side, and to treat. So what is the approach to treat this? It's basically a mechanical approach, occluding
the lesion and the transition point, using mechanical devices, which can be coils or also other devices. For example, plugs or balloons. In small lesions, it can also be occluded using ethanol, but to mainly in larger lesions,
mechanical devices are needed for cure. Type II is the common and typical AVM which describes nidus, which comes from
multiple in-flow arteries and is drained by multiple veins. So this structure, as you can see here, can be, very, very dense, with multiple tangled fistulaes. And the way to break this AVM down is mainly that you get more selective views, so you want to get selective views
on the separate compartments to treat. So what are the treatment options? As you can see here, this is a very selective view of one compartment, and this can be treated using ethanol, which can be applied
by a superselective transcatheter arterial approach, where you try to get as far as possible to the nidus. Or if tangled vessels are not allowing transcatheter access, direct puncture of the feeding arteries immediately proximal to the nidus can be done to apply ethanol. What is the difference between Type IIa and IIb?
IIb has the same in-flow pattern as Type a, but it has a different out-flow pattern, with a large vein aneurysm. It's crucial to distinguish that the nidus precedes this venous aneurysm. So here you can see a nice example for Type IIb AVM.
This is a preview of the pelvis, we can here now see, in a lateral view, that the nidus fills the vein aneurysm and precedes this venous aneurysm. So how can this lesion be accessed? Of course, direct puncture is a safe way
to detect the lesion from the venous side. So blocking the outflow with coils, and possibly also ethanol after the flow is reduced to reflux into the fistulaes. It's a safe approach from the venous side for these large vein aneurysm lesions,
but also superselective transcatheter arterial approach to the nidus is able to achieve cure by placing ethanol into the nidus, but has to be directly in front of the nidus to spare nutrient arteries.
Type IIIa has also multiple in-flow arteries, but the nidus is inside the vein aneurysm wall. So the nidus doesn't precede the lesion, but it's in the vein wall. So where should this AVM be treated?
And you can see a very nice example here. This is a Type IIIa with a single out-flow vein, of the aneurysm vein, and this is a direct puncture of the vein, and you can see quite well that this vein aneurysm has just one single out-flow. So by blocking this out-flow vein,
the nidus is blocked too. Also ethanol can be applied after the flow was reduced again to reflux into the fistulas inside the vein aneurysm wall. And here you can see that by packing a dense packing with coils, the lesion is cured.
So direct puncture again from the venous side in this venous aneurysm venous predominant lesion. Type IIIb, the difference here is again, the out-flow pattern. So we have multiple in-flow arteries, the fistulaes are again in the vein aneurysm.
Which makes it even more difficult to treat this lesion, is that it has multiple out-flow veins and the nidus can also precede into these or move into these out-flow veins. So the dense packing of the aneurysm might have to be extended into the out-flow veins.
So what you can see here is an example. Again you need a more selective view, but you can already see the vein aneurysm, which can be targeted by direct puncture. And again here, the system applies. Placing coils and dense packing of the vein aneurysm,
and possibly also of the out-flow veins, can cure the lesion. This is the angiogram showing cure of this complex AVM IIIb. Type IV is a very new entity which was not described
in any other classification system as of yet. So what is so special about this Type IV AVM is it has multiple arteries and arterioles that form innumerable AV fistulaes, but these fistulaes infiltrate the tissue. And I'm going to specify this entity in a separate talk,
so I'm not going too much into details here. But treatment strategy of course, is also direct puncture here, and in case possible to achieve transarterial access very close to the nidus transarterial approach is also possible. But there are specific considerations, for example
50/50 mixture of alcohol, I'm going to specify this in a later talk. And here you can see some examples of this micro-fistulae in Type IV AVM infiltrative type. This is a new entity described. So the conclusion is that the Yakes Classification System
is based on the angioarchitecture of AVM's and on hemodynamic features. So it offers you a clear definition here the nidus is located, and where to deliver alcohol in a safe way to cure even complex AVM's.
Thank you very much.
- Thank you, Dr. Veith, for this kind invitation. Aberrant origin of the vertebral artery is the second most common aortic arch anomaly. It is more common in patients with thoracic aortic disease when compared to the general population. It's usually of no clinical significance,
except when encountered while treating cerebro-vascular disease or aortic arch pathology. And that's when critical decision-making to preserve its perfusion becomes necessary. This picture illustrates the most common
types of aortic arch anomalies. Led by bovine arch, isolated vertebral artery, and aberrant right side. In this study, it shows a significant correlation with thoracic aortic disease. We first should evaluate the origin
of the vertebral artery. On the right side of the screen you can see the most common type and it's when it's between the left subclavian and the left common carotid artery origin. This is an example of the left vertebral artery
aberrant associated with a mycotic aneurysm of the aortic arch. And this one is a right aberrant vertebral artery associated with a descending thoracic aneurysm and center retroesophageal location. We then look at the variation of
the vertebral artery and posterior circulation. Most commonly dominant left or hypoplasia of the right vertebral artery as shown in the picture. For termination in the posterior inferior cerebellar artery, or PICA.
Or occlusive lesion on the right side, which necessitates perfusion of the left side. This study shows that vertebral artery variations that could need perfusion is up to 30% of patients
with thoracic aortic disease. There are, unfortunately, minimal literature in the vascular, mostly case reports or series. And most of this says procedure data comes from the neurosurgical literature for occlusive disease that shows in this study,
for example, low morbidity, mortality. Complications include thoracic duct injury, recurrent laryngeal nerve, Horner's and CVAs. And they showed high patency rates. The SVS guidelines for left subclavian revasculatization, although low quality,
shows they indicated routine revascularization and they mention some of the indications for left vertebral artery revasculatization. And extrapolating from that, from those guidelines, we summarize the indications for vertebral artery
revascularization dominant ipsilateral left or hypoplastic right. Incomplete circle of Willis, or termination of the left in the PICA artery. Diseased or occluded contralateral vertebral artery.
Extensive aortic coverage or inability to evaluate the circle of Willis prior to intervention. Some technical tips, we use a routine supraclavicular incision. We identify the vertebral artery posterior-medial
location to the common carotid. We carefully preserve the recurrent laryngeal nerve or non-recurrent laryngeal nerve, which is common in aortic arch anomalies. Thoracic duct on the left side. Transpose it to the posterior surface
of the common carotid. And then clamp distal to the anastomosis and to avoid prolonged ischemia to the posterior circulation. This is a completion aortagram that shows patent left vertebral artery transposed
to the common carotid. And then one month follow-up shows that the left vertebral artery is patent with a complete repair of the aorta. So in our experience, we did six vertebral transpositions over
the last couple years, four on the left, two on the right. No perioperative complications. One lost follow-up. And up to 27 months of the patent vessels. In summary, aberrant vertebral artery is uncommon
finding, but associated with thoracic aortic disease. The origin and the course of the vertebral artery should be thoroughly evaluated prior to treatment. Revascularization should be considered in certain situations to avoid
posterior circulation ischemia. But more data is needed to establish guidelines. Thank you.
- So my charge is to talk about using band for steal. I have no relevant disclosures. We're all familiar with steal. The upper extremity particularly is able to accommodate for the short circuit that a access is with up to a 20 fold increase in flow. The problem is that the distal bed
is not necessarily as able to accommodate for that and that's where steal comes in. 10 to 20% of patients have some degree of steal if you ask them carefully. About 4% have it bad enough to require an intervention. Dialysis associated steal syndrome
is more prevalent in diabetics, connective tissue disease patients, patients with PVD, small vessels particularly, and females seem to be predisposed to this. The distal brachial artery as the inflow source seems to be the highest risk location. You see steal more commonly early with graft placement
and later with fistulas, and finally if you get it on one side you're very likely to get it on the other side. The symptoms that we are looking for are coldness, numbness, pain, at the hand, the digital level particularly, weakness in hand claudication, digital ulceration, and then finally gangrene in advanced cases.
So when you have this kind of a picture it's not too subtle. You know what's going on. However, it is difficult sometimes to differentiate steal from neuropathy and there is some interaction between the two.
We look for a relationship to blood pressure. If people get symptomatic when their blood pressure's low or when they're on the access circuit, that is more with steal. If it's following a dermatomal pattern that may be a median neuropathy
which we find to be pretty common in these patients. Diagnostic tests, digital pressures and pulse volume recordings are probably the best we have to assess this. Unfortunately the digital pressures are not, they're very sensitive but not very specific. There are a lot of patients with low digital pressures
that have no symptoms, and we think that a pressure less than 60 is probably consistent, or a digital brachial index of somewhere between .45 and .6. But again, specificity is poor. We think the digital pulse volume recordings is probably the most useful.
As you can see in this patient there's quite a difference in digital waveforms from one side to the other, and more importantly we like to see augmentation of that waveform with fistula compression not only diagnostically but also that is predictive of the benefit you'll get with treatment.
So what are our treatment options? Well, we have ligation. We have banding. We have the distal revascularization interval ligation, or DRIL, procedure. We have RUDI, revision using distal inflow,
and we have proximalization of arterial inflow as the approaches that have been used. Ligation is a, basically it restores baseline anatomy. It's a very simple procedure, but of course it abandons the access and many of these patients don't have a lot of good alternatives.
So it's not a great choice, but sometimes a necessary choice. This picture shows banding as we perform it, usually narrowing the anastomosis near the artery. It restricts flow so you preserve the fistula but with lower flows.
It's also simple and not very morbid to do. It's got a less predictable effect. This is a dynamic process, and so knowing exactly how tightly to band this and whether that's going to be enough is not always clear. This is not a good choice for low flow fistula,
'cause again, you are restricting flow. For the same reason, it's probably not a great choice for prosthetic fistulas which require more flow. So, the DRIL procedure most people are familiar with. It involves a proximalization of your inflow to five to 10 centimeters above the fistula
and then ligation of the artery just below and this has grown in popularity certainly over the last 10 or 15 years as the go to procedure. Because there is no flow restriction with this you don't sacrifice patency of the access for it. It does add additional distal flow to the extremity.
It's definitely a more morbid procedure. It involves generally harvesting the saphenous vein from patients that may not be the best risk surgical patients, but again, it's a good choice for low flow fistula. RUDI, revision using distal inflow, is basically
a flow restrictive procedure just like banding. You're simply, it's a little bit more complicated 'cause you're usually doing a vein graft from the radial artery to the fistula. But it's less complicated than DRIL. Similar limitations to banding.
Very limited clinical data. There's really just a few series of fewer than a dozen patients each to go by. Finally, a proximalization of arterial inflow, in this case rather than ligating the brachial artery you're ligating the fistula and going to a more proximal
vessel that often will accommodate higher flow. In our hands, we were often talking about going to the infraclavicular axillary artery. So, it's definitely more morbid than a banding would be. This is a better choice though for prosthetic grafts that, where you want to preserve flow.
Again, data on this is very limited as well. The (mumbles) a couple years ago they asked the audience what they like and clearly DRIL has become the most popular choice at 60%, but about 20% of people were still going to banding, and so my charge was to say when is banding
the right way to go. Again, it's effect is less predictable than DRIL. You definitely are going to slow the flows down, but remember with DRIL you are making the limb dependent on the patency of that graft which is always something of concern in somebody
who you have caused an ischemic hand in the first place, and again, the morbidity with the DRIL certainly more so than with the band. We looked at our results a few years back and we identified 31 patients who had steal. Most of these, they all had a physiologic test
confirming the diagnosis. All had some degree of pain or numbness. Only three of these patients had gangrene or ulcers. So, a relatively small cohort of limb, of advanced steal. Most of our patients were autogenous access,
so ciminos and brachycephalic fistula, but there was a little bit of everything mixed in there. The mean age was 66. 80% were diabetic. Patients had their access in for about four and a half months on average at the time of treatment,
although about almost 40% were treated within three weeks of access placement. This is how we do the banding. We basically expose the arterial anastomosis and apply wet clips trying to get a diameter that is less than the brachial artery.
It's got to be smaller than the brachial artery to do anything, and we monitor either pulse volume recordings of the digits or doppler flow at the palm or arch and basically apply these clips along the length and restricting more and more until we get
a satisfactory signal or waveform. Once we've accomplished that, we then are satisfied with the degree of narrowing, we then put some mattress sutures in because these clips will fall off, and fix it in place.
And basically this is the result you get. You go from a fistula that has no flow restriction to one that has restriction as seen there. What were our results? Well, at follow up that was about almost 16 months we found 29 of the 31 patients had improvement,
immediate improvement. The two failures, one was ligated about 12 days later and another one underwent a DRIL a few months later. We had four occlusions in these patients over one to 18 months. Two of these were salvaged with other procedures.
We only had two late recurrences of steal in these patients and one of these was, recurred when he was sent to a radiologist and underwent a balloon angioplasty of the banding. And we had no other morbidity. So this is really a very simple procedure.
So, this is how it compares with DRIL. Most of the pooled data shows that DRIL is effective in 90 plus percent of the patients. Patency also in the 80 to 90% range. The DRIL is better for late, or more often used in late patients,
and banding used more in earlier patients. There's a bigger blood pressure change with DRIL than with banding. So you definitely get more bang for the buck with that. Just quickly going through the literature again. Ellen Dillava's group has published on this.
DRIL definitely is more accepted. These patients have very high mortality. At two years 50% are going to be dead. So you have to keep in mind that when you're deciding what to do. So, I choose banding when there's no gangrene,
when there's moderate not severe pain, and in patients with high morbidity. As promised here's an algorithm that's a little complicated looking, but that's what we go by. Again, thanks very much.
- So this is what I've been assigned to do, I think this is a rich topic so I'll just get into it. Here are my disclosures. So I hope to convince you at the end of this talk that what we need for massive PE when we're talking about catheter based therapy is a prospective registry. And what we need for catheter based therapy for
submassive PE is a randomized controlled trial. So we'll start with massive PE and my rational for this. So you know, really as you've heard, the goal of massive PE treatment is to rescue these patients from death. They have a 25 to 65% chance of dying
so our role, whatever type of physician we are, is to rescue that patient. So what are our tools to rescue that patient? You've heard about some of them already, intravenous thrombolysis, surgical embolectomy, and catheter directed therapy.
The focus of my talk will be catheter directed therapy but let's remember that the fastest and easiest thing to do for these patients is to give them intravenous thrombolysis. And I think we under utilize this therapy and we need to think about this as a first line therapy for massive PE.
However, there's some patients in whom thrombolytics are contraindicated or in whom they fail and then we have to look at some other options. And that's where catheter directed therapy may play a role. So I want to show you a pretty dramatic case and this was an eye-opening case for me
and sort of what launched our PERT when I was at Cornell. It's a 30 year old man, transcranial resection of a pituitary tumor post-op seizures and of course he had a frontal lobe hemorrhage at that time. Sure enough, four or five days after this discovery
he developed hypertension and hypoxia. And then is he CT of the chest, which I still remember to this day because it was so dramatic. You see this caval thrombosis right, basically a clot in transit
and this enormous clot in the right main pulmonary artery. And of course he was starting to get altered, tachycardiac and a little bit hypotensive. So the question is, what to do with this patient with an intracranial hemorrhage? Obviously, systemic thrombolytics are
contraindicated in him. His systolics were in the 90 millimeter of mercury ranged, getting more altered and tachycardiac. He was referred for a CDT and he was brought to the IR suite. And really, at this point,
you could see the multidisciplinary nature of PE. The ICU attending was actively managing him while I was getting access and trying to do my work. So this was the initial pulmonary angiogram you can see there's absolutely no flow to the right lung even with a directed injection
you see this cast of thrombus there. Tried a little bit of aspiration, did a little bit of maceration, even injected a little TPA, wasn't getting anywhere. I was getting a little bit more panicked as he was getting more panicked
and I remembered this device that I had used in AV fistula work called the Cleaner. Totally off label use here, I should disclose that and I have no interest in the company, no financial interest in the company. And so we deployed this thing, activate it a few times,
it spins at 3,000 rpm's, he coughed a little bit, and that freaked us all out also. But low and behold we actually started seeing some profusion. And you can see it in the aortogram actually in this and that's the whole point of massive PE treatment with CDT,
is try to get forward flow into the left ventricle so that you have a systemic blood pressure. Now, you know, when we talk about catheter based therapies we have all sorts of things at our disposal. And my point to you is that you know really, thank you...
You guys can see that, great. So really, the point of these catheter therapies is that you can throw the kitchen sink at massive PE because basically your role is to try to help this patient live. So, if I can get this thing to show up again.
There we go. It's not working very well, sorry. So, from clockwise we have the AngioVac circuit, you have, let's see if this will work again, okay. Nope, it's got a delay. So then you have your infusion catheter,
then you have the Inari FlowTriever, you saw the Cleaner in the previous cast, and you have the Penumbra aspiration device the CAT 8. And some of these will be spoken about in more detail in subsequent talks. But really, you can throw the kitchen sink at massive PE
just to do whatever it takes to get profusion to the left side. So, the best analysis that has been done so far was Will Kuo in 2009. He conducted a meta-analysis of about 594 patients and he found this clinical success rate of 86.5%.
This basically meant these patients survived to 30 days. Well, if that we're the case, that's a much lower mortality than we've seen historically we should basically be doing catheter directed therapy for every single massive PE that comes into the hospital. But I think we have to remember with this meta-analysis
that only 94 of these patients came from prospective studies, 500 came from retrospective, single center studies. So even though it was a very well conducted meta-analysis, the substrate for this meta-analysis wasn't great. And I think my point to you is that
we really are going to have a hard time studying this in a prospective fashion. So what is the data, as far as massive PE tell us and not tell us? Techniques are available to remove thrombus, it can be used if systemic lysis is contraindicated,
but it doesn't tell us whether catheter based therapies are better than the other therapies. Whether they should be used in combination with them and which patients should get catheter based therapy, which should get surgery and which techniques are most effective and safe.
Now, I think something we have to remember is that massive PE has a 5% incidence which is probably a good thing, if this was even higher than that we would have even more of an epidemic on our hand. But this is what makes massive PE very difficult to study.
So, if you looked at a back of the envelope calculation an RCT is just not feasible. So in an 800 bed hospital, you have 200 PE's per year, 5% are massive which means you get 10 per year in that hospital, assume 40% enroll which is actually generous,
that means that 4 massive PE's per year per institution. And then what are you going to do? Are you going to randomize them to IV lytics versus surgery versus interventional therapy, a three arm study, what is the effect size, what difference do you expect between these therapies
and how would you power it? It's really an impossible question. So I do want to make the plug for a Massive PE Prospective Registry. I think something like the PERT consortium is very well-suited to run something like this
especially with this registry endeavors. Detailed baseline characteristics including all these patients, detailing the intervention and looking at both short and long-term outcomes. Moving on to submassive PE. As you've heard much more controversial,
a much more difficult question. ICOPER as you already heard from the previous talk, alerted the world to RV dysfunction which this right ventricular hypokinesis conferring a higher mortality at 90 days than no RV dysfunction. And that's where PEITHO came in as you heard.
This showed that the placebo group met the primary endpoint of hemodynamic decompensation more commonly than the Tenecteplase group. Of course, coming at the risk of higher rate of major bleeding and intracranial hemorrhage. So I just want to reiterate what was just said
which is that systemic thrombolysis has a questionable risk benefit profile and most patients with submassive PE, as seen in the guideline documents as well. So that sort of opens a sort of door for catheter directed therapy.
Is this the next therapy to overcome some of the shortcomings of systemic thrombolysis? Well what we have in terms of CDT is these four trials, Ultima, Seattle II, Optalyse, and Perfect. Three of these trails were the ultrasound assisted catheter, the Ekos catheter.
And only one of them is randomized and that's the Ultima trial. I'm going to show you just one slide from each one of them. The Ultima trial is basically the only randomized trial and it showed that if you put catheters in these patients 24 hours later their RV to LV ratio will be lower
than if you just treat them with Heparin. Seattle II is a single arm study and there was an association with the reduction in the RV to LV ratio at 48 hours by CTA. PERFECT, I found this to be the most interesting figure from PERFECT which is that you're going to start it at
systolic pulmonary artery pressure of 51 and you're going to come down to about 37. Optalyse, a brand new study that was just published, four arms each arm has increasing dose associated with it and at 48 hours it didn't matter, all of these groups had a reduction in the RV to LV ratio.
And there was no control group here as well. What is interesting is that the more thrombolytics you used the more thrombus you cleared at 48 hours. What that means clinically is uncertain at this point. There is bleeding with CDT. 11% major bleeding rate in Seattle II,
no intracranial hemorrhages. Optalyse did have five major bleeds, most of the major bleeds happened in the highest dosed arms. So we know that thrombolytics cause bleeding that's still an issue. Now, clot extraction minus fibrinolytic,
this is an interesting question. We do have devices, you're going to hear about the FLARE trial later in this session. EXTRACT-PE is ongoing which we have enrolled about 75 patients into. What the data does and does not tell us
when it comes to CDT for submassive PE it probably reduces the RV to LV ratio at 24 hours, it's associated with a reduction at 48 hours, major bleeding is seen, we do not know what the short and long-term clinical outcomes are
following CDT for submassive PE. Whether it should be routinely used in submassive PE and in spite of the results of Optalyse this is a preliminary trial, we don't know the optimal dose and duration of thrombolytic drug. And even is spite of these early trials
on these non-lytic techniques, we don't know their true role yet. I'd liked to point out that greater than 1,600 patients have been randomized in systemic lytic trails yet only 59 have been randomized in a single, non-U.S. CDT trial.
So this means that you can randomize patients with submassive PE to one treatment or the other. And we want to get away from this PERT CDT roller coaster where you get enthusiasm, you do more cases, then you have a complication, then the number of cases drops.
You want that to be consistent because you're basing it on data. And that's where we're trying to come up with a way of answering that with this PE-TRACT trial. Which is a RCT of CDT versus no-CDT. We're looking at clinical endpoints
rather than radiographic ones greater than 400 patients, 30 to 50 sites across the country. So in summary I hope I've convinced you that we need a Prospective Registry for massive PE and a Randomized Controlled Trail for submassive PE. Thank you.
- Thank you, thanks for the opportunity to present. I have no disclosures. So, we all know that wounds are becoming more prevalent in our population, about 5% of the patient population has these non-healing wounds at a very significant economic cost, and it's a really high chance of lower extremity amputation
in these patients compared to other populations. The five-year survival following amputation from a foot ulcer is about 50%, which is actually a rate that's worse than most cancer, so this is a really significant problem. Now, even more significant than just a non-healing wound
is a wound that has both a venous and an arterial component to it. These patients are about at five to seven times the risk of getting an amputation, the end patients with either isolated venous disease or isolated PAD. It's important because the venous insufficiency component
brings about a lot more inflammation, and as we know, this is associated with either superficial or deep reflux, a history of DVT or incompetent perforators, but this adds an increasing complexity to these ulcers that refuse to heal.
So, it's estimated now about 15% of these ulcers are more of a mixed etiology, we define these as anyone who has some component of PAD, meaning an ABI of under point nine, and either superficial or deep reflux or a DVT on duplex ultrasound.
So we're going to talk for just a second about how do we treat these. Do we revascularize them first, do we do compression therapy? It has been shown in many, many studies, as with most things, that a multi-disciplinary approach
will improve the outcome of these patients, and the first step in any algorithm for these patients involves removing necrotic and infected tissue, dressings, if compression is feasible, based on the PAD level, you want to go ahead and do this secondary, if it's not, then you need to revascularize first,
and I'm going to show you our algorithm at Michigan that's based on summa the data. But remember that if the wounds fail to heal despite all of this, revascularization is a good option. So, based on the data, the algorithm that we typically use is if an ABI is less than point five
or a toe pressure is under 50, you want to revascularize first, I'll talk for a minute about the data of percutaneous versus open in these patients, but these are the patients you want to avoid compression in as a first line therapy.
If you have more moderate PAD, like in the point five to point eight range, you want to consider compression at the normal 40 millimeters of mercury, but you may need to modify it. It's actually been shown that that 40 millimeter of mercury
compression actually will increase flow to those wounds, so, contrary to what had previously been thought. So, revascularization, the data's pretty much equivocal right now, for these patients with these mixed ulcers, of whether you want to do endovascular or open. In diabetics, I think the data strongly favors
doing an open bypass if they have a good autogenous conduit and a good target, but you have to remember, in these patients, they have so much inflammation in the leg that wound healing from the surgical incisions is going to be significantly more difficult
than in a standard PAD patient, but the data has shown that about 60% of these ulcers heal at one year following revascularization. So, compression therapy, which is the mainstay either after revascularization in the severe PAD group or as a first line in the moderate group,
is really important 'cause it, again, increases blood flow to the wound. They've shown that that 40 millimeters of mercury compression is associated with a significant healing rate if you can do that, you additionally have to be careful, though,
about padding your bony areas, also, as we know, most patients don't actually keep their compression level at that 40, so there are sensors and other wearable technologies that are coming about that help patients with that, keeping in mind too, that the venous disease component
in these patients is really important, it's really important to treat the superficial venous reflux, EVLT is kind of the standard for that, treatment of perforators greater than five, all of that will help.
And I'm not going to go into any details of wound dressings, but there are plenty of new dressings that are available that can be used in conjunction with compression therapy. So, our final algorithm is we have a patient with these mixed arterial venous ulcers, we do woundcare debridement, determine the degree of PAD,
if it's severe, they go down the revascularization pathway, followed by compression, if it's moderate, then they get compression therapy first, possible treatment of venous disease, if it still doesn't heal at about 35 weeks, then you have to consider other things,
like biopsy for cancer, and then also consider revacularization. So, these ulcers are on a rise, they're a common problem, probably we need randomized control trials to figure out the optimal treatment strategies.
- I have nothing to disclose but what I will tell you is that the only way for me to learn the mechanics of treating low-flow malformations has been to learn from Wayne, follow what he's doing, and basically what I've done is I've filmed every single step he's taking,
dissect that, and then present you the way that he's doing it. The best way to do that is not listen to Wayne, but to film him, and just to check that afterwards. And he goes regularly to Cairo, this is the place of Dr. Rodovan sitting here
in front of us, and with Dr. Alaa Roshdy. I've learned a lot there from Wayne. This is Wayne's techniques, so normally if you look at puncture, the low flow malformations here then you get return or you aspirate so this is what happens, they inject contrast then they find volume
and inject whatever agent you prefer to inject. It happens to be alcohol but that is not essential. More often than not, there is no return. What to do then? There is a technique that Wayne has developed. Stab-Inject-Withdraw, just under high modification inject,
identify that you're not outside the vessel, get the vessel, start to fill slowly, and identify that and inject the alcohol. Of course you can do that under exposure just to see the effect of the alcohol thrombosing, et cetera.
Another example of no return is to subcutaneously certainly show that there is a low pressure system, and again, Stab-Inject-Withdrawal, and there is a cyst. Is it extravasation or is the malformation aspirate? And if it collapses, that's the malformation.
And then continue to fill in with contrast, define how big the malformation is, and then accordingly inject the amount of abrasive agent that you're using. Lymphatic malformation is very difficult to treat because the vessel's so small, would say microscopic,
and again, Stab-Inject-Withdraw, identify that it's not extravasating but it is the vessel, and start slowly, slowly to fill and any time in doubt that should there, just do a run, identify, and that is the vessel, or the network of the vessels and
start to fill that with the agent you're using. But there are certain zones that just don't inject anything, and these are the arteries. How often do arteries occur? When you puncture them. I just directly looked at all these 155 patients I've seen Wayne treat there a matter of,
I would say, 100 patients in three days. 30 patients per day, that's about six percent. And you see the artery by pulsating flow depending on the pressure that you apply. And we see again the artery pulsating and we have no doubt about that.
However, it could be difficult to see. Depending on how much you push in the contrast and you see these being ornery so there's a No-Go-Zone, no injection of any agent and again, a tiny bit of lottery there in the foot could be disastrous.
You inject any agent, any, you will have ended up with necrosis of course if you don't inject inhibitors, but not yet. The humorous may not end up with necrosis when all the mysticism with puncture will be gone. So we have extravasation, when you say extravasation
like starting injecting, still good, looking good, but you see how the extravasation even blows up and at the end it bursts, again under pressure they should apply, so pressure is really important to control and then you stop and don't inject any more.
Extravasation, you see how its' leaking in the back there, but you correct the position of the needle, identify all the vessels, the tiny little vessels, just have to be used to identify the pattern and then you start to inject the agent again.
Control is very essential. Here is the emphatic malformation labia and though there is this tiny little bity extravasation you continue because there is you know, run-off, it is filling the system and you can safely inject the alcohol.
Intraarticular could be malformation there and this is definitely safe pla however, if it is in the free space in the the joint, that's again, it's No-Go-Zone. How you see that is just be used to
the pattern recognition and you find that this is free. It's around the condyle there so there is no injection. Compression is again good to note to control by compression where the agents go. This is a normal vein, certainly at risk of getting with alcohol, whatever agent
you're using deep in the system, avoid that by compression. Compression can be applied manually and then that gives you a chance to fill the malformation itself and not strike connection too deep in the system. Intraosseous venous malformation,
low-flow malformations can occur anywhere, here in the spine and the axis is transpedicular patient prone because it's soft. The malformation has softened up the bone. You can just use a 21-gauge needle and identify the malformation and follow
by the agent you're using. Peculiar type of venous malformation called capillary venous malformation. Basically it's a low-flow malformation without any shunt here in the sciatic notch of the patient and geography shows that there is no shunt
there is just big veins and intense pacification. And identify the veins by indirect puncture again, see the pattern of that and inject alcohol and following geography we can see that there has decreased the density but it is a lot more left to be done.
In conclusion, direct puncture is the technique in this low-flow malformation but Stab-Inject-Withdraw is the really helpful technique for successful treatment of microvascular, microcystic lesion. No-Go-Zones for certain when you see arteries
and anytime in doubt you just have to do a run to identify if they're arteries or not. Intraarticular free space and extravasation and normal veins, similarly, No-Go-Zone. Capillary venous, intraosseous malformations can be treated successfully. Thank you.
(audience applause) - [Facilitator] Thank you, Crossey. Excellent talk, very practical and pragmatic. Any comments or questions? Dr. Yakes. - [Dr. Yakes] We have been to many meetings and people have talked about doing
other ultrasound guides, accessing the malformations. You'll never see those arteries by ultrasound. - [Facilitator] That's absolutely correct. I concur. I concur and I think some of the disasters we've seen where suddenly something falls off
have been in these situations because they don't understand or in expansile foam-based therapies, I've seen that. I've seen plenty of these, so it's always present, potentially.
- Thank you so much. We have no disclosures. So I think everybody would agree that the transposed basilic vein fistula is one of the most important fistulas that we currently operate with. There are many technical considerations
related to the fistula. One is whether to do one or two stage. Your local criteria may define how you do this, but, and some may do it arbitrarily. But some people would suggest that anything less than 4 mm would be a two stage,
and any one greater than 4 mm may be a one stage. The option of harvesting can be open or endovascular. The option of gaining a suitable access site can be transposition or superficialization. And the final arterial anastomosis, if you're not superficializing can either be
a new arterial anastomosis or a venovenous anastomosis. For the purposes of this talk, transposition is the dissection, transection and re tunneling of the basilic vein to the superior aspect of the arm, either as a primary or staged procedure. Superficialization is the dissection and elevation
of the basilic vein to the superior aspect of the upper arm, which may be done primarily, but most commonly is done as a staged procedure. The natural history of basilic veins with regard to nontransposed veins is very successful. And this more recent article would suggest
as you can see from the upper bands in both grafts that either transposed or non-transposed is superior to grafts in current environment. When one looks at two-stage basilic veins, they appear to be more durable and cost-effective than one-stage procedures with significantly higher
patency rates and lower rates of failure along comparable risk stratified groups from an article from the Journal of Vascular Surgery. Meta-ana, there are several meta-analysis and this one shows that between one and two stages there is really no difference in the failure and the patency rates.
The second one would suggest there is no overall difference in maturation rate, or in postoperative complication rates. With the patency rates primary assisted or secondary comparable in the majority of the papers published. And the very last one, again based on the data from the first two, also suggests there is evidence
that two stage basilic vein fistulas have higher maturation rates compared to the single stage. But I think that's probably true if one really realizes that the first stage may eliminate a lot of the poor biology that may have interfered with the one stage. But what we're really talking about is superficialization
versus transposition, which is the most favorite method. Or is there a favorite method? The early data has always suggested that transposition was superior, both in primary and in secondary patency, compared to superficialization. However, the data is contrary, as one can see,
in this paper, which showed the reverse, which is that superficialization is much superior to transposition, and in the primary patency range quite significantly. This paper reverses that theme again. So for each year that you go to the Journal of Vascular Surgery,
one gets a different data set that comes out. The final paper that was published recently at the Eastern Vascular suggested strongly that the second stage does consume more resources, when one does transposition versus superficialization. But more interestingly also found that these patients
who had the transposition had a greater high-grade re-stenosis problem at the venovenous or the veno-arterial anastomosis. Another point that they did make was that superficialization appeared to lead to faster maturation, compared to the transposition and thus they favored
superficialization over transposition. If one was to do a very rough meta-analysis and take the range of primary patencies and accumulative patencies from those papers that compare the two techniques that I've just described. Superficialization at about 12 months
for its primary patency will run about 57% range, 50-60 and transposition 53%, with a range of 49-80. So in the range of transposition area, there is a lot of people that may not be a well matched population, which may make meta-analysis in this area somewhat questionable.
But, if you get good results, you get good results. The cumulative patency, however, comes out to be closer in both groups at 78% for superficialization and 80% for transposition. So basilic vein transposition is a successful configuration. One or two stage procedures appear
to carry equally successful outcomes when appropriate selection criteria are used and the one the surgeon is most favored to use and is comfortable with. Primary patency of superficialization despite some papers, if one looks across the entire literature is equivalent to transposition.
Cumulative patency of superficialization is equivalent to transposition. And there is, appears to be no apparent difference in complications, maturation, or access duration. Thank you so much.
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