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How To Decrease Radiation Exposure To Operators And Assistants During Standard And Complex EVARs
How To Decrease Radiation Exposure To Operators And Assistants During Standard And Complex EVARs
advancedavoidingceliacdeclineddiagnosticdiscoverydoseendovascularevarfenestratedfindingfluoroscopicfluoroscopyframesfusionidealimagingminimizeminimizingoperatorpreoperativeradiationseptumstentsystem
Update On The Advantages, Limitations And Midterm Results With The Terumo Aortic 3 Branch Arch Device: What Lesions Can It Treat
Update On The Advantages, Limitations And Midterm Results With The Terumo Aortic 3 Branch Arch Device: What Lesions Can It Treat
4 branch CMD TAAA deviceacuteAscending Graft Replacementcardiac arrestRelayBranchRepair segment with CMD Cuffruptured type A dissection w/ tamponadestent graft systemTerumo Aortictherapeutic
Terumo Aortic Relay Thoracic Endograft For TEVAR In Complex Aortic Pathology With Angles >90°: Advantages And Results
Terumo Aortic Relay Thoracic Endograft For TEVAR In Complex Aortic Pathology With Angles >90°: Advantages And Results
Gore Tag (Gore Medical) / Valiant (Medtronic) / Zenith Alpha (Cook Medical)RelayPlusstent graft systemTerumo Aortictherapeutic
Octopus Technique To Treat Urgent Or Ruptured TAAAs With OTS Components: What Is It, Technical Tips And Results
Octopus Technique To Treat Urgent Or Ruptured TAAAs With OTS Components: What Is It, Technical Tips And Results
6.8 cm TAAAGORE MedicalGore Viabahn VBXOctopus Endovascular Techniquestent graft systemtherapeuticviabahn
Rifampin Soaked Endografts For Treating Prosthetic Graft Infections: When Can They Work And What Associated Techniques Are Important
Rifampin Soaked Endografts For Treating Prosthetic Graft Infections: When Can They Work And What Associated Techniques Are Important
2 arch homograftsOpen Ilio-Celiac bypassSacular TAA ; Endograft AbscessTAAA repair with left heart bypassTEVARtherapeutic
Value Of Parallel Grafts To Treat Chronic TBADs With Extensive TAAAs: Technical Tips And Results
Value Of Parallel Grafts To Treat Chronic TBADs With Extensive TAAAs: Technical Tips And Results
GORE MedicalGORE VIABAHNL EIA-IIA bypassleft carotid subclavian bypassstent graft systemTBAD with TAAAtherapeutic
How To Perform Endograft Repair Of TAAAs Using Branched Endografts Entirely Via Femoral Access: The Secret Is The Use Of Steerable Sheaths
How To Perform Endograft Repair Of TAAAs Using Branched Endografts Entirely Via Femoral Access: The Secret Is The Use Of Steerable Sheaths
Cook MedicalEndograft Repair using Steerable SheathGore Excluder TAMBE (Gore Medical) / Xtra-Design (Jotec)Irregular Orifice of the Right Renal Arterystent graft systemtherapeuticZenith T-Branch
Transcript

- Thank you very much for having me speak and thank you for coming this late in the day for this talk. These are my disclosures. This is our current operating system with advanced imaging and this is GE Discovery IGS 740. You can see you have fusion imaging,

you have the capacity to use combined CT. What I would like to talk to you today is about how we were significantly decrease radiation over the years. What you are seeing on this graph is my personal volume of endovascular cases. In the solid bullets you've the number of fenestrated cases

which have steadily increased over the years and in the empty rounds you've the number of any endovascular case. So what this is saying is that I am doing more fenestrated than more standard endovascular cases. And nowadays these cases are becoming more complex.

You're seeing here the number of vessels incorporated went from 2.9 all the way to 3.7 per patient. Now, at the same time, I did get better over the years. You can see that the fluoroscopy time for the procedures declined after two or three years of experience but it plateaued in 2012.

So, basically, since 2012, I am not doing these cases any faster with any last fluoroscopy time. So any change in the operator or in the patient radiation exposure would be attributed to other factors but the technique. You can see here the effective dose over the years

has dramatically declined from system 1 to system 2 to now system 3 in the blue that is the GE Discovery system to approximately 1/3rd to 1/4th of our baseline dose in the first beginning of the experience. We also recorded the operator dose over the year and you can see here that my radiation dose

has significantly declined again to about 1/3rd to 1/4th of the beginning of the experience. So, how did we achieve this improvement? I will go for eight golden rules, first is doing your work ahead of time, finding out the ideal work positions, using and leveraging all preoperative cross-sectional

imaging that you've, numerous of speakers have already talked about that, our highlights the importance of lead shooting with the work of Dijon which has a thing being remarkable contribution to the understanding of this. Optimize the system geometry, I think is very important avoiding work with the detector too high, the table low

as the abstracted on these illustration or the opposite with the table too high and really finding your way to the optimal geometry. I am sorry I advanceed, the slide is wrong way. Using the ideal dose rate, you can see here that the ideal dose rate in most operators has been down

now to 7.5 frames per second, and in some systems even 3.75 frames per second. We tend to use 7.5, we found this to be the soft spot with our system. ONLAY fusion has been also an important aspect in terms of facilitating the procedure, you're seeing

a segment of a patient before chronic dissection where you're leveraging the fusion to find the septum of trolloming using a reentrance device and really minimizing the amount of contrast and minimizing fluoroscopy, finding your ideal work position or with the use of these landmark markings

than with the fusion. Finally, nice feature of the system is the digital zoom. We really rarely magnify. What you're seeing here is a basically, digitally zoom different than magnification, so that really has allowed us to keep the dose very low

coupled with the collimation. And I think, this is a nice feature. We really avoid using DSAs unless you've to interrogate vessel. It is important to remember that 1 DSA is equivalent to approximately 500 fluoroscopic look.

So, what you're seeing here is the interrogation of a left renal stent done with a fluoroscopic loop as opposed to DSA. And, that is again a very important aspect. Avoiding high angulations wave when you're working in the sma or the celiac axis, we actually tend to that often

with the AP as opposed to the lateral view as soon as you can, you kind of transfer the image to the AP view to minimize radiation. So, in summary, we came a long ways, in terms of standard and complex EVAR where living now in a narrate that we've better devices, we've cross sectional imaging and we've

advanced image and I think we need to leverage all these three aspects to minimize radiation. Thank you very much

- 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.

- Thank you Rod and Frank, and thanks Doctor Veeth for the opportunity to share with you our results. I have no disclosures. As we all know, and we've learned in this session, the stakes are high with TEVAR. If you don't have the appropriate device, you can certainly end up in a catastrophe

with a graph collapse. The formerly Bolton, now Terumo, the RelayPlus system is very unique in that it has a dual sheath, for good ability to navigate through the aortic arch. The outer sheath provides for stability,

however, the inner sheath allows for an atraumatic advancement across the arch. There's multiple performance zones that enhance this graph, but really the "S" shape longitudinal spine is very good in that it allows for longitudinal support.

However, it's not super stiff, and it's very flexible. This device has been well studied throughout the world as you can see here, through the various studies in the US, Europe, and global. It's been rigorously studied,

and the results are excellent. The RelayPlus Type I endoleak rate, as you can see here, is zero. And, in one of the studies, as you can see here, relative to the other devices, not only is it efficacious, but it's safe as well,

as you can see here, as a low stroke rate with this device. And that's probably due to the flexible inner sheath. Here again is a highlight in the Relay Phase II trial, showing that, at 27 sites it was very effective, with zero endoleak, minimal stent migration, and zero reported graph collapses.

Here again you can see this, relative to the other devices, it's a very efficacious device, with no aneurism ruptures, no endoleaks, no migration, and no fractures. What I want to take the next couple minutes to highlight, is not only how well this graph works,

but how well it works in tight angles, greater than 90 degrees. Here you can see, compliments and courtesy of Neal Cayne, from NYU, this patient had a prior debranching, with a ascending bypass, as you can see here.

And with this extreme angulation, you can see that proximally the graph performs quite well. Here's another case from Venke at Arizona Heart, showing how well with this inner sheath, this device can cross through, not only a tortuous aorta, but prior graphs as well.

As you can see, screen right, you can see the final angiogram with a successful result. Again, another case from our colleagues in University of Florida, highlighting how this graph can perform proximally with severe angulation

greater than 90 degrees. And finally, one other case here, highlighting somebody who had a prior repair. As you can see there's a pseudoaneurysm, again, a tight proximal, really mid aortic angle, and the graph worked quite well as you can see here.

What I also want to kind of remind everybody, is what about the distal aorta? Sometimes referred to as the thoracic aorta, or the ox bow, as you can see here from the ox bow pin. Oftentimes, distally, the aorta is extremely tortuous like this.

Here's one of our patients, Diana, that we treated about a year and a half ago. As you can see here, not only you're going to see the graph performs quite well proximally, but also distally, as well. Here Diana had a hell of an angle, over 112 degrees,

which one would think could lead to a graph collapse. Again, highlighting this ox bow kind of feature, we went ahead and placed our RelayPlus graph, and you can see here, it not only performs awesome proximally, but distally as well. And again, that's related to that

"S" shaped spine that this device has. So again, A, it's got excellent proximal and distal seal, but not only that, patency as well, and as I mentioned, she's over a year and a half out. And quite an excellent result with this graph. So in summary, the Terumo Aortic Relay stent graph is safe,

effective, it doesn't collapse, and it performs well, especially in proximal and distal severe angulations. Thank you so much.

- Thank you, honored to present this work on behalf of our group at the VA, the Michael E. DeBakey VA in Houston, led by Dr. Kougias. Disclosures are here, Dr. Kougias does consultation for Cook Medical. So compared to EVAR, FEVAR has greater lower extremity ischemic times due to larger sheaths,

visceral cannulation, complexity of procedures. And lower extremity complications have been reported as high as 15%, but there's not been a careful analysis of this. So we decided to look at the incidence of lower extremity sensory or motor deficit

after FEVAR, and to look specifically at lower extremity ischemic time, iliac artery occlusive disease, and lower extremity neurologic impairment after FEVAR. So this is a retrospective study over a four-year period. Early experience with our FEVAR cases was included,

and we generally used bilateral femoral access. Iliac stenotic lesions were dilated when required to allow an 18 or 20 French sheath to be placed. Graft alignment was achieved by centering the graft over at least two sheaths in the visceral arteries

before releasing the diameter-reducing wire. Visceral stents were used for all fenestrations and selectively for some scallops. We used perfusion adjunct techniques selectively, such as antegrade 7 French sheath placement into the FSA or sometimes a Dacron conduit into the common

femoral artery, which allows you to retract the sheath. A primary outcome was neurologic impairment. Secondary outcomes were major amputations and ability to ambulate at 30 days after surgery. We measured continuous lower extremity ischemic time from the time of the large sheath insertion into

the femoral artery until it was removed. If we used perfusion adjuncts, we measured the time from the sheath insertion to the perfusion initiation via the adjunctive modality, and the longest ischemic time for each extremity was recorded. We measured common iliac artery lumen diameters.

It was the distance of inner wall to inner wall, the narrowest segment of each common iliac artery. And we entered this as a binary variable based on eight millimeters. Statistics, we did both uni- and multivariate analysis, and I'll just run through that here quickly.

And we did an interaction model looking at the association between lower extremity ischemic time, size of the residual patent common iliac artery lumen versus neurologic impairment in the lower extremities. So there was 101 FEVAR patients with 202 limbs.

Percutaneously done in 16% of cases, we used perfusion adjuncts based on understanding of the case and how long it was going to take. Conduit in eight cases, and antegrade SFA sheath placement in three cases. The configurations are shown here.

Majority were one scallop and two fens, and the ischemic times are shown there. Operative time was about three hours was the average, but the standard deviation was 122 minutes. You can see the fluid requirements there. We looked at intra- and postoperative transfusions.

Then we looked at patients with neurologic impairment. So there were 18 patients who had some neurologic impairment postoperatively. 12 of these patients has mild sensory loss, eight has complete sensory loss, and only two had motor dysfunction.

The deficits tended to resolve within four days, almost all within 14 days. But we had four limbs with persistent sensory deficits, and only one with a persistent motor deficit. Two patients could not ambulate normally at 30 days. No patient underwent an amputation.

If you look at the univariate analysis, limb ischemic time, common iliac lumen less than eight millimeters, intraoperative blood loss, change in hemoglobin, and total transfusion all seem to indicate lower extremity motor dysfunction or sensory dysfunction.

But on multivariate analysis, there are only two factors: limb ischemic time and common iliac artery diameter less than eight millimeters. If you looked at the interaction model we prepared, if the common iliac artery diameter was less than eight millimeters after about two and

a half hours of continuous ischemia, the incidence of neurologic impairment went up. This went up more slowly if it was more than three hours if the iliac artery diameter is greater than eight millimeters. So, in conclusion, lower extremity permanent

neurologic impairment is very low after FEVAR, but there is a relatively high instance of reversible neurologic impairment associated with two things: extremity ischemic time and the presence of pre-existing occlusive disease in the common iliac artery.

We acknowledge this was a single center study. We weren't able to look at extent of aortic coverage or associated spinal cord ischemia, but we conclude that when you anticipate long ischemic times based on the iliac artery diameter, you should consider adjunctive perfusion techniques.

Thank you.

- Thank you, and thanks to Dr. Veith for the opportunity to share some of our data. These are my disclosures, some devices presented here are investigational and I want to acknowledge my friend Gustavo, who actually shared some of the slides that we'll show. And I want to reference some of his papers. So a spinal cord ischemia has been presented here

as a devastating complication, after both open and endovascular repair of thoracoabdominal aortic aneurysms. The spinal drains are routinely used to ameliorate the frequency and also the severity of spinal cord ischemia, the problem with this trains is that they may result inherent morbidity and mortality.

Now, intraoperative neuromonitoring has been used to not only monitor, but also to manage potential cases of spinal cord ischemia, this is a study by the group at the Mayo Clinic, led by Gustavo. 49 patients, of which 90% had thoracoabdominal aortic aneurysms, all these patients have spinal drain splice,

spinal cord ischemia was seen in six patients. But interestingly, 63% of the patients had significant decrease in the amplitude of both motor and somatosensory evoked potentials. And interestingly all of these changes came back to baseline except in one patient once

their lower legs were reperfused. However, and despite all of these papers that have, you know, talk about the use of spinal drains for endovascular reparative thoracoabdominal aortic aneurysms against the effectiveness of the spinal drains has not been shown.

And the aim of our study was to assess the outcomes of spinal cord protection without the routine use of spinal drains. We actually has some complications in this report, we decided that we were going to use only selectively in our series, the device is used for this in patients

were all part of a physician-sponsored investigational device exemption, demonstrating branch devices were used including the drainage device. We use a similar protocol as the one described by the Mayo Clinic group, which rely on permissive hypertension maintaining the maps above 90 or 100,

and the systolic pressures above 140. However, as mentioned, we did not place spinal drains routinely, the spinal drains were only considered in those patients that had persistent motor evoked potential deficits, at the end of the procedure. Once the legs have been reperfused, we did not use

conduits, we did percutaneous access in all patients. But of note, we did use endo conduits in all patients that have significant iliocclusive disease, not only to be able to deliver the device, but also to maintain flow to the lower extremities, to avoid distal ischemia. So 34 patients were enrolled in this study,

all patients had intraoperative neuromonitoring, and select spinal drains were placed. 10 patients, 29%, were extent 4 thoracoabdominal repairs, and 24 were extent type one to three. Important all patients with type one and three thoracoabdominal aneurysms underwent a staged repair.

We use in 20% of the cases off-the-shelf device is specifically the debranch, and 80% underwent custom made devices, all these devices were pre-loaded with wires. So, of these patients, 73 were male, 9% Type I, 38% Type II, 24% were Type III,

and 29% were Type IV. We saw significant changes in the evoked potentials in 80% of the patients. In all of them those changes came back to baseline except in one patient, who actually had a spinal drain at the end of the procedure.

30-day mortality in two patients, spinal drain was required eventually in only four patients, that's 12%. One because of sustained changes in the motor evoked potentials, spinal cord ischemia occurred in four patients, in all cases secondary to hypertension. After a procedure, in these cases two were permanent,

the cases had spinal drain splice, however, the deficit persisted, two had transient paraplegia, one resolved with permissive hypertension, and one resolved with a spinal drainage, I mean, the spinal drain was only effective in half of those patients. We did have two cases of intracranial bleeding,

associated with hypertension. So in conclusions, we don't believe that the spinal drains are necessary in all patients. A standard protocol that relies on perioperative maintenance of adequate blood pressure in intraoperative neuralmonitoring is however required.

And we believe that tight blood pressure control is mandatory to avoid possible complications related to uncontrolled hypertension, thank you.

- Thank you, my disclosure says it pertains to this Centerline Biomedical specifically. As many of you know, real-time Dose Monitoring has shown that the EVAR procedures really exposes to the most amount of radiation, Of all the endovascular procedures that we do. Obviously the complexity of those

has something to do with that. But even a straight forward EVAR shows that. And most studies show that vascular surgeons are probably the least educated and knowledgeable about ways to reduce your exposure to radiation. Now Gustavo talked about this,

when you look at the radiation scatter when you're in a hybrid room you see that once the imaging intensifier moves to anything other than AP position the amount of scatter starts to increase. And it's that scatter which exposes most of us

that are near the patient to this. In addition, I will tell you that most of your patients that we operate on were right near the imaging beam, where as most peripheral interventions we do step out of the room,

during any of the major flouroscopic treatment time in DSA angiograms, as Gustavo said. So what can you do from protection strategy standpoint? Well you can use protective equipment, which includes drapes and shielding which I go over.

But the majority of it is what procedural details much of which Gustavo has gone over. Now in our institution I highlighted two things there, for many years I've used the zero gravity suit this has two advantages, number one it covers your head from exposure,

but it does not extend down to below the legs and I'll talk about that. I know that Bijan is on the podium and he probably has better education, and can talk more about his study than I know. But we have added leggings to that aspect.

The other thing about the Zero Gravity Suit is from a longevity for you as a physician you do not have the weight of the lead on your shoulders so over time the amount of neck and injuries from that aspect is probably going to be decreased. Now this is taken from Bijan's paper

it's about the Radiation Induced DNA Damage and you can see that patients that are people that did EVAR procedures had an increase in the amount of radiation damage, compared to if they did an open repair. And you can see the difference there

in purple between EVAR and branched and fenestrated repairs but the most important thing, I think that many of us took away from his paper, was that when you added leggings to it you can see in the bottom left, the amount

of radiation and DNA damage was the same. But the amount of DNA damage went way down on the black bars there, compared to the red bars pre-imposed. So why that was, is probably the subject of many more papers

and a lot of grant money for Bijan to do. I think this is going to be a very important topic in the next several years. Now Gustavo had eight things, I have a list of ten things that you can do, to help during procedure. But the biggest as he mentioned, was the

obliquity of the orientation of the tube. Eye protection is a very important approximately about 30% of the radiation comes around your eye protection wear. So either using the shield like I showed you from zero gravity, or side shields are very important.

You need to save images, optimize images use non DSA or exit the room for DSA things. Varying the technique, adding barriers, slow your frame rate down. Now Gustavo says, he said seven and a half or typically a two.

If I wanted to get a better image I will go to three or to a seven. But generally we are at two frames per second for most of our work. I unfortunately do not have yet digital zoom that's probably coming in the next version

of the models that we use. Increasing the table height, getting the table high and the imaging intensifier down is very important. What about other things? Well we have to change our habits,

most of this is getting in the right habit. And most of our radiation badges tell us a month later what happened. But we don't know what case and what we did during the case to change it. That's more modern day badges,

this is an early detection system. Basically you see your dose on the screen, as the case is going along. And it gives you direct feedback that you might need to change what you're doing. Add barriers to between you and the source

so when your dose is going higher than other people in the room. It's kind of like the concept of the canary in the coal mine. When the canary is starting to have problems and went to the bottom of the cage

the coal miners new that they needed to get ut of the coal mine because they were being exposed to lethal gasses. So what does this do? If you look at the dose aware data, it shows you here in purple

that the level of radiation exposure, once they started to use the Dose Aware, went down compared to the number of incidents of over-exposure, in the system. Gustavo talked a little bit about Intra-Operative Guidance,

vessel deformation, and customized options. Are coming down the guidelines. And you can see this is a paper with Stephan Haulon and Rob Rhee about how they reduced their dose. Lastly we need to think about moving

away from fluoroscopy and this is what's coming down the future, with Centerline Biomedical. Using electro-magnetic navigation to track devices, cathers, and wires through the system, Without ionizing radiation. And this will be the future.

So in conclusion, current advancements in vascular therapy significantly increase the exposure of vascular specialists, to the harmful effects of ionizing radiation. Maximal efforts should be employed by proceduralists to protect themselves.

Including the legs, and the neck, and the head. An immediate intra-procedural feedback is important for developing proper techniques and prevention. Future research should be focused at identifying non-ionizing methods for navigation and device implantation.

Thank you.

- I have no disclosures. - So the eye lens is a highly radiosensitive tissue. And the radiation damage is a cataract, this is a cancer-like pathology resulting from mutating events. It's a posterior sub-capsular cataract. And in several studies we have seen quite a large number of interventionalists or vascular surgeons or cardiologists

showing this exact type of posterior lens changes, characteristic of radiation exposure. About half of the interventionalists in this study. The risk increases with duration of work years and decreases with regular use of protection. So the conclusion in this paper was

that radiation injuries to the lens can be avoided. By, for example, reducing the dose. So this is obvious that we should do in every way we can do it. And there are many steps shown in this excellent paper published in the European Journal of Vascular Surgery.

And, on top of that, of course, use radiation shields. And I've been focused today on different eye shields. So we tested the eye dose reduction with several commercially-available protection glasses and shields during realistic endovascular procedures in an experimental setting,

using phantoms and dosimeters at the front of the eyes, the left and the right eyes. And this was an EVAR protocol using a Siemens C-arm. So we tested the more modern sports glasses. The reduction to the left eye was only 15 to 50 percent, or in some glasses just 10 to 15 percent.

So much, much lower than what's promised in the brochure. The fit over glasses protected best, especially if you don't use them over personal glasses. So this is because of the, it's if there is just a small gap between the cheek and the glasses, there's scattered radiation pulsing in there.

And it also scatters on your face up to the eye lens. We also tested visors and you can see the effect of having them at a correct angle. They should be downward-angled, and you have a pretty good protection. But the best of all was the ceiling-mounted shield,

if it's properly used with a very high reduction, 90 to 95 percent. So this is an image from our hospital. I'm in the middle with these fit-over glasses that we have all now beginning to use. So in this paper, it was nicely shown that the position

of the shield also is very important. So it should be very tight to the patient and close to the femoral access. Other protective measures like these surgical drapes, we use them and there is a good additive reduction of radiation exposure

to the chest and hands, shown by this paper. But no one has ever related the reduction to the head or the eye. And the latest addition in our center is this zero-gravity suit that has been shown to significantly reduce radiation exposure

to the whole body, including the head and the eyes. So I think this is a very important new device. In this study, from the London group, we can see that adherence to use these kinds of shields is depressingly low. Use of lead-protective glasses was only 36 percent

among the operators and ceiling-mounted leaded shields, no one uses them, at that time at least. So, in conclusion, there are several radiation protection eyeglasses used today. They offer a highly limited dose reduction, giving a false sense of security.

A proper use of ceiling mounted lead shields is essential for adequate protection to the eye lens. And the protection eyeglasses and visors should only be used as a complement. And consider also using additional devices as full-body protection to maximize your protection, thank you.

- When stenting are not enough, venoplasty stenting is undoubtedly the treatment of choice in relieving iliocaval obstruction and we have no doubt on what we can technically today obtain with this technique. But open surgery still has a place. The place for the iliocaval segment is today limited

only to oncological patients, their trauma. The disease, given by PTS, is not justifying an open surgery on those segments. But in some cases, at least less than ten percent in our federal center like we are, endovascular technique alone may be not sufficient

to provide durable patency of the iliocaval stenting. An open surgical approach, limited to the common femoral vein, can be required in addition to iliocaval stenting. And I would like to underline that open surgery should not be confused with open access

in event of catheterization failure. It's completely different. At the end, what we apply is endophlebectomy, which is the surgical removal of intraluminal fibrotic tissues. And contrapulizes of the extraluminal damage.

After endophlebectomy, the caliber of the vein is restored by means of bovine pericardium patch. In order to go back to the normal anatomy. Which are the indications for this type of operation? The main indication is to improve the inflow. When the deep femoral system confluence

is inadequate or the axial system is not preserved we have to try to improve the inflow at that level. And it is an essential moment to get a stable patency in the iliocaval segment. The second indication is to provide sufficient room for adequate stent expansion.

If there is lots of rubber and hard tissues that occupies the commofemoral vein, maybe in the long term, the stent can be sufficiently, adequately expanded. And if we remove this tissue we can get a better stent deployment.

The third indication is to reconstruct the vein conduit when it has been lost. This may happen after trauma, after drug injection, and after heterogenic problem. When the vein wall is too damaged, to be treated only by stenting or

only by endophlebectomy, a new conduit can be maybe the better option. What we apply today is a tubulization of bovine pericardium in order to obtain a correct way. And this is probably what we have to underline much more than everything else,

it is a type of hybrid procedure. The operation of endophlebectomy on new oxcilization are rarely performed alone today. We should go down with the stent if required to cover the endophlebectomy area and to treat iliac obstruction in the same moment.

As we listen before, the endophlebectomy limits is to open up the deep femoral conference and the stent usually stop over there. And it is essential because at the present, if we do not apply this, we can say, a kind of protection way to treat

the endophlebectomy segment, its difficult to maintain a long term patency. In this type of operation at the present, we do not apply anymore AV fistula which was limited in our historical work. I would say that today, open surgery

and hybrid procedures are essential in post traumatic treatment strategy. Outcomes in complex cases can be strongly improved. And I would like to underline that it is complex cases. This is not a surgery that is applied in every case of iliocaval stenting.

Its, there has to be attentively, selected because this type of surgery is undoubtedly very delicate, but we can get very good results and despite what we can think, get a good patency over time. It can really today be something

that we can obtain quite attentively. Thank you so much.

- Well, thank you Dr. Veith, and thank you very much for allowing me to speak on the topic. I have no disclosures. This is a nice summary that Dr. Veith is actually second author, that summarize what we know about predicting who will benefit from intervention among the patients with asymptomatic aortic disease.

You look at this eight means that we have, you realize that only one of those related to the fluid deprivation. The rest of them are related to embolic events. And that's very interesting because we know that antiplatelets have very little effect

on prevention of this. That's summarizing that review. Partially because what we focused on is that mechanism of thrombosis which requires platelet activation and attachment to the wall.

And that's where those antiplatelets that we use, act upon. However, you realize if you just look at the any ultrasound, that because of the velocities that we have and the lengths of the stenosis in carotid disease there is no way how the platelets can be attached to that

due to that mechanism. They just fly away too fast and don't have any time to do this. And it's even more because all the studies, basic science, show that at those shear rates that we have in carotid disease

that is more that 70%. There is very little probability of either platelet attachment or Von Willebrand factor attachment, or as a matter of fact even fibrinogen attachment in that particular area. So on the other hand we also know

that at those shear rates that we have, the Von Willebrand factor molecules unfold revealing tens of thousands more adhesive sites that allow them, not only to the platelets but also to the wall at that particular spot. And then the most likely mechanism

of what we dealing with in the carotid disease is this that the Von Willebrand factor attach and this unactivated platelets form conglomerates which can easily, because they don't attach to each other, easily fly. And that is probably one of

the most likely causes of the TIA. So if you look at the antiplatelet that we use on this particular mechanism, is right here. And those aspirin and clopidogrel, and combination of those we usually use, have very little, if any, effect on this particular mechanism.

So if, on the other hand, you can see that, if you specifically address that particular site you may have a much substantial effect. Now, how can we identify it? Well actually, the calculation of near-wall shear rate is quite simple.

All you need is just highest velocity and smallest diameter of the vessel. Of course, it is an estimate and actual shear rate is much higher but that's even more, because you, better than you prevent, more higher rate. Just to demonstrate, you can have the same velocity,

similar velocity, but different diameters. This stenosis technique will give different shear rate, and vice versa. So it's not really duplicating neither one of them. So we decided to look at this. We did a case control study that was published,

still online in the Journal of Vascular Surgery. And what you can see on the ROC curve, that in fact shear rate predicts symptomatic events much better than either velocity or the degree of the stenosis. And we look specifically at this group

with this thresh point of 8,000 per second and you can see that those patients who have those shear rates and the stenosis are 12 times more likely to have ischemic events. We look at the other means like microembolism. It's ongoing study, it's unpublished data that I show you.

And it's a very, very small sample but so far we have the impression that those microemboli that we can decide for, make a decision for intervention, actually happen only in this category of patient that have high shear rate. Based on this, this is our proposed algorithm,

how we deal with this. If you have asymptomatic patients with more than 70% degree of their stenosis and shear rate that exceeds certain level, we think it's about 8,000 per second, that may be an indication for intervention.

On the other hand if you a have lower shear rate then you can use other means. And what we use is microembolis per hour. Then you can duplicate their areas. If TCD on the other hand is normal you can continue best medical therapy and repeat the ultrasound in a year.

It's arbitrary. This is proposal agreed and based on our studies and that's, I'm thankful for the opportunity to share it with you. Thank you very much.

- Okay, thank you very much. I appreciate the invitation from Dr Veith to discuss this technique and really, this is a how to do it technique. These are my disclosures. So we know that if you're doing a type B dissections that are chronic and you're going to use a fenestrated

device often times you have vessels that are on the false lumen that are not easily accessible. You can see in this picture up above, here's you're flap, this is the right renal artery across the fenestration and you can't really see the actual original fenestration.

There can also be some misalignment between the natural fenestration and where you want to put your fenestration. So this technique allows us to create a neo-fenestration at your site of choice. So here's our stent graft planning in this particular patient.

Here's the dissection flap, here's our graft in the true lumen with the SMA and celiac and the right renal. We've placed the fenestration for the left renal right opposite the left renal artery. And this is a schematic representation of

our in press article. Basically once you've accessed the bottom of the graft you can use a steerable directional sheath and put it right at the level of your fenestration. Use the power wire from Baylis, and what you do is put it right up against the graft.

It's like a cautery, you step on the pedal, it gives a one second burst and that goes across the flap. You can then widen it and then connect your stent graft. This is an example of one of our early cases. Here you can see injection in the true lumen with the right renal, you can't see the left renal,

that's bowel gas and another one of the true lumen branches. You can see with the fusion imaging we've now been able to put the graft, the right renal and the graft expanded. Here you can see an injection and we've got our catheter right up against the left renal fenestration. And here you can next see, the power wire,

the tip of the power wire is just at the edge of the catheter. And if you step on the pedal you can see that the power wire goes across into the false lumen right near here, you can inject your false lumen, you can see your renal

and after that you can see that we've now accessed the artery. We balloon it and then stent it. So these are the tools that are required. You need the power wire generator, you need the power wire itself,

you need a pad on the patient just like a cautery pad, and an Oskar or other steerable sheath is very effective in helping you. A short pulse in one second is usually enough to cross the lumen. Here's a second example.

A patient again with a false lumen, the right renal artery is the one this particular time. You can see the dissection flap is here. We planned the fenestration right opposite the renal artery.

And you can see here similar technique with the catheter. The power wire is already actually been deployed across the channel and then put in place. So this is a relatively simple technique that you can use to access false lumen branches. It allows planning the fenestration on your pre-op plan

close to the target vessel, and it assists you when the natural fenestration is not visible, or misaligned. And it uses an existing technique that we've used for left subclavian in situ fenestration and for some aortic dissection acute cases where you need to fenestrate the false lumen.

Thank you.

- Thank you, Mr. Chairman. Good morning ladies and gentleman. I have nothing to disclose. Reportedly, up to 50 percent of TEVARs need a left subclavian artery coverage. It raises a question should revascularization cover the subclavian artery or not?

It will remain the question throughout the brachiograph available to all of us. SVS guidelines recommend routine revascularization in patients who need elective TEVAR with the left subclavian artery coverage. However, this recommendation

was published almost ten years ago based on the data probably even published earlier. So, we did nationwide in patient database analysis, including 7,773 TEVARs and 17% of them had a left subclavian artery revascularization.

As you can see from this slide, the SVS guideline did affect decision making since it was published in 2009, the left subclavian artery revascularization numbers have been significantly increased, however, it's still less than 20%.

As we mentioned, 50% of patient need coverage, but only less than 20% of patient had a revascularization. In the patient group with left subclavian artery revascularization, then we can see the perioperative mortality and morbidities are higher in the patient

who do not need a revascularization. We subgroup of these patient into Pre- and Post-TEVAR revascularization, as you can see. In a Post-TEVAR left subclavian revascularization group, perioperative mortality and major complications are higher than the patient who had a revascularization before TEVAR.

In terms of open versus endovascular revascularization, endovascular group has fewer mortality rate and major complications. It's safer, but open bypass is more effective, and durable in restoring original profusion. In summary, TEVAR with required left subclavian artery

revascularization is associated with higher rates of perioperative mortality and morbidities. Routine revascularization may not be necessary, however, the risks of left subclavian artery coverage must be carefully evaluated before surgery.

Those risk factors are CABG using LIMA. Left arm AV fistula, AV graft for hemodialysis. Dominant left vertebral artery. Occluded right vertebral artery. Significant bilateral carotid stenosis.

Greater than 20% of thoracic aorta is going to be or has been covered. And a history of open or endovascular aneurysm repair. And internal iliac artery occlusion or it's going to be embolized during the procedure. If a patient with those risk factors,

and then we recommend to have a left subclavian artery revascularization, and it should be performed before TEVAR with lower complications. Thank you very much.

- 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.

- 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, thanks to Dr. Veith and the program committee for allowing me to present this morning. My disclosure. So, uh, I think that there's been an abundance of literature over the years that is suggested that venography may have poured diagnostic sensitivity for identifying iliac and, and

common femoral vein obstruction. Uh, in uh published literature, 34% of patients who have chronic venous symptoms of a severe degree had iliac vein obstruction on imagining techniques other than venography such as IVUS with normal venograms and often times

patients have significant outflow obstruction and there are no pelvic collaterals present so this is not a reliable though maybe specific indicator of outflow obstruction. The video study was designed to prospectively compare multiplanar venography vs. IVUS

to address the question if you do enough views on venogram do you find the same lesions that you might detect with IVUS. And we also wanted to look, does the imaging that you do to look for iliac and common femoral vein outflow track obstruction

effect your clinical decision about intervention. These are the patients in the video trial CEAP 4 through CEAP 6. And so 100 patients were randomized in this or not randomized, but rather entered entered this prospective multi-center single-arm study

at 14 sites in the US and Europe. This was half CEAP 6 patients and the remainder were CEAP 4 and 5. The patients underwent multiplanar venography. The site investigator was asked to make a decision about whether there was a significant lesion

and how they would treat that lesion and then once that was recorded IVUS was preformed and then again after the pull back the investigator was asked to make a decision about whether there was a significant lesion and how they would treat it.

We standardized venography with a hand injection in 3 views as noted. A 30 degree RAO and LAO and an AP view and the catheter was placed at the cranial portion of the femoral vein we adopted the standards and the literature

of a 50% diameter stenosis. And venography in a 50% CSA reduction on IVUS as a significant lesions. The uh, study cohort was approximately 43 women. The left leg was the index limb and 2 to 1 ratio to uh, to the right.

The age average 62 and you can see the majority of the patients were CEAP 4 and CEAP 6. What we identified with IVUS is a 21% greater (mumbling) identification of outflow obstruction. Venography was a lot less sensitive

at identifying these lesions and therefor suggesting that IVUS is a more sensitive imaging modality for identifying outflow obstruction vs. multiplanar venography. And when you looked at the core lab over read

this was for both the IVUS imaging and for the venography. And we at first calculated the diameter stenosis for both modalities we saw that with the multiplanar venography you tended to underestimate

the degree of diameter stenosis compared to IVUS and this resulted in missing about a quarter of the lesions that were greater than 50% diameter stenosis. And in part IVUS intended to score the lesions more severe for the same lesions compared to venography and this was statistically significant.

When we looked at CSA measurements from the IVUS system and also calculated off the venography in the core lab we saw again that venography missed about 18% of the significant greater than 50% CSA lesions even with reviews.

And this resulted in a change of procedure in about 60% of the patients there was a change in the decision about whether to treat of not and in 50 of the patients the number of stents changed from either no stent to 1 stent or 1 stent to 2 stents.

So without IVUS your likely under treating iliac and common femoral vein obstruction. This was the uh, rVCSS scores after treatment in this group. On the right here in green is the improvement on the left worsening.

And you can see in large part these patients all improved uh, expect for this outlier here and then some patients there was no improvement and when you looked at a score a VCSS score greater than 4 as being significant at 1 and 6 months there was a significant improvement post intervention.

And we see here in this receiver operating curve that IVUS best predicted clinical improvement at 6 months. And so we see that IVUS was more sensitive accurate for identifying significant lesions and the iliac and common femoral vein segments. It was the best guide for stent intervention

and it appears that if use a 50% cut off either diameter or CSA reduction it best predicts that intervention will lead to an improved clinical outcome at 6 months. Thank you.

- 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 very much, Gustavo, you read the abstract so now my task is to convince you that this very counter-intuitive technique actually works, you are familiar with Petticoat, cover stent to close a proximal entry tear and then uncover stents, bear stents, downstream. This what it would look like when we open up

the bare stent, you know dissect the aorta. So here's a case example, acute type B with malperfusion, the true lumen is sickle shaped, virtually occluded. So we use Petticoat, and we end up with a nice reopening of the true lumen, it is tagged here in green, however if you look more closely you see that here

wrapping around the true lumen there is a perfused false lumen. This is not an exception, not a complication, this is what happens in most cases, because there are always reentries in the celiac portion of the aorta.

So the Stablise concept was introduced by Australian group of Nixon, Peter Mossop in 2012, after you do the Petticoat, you are going to voluntarily balloon inside both the stent graft and the bare stents in order to disrupt, to fracture the lamel, obtain a single-channeled aorta.

This is what it looks like at TEE, after deployment of the stent graft, you see the stent graft does not open up completely, there is still some false lumen here, but after the ballooning, it is completely open. So the results were immediately very, very good, however technique did not gain a lot of consensus,

mainly because people were afraid of rupturing the aorta, they dissect the aorta. So here's a Stabilise case, once again, acute setting, malperfusion, we do a carotid subclavian bypass because we are going to cover the subclavian artery, we deploy

the cover stent graft, then with one stent overlap, we deploy two bare stent devices all the way down to the iliacs and then we start ballooning from the second stent down, so you see Coda balloon is used here, but only inside the cover stent with fabric.

And then more distally we are using a valvuloplastic balloon, which is noncompliant, and decides to be not larger than the aorta. So, I need probably to go here, this is the final result, you can see from the cross-sections that the dissection is completely gone and

the aorta is practically healed. So you might need also to address reentries at the iliac levels, attention if you have vessels that only come from the false lumen, we want to protect them during the ballooning, so we have a sheath inside this target vessel, and we are

going to use a stent afterwards to avoid fragments of the intima to get into the ostium of the artery. And this is a one-year control, so as you can see there is a complete remodeling of the aorta, the aorta is no longer dissected, it's a single channel vessel, here we can see stents in two vessels that came

from the false lumen, so very satisfactory. Once again, please remember, we use compliant latex balloons only inside the the cover stent graft, and in the bare stents we use non-compliant balloons. We have published our first cases, you can find more details in the journal paper, so in conclusion,

dear colleagues, Stabilise does work, however we do need to collect high-quality data and the international registry is the way to do this, we have the Stabilise registry which is approved by our ethical committee, we have this group of initial friends that are participating,

however this registry is physician initiated, it's on a voluntary base, it is not supported by industry, so we need all the possible help in order to get patients as quickly as possible, please join, just contact us at this email, we'd be more than happy to include everybody who is

doing this technique according to this protocol, in order to have hard data as soon as possible, thank you very much for your attention.

- I have no disclosures. So I'm going to show you some pictures. Which of the following patients has median arcuate ligament syndrome? A, B, C, D, or E? Obviously the answer is none of these people.

They have compression of their celiac axis, none of them had any symptoms. And these are found, incidentally, on a substantial fraction of CT scans. So just for terminology, you could call it celiac compression

if it's an anatomic finding. You really should reserve median arcuate ligament syndrome for patients who have a symptom complex, which ideally would be post-prandial pain with some weight loss. But that's only I think a fraction of these patients.

Because most of them have sort of non-specific symptoms. So I'm going to say five things. One, compression of the celiac artery is irrelevant in most patients. It's been found in up to 1/3 of autopsies, MRIs, diagnostic angiography, CT.

This is probably about par, somewhere in that 5% or 10% of CT scans that are in asymptomatic patients will have some compression of the celiac axis. The symptoms associated with median arcuate ligament syndrome are non-specific,

and are really not going to tell you whether patients have the disease or not. So for instance, if you look here's like 400 CT scans, 19 of these patients had celiac compression. But the symptom complex in patients

who had abdominal pain for other reasons looked exactly the same as it did for people who had celiac compression. So symptoms isn't going to pull this apart. So you wind up with this kind of weird melange of neurogenic, vascular,

and you got to add a little psychogenic component. Because if any of you have taken care of these people, know that there's a supertentorial override that's pretty dramatic, I think, in some fraction of these people. So if you're not dizzy yet, the third thing I would say,

symptom relief is not predicted by the severity of post-operative celiac stenosis. And that's a little distressing for us as vascular surgeons, because we think this must be a vascular disease, it's a stenotic vessel. But it really hasn't turned out that way, I don't think.

There's several papers, Patel has one just in JVS this month. Had about a 66% success rate, and the success did not correlate with post-op celiac stenosis. And here's a bigger one,

again in Annals of Vascular Surgery a couple years ago. And they looked at pre- and post-op inspiratory and expiratory duplex ultrasound. And basically most patients got better, they had an 85% success rate. But they had patients,

six of seven who had persistent stenosis, and five of 39 who didn't have any symptoms despite improved celiac flow. So just look at this picture. So this is a bunch of patients before operation and after operation,

it's their celiac velocity. And you can see on average, their velocity went down after you release the celiac, the median arcuate ligament. But now here's six, seven patients here who really were worse

if you looked at celiac velocity post-op, and yet all these people had clinical improvement. So this is just one of these head scratchers in my mind. And it suggests that this is not fundamentally a vascular problem in most patients. It goes without saying that stents are not effective

in the presence of an intact median arcuate ligament. Balloon expandable stents tend to crush, self-expanding stents are prone to fracture. This was actually published, and I don't know if anybody in the audience will take credit for this.

This was just published in October in Vascular Disease Management. It was an ISET online magazine. And this was published as a success after a stent was put in. And you can see the crushed stent

because the patient was asymptomatic down the road. I'm not discouraging people from doing this, I'm just saying I think it's probably not a great anatomic solution. The fifth thing I'd say is that comorbid psychiatric diagnoses are relatively common

in patients with suspected median arcuate ligament syndrome. Chris Skelly over in Chicago, they've done an amazing job of doing a very elaborate psych testing on everybody. And I'll just say that a substantial fraction of these patients have some problems.

So how do you select patients? Well if you had a really classic history, and this is what Linda Riley found 30 years ago in San Francisco. If they had classic post-prandial pain with real weight loss and a little bit older patient group,

those people were the easiest and most likely to have a circulatory problem and get better. There are some provocative tests you can do. And we did a test a few years ago where we put a catheter in the SMA and shoot a vasodilator down,

like papaverine and nitroglycerin. And I've had patients who spontaneously just said, "That's the symptoms I've been having." And a light bulb went off in our head and we thought, well maybe this is actually a way you're stealing from the gastroduodenal collaterals.

And this is inducing gastric ischemia. I think it's still not a bad test to use. An alternative is gastric exercise tonometry, which is just incredibly elaborate. You got to sit on a bicycle, put an NG tube down to measure mucosal pH,

get an A-line in your wrist to check systemic pH, and then ride on a bike for 30 minutes. There's not many people that will actually do this. But it does detect mucosal ischemia. So for the group who has true circulatory deficiency, then this is sort of a way to pick those people up.

If you think it's fundamentally neurogenic, a celiac plexus block may be a good option. Try it and see if they react, if maybe it helps. And the other is to consider a neurologic, I mean psychologic testing. There's one of Tony Sadawa's partners

over at the VA in Washington, has put together a predictive model that uses the velocity in the celiac artery and the patient's age as a kind of predictive factor. And I'll let you look it up in JVS. Oddly enough,

it sort of argues again that this is not a circulatory problem, in that the severity of stenosis is sort of inversely correlated with the likelihood of success. So basically what I do is try to take a history,

look at the CTA, do inspiratory and expiratory duplex scans looking for high velocities. Consider angiography with a vasodilator down the SMA. If you're going to do something, refer it to a laparoscopist. And not all laparoscopists are equal.

That is, when you re-op these people after laparoscopic release, you often times find a lot of residual ligament. And then check post-operative duplex scans, and if they still have persistent symptoms and a high-grade stenosis,

then I would do something endovascular. Thank you.

- Thank you very much for the presentation. Here are my disclosures. So, unlike the predecessor, Zenith Alpha has nitinol stents and a modular design, which means that the proximal component has this rather gentle-looking bear stents and downward-looking barbs.

And the distal part has upward-looking barbs. And it is a lower-profile device. We reported our first 42 patients in 2014. And now for this meeting we updated our experience to 167 patients operated in the last five years.

So this includes 89 patients with thoracic aneurysms. 24 patients in was the first step of complex operations for thoracoabdominals. We have 24 cases in the arch, 19 dissections, and 11 cases were redos. And this stent graft can be used as a single stent graft,

in this case most of the instances the proximal component is used or it can be used with both components as you can see. So, during the years we moved from surgical access to percutaneous access and now most of the cases are being done percutaneously

and if this is not the case, it's probably because we need some additional surgical procedures, such as an endarterectomy or in cases of aorto-iliac occlusive disease, which was present in 16% of our patients, we are going to need the angioplasty,

this was performed in 7.7% of cases. And by this means all the stent grafts were managed to be released in the intended position. As far as tortuosity concerned, can be mild, moderate, or severe in 6.6% of cases and also in this severe cases,

with the use of a brachio-femoral wire, we managed to cross the iliac tortuosity in all the cases. Quite a challenging situation was when we have an aortic tortuosity, which is also associated with a previous TEVAR. And also in this instances,

with the help of a brachio-femoral wire, all stent grafts were deployed in intended position. We have also deployed this device both in chronic and acute subacute cases. So this can be the topic for some discussion later on. And in the environment of a hybrid treatment,

with surgical branching of the supoaortic tranch, which is offered to selected patients, we have used this device in the arch in a number of cases, with good results. So as far as the overall 30-day results concerned, we had 97.7% of technical success,

with 1.2% of mortality, and endoleaks was low. And so were reinterventions, stroke rate was 1.2%, and the spinal cord injury was 2.4%. By the way we always flash the graft with CO2 before deployment, so this could be helpful. Similar results are found in the literature,

there are three larger series by Illig, Torsello, and Starnes. And they all reported very good technical success and low mortality. So in conclusion, chairmen and colleagues, Zenith Alpha has extended indications

for narrow access vessels, provide safe passage through calcified and tortuous vessels, minimize deployment and release force, high conformability, it does retain the precision and control of previous generation devices,

however we need a longer term follow up to see this advantages are maintained over time. Thank you very much.

- Thanks, Germano. Thanks, Gustavo. These are my disclosures as it pertains to this talk. I will be talking about the devices not yet FDA approved in the U.S. for use. We know that with endovascular repair, we need to consider all the aspects

and how we can potentially get this therapy into more people's hands. So, the Gore Company really talked to many of the key opinion leaders about the steps in doing these types of cases, how to make them simple,

they talked about anatomic screening and case planning needs to be thoughtful and careful. We emphasized with them the need to have minimized aortic coverage to limit spinal cord ischemic risk and also to talk about real world applicability

and make sure the device can be used in a wide variety of patients and not in a limited subset. If you look at the other device that has extensive use with off-the-shelf thoracoabdominal repairs, it really involves the t-Branch.

In this case, the device generally requires coverage up through 11 centimeters above the celiac artery. Marcella Ferrara has described ways to limit that with modification of the device but this is it in its current stage. With that, W.L. Gore really came up with a device

that shortened that length. It generally requires about six and a half centimeters of coverage above the celiac artery. It has been designed to work with their balloon-expandable VIABAHN device. You see on the right there,

the device has four preloaded hypo-tubes. That allows for passing four wires in to pre-catheterize each of the branches. That wire system is then brought out through a subclavian access, either right or left, through a DrySeal sheath

that then allows the implantation device in the deployment. The sequential deployment is done with the device being partially open. The portals are then catheterized from above, as you see on the far left,

and the wires placed in that. Once those have been successfully done, the branch stints are placed and then eventually the distal device is deployed and then the distal completion with the bifurcated and iliac components as necessary.

Now the technical aspects of this has been presented at this meeting and has recently been submitted and accepted for publication in JVS. Dr. Oderich is the lead author on this and really comprises the initial 13 implants with the 30-day outcomes.

Now those outcomes really focus on two things, you see the mean procedure time can vary quite a bit. That really depends upon some of the aspects about use of different axillary catheters and thoraco sheaths to get it done. But the other main thing was the blood loss

which can exceed, in a few cases, quite a bit. And that, in this trial, was mainly because they used the 12 French Flexible Cook Ansel Sheath and not the DrySeal. Once we moved to the DrySeal sheath, we see that the number of amount of blood loss

through the central port is a lot less and that's going to limit that in the future trial. Now, currently there have been 16 worldwide implants and this comprises the entire cohort that's been done. You see that early on, we only had access to the retrograde and about a third of the patients

had retrograde renal portals but since that time, mid Spring of 2016, we moved to an anterograde version alone. Most cases are type four thoracos that were done in this initial experience. What about the short-term outcomes?

Well the short-term outcomes are about 18 months. Overall survival 92 percent. One patient presented four months with multi-system failure from three vessels being occluded. The right renal had already been occluded at the time of the initial implant.

Serious adverse events. About 46 percent of patients, which is very typical, acute kidney injury and only 23 percent, and no type one or three endoleaks. There have been seven branch vessel occlusions, four in that one patient that presented acutely,

one patient a year and a half with renal artery occlusions from severe dehydration and one unilateral renal artery occulusion at approximately six months. That was managed with lysis and stenting. No difference in occlusion rates

between anterograde and retrograde. So in conclusion, the TAMBE device has completed its feasibility study with similar results for complete endovascular repair of thoracoabdominal aneurisms. Longer follow-up and a Pivotal study are planned

in pursuit of FDA approval. Thank you.

- 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.

- 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.

- Thank you Louie, that title was a little too long for me, so I just shortened it. I have nothing to disclose. So Takayasu's arteritis is an inflammatory large vessel vasculitis of unknown origin. Originally described by Dr. Takayasu in young Japanese females.

The in-di-gence in North America is fairly rare. And its inflammation of the vessel wall that leads to stenosis, occlusion or aneurysmal formation. Just to review, the Mayo Clinic Bypass Series for Takayasu's, which was presented last year, basically it's 51 patients, and you can see

the mean age was 38. And you can see the breakdown based on race. If you look at the early complication rate and we look at specific graft complications, you had two patients who passed away, you had two occlusions, one stenosis, one graft infection.

And one patient ruptured from an aneurysm at a distant site than where the bypass was performed. If you look at the late complications, specifically graft complications, it's approximately 40%. Now this is a long mean follow up: this is 74 months, a little over six years.

But again, these patients recur and their symptoms can occur and the grafts are not perfect. No matter what we do we do not get superb results. So, look at the graft outcomes by disease activity. We had 50 grafts we followed long-term. And if you look at the patency, primary patency

right here of active disease versus non-ac it's significantly different. If you look at the number of re-interventions it's also significantly different. So basically, active disease does a lot worse

than non-active disease. And by the way, one of our findings was that ESR is not a great indicator of active disease. So we're really at a loss as to what to follow for active or non-active disease. And that's a whole 'nother talk maybe for another year.

So should endovascular therapy be used for Takayasu's? I'd say yes. But where and when? And let's look at the data. And I have to say, this is almost blasphemy for me

to say this, but yes it should be used. So let's look at some of the larger series in literature and just share them. 48 patients with aortic stenosis fro all were treated with PTA stenting.

All were pre-dilated in a graded fashion. So they started with smaller balloons and worked up to larger balloons and they used self expanding stents in all of them. The results show one dissection, which was treated by multiple stents and the patient went home.

And one retro-paret-tin bleed, which was self limiting, requiring transfusion. Look at the mean stenosis with 81% before the intervention. Following the intervention it was 15%. Systolic gradient: 71 milligrams of mercury versus 14. Kind of very good early results.

Looking at the long term results, ABI pre was .75, increased to .92. Systolic blood pressure dropped significantly. And the number of anti-hypertensive meds went from three to 1.1. Let's look at renal arteries stenosis.

All had a renal artery stenosis greater than 70%. All had uncontrolled hypertension. They were followed with MRI or Doppler follow up of the renal arteries. So, stents were used in 84% of the patients. Restenosis occurred in 50% of them.

They were, all eight were treated again, two more developed restenosis, they ended up losing one renal artery. So at eight years follow up, there's a 94% patency rate. What about supra-aortic lesions? And these are lesions that scare me the most for endovascular interventions.

Carotids, five had PTA, two had PTA plus stent. Subclavian, three PTA, two PTA. One Innominate, one PTA plus stent. One early minor stroke. I always challenge what a minor stroke is? I guess that's one that happens to your ex mother-in-law

rather than your mother, but we'll leave it that way. Long term patency at three years, 86%. Secondary patency at three years, 76%. Fairly good patency. So when Endo for Takayasu's, non-active disease is best. The patient is unfit for open surgery.

I believe short, concentric lesions do better. In active disease, if you have to an urgent or emergent, accept the short term success as a bridge to open repair. If you're going to do endovascular, use graded balloons or PTAs, start small. Supra-aortic location, short inflation times

I think are safer. And these three, for questions for the future. I guess for the VEITHsymposium in three years. Thank you.

- 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.

- [Presenter] Thanks Bill. And again I have no disclosures to make on this particular presentation. So, in terms of variance, the anterior accessory GSV is not a variant. It's present in most of us, but it's an unusual cause of primary varicose veins,

although a very common cause of secondary varicose veins after primary treatment. It runs parallel to the great saphenous vein, in the saphenous space, and courses a bit more anteriorly in the thighs, so that on ultrasound, you'll see a lining here,

in this case inside the saphenous space, aligning with the superficial femoral artery and the femoral vein. In some cases, it can be the primary saphenous vein along the medial aspect of the thigh, in association with hypoplasia of the great saphenous vein

as listed on the left, and the right picture with aplasia of the great saphenous vein. And many times physicians are treating what they think is the great saphenous vein, and really it's this embryologic variant,

the anterior accessory vein, with a different takeoff. A different vein to talk about in terms of variance is the superficial accessory saphenous vein. It's present in many patients. It's really a tributary of the great saphenous vein,

running in the subcutaneous fat outside the superficial fascia that eventually joins into the great saphenous vein. So on this longitudinal view, it creates this sort of appearance with the great saphenous vein below its entry

as a smaller caliber vein. Consequently, it has the name of the H-vein, and on ultrasound, below the level of its joining with the great saphenous vein, the great saphenous vein is small,

and in this particular case with varicose veins, associated with reflux in the superficial accessory saphenous vein. It's a larger caliber, and then up higher, you can see that it drains into the great saphenous vein, and it's no longer visible.

The small saphenous vein has a lot of variability related to the differences in its termination on the posterior aspect of the calf and the thigh. Many patients have what we can call saphenopopliteal junction dominant drainage, and other patients have what we might consider

thigh extension dominant drainage. It's a spectrum, most patients have these connections, and if you look carefully, you'll find the thigh extension connection even in the majority of patients that have primarily saphenopopliteal junction termination.

The termination higher on the thigh can be into a perforator on the back of the thigh, it can be into the gluteal venous system in the pelvis, and it can travel up through an intersaphenous or Giacomini vein toward the inner thigh,

and sometimes to the great saphenous vein. Duplications of the deep system are very common, particularly in the femoral vein in up to 20% of the patients. Isolated popliteal vein duplications are uncommon, but in association with femoral duplications

occur in up to 6% of the variations. These duplications all travel through the adductor canal and follow the normal course of the vein. In contrast, remnants of the sciatic vein can introduce different variants. The sciatic vein is an embryonic vein

that was the primary drainage of the lower limb in a very small fetal stage. At some point, most of it regresses, and so the popliteal vein, which is the sciatic vein remnant, eventually connects up with the pelvic circulation

through the common femoral vein and the external iliac vein which develop later. The saphenous remnants regress, with the exception of the popliteal vein, and portions of the internal iliac vein. A true sciatic vein variant is a less common variant,

where the popliteal vein is in continuity with a large caliber vein that follows the sciatic nerve up into the pelvis, draining into the internal iliac vein. But in contrast, sciatic vein remnants are not uncommon,

and it's not unusual for one to find the primary drainage of the popliteal vein not going through the adductor canal, but to ascend upward variable lengths along the course of the sciatic vein, to eventually terminate either in the femoral vein directly

or into the deep femoral vein up higher, with or without hypoplasia, or in rare cases, aplasia of the femoral vein. And so it's important to recognize these variants in distinction to post-thrombotic changes

in the femoral vein. When you have a small vein, that small vein can be normal anatomically by all other features, and may represent a variant rather than a post-thrombotic complication.

And this was recognized by Dr. Raju in 1991 in a publication where he demonstrated venograms in a patient with a post-thrombotic femoral vein, and well-formed collaterals between the popliteal vein and the profunda, in contrast to this patient,

which had no post-thrombotic changes in the femoral vein, but well-defined congenital variation connections between the popliteal vein and the deep femoral vein. So in summary, superficial venous variability is related to the variable terminations

of the small saphenous vein, the anterior accessory saphenous vein, which is inside the saphenous sheath, superficial accessory saphenous veins, which are outside the saphenous space. It's important to recognize deep vein variablity,

'cause you want to avoid false negative diagnoses of acute deep vein thrombosis by not recognizing thrombosis in a duplication, and you want to avoid false positive diagnoses of post-thrombotic syndrome when you're really dealing

with a congenital sciatic vein dominant anatomic variability. Thank you very much.

- Thank you Dr. Melissano for the kind interaction. TEVAR is the first option, or first line therapy for many pathologies of the thoracic aorta. But, it is not free from complications and two possible complications of the arch are the droop effect and the bird-beak. I was very interested as Gore came up with the new

Active Control System of the graft. The main features of this graft, of this deployment system are that the deployment is staged and controlled in putting in the graft at the intermediate diameter and then to the full diameter. The second important feature is that we can

optionally modify the angulation of the graft once the graft is in place. Was very, very interesting. This short video shows how it works. You see the graft at the intermediate diameter, we can modify the angulation also during this stage

but it's not really used, and then the expansion of the graft at the full diameter and the modification of the angulation, if we wished. This was one of the first cases done at our institution. A patient with an aneurysm after Type B dissection. You see the graft in place and you see the graft after

partial deployment and full deployment. Perhaps you can appreciate, also, a gap between the graft and the lesser curvature of the arch, which could be corrected with the angulation. As you can see here, at the completion angiography we have an ideal positioning of the graft inside the arch.

Our experience consisted only on 43 cases done during the last months. Mostly thoracic aneurysm, torn abdominal aneurysm, and patients with Type B aortic dissection. The results were impressive. No mortality, technical success, 100%,

but we had four cases with problems at the access probably due to the large bore delivery system as you can see here. No conversion, so far and no neurological injury in this patient group. We have some patients who came up for the six months follow-up and you see here we detected one Type 1b endoleak,

corrected immediately with a new graft. Type II endoleak which should be observed. This was our experience, but Gore has organized all the registry, the Surpass Registry, which is a prospective, single-arm, post market registry including 125 patients and all these patients

have been already included in these 20 centers in seven different countries in Europe. This was the pathology included, very thorough and generous, and also the landing zone was very different, including zone two down to zone five. The mean device used per patient were 1.3.

In conclusion, ladies and gentlemen, the Active Control System of the well known CTAG is a really unique system to achieve an ideal positioning of the graft. We don't need to reduce the blood pressure aggressively during the deployment because of the intermediate diameter

reached and the graft angulation can be adjusted in the arch. But, it's not reversible. Thank you very much for your attention.

- You'll be pleased to know we've got a bit better at using ceiling mounted lead shields and goggles, but there's still room for improvement. These are my disclosures. I thought I'd start just by putting into context the exposures that we receive as operators. So medical diagnostics scans

can be anything up to 25 millisieverts. If you're a classified radiation worker you can only get 20 millisieverts per year. Background radiation, depending on where you live, is something between one and 10 millisieverts per year. And it varies from department to department.

But for a complex endovascular branch and fenestrated case you get typically 50 microsieverts of radiation outside the lead. What is irrefutable is that once you get to 100 millisieverts you have got a raised risk of solid cancers and leukemia.

What we do not know, we simply don't know, is what is the dose response below that 100 millisievert threshold, and is there any individual differences in sensitivity to radiation? Why don't we know?

Because we're no good at following up operators and patients after they receive an exposure. What we need is stringent study design, we need well defined populations, they need to be large studies, 10s of thousands, we need to control for

all the confounding factors for cancer, we need really high quality followup, and we need to know what dose we're receiving. This is my interventional radiology colleague. He's been there since the inception of the complex endovascular program at St. Thomas',

and I asked him to tell me what he did over the past 10 years. And you can see that this is his logbook. It excludes quite a number of perhaps lower exposure cases including GI cases, dilatations, nephrostomies. So he's done 1071 cases in 10 years.

He doesn't know his dose. But if you think per case exposure is 20, 40, or 60 microsieverts you can see that the exposures quickly build up. And in a 20-year career he's going to breach probably that 100 microsievert threshold.

So these numbers are just worth thinking about. So what evidence do we have that exposure causes DNA damage? It has been looked at in mice. If you expose mice they have an increased instance of lung tumors, for example. The radiation at low dose causes DNA damage.

It shortens the life span, and importantly, the risk is synergistic with other risks like smoking. In the course of this DNA damage and repair process, the repair process is not perfect. And eventually you get genomic instability,

and that's what causes cancer. When the cell is irradiated with low doses you also get generation of bad factors such as ROS and inflammatory factor. And we have shown in in operators that you get DNA damage before and after

you carry out fluoroscopically guided case. You can see here foci of this gamma H2AX which signal DNA damage in operators. And what happens over long term? There are markers you can look for long term that show that you're exhibiting genomic instability,

and this includes diccentrics. You can see these chromosomes are abnormal, and that happens as result of chronic radiation exposure. And micronuclei, so you can see that these cells express micronuclei. That is abnormal.

That is genomic instability and that means that your risk of cancer is increased. We haven't measured for these yet in operators, but they may well be present. So I think you need a combination of physical and biological dosimetry.

How do you do that? Well you need high throughput methods for doing it, which we don't have as yet. The current methods are laborious. You need to cont lots of cells and it takes a long time to do it.

But perhaps with the next generation high throughout sequencing this is what we'll be doing. Regular samples from operators and deciding whether there exhibiting genomic instability or not, should they be doing something other than carrying out endovascular operations.

In the meantime, radiation is really dangerous. I think that's what we've got to assume. No matter how much of a dose you're getting it's dangerous. The ALARA principles, you should hopefully all be familiar with, maximal shielding, and as mentioned,

the zero gravity suit. We've started using this. And obviously we wear leg shields. Just as something different, I mentioned that when your cell gets irradiated it produces lots of nasty factors

such as radioactive oxygen species and pro-inflammatory factors, and that can again cause DNA damage. Kieran Murphy spoke earlier on in the previous session about effective low-dose exposure. What they've done is given a cocktail of antioxidants

to patients who have cancer staging. And that actually reduces DNA damage. This is another study that came out recently, another cocktail of antioxidants, exposed to cells in vitro that were irradiated, and this is probably a less relevant study

because it's all in vitro. But again, in a very controlled situation these antioxidants do reduce the production of inflammatory factors in DNA damage. So perhaps we should all be taking a cocktail of pills before we operate.

So in summary, we live in a world of increasing radiation exposures. The health effects are unknown. We need better radiation in epidemiology, a combination of biological and physical dosimetry probably, and in the meantime we have to insist

on maximal protection and assume that all radiation is dangerous. Thank you very much.

- Thank you, Mr. Chairman. Ladies and gentleman. I'd also like to thank Dr. Veith for the kind invitation. This presentation really ties to the presentation of Erik Verhoven, I believe. These are my disclosures. So we basically have, obviously, two problems. We treat a dynamic disease by fairly static means.

One of the problems, a local problem, is aortic neck degeneration which is the problem basically of progression of disease. We know in general if you stent them, if you operate them, if you don't treat them they will just dilate and it's a question of time

whether you have a problem or not. So, they will inevitably, if patients live long enough, cause a change of geometry of the aorta and the branch vessels and that cause obviously, that can cause stent fractures and other problems.

That's just one of many papers Erik also has shown a migrated graft. With his fenestrated grafts showing that the problem is also prevalent in M stents and Z stents, and obviously also in

as in the Fenestrated Anaconda. So I'll talk briefly about our experience. In Vienna where we have treated so far 179 patients with either double, triple, or quadruple fenestrated grafts. Majority nowadays are quadruple in our series

where we have also treated patients with extensions of thoracic stent grafts or extensions further down to the iliac arteries. In these patients we've had relevant neck degenerations in five cases. Where either the branches had issues

or the graft had migrated relevantly. And these basically represent three different faces of the problem. So one is neck degeneration with migration and loss of seal. Certainly the biggest problem that can cause ruptures. That's one of the cases in 2015

what is certainly important is to have a look at the super celiac area of the aorta and you see it's degenerated, it's dilated. So we have a nice ring of aorta at the visceral segment but above it wasn't. And it was a

you see the saddle of the stent graft and one and a half years later the saddle (cough) has flattened out. We've had a stent fracture of the left renal stent.

We screwed it with anchors and fixed the stent graft. We believe that's going to be the solution. We were wrong. Yet anothe leak and a further migration of the case.

So we had to put in a thoracic endograft and bring in a 4 fen and a mono-iliac crossover solution. The other problem would be neck degeneration or progression of disease without migration or loss of seal. As in this case where we have implanted a 4 fen case and you can see here that there is

a diseased proportion of the thoracic aorta. Could look like a penetrating ulcer. And again we had to put in a thoracic stent graft and a 4 fen solution with a mono-iliac ending and a crossover. What's more important, I believe,

is the progression of general, generalized aortic disease. So there is no real migration, as in this case in 2013. You can see a nice saddle and very straight iliac limbs. 2018 you can see that the saddle is actually flattened out. Renal arteries look upwards, so you would actually believe in

a migration of the stent graft. Also if you look at the iliac limbs you can see that they have actually compressed somewhat. But if you look closely at the difference between the ring and the SMA, so that's lateral view, you can see that there is no difference.

The stent graft actually has not migrated. What happened is that the patient developed a thoracic aneurysm of 7.5cm and the whole aorta is not only increased in diameter but also in length. So the whole thing has moved its confirmation without basically a migration of the

not yet. So, Mr Chairman, Ladies a lessons we have learned is- and I could also repeat wh

seal in the healthiest proportion of the aorta. So if you see a nice visceral ring and above that you see a diseased proportion of the aorta, as in this case, where you have already a degenerated thoracic aorta.

You should really treat this as well and not go for a 2 or 3 fen case. And also the progressio the general progression of disease is an issue. So even if you have no migrations

you may end up with real problems and target vessel occlusions or stent graft fractures. Thank you very much

- Sam, Louis, thank you very much. I also kind of reduced the title to make it fit in a slide. Those are my disclosures. We've switched to using a hybrid room routinely a couple of years ago and what happened then is that we started using 3D imaging

to guide us during the procedure using a fusion overlay. Obviously this was a huge benefit but the biggest benefit was actually 3D imaging at the end of the procedure so rather than doing an AP fluoro run, we would do a 3D acquisition in a cone beam CT

and have those reconstructions available to check technical success and to fix any issues. We've been using this technique to perform translumbar type 2 endoleak treatment and what we do is we do a cone beam CT non contrast and we fuse the pre-op CT on top of this cone beam CT

and it's actually quite easy to do because you can do it with the spine but also obviously with the endograft so it's a registration on the graft on top of the endograft and then the software is really straightforward. You just need to define a target in the middle

of the endoleak. You need to define where you want to puncture the skin and then the system will automatically generate to you a bull-eye view which is a view where you puncture the back of the patient and the progression view you obviously see the needle

go all the way to your target. And what is interesting is that if you reach the target and if you don't have a backflow so you're not in the endoleak, you have this stereo 3D software which is interesting because you do two lateral fluoro runs

and then you check the position of the needle and then it shows you on the pre-op CT where you are. So here in this specific patient, I didn't advance the needle far enough. I was still in the aortic wall,

that's why I didn't get backflow so I just slightly advanced the needle and I got backflow and I could finish the embolization by injecting contrast, close and then ONYX to completely exclude this type 2 endoleak. So now let's go to our focus today is fenestrated endograft.

You see this patient that were treated with a fenestration and branches. You can see that the selective angio in the left renal looks really good but if on the cone beam CT at the end of the procedure we actually had a kink on the left renal stent

so because I had depicted it right away at the end of the procedure I could fix it right away so this is not a secondary procedure. This is done during the index procedure so I'll go directly to what we did is we reinflated a ballon,

we re-fed the balloon and then had a nice result but what happen if you actually fail to catheterize? This was the case in this patient. You see the left renal stent is completely collapsed. I never managed to get a wire from the aortic lumen and back into the renal artery

so we position the patient in the lateral position, did a cone beam CT and used the same software so the target is now the renal artery just distal to this crushed renal stent and we punctured this patient back in the target and so you can see is right here

and you can see that the puncturing the back. We've reached the renal artery, pushed a wire through the stent now in the artery lumen and snared the wire and over this through and through wire coming out from the back we managed

to reopen this kinked left renal stent. You can see here the result from this procedure and this was published a couple of years, two years ago. Now another example, you can see here the workflow. I'm actually advancing the needle in the back

of the patient, looking at the screen and you can see in this patient that had a longer renal stent I actually punctured the renal stent right away because at the end of the procedure I positioned another covered stent inside

to exclude this puncture site and then, oops sorry, and then, can we go to the, yeah great thank you. And then I advance the wire again through this kinked renal stent into the endograft lumen and this is a snare from the groin

and I got the wire out from the groin. So you see the wire is coming from the back of the patient here, white arrow, to the groin, red arrow and this is the same patient another view and over this through and through wire

we manged to re advance and reopen this stent and we actually kinked the stent by getting the system of branched endograft through a previous fenestrated repair and fortunately my fellow told me at the end of the procedure we should check the FEVAR

with a cone beam CT and this is how we depicted this kink. So take home message, it's a very easy, straightforward workflow. It's a dedicated workflow that we use for type 2 endoleak embolization. We have this intermediate assessment with Stereo 3D

that helps us to check where we are so with 3D imaging after the learning curve it's become routine and we have new workflows like this way of salvaging a kinked renal stent. Thank you very much for your attention.

- Thanks, Stefan and Frank for having me back again this year. These are my disclosures as it pertains to the renal topics here. We all know that renal dysfunction severely impacts survival, whether we're doing open or endovascular aortic repair,

as you see by these publications over the past decade, patients with no dysfunction have a significant advantage in the long term, compared to those patients who suffer acute kidney injury, or go on to be on new hemodialysis. When you look at the literature,

traditionally, through open repair, we see that the post-operative rate of acute kidney injury ranges anywhere from 20 to almost 40 percent, and it doesn't seem to vary whether it's a suprarenal or infrarenal type

of clamp or repair. Chronic renal replacement therapy in this population ranges somewhere between 0 and 3 percent. That really forms a baseline when we want to compare this to the newer techniques such as chimney and fenestrated or branched EVAR.

Now, if you look at the results of the ZFEN versus Zenith AAA trials, and this is published by Gustavo, the acute kidney injury rate is approximately at 25%, acute kidney injury rate being defined as patients, excuse me, greater than 25% change in GFR,

but in one month acute kidney injury rate is 5% for FEVAR and about 9% for EVAR in this study. There's no difference in these rates at two years or five years between the Zenith AAA and the ZFEN devices. What about the progression of patients

with Stage 4 or Stage 5? At two years, it's about the same, 2% versus 3% for EVAR, and at five years, 7 and 8% respectively. Overall, progression to renal failure occurs in about 1.5% of patients in this cohort.

Well, how does that compare to chimney cases, if you look at the Pythagoras and PERICLES studies, there are a limited number of patients, you see in Pythagoras, 128 patients, 92% of them had either one or two chimneys, meaning generally addressing renal arteries in this case,

patency of those grafts was about 96% and there is no real discussion in that manuscript of the degree of acute kidney injury. And in PERICLES registry, however, they report a 17.5% incidence of acute kidney injury post-op,

and a 1.5% incidence of temporary or permanent dialysis. What about if you compare them? This is a publication in 2017, if you look at both of these studies, very similar, 17.8% for acute kidney injury in FEVAR, and about 19% for a chimney.

You have to realize, though, there are more complete repairs in the FEVAR group, and there are more symptomatic patients in the ChEVAR group, so these aren't completely comparable, but you get some idea that they're probably in the general range of one another.

So the real questions, I think, that come up, is, which arteries can you sacrifice? Are renal embolizations impacting patients' overall function? And what is the mid-term impact of branch and fenestrate on volume of your kidneys

and patients' eGFR. We've studie we looked at the incidence and clinical significance of renal infarcts, whether we actually embolized these pre-procedure,

or whether we accidentally covered or intentionally covered an accessory renal artery, what was the outcome of those patients? We see over time, the average renal volume loss, calculated by a CT scan and VAT volume, is about 2.5% if you embolize it

and if you just cover an accessory renal, about 6.4%. But overall, about 4%, didn't change significantly, overall the GFR changed over the lifespan of the first two years of the patient of 0.1, so it wasn't a significant clinical impact on the patient's overall renal function.

Now what about looking at it specifically of what happens when you do branch and fenestrate cases with respect to eGFR and volume of those? We presented this at this past year's SABS, and it is in submission. If you look at the changes of eGFR,

you notice that in the first six months, the patient declines, but not significantly, and then you see in the graph there, it tends to come back up by a year, year and a half. Very similar to what Roy Greenberg published in his initial studies,

but what we did in this study was actually compare it to the age match publications, and you see that eGFR over time was similar to what happens in age-related changes, but we also noticed that 16% of the patients, 9 of 56, had improvement of their eGFR

to greater than 60. Now whether this is just related to the inaccuracy of the eGFR and its variance, or whether we actually improved some renal stenosis, is difficult to tell in this small study. In conclusion, open, fenestrated,

and chimney EVAR procedures are associated with acute kidney injury in approximately 20% of patients. Causes of deterioration are likely multifactorial and may be different for each technique used. Renal infarcts from covering accessory renal arteries

and embolization occur in about a quarter of the patients, and is a small contributor to renal decline over time. Renal decline made after FEVAR is similar to associated with age. Thank you.

- 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.

- Thank you very much Germano. Thanks to Dr. Veith for inviting us and allowing us to present this here. This is work that we've done in a group in Hamburg together with Nikolaos Tsilimparis. And these are my disclosures. It's been now, more than 15 years ago

that branched endografting has been introduced as a technique for thoracoabdominal aneurysms. And for about five years we have access to the T-Branch device as we've learned from the presentations before. And as we heard from Mark Farber

there's more companies going into that space. In Europe it's also the JOTEC company, which is CryoLife now, and we will, I believe, see more companies going into this space. So, about access, we've been discussing in the past

very much about whether right or left side is the better, or safer, access for branched TEVAR, and at that moment in this publication from our center, we phrased this, the unavoidable use of an upper extremity access. We show you that we've been believing that it's unavoidable.

But is it really unavoidable? In some cases I believe it should be avoided, because we have aortic branch vessels that are occluded, thrombotic, we have AV-fistulas and LIMA Bypasses that we may risk. And we may have antegrade branches

from previous artery repair which we would judge as almost a no antegrade access option here. So what can we do in those cases? And furthermore, upper extremity access has complications and it comes at a cost.

Not only hematoma and nerve damage, plexus damage at the access site, but also stroke is reported being a complication of arm access. We've looked into our experience from two years and found that about 5% of patients needed

some sort of re-operations from complications of upper extremity access, and this is just one of the more severe complications we had with a brachial on the stick due to too small access vessels. Another point is radiation.

Because radiation also as we've shown here, this is unpublished data, is significantly higher if a operator stands at the arm compared to standing at the groin. Is it really unavoidable? If we think about this as our traditional access,

but how about this? I know this has been used a lot in fenestrated endografting. But we started applying this technology also for branched endografting to avoid upper extremity access. First case that we did was a patient

that had an irregular orifice of the right renal artery and it was only one branch that we didn't want to go through all the hassle with upper extremity access. You see here, steerable sheath. You can very well attach that artery without upper extremity access.

Next case, for fenestrated and branched, then have one branch difficult celiac artery, very small stenotic orifice from a large aneurism, but it was attachable from the groin, a good result. Next case, two branches, two fenestrations. As you can imagine,

it also went well for the SMA and for the celiac with a good result without the need of touching arm, without the need going through the arch. This is a more severe one. This is a redo after EVAR patient with an occluded one-sided iliac lack

and a crossover bypass. This is the SMA. This is the right renal artery. You see that we were able to complete this repair from one access side alone, doing a full four-branch thoracoabdominal repair using steerable sheaths.

This series has been recently published as a case series, but we have extended on that experience. I can tell you in all patients that we tried to do it, it was possible to avoid the upper extremity access. Concluding: Endovascular repair has matured over years

and can, in my view, be considered gold-standard for thoracoabdominal repair. Upper extremity access is avoidable if possible. Success rate of femoral access with steerable sheath is safe. And I thank you very much for your attention.

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