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Lung Adenocarcinoma, Post lobectomy & Wedge Resection|Cryoablation|63|Male
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Transcript

So this is a 68 year old who had two prior histories of lung cancer who's a Vietnam vet and he has a 60% predicted FED1, 65% DL so not bad but had already had two cancers.

He was done having surgery. He said, I'm not doing any more of this and we found a new lesion. EBUS was again negative and it was a biopsy proven adenocarcinoma. This here is our lesion down here. Here's our aorta. Here's vertebral bodies.

You can see some of these chain sutures. Ignore the subcutaneous air for now. So what will we use and why? So right in the center in your vital structures. Who says RF? So there is some data to suggest it's okay.

How about microwave? We get a couple of people again also some data to suggests okay. How about cryo? All right. You guys know that I'm a cryo guy at this point. [LAUGH]

So the answer is in fact cryo. The reason being the adventitia or the collagen matrix of a surrounding structure in cryo is maintained, and what we would see in this particular case is that the outside of the aortic wall and the inside of the aortic wall is being maintained by continuous flow of blood,

and then also by the collagen matrix. And what we expect to see is an ice formation like this where you have the aorta causing some decreased ice formation, there's a cold sink. The bronchus here causing another cold sink and a nice ovoid shape ablation. So here that we are intra procedurally.

Notice how I kind of cheated toward the aorta, that was intentional. All right so this is a Perk 24 being placed into the lesion. The tip is beyond it and as soon as I got it to here I stuck frozen immediately and then hoped for the best.

And then we monitored the aorta very carefully, did give him some contrast to make sure it didn't have a psuedo aneurysm. Notice that we are at a tangent to the aorta to the vascular structure. You don't really pointing at the vascular structure with the cutting tip needle, its just bad form. And here we are post. Where we see the ice track being formed out here and of course you

can see that air has found its way from the inside world to the subcutaneous tissues. Didn't drop his lung because he had multiple surgeries before. And this is a good example of how to do a cryo on the aorta. Guy did great. He died four years later from heart disease.

So I'll stop there. >> No why didn't you mobilize that again because this is really- >> Could not. >> You tried? >> He was multiple surgeries already.

> You tried though? >> And even with this you could see that dropping his lung putting lots of air, it won't go any where. So he was stuck. All right. Please. >> Great. >> [INAUDIBLE] >> I did nothing.

I did a small dermotomy in the skin surface, let it all come out and did nothing. It all went away the next day. >> You don't need to do anything. >> But I did it was kind of cool because I put a [UNKNOWN] and hoped for the best.

>> [LAUGH]

- Good morning. Thank you for the opportunity to speak. So thirty day mortality following unselected non-cardiac surgery in patients 45 years and older has been reported to be as high as 1.9%. And in such patients we know that postoperative troponin elevation has

a very strong correlation with 30-day mortality. Considering that there are millions of major surgical procedures performed, it's clear that this equates to a significant health problem. And therefore, the accurate identification of patients at risk of complications

and morbidity offers many advantages. First, both the patient and the physician can perform an appropriate risk-benefit analysis based on the expected surgical benefit in relation to surgical risk. And surgery can then be declined,

deferred, or modified to maximize the patient's benefit. Secondly, pre-operative identification of high-risk patients allows physicians to direct their efforts towards those who might really benefit from additional interventions. And finally, postoperative management,

monitoring and potential therapies can be individualized according to predicted risk. So there's a lot of data on this and I'll try to go through the data on predictive biomarkers in different groups of vascular surgery patients. This study published in the "American Heart Journal"

in 2018 measured troponin levels in a prospective blinded fashion in 1000 patients undergoing non-cardiac surgery. Major cardiac complications occurred overall in 11% but in 24% of the patients who were having vascular surgery procedures.

You can see here that among vascular surgery patients there was a really high prevalence of elevated troponin levels preoperatively. And again, if you look here at the morbidity in vascular surgery patients 24% had major cardiac complications,

the majority of these were myocardial infarctions. Among patients undergoing vascular surgery, preoperative troponin elevation was an independent predictor of cardiac complications with an odds ratio of 1.5, and there was an increased accuracy of this parameter

in vascular surgery as opposed to non-vascular surgery patients. So what about patients undergoing open vascular surgery procedures? This is a prospective study of 455 patients and elevated preoperative troponin level

and a perioperative increase were both independently associated with MACE. You can see here these patients were undergoing a variety of open procedures including aortic, carotid, and peripheral arterial. And you can see here that in any way you look at this,

both the preoperative troponin, the postoperative troponin, the absolute change, and the relative change were all highly associated with MACE. You could add the troponin levels to the RCRI a clinical risk stratification tool and know that this increased the accuracy.

And this is additionally shown here in these receiver operator curves. So this study concluded that a combination of the RCRI with troponin levels can improve the predictive accuracy and therefore allow for better patient management.

This doesn't just happen in open-vascular surgery patients. This is a study that studied troponin levels in acute limb ischaemia patients undergoing endovascular therapy. 254 patients all treated with endovascular intervention

with a 3.9% mortality and a 5.1% amputation rate. Patients who died or required amputation more frequently presented with elevated troponin levels. And the relationship between troponin and worse in-hospital outcome remains significant even when controlling for other factors.

In-hospital death or amputation again and amputation free survival were highly correlated with preoperative troponin levels. You can see here 16.9% in patients with elevated troponins versus 6% in others. And the cardiac troponin level

had a high hazard ratio for predicting worse in-hospital outcomes. This is a study of troponins just in CLI patients with a similar design the measurement of troponin on admission again was a significant independent predictor

of survival with a hazard ratio of 4.2. You can see here that the majority of deaths that did occur were in fact cardiac, and troponin levels correlated highly with both cardiac specific and all-cause mortality. The value of the troponin test was maintained

even when controlling for other risk factors. And these authors felt that the realistic awareness of likely long term prognosis of vascular surgery patients is invaluable when planning suitability for either surgical or endovascular intervention.

And finally, we even have data on the value of preoperative troponin in patients undergoing major amputation. This was a study in which 10 of 44 patients had a non-fatal MI or died from a cardiac cause following amputation.

A rise in the preoperative troponin level was associated with a very poor outcome and was the only significant predictor of postoperative cardiac events. As you can see in this slide. This clearly may be a "Pandora's box".

We really don't know who should have preoperative troponins. What is the cost effectiveness in screening everybody? And in patients with elevated troponin levels, what exactly do we do? Do we cancel surgery, defer it, or change our plan?

However, certainly as vascular surgeons with our high-risk patient population we believe in risk stratification tools. And the RCRI is routinely used as a clinical risk stratification tool. Adding preoperative troponin levels to the RCRI

clearly increases its accuracy in the prediction of patients who will have perioperative cardiac morbidity or mortality. And you can see here that the preoperative troponin level had one of the highest independent hazard ratios at 5.4. Thank you very much for your attention.

- Thank you, and thank you Dr. Veith for the opportunity to present. So, acute aortic syndromes are difficult to treat and a challenge for any surgeon. In regionalization of care of acute aortic syndromes is now a topic of significant conversation. The thoughts are that you can move these patients

to an appropriate hospital infrastructure with surgical expertise and a team that's familiar with treating them. Higher volumes, better outcomes. It's a proven concept in trauma care. Logistics of time, distance, transfer mortality,

and cost are issues of concern. This is a study from the Nationwide Inpatient Sample which basically demonstrates the more volume, the lower mortality for ruptured abdominal aortic aneurysms. And this is a study from Clem Darling

and his Albany Group demonstrating that with their large practice, that if they could get patients transferred to their central hospital, that they had a higher incidence of EVAR with lower mortality. Basically, transfer equaled more EVARs and a

lower mortality for ruptured abdominal aortic aneurysms. Matt Mell looked at interfacility transfer mortality in patients with ruptured abdominal aortic aneurysms to try to see if actually, transfer improved mortality. The take home message was, operative transferred patients

did do better once they reached the institution of destination, however they had a significant mortality during transfer that basically negated that benefit. And transport time, interestingly did not affect mortality. So, regional aortic management, I think,

is something that is quite valuable. As mentioned, access to specialized centers decrease overall mortality and morbidity potentially. In transfer mortality a factor, transport time does not appear to be. So, we set up a rapid transport system

at Keck Medical Center. Basically predicated on 24/7 coverage, and we would transfer any patient within two hours to our institution that called our hotline. This is the number of transfers that we've had over the past three years.

About 250 acute aortic transfers at any given... On a year, about 20 to 30 a month. This is a study that we looked at, that transport process. 183 patients, this is early on in our experience. We did have two that expired en route. There's a listing of the various

pathologies that we treated. These patients were transferred from all over Southern California, including up to Central California, and we had one patient that came from Nevada. The overall mortality is listed here. Ruptured aortic aneurysms had the highest mortality.

We had a very, very good mortality with acute aortic dissections as you can see. We did a univariate and multivariate analysis to look at factors that might have affected transfer mortality and what we found was the SVS score greater than eight

had a very, very significant impact on overall mortality for patients that were transferred. What is a society for vascular surgery comorbidity score? It's basically an equation using cardiac pulmonary renal hypertension and age. The asterisks, cardiac, renal, and age

are important as I will show subsequently. So, Ben Starnes did a very elegant study that was just reported in the Journal of Vascular Surgery where he tried to create a preoperative risk score for prediction of mortality after ruptured abdominal aortic aneurysms.

He found four factors and did an ROC curve. Basically, age greater than 76, creatinine greater than two, blood pressure less than 70, or PH less than 7.2. As you can see, as those factors accumulated there was step-wise increased mortality up to 100% with four factors.

So, rapid transport to regional aortic centers does facilitate the care of acute aortic syndromes. Transfer mortality is a factor, however. Transport mode, time, distance are not associated with mortality. Decision making to deny and accept transfer is evolving

but I think renal status, age, physiologic insult are important factors that have been identified to determine whether transfer should be performed or not. Thank you very much.

- Good morning. I'd like to thank Dr. Veith and Symposium for my opportunity to speak. I have no disclosures. So the in Endovascular Surgery, there is decrease open surgical bypass. But, bypass is still required for many patients with PAD.

Autologous vein is preferred for increase patency lower infection rate. And, Traditional Open Vein Harvest does require lengthy incisions. In 1996 cardiac surgery reported Endoscopic Vein Harvest. So the early prospective randomized trial

in the cardiac literature, did report wound complications from Open Vein Harvest to be as high as 19-20%, and decreased down to 4% with Endoscopic Vein Harvest. Lopes et al, initially, reported increase risk of 12-18 month graft failure and increased three year mortality.

But, there were many small studies that show no effect on patency and decreased wound complications. So, in 2005, Endoscopic Vein Harvest was recommended as standard of care in cardiac surgical patients. So what about our field? The advantages of Open Vein Harvest,

we all know how to do it. There's no learning curve. It's performed under direct visualization. Side branches are ligated with suture and divided sharply. Long term patency of the bypass is established. Disadvantages of the Open Vein Harvest,

large wound or many skip wounds has an increased morbidity. PAD patients have an increased risk for wound complications compared to the cardiac patients as high as 22-44%. The poor healing can be due to ischemia, diabetes, renal failure, and other comorbid conditions.

These can include hematoma, dehiscense, infection, and increased length of stay. So the advantages of Endoscopic Vein Harvest, is that there's no long incisions, they can be performed via one or two small incisions. Limiting the size of an incision

decreases wound complications. It's the standard of care in cardiac surgery, and there's an overall lower morbidity. The disadvantages of is that there's a learning curve. Electro-cautery is used to divide the branches, you need longer vein compared to cardiac surgery.

There's concern about inferior primary patency, and there are variable wound complications reported. So recent PAD data, there, in 2014, a review of the Society of Vascular Surgery registry, of 5000 patients, showed that continuous Open Vein Harvest

was performed 49% of the time and a Endo Vein Harvest about 13% of the time. The primary patency was 70%, for Continuous versus just under 59% for Endoscopic, and that was significant. Endoscopic Vein Harvest was found to be an independent risk factor for a lower one year

primary patency, in the study. And, the length of stay due to wounds was not significantly different. So, systematic review of Endoscopic Vein Harvest data in the lower extremity bypass from '96 to 2013 did show that this technique may reduce

primary patency with no change in wound complications. Reasons for decreased primary patency, inexperienced operator, increased electrocautery injury to the vein. Increase in vein manipulation, you can't do the no touch technique,

like you could do with an Open Harvest. You need a longer conduit. So, I do believe there's a roll for this, in the vascular surgeon's armamentarium. I would recommend, how I use it in my practices is, I'm fairly inexperienced with Endoscopic Vein Harvest,

so I do work with the cardiac PA's. With increased percutaneous procedures, my practice has seen decreased Saphenous Vein Bypasses, so, I've less volume to master the technique. If the PA is not available, or the conduit is small, I recommend an Open Vein Harvest.

The PA can decrease the labor required during these cases. So, it's sometimes nice to have help with these long cases. Close surveillance follow up with Non-Invasive Arterial Imaging is mandatory every three months for the first year at least. Thank you.

- I'd like to thank Dr. Veith and the committee for the privilege of presenting this. I have no disclosures. Vascular problems and the type of injuries could be varied. We all need to have an awareness of acute and chronic injuries,

whether they're traumatic, resulting with compression, occlusion, tumoral and malformation results, or vasospastic. I'd like to present a thoracoscopic manipulation of fractured ribs to prevent descending aortic injury

in a patient with chest trauma. You know, we don't think about this but they can have acute or delayed onset of symptoms and the patient can change and suddenly deteriorate with position changes or with mechanical ventilation,

and this is a rather interesting paper. Here you can see the posterior rib fracture sitting directly adjacent to the aorta like a knife. You can imagine the catastrophic consequences if that wasn't recognized and treated appropriately.

We heard this morning in the venous session that the veins change positions based on the arteries. Well, we need to remember that the arteries and the whole vascular bundle changes position based on the spine

and the bony pieces around them. This is especially too when you're dealing with scoliosis and scoliotic operations and the body positioning whether it's supine or prone the degree of hypo or hyperkyphosis

and the vertebral angles and the methods of instrumentation all need to be considered and remembered as the aorta will migrate based on the body habits of the patient. Screws can cause all kinds of trouble.

Screws are considered risky if they're within one to three millimeters of the aorta or adjacent tissues, and if you just do a random review up to 15% of screws that are placed fall into this category.

Vertebral loops and tortuosity is either a congenital or acquired anomaly and the V2 segment of the vertebral is particularly at risk, most commonly in women in their fifth and sixth decades,

and here you can see instrumentation of the upper cervical spine, anterior corpectomy and the posterior exposures are all associated with a significant and lethal, at times, vertebral artery injuries.

Left subclavian artery injury from excessively long thoracic pedicle screws placed for proximal thoracic scoliosis have been reported. Clavicular osteosynthesis with high neurovascular injury especially when the plunge depth isn't kept in mind

in the medial clavicle have been reported and an awareness and an ability to anticipate injury by looking at the safe zone and finding this on the femur

with your preoperative imaging is a way to help prevent those kinds of problems. Injuries can be from stretch or retraction. Leave it to the French. There's a paper from 2011 that describes midline anterior approach

from the right side to the lumbar spine, interbody fusion and total disc replacement as safer. The cava is more resistant to injury than the left iliac vein and there's less erectile dysfunction reported. We had a patient present recently

with the blue bumps across her abdomen many years after hip complicated course. She'd had what was thought to be an infected hip that was replaced, worsening lower extremity edema, asymmetry of her femoral vein on duplex

and her heterogeneous mask that you can see here on imaging. The iliac veins were occluded and compressed and you could see in the bottom right the varicosities that she was concerned about. Another case is a 71-year-old male who had a post-thrombotic syndrome.

It was worsened after his left hip replacement and his wife said he's just not been the same since. Initially imaging suggests that this was a mass and a tumor. He underwent biopsy

and it showed ghost cells. Here you can see the venogram where we tried to recanalize this and we were unsuccessful because this was actually a combination of bone cement and inflammatory reaction.

Second patient in this category, bless you, is a 67-year-old female who had left leg swelling again after a total hip replacement 20 plus years ago. No DVTs but here you can see the cement compressing the iliac vein.

She had about a 40% patency when you put her through positioning and elected not to have anything done with that. Here you could see on MR how truly compressed this is. IVA suggested it was a little less tight than that.

So a vascular injury occurs across all surgical specialties. All procedures carry risk of bleeding and inadvertent damage to vessels. The mechanisms include tearing, stretching, fracture of calcific plaques,

direct penetration and thermal injury. The types of injuries you hear are most common after hip injuries, they need to be recognized in the acute phase as looking for signs of bleeding or ischemia. Arterial lesions are commonly prone then.

Bone cement can cause thermal injury, erosion, compression and post-implant syndrome. So again, no surgery is immune. You need to be aware and especially when you look at patients in the delayed time period

to consider something called particle disease. This has actually been described in the orthopedic literature starting in the 70s and it's a complex interaction of inflammatory pathways directed at microparticles that come about

through prosthetic wear. So not only acute injury but acute and chronic symptoms. Thank you for the privilege of the floor.

- Thank you Dr. Albaramum, it's a real pleasure to be here and I thank you for being here this early. I have no disclosures. So when everything else fails, we need to convert to open surgery, most of the times this leads to partial endograft removal,

complete removal clearly for infection, and then proximal control and distal control, which is typical in vascular surgery. Here's a 73 year old patient who two years after EVAR had an aneurism growth with what was thought

to be a type II endoleak, had coiling of the infermius mesenteric artery, but the aneurism continued to grow. So he was converted and what we find here is a type III endoleak from sutures in the endograft.

So, this patient had explantations, so it is my preference to have the nordic control with an endovascular technique through the graft where the graft gets punctured and then we put a 16 French Sheath, then we can put a aortic balloon.

And this avoids having to dissect the suprarenal aorta, particularly in devices that have super renal fixation. You can use a fogarty balloon or you can use the pruitt ballon, the advantage of the pruitt balloon is that it's over the wire.

So here's where we removed the device and in spite of the fact that we tried to collapse the super renal stent, you end up with an aortic endarterectomy and a renal endarterectomy which is not a desirable situation.

So, in this instance, it's not what we intend to do is we cut the super renal stent with wire cutters and then removed the struts individually. Here's the completion and preservation of iliac limbs, it's pretty much the norm in all of these cases,

unless they have, they're not well incorporated, it's a lot easier. It's not easy to control these iliac arteries from the inflammatory process that follows the placement of the endograft.

So here's another case where we think we're dealing with a type II endoleak, we do whatever it does for a type II endoleak and you can see here this is a pretty significant endoleak with enlargement of the aneurism.

So this patient gets converted and what's interesting is again, you see a suture hole, and in this case what we did is we just closed the suture hole, 'cause in my mind,

it would be simple to try and realign that graft if the endoleak persisted or recurred, as opposed to trying to remove the entire device. Here's the follow up on that patient, and this patient has remained without an endoleak, and the aneurism we resected

part of the sack, and the aneurism has remained collapsed. So here's another patient who's four years status post EVAR, two years after IMA coiling and what's interesting is when you do delayed,

because the aneurism sacks started to increase, we did delayed use and you see this blush here, and in this cases we know before converting the patient we would reline the graft thinking, that if it's a type III endoleak we can resolve it that way

otherwise then the patient would need conversion. So, how do we avoid the proximal aortic endarterectomy? We'll leave part of the proximal portion of the graft, you can transect the graft. A lot of these grafts can be clamped together with the aorta

and then you do a single anastomosis incorporating the graft and the aorta for the proximal anastomosis. Now here's a patient, 87 years old, had an EVAR,

the aneurism grew from 6 cm to 8.8 cm, he had coil embolization, translumbar injection of glue, we re-lined the endograft and the aneurism kept enlarging. So basically what we find here is a very large type II endoleak,

we actually just clip the vessel and then resected the sack and closed it, did not remove the device. So sometimes you can just preserve the entire device and just take care of the endoleak. Now when we have infection,

then we have to remove the entire device, and one alternative is to use extra-anatomic revascularization. Our preference however is to use cryo-preserved homograft with wide debridement of the infected area. These grafts are relatively easy to remove,

'cause they're not incorporated. On the proximal side you can see that there's a aortic clamp ready to go here, and then we're going to slide it out while we clamp the graft immediately, clamp the aorta immediately after removal.

And here's the reconstruction. Excuse me. For an endograft-duodenal fistula here's a patient that has typical findings, then on endoscopy you can see a little bit of the endograft, and then on an opergy I series

you actually see extravasation from the duodenal. In this case we have the aorta ready to be clamped, you can see the umbilical tape here, and then take down the fistula, and then once the fistula's down

you got to repair the duodenal with an omental patch, and then a cryopreserved reconstruction. Here's a TEVAR conversion, a patient with a contained ruptured mycotic aneurysm, we put an endovascular graft initially, Now in this patient we do the soraconomy

and the other thing we do is, we do circulatory support. I prefer to use ECMO, in this instances we put a very long canula into the right atrium, which you're anesthesiologist can confirm

with transassof forgeoligico. And then we use ECMO for circulatory support. The other thing we're doing now is we're putting antibiotic beads, with specific antibiotic's for the organism that has been cultured.

Here's another case where a very long endograft was removed and in this case, we put the device offline, away from the infected field and then we filled the field with antibiotic beads. So we've done 47 conversions,

12 of them were acute, 35 were chronic, and what's important is the mortality for acute conversion is significant. And at this point the, we avoid acute conversions,

most of those were in the early experience. Thank you.

- Good afternoon, Dr. Veith, organizer. Thank you very much for the kind invitation. I have nothing to disclose. In the United States, the most common cause of mortality after one year of age is trauma. So, thankfully the pediatric vascular trauma

is only a very small minority, and it happens in less that 1% of all the pediatric traumas. But, when it happens it contributes significantly to the mortality. In most developed countries, the iatrogenic

arterial injuries are the most common type of vascular injuries that you have in non-iatrogenic arterial injuries, however are more common in war zone area. And it's very complex injuries that these children suffer from.

In a recent study that we published using the national trauma data bank, the mortality rate was about 7.9% of the children who suffer from vascular injuries. And the most common mechanism of injury were firearm and motor vehicle accidents. In the US, the most common type of injury is the blunt type

of injury. As far as the risk factors for mortality, you can see some of them that are significantly affecting mortality, but one of them is the mechanism of injury, blunt versus penetrating and the penetrating is the risk factor for

mortality. As far as the anatomical and physiological consideration for treatment, they are very similar to adults. Their injury can cause disruption all the way to a spasm, or obstruction of the vessel and for vasiospasm and minimal disruption, conservative therapy is usually adequate.

Sometimes you can use papevrin or nitroglycerin. Of significant concern in children is traumatic AV fissure that needs to be repaired as soon as possible. For hard signs, when you diagnose these things, of course when there is a bleeding, there is no question that you need to go repair.

When there are no hard signs, especially in the blunt type of injuries, we depend both on physical exams and diagnostic tools. AVI in children is actually not very useful, so instead of that investigators are just using what is called an Injured Extremity Index, which you measure one leg

versus the other, and if there is also less than 0.88 or less than 0.90, depending on the age of the children, is considered abnormal. Pulse Oximetry, the Duplex Ultrasound, CTA are all very helpful. Angiography is actually quite risky in these children,

and should be avoided. Surgical exploration, of course, when it's needed can give very good results. As far as the management, well they are very similar to adults, in the sense that you need to expose the artery, control the bleeding, an then restore circulation to the

end organ. And some of the adjuncts that are using in adult trauma can be useful, such as use of temporary shunts, that you can use a pediatric feeding tube, heparin, if there are no contraindications, liberal use of fasciotomy and in the vascular technique that my partner, Dr. Singh will be

talking about. Perhaps the most common cause of PVI in young children in developed countries are iatrogenic injuries and most of the time they are minimal injuries. But in ECMO cannulation, 20-50% are injuries due to

ECMO have been reported in both femoral or carotid injuries. So, in the centers are they are doing it because of the concern about limb ischemia, as well as cognitive issues. They routinely repair the ECMO cannulation site.

For non-iatrogenic types, if is very common in the children that are above six years of age. Again, you follow the same principal as adult, except that these arteries are severely spastic and interposition graft must accommodate both axial and radial growths of these arteries, as well as the limb that it's been

repaired in. Primary repair sometimes requires interrupted sutures and Dr. Bismuth is going to be talking about some of that. Contralateral greater saphenous vein is a reasonable option, but this patient needs to be followed very, very closely.

The most common type of injury is upper extremity and Dr. McCurdy is going to be talking about this. Blunt arterial injury to the brachial artery is very common. It can cause ischemic contracture and sometimes amputation.

In the children that they have no pulse, is if there are signs of neurosensory deficit and extremity is cold, exploration is indicated, but if the extremity is pulseless, pink hand expectant treatment is reasonable. As far as the injuries, the most common, the deadliest injuries are related to the truncal injuries and the

mechanism severity of this injury dictates the treatment. Blunt aortic injuries are actually quite uncommon and endovascular options are limited. This is an example of one that was done by Dr Veith and you can see the arrow when the stent was placed and then moved.

So these children, the long-term results of endovascular option is unknown. So in summary, you basically follow many tenets of adult vascular trauma. Special consideration for repair has to do with the fact that you need to accommodate longitudinal

and radial growth and also endovascular options are limited. Ultimately, you need a collaborative effort of many specialists in taking care of these children. Thank you.

- I will be talking about new KDOQI guidelines. I know many of you have heard about KDOQI guidelines being revised for the past maybe over a year or maybe two. Yes, it is being done, and it is going slow only because it's being done in a very different way. It's more than an update.

It's going to be more of an overhaul for the entire KDOQI guidelines. We in KDOQI have looked at access as a solitary problem like we talked about grafts, catheters, fistulas for access, but actually it sort of turns out

that access is part of a bigger problem. Fits into a big ESKD lifeline of a patient. Instated distal patients come in many varieties. It can affect any age, and they have a lot of other problems so once you have chronic renal failure, renal replacement mortality fits in

only when it becomes Stage IV or Stage V. And renal replacement mortality is not just access, it is PD access, it's hemo access, it is transplant. So these things, we need to see how they fit in in a given person. So the new KDOQI guidelines concentrates more

on individualizing care. For example, here the young Darien was an 11 year old with a prune belly syndrome. Now he has failed PD. Then there's another person here who is Lydia who is about 36 or 40 year old lady

with a insulin dependent diabetes. Already has bad vascular pedicle. Lost both legs. Needs access. Now both these patient though they need access, it's not the same.

It's different. For example, if you think of Darien, he was in PD but he has failed PD. We would love to get him transplanted. Unfortunately he's got terrible social situation so we can't get him transplanted.

So he needs hemo. Now if he needs hemo, we need to find an access that lasts for a long time because he's got many years ahead of him. On the other hand we have Lydia, who has got significant vascular disease.

With her obesity and existing infectious status, probably PD won't be a good option for her. So she needs hemo, and she's obviously not a transplant candidate. So how are we going to plan for hemo? So these are things which we are to more concentrate

and individualize when we look at patients, and the new guidelines concentrate more on these sort of aspects. Doing right access for right patient, right time, and for right reasons. And we go about planning this keeping the patient first

then a life plan ESKD lifeline for the patient, and what access we are looking at, and what are the needs of the patient? Now this is also different because it has been done more scientifically. We actually have a evidence review team.

We just poured over pretty much 1500 individual articles. Recent articles. And we have looked through about 4000 abstracts and other articles. And this data is correlated through a workgroup. There a lot of new chapters.

Chapter specific surgery like peri-operative, intra-operative, post-operative, cat issues, managing complication issues. And we started off with the coming up with the Scope of Work. The evidence review team took the Scope of Work

and tried to get all the articles and sift through the articles and came up and rated the evidence using a certain rating system which is very scientific. The workgroup then kind of evaluated the whole system, and then came up with what is clinically relevant.

It's one thing for statisticians to say how strong evidence this is, but it's another thing how it is looked upon by the clinicians. So then we kind of put this into a document. Document went through internal and external review process.

This is the process we have tried to do it. Dr. Lok has been the Chair of the group. Myself and Dr. Yevzlin are the Vice-Chairs. We have incredible workgroup which has done most of the work. And here are the workgroup members.

We comprised of nephrologist, transplant surgeons, vascular surgeons, Allied Health personnel, pediatric nephrologist so it's a multi interventional radiologist and interventional nephrologist. This is a multi disciplinary group which has gone through this process.

Timothy Wilt from Minnesota was the head of the Evidence Review Team, who has worked on the evidence building. And now for the editorial sections we have Dr. Huber, Lee, and Dr. Lok taking care of it. So where are we today?

We have pretty much gone through the first part of it. We are at the place where we are ready for the Internal Review and External Review. So many of you probably will get a chance to look through it when it comes for the External Review and would love

to have your comments on this document. Essentially, we are looking at access in the context of end stage renal disease, and that is new. And obviously we have gone through and done a very scientific review, a very scientific methodology to try

to evaluate the evidence and try to come up with guidelines. Thank you.

- Thank you very much. It's an hono ou to the committee for the invitation. So, I'll be discussing activity recommendations for our patients after cervical artery dissection. I have no relevant disclosures.

And extracranial cervical artery dissection is an imaging diagnosis as we know with a variety of presentations. You can see on the far left the intimal flap and double lumen in the left vertebral artery

on both coronal and axial imaging, a pseudoaneurysm of the internal carotid artery, aneurysmal degeneration in an older dissection, and an area of long, smooth narrowing followed by normal artery, and finally a flame-tipped occlusion.

Now, this affects our younger patients with really opposity of atherosclerotic risk factors. So, cervical artery dissection accounts for up to 25% of stroke in patients under the age of 45. And, other than hypertension, it's not associated with any cardiovascular risk factors.

There is a male predominance, although women with dissections seem to present about five years younger. And there is an indication that there may be a systemic ateriopathy contributing to this in our patients, and I'll show you some brief data regarding that.

So, in studies that have looked at vessel redundancy, including loops, coils, and in the video image, an S curve on carotid duplex. Patients with cervical artery dissection have a much higher proportion of these findings, up to three to four times more than

age and sex matched controls. They also have findings on histology of the temporal artery when biopsied. So one study did this and these patients had abnormal capillary formation as well as extravasation of blood cells between the median adventitia

of the superficial temporal artery. And there is an association with FMD and a shared genetic polymorphism indicating that there may be shared pathophysiology for these conditions. But in addition, a lot of patients report minor trauma around the time or event of cervical artery dissection.

So this data from CADISP, and up to 40% of cases had minor trauma related to their dissection, including chiropractic neck manipulation, extreme head movements, or stretching, weight lifting, and sports-related injuries. Thankfully, the majority of patients do very well after

they have a dissection event, but a big area of concern for the patient and their provider is their risk for recurrence. That's highest around the original event, about 2% within the first month, and thereafter, it's stable at 1% per year,

although recurrent pain can linger for many years. So what can we tell our patients in terms of reducing their risk for a recurrent event? Well, most of the methods are around reducing any sort of impulse, stress, or pressure on the arteries, both intrinsically and extrinsically,

including blood pressure control. I advise my patients to avoid heavy lifting, and by that I mean more than 30 pounds, and intense valsalva or isometric exercise. So shown here is a photo of the original World's Strongest Man lifting four

adult-sized males in addition to weights, but there's been studies in the physiology literature with healthy, younger males in their 20s, and they're asked to do a double-leg press, or even arm-curls, and with this exercise and repetitions, they can get mean systolic pressures,

or mean pressures up into the 300s, as well as heart rate into the 170s. I also tell my patients to avoid any chiropractic neck manipulation or deep tissue massage of the neck, as well as high G-force activities like a roller coaster.

There are some case reports of cervical artery dissection related to this. And then finally, what can they do about cardio? A lot of these patients are very anxious, they're concerned about re-incorporating exercise after they've been through something like this,

so I try to give them some kind of guidelines and parameters that they can follow when they re institute exercise, not unlike cardiac rehabilitation. So initially, I tell them "You can do light walking, but if you don't feel well,

or something's hurting, neck pain, headache, don't push it." Thereafter, they can intensify to a heart rate maximum of 70-75% of their maximum predicted heart rate, and that's somewhere between months zero and three, and then afterwards when they're feeling near normal,

I give them an absolute limit of 90% of their maximum predicted heart rate. And I advise all of my patients to avoid extreme exercise like Orange Theory, maybe even extreme cycling classes, marathons, et cetera. Thank you.

- These are my disclosures. So central venous access is frequently employed throughout the world for a variety of purposes. These catheters range anywhere between seven and 11 French sheaths. And it's recognized, even in the best case scenario, that there are iatrogenic arterial injuries

that can occur, ranging between three to 5%. And even a smaller proportion of patients will present after complications from access with either a pseudoaneurysm, fistula formation, dissection, or distal embolization. In thinking about these, as you see these as consultations

on your service, our thoughts are to think about it in four primary things. Number one is the anatomic location, and I think imaging is very helpful. This is a vas cath in the carotid artery. The second is th

how long the device has been dwelling in the carotid or the subclavian circulation. Assessment for thrombus around the catheter, and then obviously the size of the hole and the size of the catheter.

Several years ago we undertook a retrospective review and looked at this, and we looked at all carotid, subclavian, and innominate iatrogenic injuries, and we excluded all the injuries that were treated, that were manifest early and treated with just manual compression.

It's a small cohort of patients, we had 12 cases. Eight were treated with a variety of endovascular techniques and four were treated with open surgery. So, to illustrate our approach, I thought what I would do is just show you four cases on how we treated some of these types of problems.

The first one is a 75 year-old gentleman who's three days status post a coronary bypass graft with a LIMA graft to his LAD. He had a cordis catheter in his chest on the left side, which was discovered to be in the left subclavian artery as opposed to the vein.

So this nine French sheath, this is the imaging showing where the entry site is, just underneath the clavicle. You can see the vertebral and the IMA are both patent. And this is an angiogram from a catheter with which was placed in the femoral artery at the time that we were going to take care of this

with a four French catheter. For this case, we had duel access, so we had access from the groin with a sheath and a wire in place in case we needed to treat this from below. Then from above, we rewired the cordis catheter,

placed a suture-mediated closure device, sutured it down, left the wire in place, and shot this angiogram, which you can see very clearly has now taken care of the bleeding site. There's some pinching here after the wire was removed,

this abated without any difficulty. Second case is a 26 year-old woman with a diagnosis of vascular EDS. She presented to the operating room for a small bowel obstruction. Anesthesia has tried to attempt to put a central venous

catheter access in there. There unfortunately was an injury to the right subclavian vein. After she recovered from her operation, on cross sectional imaging you can see that she has this large pseudoaneurysm

coming from the subclavian artery on this axial cut and also on the sagittal view. Because she's a vascular EDS patient, we did this open brachial approach. We placed a stent graft across the area of injury to exclude the aneurism.

And you can see that there's still some filling in this region here. And it appeared to be coming from the internal mammary artery. We gave her a few days, it still was patent. Cross-sectional imaging confirmed this,

and so this was eventually treated with thoracoscopic clipping and resolved flow into the aneurism. The next case is a little bit more complicated. This is an 80 year-old woman with polycythemia vera who had a plasmapheresis catheter,

nine French sheath placed on the left subclavian artery which was diagnosed five days post procedure when she presented with a posterior circulation stroke. As you can see on the imaging, her vertebral's open, her mammary's open, she has this catheter in the significant clot

in this region. To manage this, again, we did duel access. So right femoral approach, left brachial approach. We placed the filter element in the vertebral artery. Balloon occlusion of the subclavian, and then a stent graft coverage of the area

and took the plasmapheresis catheter out and then suction embolectomy. And then the last case is a 47 year-old woman who had an attempted right subclavian vein access and it was known that she had a pulsatile mass in the supraclavicular fossa.

Was noted to have a 3cm subclavian artery pseudoaneurysm. Very broad base, short neck, and we elected to treat this with open surgical technique. So I think as you see these consults, the things to factor in to your management decision are: number one, the location.

Number two, the complication of whether it's thrombus, pseudoaneurysm, or fistula. It's very important to identify whether there is pericatheter thrombus. There's a variety of techniques available for treatment, ranging from manual compression,

endovascular techniques, and open repair. I think the primary point here is the prevention with ultrasound guidance is very important when placing these catheters. Thank you. (clapping)

- Thank you. I have two talks because Dr. Gaverde, I understand, is not well, so we- - [Man] Thank you very much. - We just merged the two talks. All right, it's a little joke. For today's talk we used fusion technology

to merge two talks on fusion technology. Hopefully the rest of the talk will be a little better than that. (laughs) I think we all know from doing endovascular aortic interventions

that you can be fooled by the 2D image and here's a real life view of how that can be an issue. I don't think I need to convince anyone in this room that 3D fusion imaging is essential for complex aortic work. Studies have clearly shown it decreases radiation,

it decreases fluoro time, and decreases contrast use, and I'll just point out that these data are derived from the standard mechanical based systems. And I'll be talking about a cloud-based system that's an alternative that has some advantages. So these traditional mechanical based 3D fusion images,

as I mentioned, do have some limitations. First of all, most of them require manual registration which can be cumbersome and time consuming. Think one big issue is the hardware based tracking system that they use. So they track the table rather than the patient

and certainly, as the table moves, and you move against the table, the patient is going to move relative to the table, and those images become unreliable. And then finally, the holy grail of all 3D fusion imaging is the distortion of pre-operative anatomy

by the wires and hardware that are introduced during the course of your procedure. And one thing I'd like to discuss is the possibility that deep machine learning might lead to a solution to these issues. How does 3D fusion, image-based 3D fusion work?

Well, you start, of course with your pre-operative CT dataset and then you create digitally reconstructed radiographs, which are derived from the pre-op CTA and these are images that resemble the fluoro image. And then tracking is done based on the identification

of two or more vertebral bodies and an automated algorithm matches the most appropriate DRR to the live fluoro image. Sounds like a lot of gobbledygook but let me explain how that works. So here is the AI machine learning,

matching what it recognizes as the vertebral bodies from the pre-operative CT scan to the fluoro image. And again, you get the CT plus the fluoro and then you can see the overlay with the green. And here's another version of that or view of that.

You can see the AI machine learning, identifying the vertebral bodies and then on your right you can see the fusion image. So just, once again, the AI recognizes the bony anatomy and it's going to register the CT with the fluoro image. It tracks the patient, not the table.

And the other thing that's really important is that it recognizes the postural change that the patient undergoes between the posture during the CT scan, versus the posture on the OR table usually, or often, under general anesthesia. And here is an image of the final overlay.

And you can see the visceral and renal arteries with orange circles to identify them. You can remove those, you can remove any of those if you like. This is the workflow. First thing you do is to upload the CT scan to the cloud.

Then, when you're ready to perform the procedure, that is downloaded onto the medical grade PC that's in your OR next to your fluoro screen, and as soon as you just step on the fluoro pedal, the CYDAR overlay appears next to your, or on top of your fluoro image,

next to your regular live fluoro image. And every time you move the table, the computer learning recognizes that the images change, and in a couple of seconds, it replaces with a new overlay based on the obliquity or table position that you have. There are some additional advantages

to cloud-based technology over mechanical technology. First of all, of course, or hardware type technology. Excuse me. You can upgrade it in real time as opposed to needing intermittent hardware upgrades. Works with any fluoro equipment, including a C-arm,

so you don't have to match your 3D imaging to the brand of your fluoro imaging. And there's enhanced accuracy compared to mechanical registration systems as imaging. So what are the clinical applications that this can be utilized for?

Fluoroscopy guided endovascular procedures in the lower thorax, abdomen, and pelvis, so that includes EVAR and FEVAR, mid distal TEVAR. At present, we do need two vertebral bodies and that does limit the use in TEVAR. And then angioplasty stenting and embolization

of common iliac, proximal external and proximal internal iliac artery. Anything where you can acquire a vertebral body image. So here, just a couple of examples of some additional non EVAR/FEVAR/TEVAR applications. This is, these are some cases

of internal iliac embolization, aortoiliac occlusion crossing, standard EVAR, complex EVAR. And I think then, that the final thing that I'd like to talk about is the use with C-arm, which is think is really, extremely important.

Has the potential to make a very big difference. All of us in our larger OR suites, know that we are short on hybrid availability, and yet it's difficult to get our institutions to build us another hybrid room. But if you could use a high quality 3D fusion imaging

with a high quality C-arm, you really expand your endovascular capability within the operating room in a much less expensive way. And then if you look at another set of circumstances where people don't have a hybrid room at all, but do want to be able to offer standard EVAR

to their patients, and perhaps maybe even basic FEVAR, if there is such a thing, and we could use good quality imaging to do that in the absence of an actual hybrid room. That would be extremely valuable to be able to extend good quality care

to patients in under-served areas. So I just was mentioning that we can use this and Tara Mastracci was talking yesterday about how happy she is with her new room where she has the use of CYDAR and an excellent C-arm and she feels that she is able to essentially run two rooms,

two hybrid rooms at once, using the full hybrid room and the C-arm hybrid room. Here's just one case of Dr. Goverde's. A vascular case that he did on a mobile C-arm with aortoiliac occlusive disease and he places kissing stents

using a CYDAR EV and a C-arm. And he used five mils of iodinated contrast. So let's talk about a little bit of data. This is out of Blain Demorell and Tara Mastrachi's group. And this is use of fusion technology in EVAR. And what they found was that the use of fusion imaging

reduced air kerma and DSA runs in standard EVAR. We also looked at our experience recently in EVAR and FEVAR and we compared our results. Pre-availability of image based fusion CT and post image based fusion CT. And just to clarify,

we did have the mechanical product that Phillip's offers, but we abandoned it after using it a half dozen times. So it's really no image fusion versus image fusion to be completely fair. We excluded patients that were urgent/emergent, parallel endographs, and IBEs.

And we looked at radiation exposure, contrast use, fluoro time, and procedure time. The demographics in the two groups were identical. We saw a statistically significant decrease in radiation dose using image based fusion CT. Statistically a significant reduction in fluoro time.

A reduction in contrast volume that looks significant, but was not. I'm guessing because of numbers. And a significantly different reduction in procedure time. So, in conclusion, image based 3D fusion CT decreases radiation exposure, fluoro time,

and procedure time. It does enable 3D overlays in all X-Ray sets, including mobile C-arm, expanding our capabilities for endovascular work. And image based 3D fusion CT has the potential to reduce costs

and improve clinical outcomes. Thank you.

- Good afternoon to everybody, this is my disclosure. Now our center we have some experience on critical hand ischemia in the last 20 years. We have published some papers, but despite the treatment of everyday, of food ischemia including hand ischemia is not so common. We had a maximum of 200 critical ischemic patients

the majority of them were patient with hemodialysis, then other patients with Buerger's, thoracic outlet syndrome, etcetera. And especially on hemodialysis patients, we concentrate on forearms because we have collected 132 critical ischemic hands.

And essentially, we can divide the pathophysiology of this ischemic. Three causes, first is that the big artery disease of the humeral and below the elbow arteries. The second cause is the small artery disease

of the hand and finger artery. And the third cause is the presence of an arterial fistula. But you can see, that in active ipsillateral arteriovenous fistula was present only 42% of these patients. And the vast majority of the patients

who had critical hand ischemia, there were more concomitant causes to obtain critical hand ischemia. What can we do in these types of patients? First, angioplasty. I want to present you this 50 years old male

with diabetes type 1 on hemodialysis, with previous history of two failed arteriovenous fistula for hemodialysis. The first one was in occluded proximal termino-lateral radiocephalic arteriovenous fistula. So, the radial artery is occluded.

The second one was in the distal latero-terminal arteriovenous fistula, still open but not functioning for hemodialysis. Then, we have a cause of critical hand ischemia, which is the occlusion of the ulnar artery. What to do in a patient like this?

First of all, we have treated this long occlusion of the ulnar artery with drug-coated ballooning. The second was treatment of this field, but still open arteriovenous fistula, embolized with coils. And this is the final result,

you can see how blood flow is going in this huge superficial palmar arch with complete resolution of the ischemia. And the patient obviously healed. The second thing we can do, but on very rarely is a bypass. So, this a patient with multiple gangrene amputations.

So, he came to our cath lab with an indication to the amputation of the hand. The radial artery is totally occluded, it's occluded here, the ulnar artery is totally occluded. I tried to open the radial artery, but I understood that in the past someone has done

a termino-terminal radio-cephalic arteriovenous fistula. So after cutting, the two ends of the radial artery was separated. So, we decided to do a bypass, I think that is one of the shortest bypass in the world. Generally, I'm not a vascular surgeon

but generally vascular surgeons fight for the longest bypass and not for the shortest one. I don't know if there is some race somewhere. The patient was obviously able to heal completely. Thoracic sympathectomy. I have not considered this option in the past,

but this was a patient that was very important for me. 47 years old female, multiple myeloma with amyloidosis. Everything was occluded, I was never able to see a vessel in the fingers. The first time I made this angioplasty,

I was very happy because the patient was happy, no more pain. We were able to amputate this finger. Everything was open after three months. But in the subsequent year, the situation was traumatic. Every four or five months,

every artery was totally occluded. So, I repeated a lot of angioplasty, lot of amputations. At the end it was impossible to continue. After four years, I decided to do something, or an amputation at the end. We tried to do endoscopic thoracic sympathectomy.

There is a very few number of this, or little to regard in this type of approach. But infected, no more pain, healing. And after six years, the patient is still completely asymptomatic. Unbelievable.

And finally, the renal transplant. 36 years old female, type one diabetes, hemodialysis. It was in 2009, I was absolutely embarrassed that I tried to do something in the limbs, inferior limbs in the hand.

Everything was calcified. At the end, we continued with fingers amputation, a Chopart amputation on one side and below the knee major amputation. Despite this dramatic clinical stage, she got a double kidney and pancreas transplant on 2010.

And then, she healed completely. Today she is 45 years old, this summer walking in the mountain. She sent to me a message, "the new leg prostheses are formidable". She's driving a car, totally independent,

active life, working. So, the transplant was able to stop this calcification, this small artery disease which was devastating. So, patients with critical high ischemia have different pathophysiology and different underlying diseases.

Don't give up and try to find for everyone the proper solution. Thank you very much for your attention.

- Thank you very much and thank you Dr. Veith for the kind invite. Here's my disclosures, clearly relevant to this talk. So we know that after EVAR, it's around the 20% aortic complication rate after five years in treating type one and three Endoleaks prevents subsequent

secondary aortic rupture. Surveillance after EVAR is therefore mandatory. But it's possible that device-specific outcomes and surveillance protocols may improve the durability of EVAR over time. You're all familiar with this graph for 15 year results

in terms of re-intervention from the EVAR-1 trials. Whether you look at all cause and all re-interventions or life threatening re-interventions, at any time point, EVAR fares worse than open repair. But we know that the risk of re-intervention is different

in different patients. And if you combine pre-operative risk factors in terms of demographics and morphology, things are happening during the operations such as the use of adjuncts,

or having to treat intro-operative endoleak, and what happens to the aortic sac post-operatively, you can come up with a risk-prediction tool for how patients fare in the longer term. So the LEAR model was developed on the Engage Registry and validated on some post-market registries,

PAS, IDE, and the trials in France. And this gives a predictive risk model. Essentially, this combines patients into a low risk group that would have standard surveillance, and a higher risk group, that would have a surveillance plus

or enhanced surveillanced model. And you get individual patient-specific risk profiles. This is a patient with around a seven centimeter aneurysm at the time of repair that shows sac shrinkage over the first year and a half, post-operatively. And you can see that there's really a very low risk

of re-intervention out to five years. These little arrow bars up here. For a patient that has good pre-operative morphology and whose aneurysm shrinks out to a year, they're going to have a very low risk of re-intervention. This patient, conversely, had a smaller aneurysm,

but it grew from the time of the operation, and out to two and a half years, it's about a centimeter increase in the sac. And they're going to have a much higher risk of re-intervention and probably don't need the same level of surveillance as the first patient.

and probably need a much higher rate of surveillance. So not only can we have individualized predictors of risk for patients, but this is the regulatory aspect to it as well.

Multiple scenario testing can be undertaken. And these are improved not only with the pre-operative data, but as you've seen with one-year data, and this can tie in with IFU development and also for advising policy such as NICE, which you'll have heard a lot about during the conference.

So this is just one example. If you take a patient with a sixty-five millimeter aneurysm, eighteen millimeter iliac, and the suprarenal angle at sixty degrees. If you breach two or more of these factors in red, we have the pre-operative prediction.

Around 20% of cases will be in the high risk group. The high risk patients have about a 50-55% freedom from device for related problems at five years. And the low risk group, so if you don't breach those groups, 75% chance of freedom from intervention.

In the green, if you then add in a stent at one year, you can see that still around 20% of patients remain in the high risk group. But in the low risk group, you now have 85% of patients won't need a re-intervention at five years,

and less of a movement in the high risk group. So this can clearly inform IFU. And here you see the Kaplan-Meier curves, those same groups based pre-operatively, and at one year. In conclusion, LEAR can provide

a device specific estimation of EVAR outcome out to five years. It can be based on pre-operative variables alone by one year. Duplex surveillance helps predict risk. It's clearly of regulatory interest in the outcomes of EVAR.

And an E-portal is being developed for dissemination. Thank you very much.

- I just like the title 'cuz I think we're in chaos anyway. Chaos management theory. Alright, unfortunately I have nothing to disclose, it really upsets me. I wish I had a laundry list to give you. Gettin' checks from everybody, it would be great. Let's start off with this chaos, what has been published.

Again "Ul Haq et al" is a paper from Hopkins. Bleomycin foam treatment of malformations, a promising agent. And they had 20 patients, 21 Bleomycin procedures. (mumbles) sclerosants in a few other patients, 40% complication rate, 30% minor, 10% major.

On a per procedure basis it was a 29% with about 7% major. All patients had decrease in symptoms. But to say "I use Bleomycin" or "I use X" because a complication (mumbles) is nonsense, you're mentally masturbating. It ain't going to be that way, you're going to have complications.

Alright, the use of Bleomycin should be reserved for locations where post-procedure swelling would be dangerous. Well they used it, and one patient required intubation for four days and another patient 15 days. So, it can happen with any agent.

So I don't know why that statement was made. "Hassan et al", noninvasive management of hemangiomas and vascular malformations using Bleomycin again, this handles the plastic surgery a few years ago. 71% effectiveness rate, 29% failure rate,

14% complication rate, 5 major ulcerations. Ulcerations happen with any agent. You're not going to escape that by saying, "Oh, well I'm not going to use alcohol because (mumbles)." No you're going to get it anyway. You all in the literature.

"Sainsbury", intra-lesional Bleomycin injection for vascular birthmarks five year experience again, 2011. 82% effectiveness, 17.3 for failure. Compli- severe blistering, ulcers, swelling, infections, recurrences. Okay, everybody's reporting it.

"Bai et al" sclerotherapy for lymphatic, oral and facial region, 2009. 43% effectiveness, but they found if they used it with surgery they had a higher effectiveness rate. Good. But again that's their effectiveness.

"Young et al", Bleomycin A5 cervico-facial vascular surgery, 2011. 81% effectiveness rate 19% failure for macrocystic. 37% failure from microcystic disease. Complications: ulcerations, hematoma, bleeding, fevers, soft tissue atrophy.

"Zhang et al." Now this is a study. They're goin' head-to-head alcohol versus Bleo. Oh, isn't that a nice thing to do. Huh, funny how that can happen sometimes. There's another paper out of Canada

that doesn't matter, there's 17 pages and there's no statistical significance for that. 138 patients, you got a lot of statistics. "Zhang et al", 138 children. 71 of 75 patients, which is 95% of that serie, were either cured,

markedly effective, or effective, with alcohol. In the Bleo group 41 of 63, that is 65% of the patients, had effective treatment. That means no cures, no markedly effective, just effective. That's their head-to-head comparison. Difference between Ethanol and

the Bleo group again was statistically significant. Ethanol at 75 patients of 14 cases skin necrosis. Bleo group at 63 patients of 5 cases skin necrosis. And in that group they stated it is statistically superior to Bleo. 95 versus 60, that's a big deal.

Again, cured, disappearance post-treatment without recurrence. Markedly effective, meant that greater than 80% was ablated. Effective means about less that 80% reduction but improved. Ineffective, no change. That was their criterion on that paper.

Again, 30 cases, superficial VMs effective rate was 95% in the Ethanol group and the deep group 94%. Okay. What was in the Bleo group? 68% superficial, 56% of deep group. So that's a statistical significance

of failure, between the two agents, comparing head-to-head in anatomic areas. Ethanol VM papers, let's go on to that, we're goin' to do other stuff. "Lee et al", advanced management, 2003, midterm results. 399 procedures in 87 patients,

95% significant or complete ablation, 12.4% complication. "Johnson et al", Kansas. University of Kansas med center, 2002. 100% success rate in tongues. One patient had a massive tongue and had breathing difficulties prior to treatment

remained intubated 5 days and then uneventfully discharged, that was their only complication. "Su et al", ethanol sclerotherapy, face and neck. Again, these are complex anatomies with complex issues of cranial nerves as well as airway control. 2010, 56 of 60 procedures, 90%, four minimal residual,

no skin necrosis, no nerve injuries. "Orlando", outpatient percutaneous treatment, low doses under local anesthesia. This is a very interesting paper out of Brazil. They did 'em under IV sedation, just a little bit by little bit.

They said they had trouble gettin' general so they had to figure another way. Smart, I like people thinkin' things out. Who here doesn't have a problem with anesthesia? Gettin' 'em not to quit before two o'clock? (laughs)

Alright, used local only 39 patients extremity VMs, main symptoms of pain. Cure or significant improvement in 94%. One ulcer, 3 transient paresthesias. "Lee et al", sclerotherapy craniofacial again, 2009. 87 patients, 75% were reductions.

71 of 87 excellent outcomes. One patient transient, tongue decreased sensation. One transient facial nerve palsy, no skin injuries. "Vogelzang" is a very important paper of a single center. Is that author- anybody here? Again, they did VMs and AVMs in this series

and then a per patient complication rate is 13.3, in AMVs 9.7 per patient, but I think what also is important is to do things with regards to procedures. And they listed both. So we'll just, it's about time to quit. This is our embolization series.

And neck, upper extremity, all the anatomies. And we're about a 10 to three ratio with regards to VM/LMs to AVMs in numbers. I think everybody's pretty much like that, a third of their practice. Again, our minor complications are that.

Major complications are these. Summary, what we found in the literature is that Ethanol publications state its efficacy rate routinely at 90 to 100%. And all other second tier sclerosants are 60 to 80%. So I think that's the take home message.

Thank you.

- Thank you Mr Chairman, ladies and gentlemen. These are my disclosure. Open repair is the gold standard for patient with arch disease, and the gupta perioperative risk called the mortality and major morbidity remain not negligible.

Hybrid approach has only slightly improved these outcomes, while other off-the-shelf solution need to be tested on larger samples and over the long run. In this scenario, the vascular repair would double in the branch devices as emerging, as a tentative option with promising results,

despite addressing a more complex patient population. The aim of this multi-center retrospective registry is to assess early and midterm results after endovascular aortic arch repair. using the single model of doubling the branch stent graft in patient to fit for open surgery.

All patient are treated in Italy, with this technique. We're included in this registry for a total of 24 male patient, fit for open surgery. And meeting morphological criteria for double branch devices.

This was the indication for treatment and break-down by center, and these were the main end points. You can see here some operative details. Actually, this was theo only patient that did not require the LSA

re-revascularization before the endovascular procedure, because the left tibial artery rising directly from the aortic arch was reattached on the left common carotid artery. You can see here the large window in the superior aspect of the stent graft

accepting the two 13 millimeter in the branches, that are catheterized from right common carotid artery and left common carotid artery respectively. Other important feature of this kind of stent graft is the lock stent system, as you can see, with rounded barbs inside

the tunnels to prevent limb disconnection. All but one patient achieved technical success. And two of the three major strokes, and two retrograde dissection were the cause of the four early death.

No patient had any type one or three endoleak. One patient required transient dialysis and four early secondary procedure were needed for ascending aorta replacement and cervical bleeding. At the mean follow-up of 18 months,

one patient died from non-aortic cause and one patient had non-arch related major stroke. No new onset type one or three endoleak was detected, and those on standard vessel remained patent. No patient had the renal function iteration or secondary procedure,

while the majority of patients reported significant sac shrinkage. Excluding from the analysis the first six patients as part of a learning curve, in-hospital mortality, major stroke and retrograde dissection rate significant decrease to 11%, 11% and 5.67%.

Operative techniques significantly evolve during study period, as confirmed by the higher use of custom-made limb for super-aortic stenting and the higher use of common carotid arteries

as the access vessels for this extension. In addition, fluoroscopy time, and contrast median's significantly decrease during study period. We learned that stroke and retrograde dissection are the main causes of operative mortality.

Of course, we can reduce stroke rate by patient selection excluding from this technique all those patient with the Shaggy Aorta Supra or diseased aortic vessel, and also by the introduction and more recent experience of some technical points like sequentIal clamping of common carotid arteries

or the gas flushing with the CO2. We can also prevent the retrograde dissection, again with patient selection, according to the availability of a healthy sealing zone, but in our series, 6 of the 24 patients

presented an ascending aorta larger than 40 millimeter. And on of this required 48-millimeter proximal size custom-made stent graft. This resulted in two retrograde dissection, but on the other hand, the availability on this platform of a so large proximal-sized,

customized stent graft able to seal often so large ascending aorta may decrease the incidence of type I endoleak up to zero, and this may make sense in order to give a chance of repair to patients that we otherwise rejected for clinical or morphological reasons.

So in conclusion, endovascular arch repair with double branch devices is a feasible approach that enrich the armamentarium for vascular research. And there are many aspects that may limit or preclude the widespread use of this technology

with subsequent difficulty in drawing strong conclusion. Operative mortality and major complication rates suffer the effect of a learning curve, while mid-term results of survival are more than promising. I thank you for your attention.

- These are my disclosures. So aortic neck dilatation is not a new problem. It's been described even before the era of endovascular repair and it's estimated to occur in about 20% of all patients that undergo EVAR two years after the index procedure.

We're seeing more and more cases where patients that survive long enough after EVAR, they develop aortic neck dilatation beyond the nominal diameter of the endograft and like on this patient, this image, large type 1A endoleaks that are difficult to treat.

There's a number of factors that are contributing to aortic neck dilatation including a continuous outward force that is exerted by the endograft. Progression of aortic wall degeneration. Aneurisymal disease is a degenerative procedure.

The presence of endoleaks, particularly type two endoleaks have been implicated in aortic neck dilatation. And then incomplete seal at the proximal neck in the form of microleaks or positional leaks. HeliFX EndoAnchors as you heard were

designed to stabilize and improve the apposition of the endograft to the aortic neck. And as you saw on this video, their presence even when the super no fixation disengages from the wall of the aorta, may help stabilize the graft onto

the aorta and prevent type 1A endoleaks. About three or four years ago we started looking at the anchor registry data, trying to identify predictors of aortic neck dilatation in patients who are undergoing EVAR with EndoAnchors. We published those results about a year ago.

In terms of the one year mark, we had 267 patients in that cohort. We measured the aortic diameter at four different levels. 20 millimeters proximal to the lowest main renal artery and then at the level of the lowest renal artery, five and 10 millimeters distal to that.

We defined the change in diameter that occurred between the pre-implantation EVAR and the first post-implantation EVAR at about one month. As adoptive enlargement due mainly to the effect of endograaft and the interaction with the aortic wall.

And then we defined this dilatation, what occurred between the one month and the 12 month mark, post EVAR. We used 20 different variables and we ran all these variables at the three levels. And what we found in terms of

post-operative neck dilatation is that it occurred in 3.1% of patients at the level of the lowest renal artery. 7.7% five millimeters distal to it and 4.6% at 10 millimeters distal to it. And this is a dilatation with a threshold

of at least three millimeters. We felt that this was much more clinically relevant. In terms of protective factors for adaptive enlargement, the presence of calcium and the aortic diameter of the level of the lowest renal, both of these are easy to understand.

The stiffer the aorta, the lesser the degree of the immediate dilatation. But then when we looked at the true dilatation, we found out that the aortic neck diameter at the lowest renal artery was a significant risk factor as was Endograft oversizing.

So if you started with a large aorta to begin with, these patients were much more likely to develop neck dilatation and if you significantly oversize the endograft that was also an independent risk factor. On the other hand, the neck length as well as the number of EndoAnchors that

were placed in these patients, both appear to have independent protective effects. So the two year preliminary analysis results is what I'm going to present. The analysis is still ongoing, but now we have a larger number of patients, 674.

We performed the same measurements at the same levels. What we found in terms of time course and location of the aortic neck dilatation is that in the suprarenal site, there is negligible dilatation up to 24 months. The largest dilatation occurs at five millimeters,

but more interestingly, a significant number of patients did not even have endograft present in that location. And then at 10 millimeters distal to the lowest renal artery right where most of the aneurysm changes you would expect to occur,

that change in diameter was again negligible. Indirectly suggesting that EndoAnchors have protective effect. So these are our interesting, some interesting insights. Female sex and graft oversize do play a significant role in the post-operative neck dilatation.

With EndoAnchors implanted at the index procedure neck dilatation 10 millimeters distal to the lowest renal artery appears to be negligible both at 12 and at 24 months. But we're working to see a little bit more finer elements at this analysis.

As where exactly the EndoAnchors were placed and how this was associated with the changes in the aortic neck. We hope to have those results later this year. Thank you.

- I'd like to thank Dr. Veith for this kind invitation and the committee as well. So these are my disclosures, there's none. So for a quick background regarding closure devices. Vascular closure devices have been around

for almost 20 years, various types. Manual compression in most studies have always been shown to be superior to vascular closure devices mainly because there's been no ideal device that's been innovated to be able

to handle all sorts of anatomies, which include calcified vessels, soft plaque, etc. So in this particular talk we wanted to look at to two particular devices. One is the Vascade vascular closure device

made by Cardiva and the other is the CELT arterial closure device made by Vasorum in Ireland. Both these devices are somewhat similar in that they both use a disc. The Vascade has a nitinol disc

as you can see here that's used out here to adhere to the interior common femoral artery wall. And then once tension is applied, a series of steps is involved to deploy the collagen plug

directly on to the artery which then allows it to expand over a period of time. The CELT is similar in that it also uses a stainless steel disc as you can see here. Requires tension up against the interior wall of the common femoral artery.

Nice and tight and then you screw on the top end of the device on to the interior wall of the artery creating a nice little cylinder that compresses both walls of artery. As far as comparability is concerned between the two devices you can see

here that they're both extravascular, one's nitinol, one's stainless steel. One uses a collagen material, the other uses an external clip in a spindle-type fashion. Both require about, anywhere between three to seven minutes of pressure

to essentially stop the tract ooze. But the key differences between the two devices, is the amount of time it takes for patients to ambulate. So the ambulation time is two hours roughly for Vascade, whereas for a CELT device

it's anywhere from being immediate off the table at the cath lab room to about 20 minutes. The data for Vascade was essentially showing the RESPECT trial which I'll summarize here, With 420 patients that was a randomized trial

to other manual compression or the device itself. The mean points of this is that the hemostasis time was about three minutes versus 21 minutes for manual compression. And time to ambulation was about 3.2 hours versus 5.7 hours.

No major complications were encountered. There were 1.1% of minor complications in the Vascade versus 7% in the manual compression arm. This was actually the first trial that showed that a actual closure devices

had better results than manual compression. The main limitations in the trial didn't involved complex femoral anatomy and renal insufficiency patients which were excluded. The CELT ACD trial involved 207 patients that were randomized to CELT or to manual

compression at five centers. Time to hemostasis was anywhere between zero minutes on average versus eight minutes in the manual compression arm. There was one complication assessed at 30 days and that was a distal embolization that occurred

early on after the deployment with a successfully retrieved percutaneously with a snare. So complication rate in this particular trial was 0.7% versus 0% for manual compression. So what are some pros and cons with the Vascade device?

Well you can see the list of pros there. The thing to keep in mind is that it is extravascular, it is absorbable, it's safe, low pain tolerance with this and the restick is definitely possible. As far as the cons are involved.

The conventional bedrest time is anywhere between two to three hours. It is a passive closure device and it can create some scarring when surgical exploration is necessary on surgical dissections.

The key thing also is you can not visualize the plug after deployment. The pros and cons of the CELT ACD device. You can see is the key is the instant definitive closure that's achieved with this particular device, especially in

calcified arteries as well. Very easy to visualize under fluoroscopy and ultrasound. It can be used in both antegrade and retrograde approaches. The key cons are that it's a permanent implant.

So it's like a star closed devised, little piece of stainless steel that sits behind. There's a small learning curve with the device. And of course there's a little bit of discomfort associated with the cinching under the (mumbles) tissue.

So we looked at our own experience with both devices at the Christie Clinic. We looked at Vascade with approximately 300 consecutive patients and we assessed their time to hemostasis, their time to ambulation,

and their time to discharge, as well as the device success and minor and major complications. And the key things to go over here is that the time to hemostasis was about 4.7 minutes for Vascade, at 2.1 hours for ambulation, and roughly an average

of 2.4 hours for discharge. The device success was 99.3% with a minor complication rate of .02% which we have four hematomas and two device failures requiring manual compression. The CELT ACD device we also similarly did

a non-randomized perspective single center trial assessing the same factors and assessing the patients at seven days. We had 400 consecutive patients enrolled. And you can see we did 232 retrograde. We did a little bit something different

with this one, we did we 168 antegrade but we also did direct punctures to the SFA both at the proximal and the mid-segments of the SFA. And the time to hemostasis in this particular situation was 3.8 minutes,

ambulation was 18.3 minutes, and discharge was at 38.4 minutes. We did have two minor complications. One of which was a mal-deployment of the device requiring manual compression. And the second one was a major complication

which was an embolization of the device immediately after deployment which was done successfully snared through an eighth front sheath. So in conclusion both devices are safe and effective and used for both

antegrade and retrograde access. They're definitely comparable when it comes, from the standpoint of both devices (mumbles) manual compression and they're definitely really cost effective in that they definitely do increase the

throughput in the cath lab allowing us to be able to move patients through our cath lab in a relatively quick fashion. Thank you for your attention.

- Thank you Mr. Chairman, good morning ladies and gentlemen. So that was a great setting of the stage for understanding that we need to prevent reinterventions of course. So we looked at the data from the DREAM trial. We're all aware that we can try

to predict secondary interventions using preoperative CT parameters of EVAR patients. This is from the EVAR one trial, from Thomas Wyss. We can look at the aortic neck, greater angulation and more calcification.

And the common iliac artery, thrombus or tortuosity, are all features that are associated with the likelihood of reinterventions. We also know that we can use postoperative CT scans to predict reinterventions. But, as a matter of fact, of course,

secondary sac growth is a reason for reintervention, so that is really too late to predict it. There are a lot of reinterventions. This is from our long term analysis from DREAM, and as you can see the freedom, survival freedom of reinterventions in the endovascular repair group

is around 62% at 12 years. So one in three patients do get confronted with some sort of reintervention. Now what can be predicted? We thought that the proximal neck reinterventions would possibly be predicted

by type 1a Endoleaks and migration and iliac thrombosis by configurational changes, stenosis and kinks. So the hypothesis was: The increase of the neck diameter predicts proximal type 1 Endoleak and migration, not farfetched.

And aneurysm shrinkage maybe predicts iliac limb occlusion. Now in the DREAM trial, we had a pretty solid follow-up and all patients had CT scans for the first 24 months, so the idea was really to use

those case record forms to try to predict the longer term reinterventions after four, five, six years. These are all the measurements that we had. For this little study, and it is preliminary analysis now,

but I will be presenting the maximal neck diameter at the proximal anastomosis. The aneurysm diameter, the sac diameter, and the length of the remaining sac after EVAR. Baseline characteristics. And these are the re-interventions.

For any indications, we had 143 secondary interventions. 99 of those were following EVAR in 54 patients. By further breaking it down, we found 18 reinterventions for proximal neck complications, and 19 reinterventions

for thrombo-occlusive limb complications. So those are the complications we are trying to predict. So when you put everything in a graph, like the graphs from the EVAR 1 trial, you get these curves,

and this is the neck diameter in patients without neck reintervention, zero, one month, six months, 12, 18, and 24 months. There's a general increase of the diameter that we know.

But notice it, there are a lot of patients that have an increase here, and never had any reintervention. We had a couple of reinterventions in the long run, and all of these spaces seem to be staying relatively stable,

so that's not helping much. This is the same information for the aortic length reinterventions. So statistical analysis of these amounts of data and longitudinal measures is not that easy. So here we are looking at

the neck diameters compared for all patients with 12 month full follow-up, 18 and 24. You see there's really nothing happening. The only thing is that we found the sac diameter after EVAR seems to be decreasing more for patients who have had reinterventions

at their iliac limbs for thrombo-occlusive disease. That is something we recognize from the literature, and especially from these stent grafts in the early 2000s. So conclusion, Mr. Chairman, ladies and gentlemen, CT changes in the first two months after EVAR

predict not a lot. Neck diameter was not predictive for neck-reinterventions. Sac diameter seems to be associated with iliac limb reinterventions, and aneurysm length was not predictive

of iliac limb reinterventions. Thank you very much.

- Good morning. It's a pleasure to be here today. I'd really like to thank Dr. Veith, once again, for this opportunity. It's always an honor to be here. I have no disclosures. Heel ulceration is certainly challenging,

particularly when the patients have peripheral vascular disease. These patients suffer from significant morbidity and mortality and its real economic burden to society. The peripheral vascular disease patients

have fivefold and increased risk of ulceration, and diabetics in particular have neuropathy and microvascular disease, which sets them up as well for failure. There are many difficulties, particularly poor patient compliance

with offloading, malnutrition, and limitations of the bony coverage of that location. Here you can see the heel anatomy. The heel, in and of itself, while standing or with ambulation,

has tightly packed adipose compartments that provide shock absorption during gait initiation. There is some limitation to the blood supply since the lateral aspect of the heel is supplied by the perforating branches

of the peroneal artery, and the heel pad is supplied by the posterior tibial artery branches. The heel is intolerant of ischemia, particularly posteriorly. They lack subcutaneous tissue.

It's an end-arterial plexus, and they succumb to pressure, friction, and shear forces. Dorsal aspect of the posterior heel, you can see here, lacks abundant fat compartments. It's poorly vascularized,

and the skin is tightly bound to underlying deep fascia. When we see these patients, we need to asses whether or not the depth extends to bone. Doing the probe to bone test

using X-ray, CT, or MRI can be very helpful. If we see an abcess, it needs to be drained. Debride necrotic tissue. Use of broad spectrum antibiotics until you have an appropriate culture

and can narrow the spectrum is the way to go. Assess the degree of vascular disease with noninvasive testing, and once you know that you need to intervene, you can move forward with angiography. Revascularization is really operator dependent.

You can choose an endovascular or open route. The bottom line is the goal is inline flow to the foot. We prefer direct revascularization to the respective angiosome if possible, rather than indirect. Calcanectomy can be utilized,

and you can actually go by angiosome boundaries to determine your incisions. The surgical incision can include excision of the ulcer, a posterior or posteromedial approach, a hockey stick, or even a plantar based incision. This is an example of a posterior heel ulcer

that I recently managed with ulcer excision, flap development, partial calcanectomy, and use of bi-layered wound matrix, as well as wound VAC. After three weeks, then this patient underwent skin grafting,

and is in the route to heal. The challenge also is offloading these patients, whether you use a total contact cast or a knee roller or some other modality, even a wheelchair. A lot of times it's hard to get them to be compliant.

Optimizing nutrition is also critical, and use of adjunctive hyperbaric oxygen therapy has been shown to be effective in some cases. Bone and tendon coverage can be performed with bi-layered wound matrix. Use of other skin grafting,

bi-layered living cell therapy, or other adjuncts such as allograft amniotic membrane have been utilized and are very effective. There's some other modalities listed here that I won't go into. This is a case of an 81 year old

with osteomyelitis, peripheral vascular disease, and diabetes mellitus. You can see that the patient has multi-level occlusive disease, and the patient's toe brachial index is less than .1. Fortunately, I was able to revascularize this patient,

although an indirect revascularization route. His TBI improved to .61. He underwent a partial calcanectomy, application of a wound VAC. We applied bi-layer wound matrix, and then he had a skin graft,

and even when part of the skin graft sloughed, he underwent bi-layer living cell therapy, which helped heal this wound. He did very well. This is a 69 year old with renal failure, high risk patient, diabetes, neuropathy,

peripheral vascular disease. He was optimized medically, yet still failed to heal. He then underwent revascularization. It got infected. He required operative treatment,

partial calcanectomy, and partial closure. Over a number of months, he did finally heal. Resection of the Achilles tendon had also been required. Here you can see he's healed finally. Overall, function and mobility can be maintained,

and these patients can ambulate without much difficulty. In conclusion, managing this, ischemic ulcers are challenging. I've mentioned that there's marginal blood supply, difficulties with offloading, malnutrition, neuropathy, and arterial insufficiency.

I would advocate that partial or total calcanectomy is an option, with or without Achilles tendon resection, in the presence of osteomyelitis, and one needs to consider revascularization early on and consider a distal target, preferentially in the angiosome distribution

of the posterior tibial or peroneal vessels. Healing and walking can be maintained with resection of the Achilles tendon and partial resection of the os calcis. Thank you so much. (audience applauding)

- I'd like the thank Doctor Veith for inviting me back to speak. I have no disclosures, we will be discussing some slight off-label use of the anitcoagulants. As we all know, acute limb ischemia occurs as a result of acute thrombosis of a native artery or bypass graft or embolism from a proximal

source, dissection, or trauma. The incidence is not insignificant, 15 cases per 100 000 persons per year, or interestingly about 10 to 16% of our vascular workload. Despite the relative frequency of this condition, there are relatively few guidelines to

guide us for anticoagulation therapy. The last set of guidelines for the American College of Chest Physicians regarding PAD gives some very brief, generic recommendations from 2012. They state, suggest immediate systemic anticoagulation with unfractionated heparin.

We suggest reperfusion over no reperfusion, which seems pretty obvious to an audience of vascular specialists. One of the challenges with acute limb ischemia is that it is a fairly heterogenous group. It can be thrombosis or embolism to the aorticiliac segments to the infrainguinal segments, and

there's also the patients who develop ALI from trauma. So we actually looked at the various phases of anticoagulation for acute limb ischemia and then we do, as with many institutions, utilize intravenous heparin at the time of the diagnosis, as well as obviously at the time of surgery,

but we found that there was a significant variation with regard to the early, post-operative anticoagulation regimens. One option is to give therapeutic intravenous heparin on an adjusted dose, but what we found in a significant minority of patients across the country actually,

is that people are giving this fixed mini-dose 500 unit an hour of heparin without any standardization or efficacy analysis. Then, obviously you go the long-term anticoagulation. We reviewed 123 patients who had ALI at our institution, who underwent surgical revascularization.

And they had the typical set of comorbidities you might expect in someone who has PAD or atheroembolism. In these patients, the Rutherford Classification was viable or marginally threatened in the majority, with about 25% having immediately threatened limb.

Various procedures were performed for these patients, including thromboembolectomy in the majority, bypass operations, angioplasty and stenting was performed in the significant minority and then primary amputation in the various selects few. We divided these patients into

the first four days of anticoagulation. Therapeutic with unfractionated heparin early on versus subtherapeutic or this mini-dose unfractionated heparin and we found that 29% of our patients were receiving the mini-dose unfractionated heparin, again without much efficacy analysis.

We used the International Society for Thrombosis and Haemostasis Anticoagulation Outcome Guidelines to look at the ischemic complications, as well as major and minor bleeding for these patients, and we identified actually not a significant rate of difference between the

subtherapeutic category and the therapeutic category of patients, with regard to mortality, with regard to recurrent limb ischemia, MI, VTE, or stroke, major amputation, and we actually didn't find because it's a fairly small study, any significant difference in major or minor bleeding for these patients.

So, we do feel that this small study did justify some efficacy of mini-dose unfractionated heparin because we didn't find that it was causing recurrent lower extremity thromboembolsim in these patients. Now on to long-term anticoagulation, for these patients, after that first three or four days

after the surgery, the options are long-term vitamin K antagonists, the DOAC's or vitamin K antagonists if you have atrial arrhythmia, or in the patients who had no other comorbidities, there really is not much guidance until recently. The compass trial was recently published in 2018

in stable PAD and carotid disease patients, identifying that rivaroxaban plus aspirin had a significant benefit over aspirin alone in patients who had stable PAD. And then, an upcoming trial, which is still ongoing currently in patients who underwent recent

revascularization, whether open or endo, is hopefully going to demonstrate that rivaroxaban, again has a role in patients with lower extremity ischemia. So in conclusion, there is relatively a scarcity of clinical data to help guide anticoagulation after acute limb ischemia.

Unfractionated heparin pre and intraop are standardized, but postop anticoagulation is quite variable. The mini-dose, we consider to be a reasonable option in the first few days to balance bleeding versus rethrombrosis, and fortunately we are having larger randomized clinical trials to help demonstrate the benefit of the DOACs and

aspirin in patients who are stable or post-revascularization for PAD, thank you.

- So Beyond Vascular procedures, I guess we've conquered all the vascular procedures, now we're going to conquer the world, so let me take a little bit of time to say that these are my conflicts, while doing that, I think it's important that we encourage people to access the hybrid rooms,

It's much more important that the tar-verse done in the Hybrid Room, rather than moving on to the CAT labs, so we have some idea basically of what's going on. That certainly compresses the Hybrid Room availability, but you can't argue for more resources

if the Hybrid Room is running half-empty for example, the only way you get it is by opening this up and so things like laser lead extractions or tar-verse are predominantly still done basically in our hybrid rooms, and we try to make access for them. I don't need to go through this,

you've now think that Doctor Shirttail made a convincing argument for 3D imaging and 3D acquisition. I think the fundamental next revolution in surgery, Every subspecialty is the availability of 3D imaging in the operating room.

We have lead the way in that in vascular surgery, but you think how this could revolutionize urology, general surgery, neurosurgery, and so I think it's very important that we battle for imaging control. Don't give your administration the idea that

you're going to settle for a C-arm, that's the beginning of the end if you do that, this okay to augment use C-arms to augment your practice, but if you're a finishing fellow, you make sure you go to a place that's going to give you access to full hybrid room,

otherwise, you are the subservient imagers compared to radiologists and cardiologists. We need that access to this high quality room. And the new buzzword you're going to hear about is Multi Modality Imaging Suites, this combination of imaging suites that are

being put together, top left deserves with MR, we think MR is the cardiovascular imaging modality of the future, there's a whole group at NIH working at MR Guided Interventions which we're interested in, and the bottom right is the CT-scan in a hybrid op

in a hybrid room, this is actually from MD Anderson. And I think this is actually the Trauma Room of the future, makes no sense to me to take a patient from an emergency room to a CT scanner to an and-jure suite to an operator it's the most dangerous thing we do

with a trauma patient and I think this is actually a position statement from the Trauma Society we're involved in, talk about how important it is to co-localize this imaging, and I think the trauma room of the future is going to be an and-jure suite

down with a CT scanner built into it, and you need to be flexible. Now, the Empire Strikes Back in terms of cloud-based fusion in that Siemans actually just released a portable C-arm that does cone-beam CT. C-arm's basically a rapidly improving,

and I think a lot of these things are going to be available to you at reduced cost. So let me move on and basically just show a couple of examples. What you learn are techniques, then what you do is look for applications to apply this, and so we've been doing

translumbar embolization using fusion and imaging guidance, and this is a case of one of my partners, he'd done an ascending repair, and the patient came back three weeks later and said he had sudden-onset chest pain and the CT-scan showed that there was a

sutured line dehiscence which is a little alarming. I tried to embolize that endovascular, could not get to that tiny little orifice, and so we decided to watch it, it got worse, and bigger, over the course of a week, so clearly we had to go ahead and basically and fix this,

and we opted to use this, using a new guidance system and going directly parasternal. You can do fusion of blood vessels or bones, you can do it off anything you can see on flu-roid, here we actually fused off the sternal wires and this allows you to see if there's

respiratory motion, you can measure in the workstation the depth really to the target was almost four and a half centimeters straight back from the second sternal wire and that allowed us really using this image guidance system when you set up what's called the bullseye view,

you look straight down the barrel of a needle, and then the laser turns on and the undersurface of the hybrid room shows you where to stick the needle. This is something that we'd refined from doing localization of lung nodules

and I'll show you that next. And so this is the system using the C-star, we use the breast, and the localization needle, and we can actually basically advance that straight into that cavity, and you can see once you get in it,

we confirmed it by injecting into it, you can see the pseudo-aneurism, you can see the immediate stain of hematoma and then we simply embolize that directly. This is probably safer than going endovascular because that little neck protects about

the embolization from actually taking place, and you can see what the complete snan-ja-gram actually looked like, we had a pig tail in the aura so we could co-linearly check what was going on and we used docto-gramming make sure we don't have embolization.

This patient now basically about three months follow-up and this is a nice way to completely dissolve by avoiding really doing this. Let me give you another example, this actually one came from our transplant surgeon he wanted to put in a vas,

he said this patient is really sick, so well, by definition they're usually pretty sick, they say we need to make a small incision and target this and so what we did was we scanned the vas, that's the hardware device you're looking at here. These have to be

oriented with the inlet nozzle looking directly into the orifice of the mitro wall, and so we scanned the heart with, what you see is what you get with these devices, they're not deformed, we take a cell phone and implant it in your chest,

still going to look like a cell phone. And so what we did, image fusion was then used with two completely different data sets, it mimicking the procedure, and we lined this up basically with a mitro valve, we then used that same imaging guidance system

I was showing you, made a little incision really doing onto the apex of the heart, and to the eur-aph for the return cannula, and this is basically what it looked like, and you can actually check the efficacy of this by scanning the patient post operatively

and see whether or not you executed on this basically the same way, and so this was all basically developed basing off Lung Nodule Localization Techniques with that we've kind of fairly extensively published, use with men can base one of our thoracic surgeons

so I'd encourage you to look at other opportunities by which you can help other specialties, 'cause I think this 3D imaging is going to transform what our capabilities actually are. Thank you very much indeed for your attention.

- The Chairmans, Doctor Reed, thank you very much to accept our data or hypothesis. This is a little bit different of the other subject. I have no disclosure. So, very sure that the type A and B dissections are potentially lethal diseases.

Typically silent with progression. But we know variation point, or the focus, we know now in the last 20 years that 29 genes, when they are not the codes but they are weakening factors after our, therein, and we want to demonstrate here,

that in description or hypothesis is that the intimal and the medial injuries of the aortic wall, in the thoracic aortic anarithmias and dissections are caused primarily only from one type of kinetic forces which appears on the aortic wall in three different forms: That is the pouc

e-entry, the cl entry that is wall haematom. This is the same aortic dissections in three forms. We don't think that the wall stress and the wall force are significant factors.

Seeing that factors come from the vorticis, Leonardo already described. Even different levels, and most typical is the sinus of valsalva, main flow way is not contact with the sinus vawe turbulence. There is the main flow, actually the laminal flow

is not real, it is a parabolic, rotating pressure and the blood mass vawe sliding on the endothelium. Endothelium, that is the multilayer, non-thrombotic, in the sagital view, in a vawe form surface, and on the vawe form surface, induced low scale vorticis, and the main flow is sliding on theses vorticis.

This is a very difficult kinetic situation. Any geometrical changes makes significant side-vortex development, and kinetic and turbulence differences. Here you can see the rotating parabolic mass vawe, sliding on the endothelial.

And when this vorticis, the main vorticis effect on the wall are the same place as the most frequent entry line of the Type A dissection. In this case, and other uncular and right sinus. Here we are, actually the human aortic dissections and the aneurysms are developing mainly

behind the side-branches and valves-behind turbulences and vorticis. Here gene factors are stored not really on the 29, mostly in the TGF-B pathways, and the smooth muscles and cells. And genes, after all, this is not relevant,

although there is two theories: The genetic theory and the hemodynamic theory. You can see on the right side that it's two different bicuspid valve, causes different turbulences and different velocity and different forces of the aortic wall.

Any forms of the form changes of the vessels cause turbulences and also different poststenotic vorticis. Here and then, had a print, imprint of the endothelial structure changes, endothelial surface changes,

and endothelial migration in the middle column, as you see and on the graphic. Here you can see the different velocity turning point of the dilated aorta and the replace aorta. Even in the bisupidal and the tricuspidal, you can see the diameter and their form

are the length and the heights are different of the turbulences and the turbulence formed here. You can see, we can close out the sheer stress, because that you can see, in the stress points they are the small curvature in the bicuspidal and the tricuspidal aortic wall.

Although, the typical point of entry on the main curvature. But a very important difference, is the left ventricul ascension and angulation. Different flow and velocity forces. And also,

pressure point with the typical Type A/Type B dissections. The main pressure is in the ascendance, although the typical ended underneath are near the left subclavian artery, but the flow is, we can see the right side are the speed, are the largest displaced.

Numbers of possible re-entries are dependent from the size and the location of the main entries and re-entries. That is, different type of type arch, form, flow, and a means different re-entry size and location as you can see.

In this case, also, bare stent vibration by turbulence can cause different turbulences and side-vortex formation, as you can see on the right side. And back to the vorticis. The vorticis this kinetic force that would be a hypothetic,

hypothesis, our hypothesis, it comes from the vortex merge, ita-filaments and double vortex, double the phalanx form. And by to reach that, they give up light, heat,

velocity changes, and kinetic force. Here that is the double-helix form and also when at the collision of this that I'm speaking about, these are the forces, and they are very high scale forces. Not the same scale as the sheer wall, and the wall forces.

So, the conclusion and then, the take home message, is we conclude that the gradient between significant turbulence-vortex merge or collision generated kinetic force divided by the wall resistance is the deciding factor about endothelial injury and the real potentially fatal aortic vawe dissection.

It gives us a realistic prognosis and can determine the seriosity of the aortic wall injury, we can differentiate a simple endothelium injury to the life threatening type A or type B dissection. We need in the future develop a new imaging programs form NMR or CONTRAST TEE transform this visualization,

this image into kinetic vectors. We need a prognostic calendar for time related aortic wall changes based on genetics and patients symptomatic. And need a device to measure in vivo online aortic vessel wall resistance.

And at the end a cartoon. Actually, black holes are also, you can see, as vorticis. And this force cannot be only positive, it can be only negative, a vacuum, as in the tornadoes. But can rise in the aortic wall.

That is positive or negative force can be. Thank you very much for your attention.

- These are my disclosures. So we all know the problems with long-term failure of EVAR and TEVAR. Type one endoleak being a particular significant concern. We've heard the results of the three year ANCHOR Registry. We know from this 85% of those cases taken on for type one endoleak were successful

and it's fantastic that these cases are still successful at three years. But I guess it's 15% failures and it's important that we talk about how we get success like this. If we're going to talk about a recipe for success we need to think about first of all the indications

for treatment of endoleaks. This is key. Not all endoleaks are the same. Those endoleaks where there's an inadvertent creation of a leak channel around the graft at the top end because of a hostile landing zone

or excessive oversiding of your graft or noncircular aorta, all can be well treated with endoanchors. Again, migration and loss of seal can also be well treated. But others where there's excessive thrombus or calcium won't work and where there's insufficient apposition between the graft and the aorta, again,

this is not a treatment case for endoanchors. So intraoperative type one endoleaks where there's poor conformability of the graft you can see here this barrel-shaped neck, there's a leak around the aorta, and there's a series of endoanchors

placed in rows circumferentially, do really well to seal up that. You can do the same at the distal end of the thoracic graft as we've just seen in those conical necks when you have a type one endoleak. If you have time to treat your leak channel,

you want to get a CT scan and evaluate where that leak channel is. Or you can do more detailed imaging with triangulation on angiography, but that's difficult. You fix the side away from the endoanchor first,

and then fixing rows of staples along the endoleak channel as you can see here, by moving the C-Arm in 15 degree increments across the aortic wall. This is a good example of a case with a leak channel. This graft is in the angulated aorta

with a channel underneath in the bottom end. There's a big endoleak there. And what we've done is fix the contralateral side first and then you're placing a series or rows of endoanchors underneath the stent graft. You can even zipper that up to change the bird beaking.

And that endoleak stayed sealed for three years. The same is true in the proximal thoracic aorta. This is one of Firas Mussa's cases. There's an endoleak on the underside of the arch and five endoanchors placed on the underside of the arch as we've just seen in JP's talk,

can resolve that endoleak quite successfully. When you are doing it in the arch you do need to plan properly. If you have an endoleak at the end of the case what you can do is put the C-Arm in an LAO position and line up the markers on the graft,

place the superior and inferior endoanchors and then rotate cranially and caudally at 15 degree intervals to put a series of endoanchors at the superior and inferior surfaces. That will fix the graft well. Otherwise, if you've got time and plan the case well,

you can work out dedicated C-Arm angles using one of the CT evaluation softwares. The best example is written by Rousseau, and I would get you to read that article to learn further. And that's how I learnt. There is a learning curve.

And this is necessary for success in treating type one endoleaks. You need some experience to gain good endoanchor placement. That's crucial, we've heard that. Start with the infrarenal segment, doing prophylactic cases,

the conical necks and slightly dilated necks, and then move into the thoracic segment. You need to use different size guides for different parts of the arch. On the upper surface the smaller guide is more useful. On the undersurface a larger guide to place the endoanchors

on the under surfaces of the arch is useful. Place them in rows coming back and have some patience. It's not all as easy as it looks right up there in the arch. For migration it's often an excellent strategy. If you can fix your migrated endograft to the native neck it's a good thing to do.

But remember these grafts have migrated and there's often great tortuosity there. If you can extend to gain a seal zone and then place a series of circumferential endoanchors it will fix that well and usually stay fixed for a good period of time.

There are limitations as I alluded to in the first few slides, excessive thrombus, excessive calcification, and where the aorta is dilated excessively and the endograft has stayed the same size. These will not work with endoanchor placement.

These are my tips, really, for success. There is a learning curve. Start with some easier ones. Think about the endoleak and why you've got an endoleak and don't be tricked into thinking the endoanchors will create a landing zone for you.

It won't. You should treat the type one endoleak immediately if you have it at the end of the case with re-interventions. You need to target that effectively and place multiple rows often cranially and caudally. And if you have one of the 13.4% failures,

remember that the use of endoanchors doesn't preclude you from doing something else so don't be too depressed. Thank you very much.

- So again, I'd like to thank Dr. Veith for the opportunity to participate in this interesting debate. So, I have been tasked with the position Intra-operative Completion Study is not mandatory, and in fact I will show you why a selective approach will actually provide better results for our patients. These are my disclosures related to ongoing

clinical research and clinical trials. So again, Professor Eckstein and his colleagues should be very significantly commended for getting the entire German vascular surgery community to look at their data in a very rigorous fashion. However, both he and his co-authors will acknowledge

within the manuscript that there are significant problems with this database. A very large number of 142,000 elective carotid endarterectomy procedures with very ballotable stroke and death rates of 1.4 and 2.5%. However, a typical criticism from outside the

vascular surgery community, these are all self-reported. These are not 30 day outcomes, they're actually in-hospital outcomes. And while in Germany that still may be four days, it's not the 30 days that we see. I'll show you a little bit later on within the Crest data.

And interestingly, within their own manuscript only 50% of the patients actually had neurologic assessment both pre- and post-procedural. So, how can we make a relevant decision in terms of thinking about how we're going to treat these patients if we only have neuro data on half of them.

Lets for the moment assume we can call out those patients. How does this relate to clinical practice? Well the authors also admit that this is an observational study, and that even though there is some association, there clearly is no causal relationship

as my previous debater just admitted. And in fact, they argue that this is perhaps the best method to look at generating hypotheses for future randomized trials, much like Dr. Aborama has done with the use of carotid endarterectomy with patching. So, let's look a little bit more about the data

and see how relevant it is to your current practice. So in the Germany registry, a quarter of the patients are treated under local anesthetic. 40% have no type of neurologic monitoring, and over 40% are performed with aversion endarterectomy. Very, very different than the practice that we see

in our institution, and in the New England region. And I would argue that there's a lot of concern in terms of what the indications are for monitoring, what the indications are for shunt use. Again, that's 43%. But there's absolutely no data in this registry about

indications for shunting, when it was used, or when patients were re-explored and what they found at the time. And a little bit concerning is in 17% of the patients, there was no anti-platelet agent used in patients undergoing carotid endarterectomy.

And, I would argue that that number is just a little bit high. How about when we go to the univariate analysis? Once again, we see that there's a benefit of 0.4% decrease in stroke and death for a local anesthetic, although we are well aware that there are numerous other

perspectives that have looked at this and not shown that same relationship. Again, there's a benefit for aversion endarterectomy, but I would argue at least in the New England region and perhaps in the United States except for select centers, aversion endarterectomy is used the minority of the time

and that in fact is an indication in my mind to have a lower threshold for either angiogram or completion duplex. Most concerning, there was 0.3% difference in the stroke and death rate with the lack of an intraoperative completion study, but there was no data about indications, findings,

whether that resulted in an intervention, or what the result of that intervention was. And initially in the univariate analysis, neuro-psyche, physiologic monitoring was protective, but later on in the multivariate, it was not. Here is that same multivariate analysis that shows again

that in fact shunting and neuro-physiologic monitoring are increased risk factors for stroke. Certainly there's going to be some bias. My concern is I'm not convinced the authors are able to call out the co founding variables, even in their multivariate regression analysis.

And in fact, in their concluding paragraphs they state there's no information supplied on whether intraoperative completion studies caused an operative revision or not, and no information about cause of death. In fact, they don't even have information about

intraoperative heparin or protamine application. So I would argue I'd be very skeptical about making my final decisions based on this. Thinking about the technical aspects of angiography, there's no doubt that this is very helpful at times, but think about the details of where do you put the needle.

What type of imaging? Is it a C-arm, is it a flat plate? Who interprets it, and what are your thresholds for intervention? So, it certainly may be harmful, may be unnecessary, and may even give you false positives.

Similarly with Completion Duplex studies, there certainly is a false positive rate and then there's risk for re-clamping. I reached out to my friend and colleague Braglol to see if there was any data from Crest that would help us, and unfortunately other than the fact that stroke happens

up to 30 days after our initial endarterectomy, there was no data supporting that. So, perhaps the best study that we have is our current practice in New England where we had 6,000 patients, a third of whom received completion studies. We broke this down into rare, selective, and routine

duplex or angio studies. And in fact, in the selective group we had a very low rate of re-exploration versus the other group, and a much lower incidence of overall stroke and death. In fact, the only benefit that was statistically significant was a decrease one year rate of re-stenosis.

So in conclusion, I would argue that this is probably unnecessary, and in fact maybe harmful. Meticulous technique, intra-procedural monitoring with selective shunt use, and continuous wave doppler use may, in fact, be the way to go. But this does give us an opportunity for prospective,

randomized trial as part of another study to look for completion study indications. Thank you very much.

- Dear Chairman, Ladies and Gentlemen, Thank you Doctor Veith. It's a privilege to be here. So, the story is going to be about Negative Pressure Wound Non-Excisional Treatment from Prosthetic Graft Infection, and to show you that the good results are durable. Nothing to disclose.

Case demonstration: sixty-two year old male with fem-fem crossover PTFE bypass graft, Key infection in the right groin. What we did: open the groin to make the debridement and we see the silergy treat, because the graft is infected with the microbiology specimen

and when identified, the Enterococcus faecalis, Staphylococcus epidermidis. We assess the anastomosis in the graft was good so we decided to put foam, black foam for irrigation, for local installation of antiseptics. This our intention-to treat protocol

at the University hospital, Zurich. Multi-staged Negative Pressure for the Wound Therapy, that's meets vascular graft infection, when we open the wound and we assess the graft, and the vessel anastomosis, if they are at risk or not. If they are not at risk, then we preserve the graft.

If they are at risk and the parts there at risk, we remove these parts and make a local reconstruction. And this is known as Szilagyi and Samson classification, are mainly validated from the peripheral surgery. And it is implemented in 2016 guidelines of American Heart Association.

But what about intracavitary abdominal and thoracic infection? Then other case, sixty-one year old male with intracavitary abdominal infection after EVAR, as you can see, the enhancement behind the aortic wall. What we are doing in that situation,

We're going directly to the procedure that's just making some punctures, CT guided. When we get the specimen microbiological, then start with treatment according to the microbiology findings, and then we downgrade the infection.

You can see the more air in the aneurism, but less infection periaortic, then we schedule the procedure, opening the aneurysm sac, making the complete removal of the thrombus, removing of the infected part of the aneurysm, as Doctor Maelyna said, we try to preserve the graft.

That exactly what we are doing with the white foam and then putting the black foam making the Biofilm breakdown with local installation of antiseptics. In some of these cases we hope it is going to work, and, as you see, after one month

we did not have a good response. The tissue was uneager, so we decided to make the removal of the graft, but, of course, after downgrading of this infection. So, we looked at our data, because from 2012 all the patients with

Prostetic Graft infection we include in the prospective observational cohort, known VASGRA, when we are working into disciplinary with infectious disease specialist, microbiologists, radiologist and surgical pathologist. The study included two group of patients,

One, retrospective, 93 patient from 1999 to 2012, when we started the VASGRA study. And 88 patient from April 2012 to Seventeen within this register. Definitions. Baseline, end of the surgical treatment and outcome end,

the end of microbiological therapy. In total, 181 patient extracavitary, 35, most of them in the groin. Intracavitary abdominal, 102. Intracavitary thoracic, 44. If we are looking in these two groups,

straight with Negative Pressure Wound Therapy and, no, without Negative Pressure Wound Therapy, there is no difference between the groups in the male gender, obesity, comorbidity index, use of endovascular graft in the type Samson classification,

according to classification. The only difference was the ratio of hospitalization. And the most important slide, when we show that we have the trend to faster cure with vascular graft infection in patients with Negative Pressure Wound Therapy

If we want to see exactly in the data we make uni variant, multi variant analysis, as in the initial was the intracavitary abdominal. Initial baseline. We compared all these to these data. Intracavitary abdominal with no Pressure Wound Therapy

and total graft excision. And what we found, that Endovascular indexoperation is not in favor for faster time of cure, but extracavitary Negative Pressure Wound Therapy shows excellent results in sense of preserving and not treating the graft infection.

Having these results faster to cure, we looked for the all cause mortality and the vascular graft infection mortality up to two years, and we did not have found any difference. What is the strength of this study, in total we have two years follow of 87 patients.

So, to conclude, dear Chairman, Ladies and Gentlemen, Explant after downgrading giving better results. Instillation for biofilm breakdown, low mortality, good quality of life and, of course, Endovascular vascular graft infection lower time to heal. Thank you very much for your attention.

(applause)

- Thank you Dr. Asher. What an honor it is to be up here with Dr. Veith and Dr. Asher towards the end. You guys are leading by example being at the end of the meetings. So, thank you for allowing me to be up and talking about something

that not a lot of vascular surgeons have experience with, including me. I have no disclosures. On your left, I have listed some of the types of diseases that we most commonly see in the vertebral artery, and there are quite a lot.

And on the right, the standard types of treatment that we pursue in vascular surgery or as a vascular specialist. And often, in the vertebral artery, if we are going to pursue treatment, it's the endovascular route.

But I'll talk a little bit about open surgery. The clinical presentation is often vague. And the things I wanted to point out here in this long list are things like alternating paresthesias, dysphagia, or perioral numbness may be something in the history to look for

that you may not be thinking about when you're thinking about vertebral basilar disease. The anatomy looks straightforward in this picture, with the four segments, as you can see. It gets a little more complicated with just the arterial system,

but then when you start looking at all these structures, that you have to get out of of the way to get to the vertebral artery, it actually can be a difficult operation, particularly even in the V1 segment. The V1 typically is atherosclerotic disease.

V2 is often compression, via osteophyte or musculo-tendon structures. And V3 and V4, at the top, are typically from a dissection injury from sort of stretch or trauma injury. The pathophysiology isn't that well understood.

You have varying anatomy. It's very difficult to access this artery. Symptoms can be difficult to read, and treatment outcomes are not as reliable. But I'm going to take you through a very quick path through history here in the description

of the V1 segment exposure by Dr. Rentschler from 1958. And I love these pictures. Here is a transverse incision over the sternocleidomastoid, just above the clavicular head on the right side. And once you get the sternoclavicular head divided, you can see the longus colli muscle there.

Anteromedial is the carotid. Of course, you surround that with a Penrose drain. And then once you do that, you can separate your longus colli, and deep to that, the vertebral artery just easily slips right up, so you can do your transposition.

It's not quite that easy. I've done one of these operations, and it was difficult finding t e. And, again, here is on the opposite side, you can see the transposition in this cartoon.

Dr. Berguer is the world's expert, and a lot of this open surgical work comes out of the University of Michigan. Here is a study looking at 369 consecutive extracranial vertebral artery reconstructions. You can see the demographics of clinical presentation.

And note that about 34% of patients are presenting with hemispheric symptoms, with 60% in the vertebral basilar distribution. 300 of these reconstructions were for atherosclerosis. And the outcomes were pretty good. Before 1991, there wasn't really a protocol in place

in assessing and doing these procedures. And you can see the stroke and death rates of 4.1 and 3.2% respectively. And then the outcomes after 1991 are considerably better with a five year patency rate of 80%. So, in summary, vertebral artery disease is,

I think if you review this, is somewhat under diagnosed. Revascularization is a viable option. Most often, it's endovascular. But if you have endo-hostility, then an open, particularly for the V1 segment, may be a better option.

And this requires people with good operative experience. Thank you very much.

- Good morning, thank you very much to Dr. Veith and Professor Veith and the organizers. So this is real holography. It's not augmented reality. It's not getting you separated from the environment that you're in. This is actually taking the 3D out of the screen

so the beating heart can be held in the palm of your hand without you having to wear any goggles or anything else and this is live imaging. It can be done intra-procedure. This is the Holoscope-i and the other one is the Holoscope-x

where in fact you can take that actually 3D hologram that you have and you can implant it in the patient and if you co-register it correctly then you can actually do the intervention in the patient

make a needle tract to the holographic needle and I'm going to limit this to just now what we're actually doing at the moment and not necessarily what the future can be. This is ultimate 3D visualization, true volumes floating in the air.

This is a CT scan. So it started working, So we get rid of the auto-segmented and you can just interact. It's floating 45 centimeters away from you and you can just hold the patient's anatomy here and you can slice into the anatomy.

This is for instance a real CT of an aorta with the aortic valve which they wanted to analyze for a core valve procedure. This is done by Phelps. If you take the information

and they've looked at the final element analysis and interaction between the stem and the tissue. So here you can make measurements in real time. So if you did the 3D rotation and geography and you had the aorta and you wanted to put in a stent graft EVAR TVAR, and you would see,

and you could put in a typical tuber that you would do, and you could see how it, and this is a dynamic hologram, so you can see how it would open up, you can mark where your fenestration's chimney is and all that type of stuff would be. And you can move it around, and you have

a complete intuitive understanding of a, can we go to the next slide please, I can't, it seems to be clicking, thank you. So how do we do all this? Well, to create a hologram, what you need to do is just conceptualize it as printing in light.

Like if you had plastic and you took the XYZ data and you just put it into a 3D printer, and it would print it for you in light, then you'd go, Okay, so I understand, if it was printed for you in plastic then you'd understand. But imagine it's printing in light.

So we have every single piece of light focused, each photon is focused so that you can see it with a naked eye, in a particular place, but the difference is that it's totally sterile, you don't have to take off your gloves, you don't have to use a mouse,

you can interact with it directly. And all the XYZ data is 100% in place, so we've just seen a beautiful demonstration of augmented reality, and in augmented reality, you have to wear something, it isolates you from the environment that you're in, and it's based on

stereoscopy, and stereoscopy is how you see 3D movies, and how you see augmented reality, is by taking two images and fusing them in one focal plane. But you can't touch that image, because if you look at me now, you can see me very well, but if you hold your finger up 45 centimeters

and you focus on your finger, I become blurred. And so, you can only focus in one plane, you can't touch that image, because that image is distant from you, and it's a fused image, so you have the focus plane and you have the convergence plane, and this is an illusion

of 3D, and it's very entertaining, and it can be very useful in medical imaging, but in intra-operative procedures it has to be 100% accurate. So you saw a very beautiful example in the previous talk of augmented reality, where you have gesturing, where you can actually gesture with the image,

you can make it bigger, you can make it smaller. But what RealView does by creating real holography, which is all the XYZ data, is having it in the palm of your hand, with having above 20 focal planes, here, very very close to your eye, and that in another way, of having all those focal planes not only actually lets you

do the procedure but prevents nausea and having a feeling of discomfort because the image is actually there as of having the illusion of the images there. So just to go back, all RealView imaging is doing, is it's not changing your 3D RA cone, BMCT, MRI,

we can do all those XYZ datas and we can use them and we can present them, all we're doing, so you use your acquisition, we're just taking that, and we're breaking open the 3D displays and seeing all that 3D data limited in the 2D screen, let's set it free and have it floating in the air.

So we have the holoscope-i for structural cardiology and electrophysiology, and obviously the holoscope-x, which makes the patient x-rayed, completely visible. So its an over the head, this is now, obviously, free-standing when somebody buys us like Phillips or Siemens, it will be integrated into your lab,

come down from the ceiling, it's an independent system, and you just have a visor that you look through, which just goes up and down whenever you want to use it. You can interact with it the same as you do with your iPhone you can visualize, you can rotate, you can mark, you can slice, you can measure, as I showed you

some examples of it, and you can do this by voice as well, you just talk to it, you say slice and you slice it with your hand, it recognizes everybody's hand, there's no delay for whatever you're imaging. So structural cardiac procedures, this is what

a mitral valve will look like, floating in the air in front of you, you can see the anterior leaflet, the posterior leaflet. And once the catheter is inside and you're guiding the catheter inside the procedure, you can turn on your doppler, you'll be able to see that the catheter

movements, so for someone doing a mitral clip, or whatever, this would be very very useful. This is an electrophysiological procedure, and you can see how the catheter moves, when the catheter will move, and obviously, as my previous speaker was saying, you are appreciating 3D in a 2D screen,

so it's very difficult to appreciate, you'll have to take my word for it. But I think you can see dynamic colography at this quality, that you can interact with, that is something that is very special, we've presented at a number of conferences,

including at Veith, and we've already done a first in man, and the most exciting thing for now, is just this week, the first machine was installed at Toronto general, at the Peter Munk Cardiac Center, and they've done their first case, and so now we are launching and clinical trials in 2018, and hopefully,

I'll have something which is more vascular relevant, at the next time, Veith 2019, thank you very much.

- Good morning, thank you, Dr. Veith, for the invitation. My disclosures. So, renal artery anomalies, fairly rare. Renal ectopia and fusion, leading to horseshoe kidneys or pelvic kidneys, are fairly rare, in less than one percent of the population. Renal transplants, that is patients with existing

renal transplants who develop aneurysms, clearly these are patients who are 10 to 20 or more years beyond their initial transplantation, or maybe an increasing number of patients that are developing aneurysms and are treated. All of these involve a renal artery origin that is

near the aortic bifurcation or into the iliac arteries, making potential repair options limited. So this is a personal, clinical series, over an eight year span, when I was at the University of South Florida & Tampa, that's 18 patients, nine renal transplants, six congenital

pelvic kidneys, three horseshoe kidneys, with varied aorto-iliac aneurysmal pathologies, it leaves half of these patients have iliac artery pathologies on top of their aortic aneurysms, or in place of the making repair options fairly difficult. Over half of the patients had renal insufficiency

and renal protective maneuvers were used in all patients in this trial with those measures listed on the slide. All of these were elective cases, all were technically successful, with a fair amount of followup afterward. The reconstruction priorities or goals of the operation are to maintain blood flow to that atypical kidney,

except in circumstances where there were multiple renal arteries, and then a small accessory renal artery would be covered with a potential endovascular solution, and to exclude the aneurysms with adequate fixation lengths. So, in this experience, we were able, I was able to treat eight of the 18 patients with a fairly straightforward

endovascular solution, aorto-biiliac or aorto-aortic endografts. There were four patients all requiring open reconstructions without any obvious endovascular or hybrid options, but I'd like to focus on these hybrid options, several of these, an endohybrid approach using aorto-iliac

endografts, cross femoral bypass in some form of iliac embolization with an attempt to try to maintain flow to hypogastric arteries and maintain antegrade flow into that pelvic atypical renal artery, and a open hybrid approach where a renal artery can be transposed, and endografting a solution can be utilized.

The overall outcomes, fairly poor survival of these patients with a 50% survival at approximately two years, but there were no aortic related mortalities, all the renal artery reconstructions were patented last followup by Duplex or CT imaging. No aneurysms ruptures or aortic reinterventions or open

conversions were needed. So, focus specifically in a treatment algorithm, here in this complex group of patients, I think if the atypical renal artery comes off distal aorta, you have several treatment options. Most of these are going to be open, but if it is a small

accessory with multiple renal arteries, such as in certain cases of horseshoe kidneys, you may be able to get away with an endovascular approach with coverage of those small accessory arteries, an open hybrid approach which we utilized in a single case in the series with open transposition through a limited

incision from the distal aorta down to the distal iliac, and then actually a fenestrated endovascular repair of his complex aneurysm. Finally, an open approach, where direct aorto-ilio-femoral reconstruction with a bypass and reimplantation of that renal artery was done,

but in the patients with atypical renals off the iliac segment, I think you utilizing these endohybrid options can come up with some creative solutions, and utilize, if there is some common iliac occlusive disease or aneurysmal disease, you can maintain antegrade flow into these renal arteries from the pelvis

and utilize cross femoral bypass and contralateral occlusions. So, good options with AUIs, with an endohybrid approach in these difficult patients. Thank you.

- Relevant disclosures are shown in this slide. So when we treat patients with Multi-Segment Disease, the more segments that are involved, the more complex the outcomes that we should expect, with regards to the patient comorbidities and the complexity of the operation. And this is made even more complex

when we add aortic dissection to the patient population. We know that a large proportion of patients who undergo Thoracic Endovascular Aortic Repair, require planned coverage of the left subclavian artery. And this also been demonstrated that it's an increase risk for stroke, spinal cord ischemia and other complications.

What are the options when we have to cover the left subclavian artery? Well we can just cover the artery, we no that. That's commonly performed in emergency situations. The current standard is to bypass or transpose the artery. Or provide a totally endovascular revascularization option

with some off-label use , such as In Situ or In Vitro Fenestration, Parallel Grafting or hopefully soon we will see and will have available branched graft devices. These devices are currently investigational and the focus today's talk will be this one,

the Valiant Mona Lisa Stent Graft System. Currently the main body device is available in diameters between thirty and forty-six millimeters and they are all fifteen centimeters long. The device is designed with flexible cuff, which mimics what we call the "volcano" on the main body.

It's a pivotal connection. And it's a two wire pre-loaded system with a main system wire and a wire through the left subclavian artery branch. And this has predominately been delivered with a through and through wire of

that left subclavian branch. The system is based on the valiant device with tip capture. The left subclavian artery branch is also unique to this system. It's a nitinol helical stent, with polyester fabric. It has a proximal flare,

which allows fixation in that volcano cone. Comes in three diameters and they're all the same length, forty millimeters, with a fifteen french profile. The delivery system, which is delivered from the groin, same access point as the main body device. We did complete the early feasibility study

with nine subjects at three sites. The goals were to validate the procedure, assess safety, and collect imaging data. We did publish that a couple of years ago. Here's a case demonstration. This was a sixty-nine year old female

with a descending thoracic aneurysm at five and a half centimeters. The patient's anatomy met the criteria. We selected a thirty-four millimeter diameter device, with a twelve millimeter branch. And we chose to extend this repair down to the celiac artery

in this patient. The pre-operative CT scan looks like this. The aneurysm looks bigger with thrombus in it of course, but that was the device we got around the corner of that arch to get our seal. Access is obtained both from the groin

and from the arm as is common with many TEVAR procedures. Here we have the device up in the aorta. There's our access from the arm. We had a separate puncture for a "pigtail". Once the device is in position, we "snare" the wire, we confirm that we don't have

any "wire wrap". You can see we went into a areal position to doubly confirm that. And then the device is expanded, and as it's on sheath, it does creep forward a bit. And we have capture with that through and through wire

and tension on that through and through wire, while we expand the rest of the device. And you can see that the volcano is aligned right underneath the left subclavian artery. There's markers there where there's two rings, the outer and the inner ring of that volcano.

Once the device is deployed with that through and through wire access, we deliver the branch into the left subclavian artery. This is a slow deployment, so that we align the flair within the volcano and that volcano is flexible. In some patients, it sort of sits right at the level of

the aorta, like you see in this patient. Sometimes it protrudes. It doesn't really matter, as long as the two things are mated together. There is some flexibility built in the system. In this particular patient,

we had a little leak, so we were able to balloon this as we would any others. For a TEVAR, we just balloon both devices at the same time. Completion Angiogram shown here and we had an excellent result with this patient at six months and at a year the aneurysm continued

to re-sorb. In that series, we had successful delivery and deployment of all the devices. The duration of the procedure has improved with time. Several of these patients required an extension. We are in the feasibility phase.

We've added additional centers and we continue to enroll patients. And one of the things that we've learned is that details about the association between branches and the disease are critical. And patient selection is critical.

And we will continue to complete enrollment for the feasibility and hopefully we will see the pivotal studies start soon. Thank you very much

- Thank you and thanks again Frank for the kind invitation to be here another year. So there's several anatomic considerations for complex aortic repair. I wanted to choose between fenestrations or branches,

both with regards to that phenotype and the mating stent and we'll go into those. There are limitations to total endovascular approaches such as visceral anatomy, severe angulations,

and renal issues, as well as shaggy aortas where endo solutions are less favorable. This paper out of the Mayo Clinic showing that about 20% of the cases of thoracodynia aneurysms

non-suitable due to renal issues alone, and if we look at the subset that are then suitable, the anatomy of the renal arteries in this case obviously differs so they might be more or less suitable for branches

versus fenestration and the aneurysm extent proximally impacts that renal angle. So when do we use branches and when do we use fenestrations? Well, overall, it seems to be, to most people,

that branches are easier to use. They're easier to orient. There's more room for error. There's much more branch overlap securing those mating stents. But a branch device does require

more aortic coverage than a fenestrated equivalent. So if we extrapolate that to juxtarenal or pararenal repair a branched device will allow for much more proximal coverage

than in a fenestrated device which has, in this series from Dr. Chuter's group, shows that there is significant incidence of lower extremity weakness if you use an all-branch approach. And this was, of course, not biased

due to Crawford extent because the graft always looks the same. So does a target vessel anatomy and branch phenotype matter in of itself? Well of course, as we've discussed, the different anatomic situations

impact which type of branch or fenestration you use. Again going back to Tim Chuter's paper, and Tim who only used branches for all of the anatomical situations, there was a significant incidence of renal branch occlusion

during follow up in these cases. And this has been reproduced. This is from the Munster group showing that tortuosity is a significant factor, a predictive factor, for renal branch occlusion

after branched endovascular repair, and then repeated from Mario Stella's group showing that upward-facing renal arteries have immediate technical problems when using branches, and if you have the combination of downward and then upward facing

the long term outcome is impaired if you use a branched approach. And we know for the renals that using a fenestrated phenotype seems to improve the outcomes, and this has been shown in multiple trials

where fenestrations for renals do better than branches. So then moving away from the phenotype to the mating stent. Does the type of mating stent matter? In branch repairs we looked at this

from these five major European centers in about 500 patients to see if the type of mating stent used for branch phenotype grafts mattered. It was very difficult to evaluate and you can see in this rather busy graph

that there was a combination used of self-expanding and balloon expandable covered stents in these situations. And in fact almost 2/3 of the patients had combinations in their grafts, so combining balloon expandable covered stents

with self expanding stents, and vice versa, making these analyses very very difficult. But what we could replicate, of course, was the earlier findings that the event rates with using branches for celiac and SMA were very low,

whereas they were significant for left renal arteries and if you saw the last session then in similar situations after open repair, although this includes not only occlusions but re-interventions of course.

And we know when we use fenestrations that where we have wall contact that using covered stents is generally better than using bare stents which we started out with but the type of covered stent

also seems to matter and this might be due to the stiffness of the stent or how far it protrudes into the target vessel. There is a multitude of new bridging stents available for BEVAR and FEVAR: Covera, Viabahn, VBX, and Bentley plus,

and they all seem to have better flexibility, better profile, and better radial force so they're easier to use, but there's no long-term data evaluating these devices. The technical success rate is already quite high for all of these.

So this is a summary. We've talked using branches versus fenestration and often a combination to design the device to the specific patient anatomy is the best. So in summary,

always use covered stents even when you do fenestrated grafts. At present, mix and match seems to be beneficial both with regards to the phenotype and the mating stent. Short term results seem to be good.

Technical results good and reproducible but long term results are lacking and there is very limited comparative data. Thank you. (audience applauding)

- So thank you for the kind introduction and thanks for professor Viet for the invitation again this year. So, if we talk about applicability, of course you have to check the eye views from this device and you're limited by few instructions for users. They changed the lengths between the target vessel

and the orifice and the branch, with less than 50 mm , they used to be less than 25 mm. Also keep in mind, that you need to have a distance of more than 67 mm between your renal artery cuff and your iliac bifurcation. The good thing about branch endografts

is that if you have renal artery which comes ... or its orifice at the same level of the SME, you can just advance and put your endorafts a bit more proximally, of course risking more coverage of your aorta and eventually risking high rate

of paraplegia or spinal cord ischemia. Also if your renal artery on one side or if your target vessel is much lower with longer bridging stent grafts which are now available like the VBX: 79 mm or combination of bridging stem grafts, this can be treated as well.

Proximally, we have short extensions like the TBE which only allows 77 or 81 mm. This can also expand its applicability of this device. The suitability has already been proven in.. or assessed by Gaspar and vistas and it came around plus 60%

of all patients with aortic aneurysms. Majority of them are limitations where the previous EVAR or open AAA repair or the narrow diameter reno visceral segment in case of diabetes sections. So, what about the safety of the T-branch device?

We performed an observational study Mister, Hamburg and Milner group and I can present you here the short term results. We looked at 80 patients in prospective or retro prospective manner with the t-branch as instructed for use.

Majority were aneurysms with the type two or type four Crawford tracheal aneurysms, also a few with symptomatic or ruptured cases. Patient characteristics of course, we have the same of the usual high risk cardiovascular profiling,

this group of patients that has been treated. Majority was performed percutaneously in 55%. The procedure time shows us that there is still a learning curve. I think nowadays we can perform this under 200 minutes. What is the outcome?

We have one patient who died post operative day 30, after experiencing multiorgan failure. These are 30 day results. No rupture or conversion to open surgery. We had one patient with cardiac ischemia, seven patients with spinal cord ischemia

and one patient has early branch occlusion. There was both renal arteries were occluded, he had an unknown heparin induced thrombocytopenia and was treated with endovascular thrombectomy and successfully treated as well. Secondary interventions within 30 days were in one patient

stent placement due to an uncovered celiac stent stenosis In one patient there was a proximal type one endoleak with a proximal extension. One patient who had paraplegia or paraparesis, he had a stenosis of his internal iliac artery which stem was stented successfully,

and the paraparesis resolved later on in this patient. And of course the patient I just mentioned before, with his left and right renal artery occlusion. So to conclude, the T-branch has wide applicability as we've seen also before, up to 80% especially with adjuvant procedures.

Longer, more flexible bridging stent grafts will expand the use of this device. Also the TBE proximal extensions allows aortic treatment of diameters for more than 30 mm and I think the limitations are still the diameter at reno visceral segment,

previous EVAR or open AAA repair and having of course multiple visceral arteries. Thank you.

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