- That's a long title, thank you. We shortened the title, and just said, The Iliac Artery's Complicating Complex Juxtarenal and Thoracal Abdominal Repair. I have no disclosures. So, Iliac artery preservation is important whenever we start doing complex aortic aneurysm repair.
We don't understand completely what the incidence is with these extensive aneurysms. We know with AAAs, anywhere in the 10 to 40% have some sort of iliac artery involvement. It certainly can complicate the management as we get to these more complicated repairs.
Iliac artery preservation may be important for prevention of spinal cord ischemia, and those people in whom we can maintain both hypogastric arteries, it occurs at a less significant rate, with less severe symptoms and higher rates of recovery.
The aim of our study was to evaluate the incidence, management, and outcomes of iliac artery aneurysms associated with complex aortic aneurysms treated with fenestrated and branched endografts. Part of a PS-IDE study over a 15 year period of time,
this is dated from the Cleveland Clinic for the treatment of juxtarenal aneurysms and thoracal abdominal aortic aneurysms. For the purpose of this study, we defined an iliac artery aneurysm is 21 mm or greater as determined by diameter
by our core lab. We chose 21 mm because this was outside of the IFU for the iliac wounds that we had currently available to us at that time. We did multivariable analysis on the number of different outcomes. And we looked at the incidence
of iliac artery aneurysms by repair type. In all the aneurysms we treated, we see about a third of the patients had some level of iliac artery aneurysm involvement. In those patients that had less extensive thoracal abdominals, the type three
and type four abdominals, it occurred in about a third of the cases. A little bit less than the type two and the type one thoracal abdominals. We look at the demographics between those that had iliac artery aneurysm
involvement and those that did not have iliac artery involvement. It was more common in males to have iliac artery involvement than any other group. There are more females that didn't have iliac artery aneurysms. The rest
of the demographics were the same between the two groups. We look at the anatomic characteristics of the iliac artery aneurysms, about 60% of them were unilateral, about 40% of them were bilateral.
The mean iliac artery aneurysm size was 28 mm and that was the same on both sides. And we look at thought the percent that were actually very large, or considered large enough to potentially in and of themselves the repairs
greater than three centimeters. About 28% of them were greater than three centimeters on each side. If we look at our iliac artery aneurysm treatment type, this is 509 iliac artery aneurysms that
were treated out of all these patients. About 46% of them, we were able to obtain a seal distal to the iliac artery aneurysm. So it really only involved the proximal portion, the proximal half of the iliac artery.
20% of them, we placed a hypogastric branched endograft, and about 20% of them, we placed a hypogastric coverage plus embolization of that internal iliac artery. About 13% of them were left untreated at the time for a variety of different operative reasons.
Why is there a difference between the hypogastric coverage and embolization? It was availability of devices and surgeon choice at the time. At one point, we had a opportunity to be able to treat both fairly easily
on both sides and at one point we did not. Larger iliac artery aneurysms were treated with hypogastric coverage or hypogastric branched endografts, and there was a significant difference between the two. Most of the mean
size of those that were actually treated with either hypogastric branch or embolization for greater than three centimeters. If we look at peri-operative outcomes in those without iliac artery aneurysms versus those with iliac artery aneurysms.
We see that the fluoroscopy estimated blood loss is larger for those with iliac artery aneurysms, fluoroscopy time was longer and procedure duration was a bit longer as well. Obviously, a bit more complicated procedure,
more steps that's going to take a little bit longer to perform them. It did not effect the length of stay for these patients or the length of stay in the intensive care unit following the procedures. We look
at all-cause mortality at five years, no difference in whether they had an iliac artery aneurysm or not. It didn't matter whether it was unilateral or bilateral. If we look at aneurysm-related mortality, it's the same whether
they had the iliac artery aneurysm or not. Same for unilateral versus bilateral as well. Where we start to see some differences are the freedom from reintervention. This did vary between, among the three groups. In those patients without an iliac
artery aneurysm, they had the lower reintervention rate than those with the unilateral iliac artery aneurysm, and even lower rates from freedom from reintervention in those that had bilateral iliac artery aneurysms. Spinal cord ischemia, one of the
reasons we try to preserve both the hypogastric arteries. Look at our total spinal cord ischemia incidents. It didn't vary between the two groups, but if we look specifically, the type two thoracal abdominal aortic aneurysms in those patients that had bilateral
iliac arte higher rate of spinal cord ischemia compared to those that did not have any iliac artery aneurysms or those that had an internal iliac, a single iliac artery aneurysm.
So, iliac artery aneurysms affect about a third of the patients with complex aortic disease. They do not, their presence does not affect all-cause mortality or aneurysm related mortality. They are associated with a higher reintervention rate.
In extensive aneurysms, may be higher association with higher spinal cord ischemia rates. We need additional efforts are needed to improve outcomes and understanding appropriate application of different treatment options for patients with
complex aortic disease. Thank you.
- 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.
- 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 very much Mr. Chairman. Thank you Frank, for this kind invitation again to this symposium. This is my disclosure. With the drug coated balloons it is important to minimize the drug loss during the balloon transit during the inflation of the balloon.
Because Paclitaxel has a high degree of cytotoxicity that may induce necrosis and increase inflammation in the distal tissue, and we know that even with the best technique, we can loose 70 - 80% of the drop to the distal circulation,
the inference by different factors between them and the calcification of degree of these blood cells. There are adverse events secondary to drug coated balloons that have been reported recently. In animal molders it has shown that Downstream Vascular Changes are more frequent with
Drug Coated Balloons than with Drug-Eluting Stents. In animal molders it has been also shown that there is no evidence of significant downstream emboli or systemic toxicity with DCB's than with patients with controls. This was a study presented yesterday by (mumbles)
with a very nice and elegant study with a good methodology that shows in animals that there are different concentrations of the drug in distal tissue depending on the balloon that you are using. In this case, the range in balloon (mumbles)
those ones have the lowest concentration in the distal tissue. In clinical experience in this meta-analysis amputations and wound healing rate are lower with this series with controls. But there is controversy because
Complete Index Ulcer Healing is higher in this series than with control patients. But there are lower wound healing index in patients compared with drug-eluting stents. In the debate, (mumbles) and also in the dialux which are clinical trials in diuretic patients with CLI,
there we no issues of safety and no impair of the wounds healing. But, remember the negative result of the IN PACT DEEP trial in which there were more amputation at six months that could be influenced, but in all their factors, the lack of standardized
wound care protocols. (mumbles) has also reported recently good survival to 100% in patient treated with DCB's compared with plain balloons and with lutonic balloons. So in our institution, we did a study with the objective to examine
patient outcomes following the use of the drug-coated balloons in patients with CLI and diuretic patients with Complex Real World lesions undergoing endovascular intervention below-the-knee with the Ranger balloon coated with Paclitaxel.
This is a Two-Center Experience that is headed by the National University of Mexico in 30 patients with strict followup. With symptomatic Rutherford four to six. With the Stenosis and occlusion of infrapopliteal vessels and many degrees of calcification.
It was mandatory for all patients to have Pre-dilation before the use of DCB. We studied some endpoints like efficacy. (mumbles) Limb salvage, sustained clinical improvement, wound healing rate
and technical success and some other endpoints of safety. This is an example of multi level disease in a patient that has to be approached by (mumbles) access with a balloon preparation of the artery before the use of the DCB, and after this, we treated the anterior artery
and even to the arch of the foot. This is the way we follow our patient with ultra sound duplex with an index fibular of no more that 2.4. All patients were diabetic with Rutherford 5-6. 77% have a (mumbles) at the initial of the study.
And as you can see there were longer lesions and with higher degree of calcification and stenosis only in two of them we produced (mumbles). There were bailout stent placements in five patients and we did retrograde access in 43 patients.
Subintimal angioplasty was done in 32 patients, and Complete Index Wound Healing was in 93 of our patients. This is our Limb Salvage 94%. The Patency rate was 96% with this Kaplan Meir analysis. And in some patients we did a determination of Paclitaxel concentration in distal tissue
with the High Pressure Liquid Chromatography method. We only did this in five patients because of the lack of financial support, and technical problems. As you can see in three of them we had Complete Wound Healing.
Only one we had major amputation. This was the patient with the higher concentration of Paclitaxel in the distal tissue, and in one patient, we could not determine the concentration of Paclitaxel. This is the way we do this.
They take the sample of the patient at the moment we do the minor amputation. During day 10 after the angioplasty, we also do a (mumbles) analysis of the patient we have a limb salvage we can see arterial and capillar vessel proliferation and hyperplasia of the
arteriole media layer. But, in those patients that have major amputation even when they have a good sterio-graphic result like in this case, we see more fibrinoid necrosis which is a bad determination. So in conclusion,
angioplasty with the (mumbles) balloon maintain clinical efficacy over time is possible. We didn't see No Downstream clinical important or significant effects and high rates of Limb Salvage in complex CLI patients is possible.
Local toxic effects of paclitaxel and significant drug loss on the way to the lesion are theoretical considerations up to now because there is no biological study that can confirm this. Thank you very much.
- Thank you. Historically, common femoral endarterectomy is a safe procedure. In this quick publication that we did several years ago, showed a 1.5% 30 day mortality rate. Morbidity included 6.3% superficial surgical site infection.
Other major morbidity was pretty low. High-risk patients we identified as those that were functionally dependent, dyspnea, obesity, steroid use, and diabetes. A study from Massachusetts General Hospital their experience showed 100% technical success.
Length of stay was three days. Primary patency of five years at 91% and assisted primary patency at five years 100%. Very little perioperative morbidity and mortality. As you know, open treatment has been the standard of care
over time the goal standard for a common femoral disease, traditionally it's been thought of as a no stent zone. However, there are increased interventions of the common femoral and deep femoral arteries. This is a picture that shows inflection point there.
Why people are concerned about placing stents there. Here's a picture of atherectomy. Irritational atherectomy, the common femoral artery. Here's another image example of a rotational atherectomy, of the common femoral artery.
And here's an image of a stent there, going across the stent there. This is a case I had of potential option for stenting the common femoral artery large (mumbles) of the hematoma from the cardiologist. It was easily fixed
with a 2.5 length BioBond. Which I thought would have very little deformability. (mumbles) was so short in the area there. This is another example of a complete blow out of the common femoral artery. Something that was much better
treated with a stent that I thought over here. What's the data on the stenting of the endovascular of the common femoral arteries interventions? So, there mostly small single centers. What is the retrospective view of 40 cases?
That shows a restenosis rate of 19.5% at 12 months. Revascularization 14.1 % at 12 months. Another one by Dr. Mehta shows restenosis was observed in 20% of the patients and 10% underwent open revision. A case from Dr. Calligaro using cover stents
shows very good primary patency. We sought to use Vascular Quality Initiative to look at endovascular intervention of the common femoral artery. As you can see here, we've identified a thousand patients that have common femoral interventions, with or without,
deep femoral artery interventions. Indications were mostly for claudication. Interventions include three-quarters having angioplasty, 35% having a stent, and 20% almost having atherectomy. Overall technical success was high, a 91%.
Thirty day mortality was exactly the same as in this clip data for open repair 1.6%. Complications were mostly access site hematoma with a low amount distal embolization had previously reported. Single center was up to 4%.
Overall, our freedom for patency or loss or death was 83% at one year. Predicted mostly by tissue loss and case urgency. Re-intervention free survival was 85% at one year, which does notably include stent as independent risk factor for this.
Amputation free survival was 93% at one year, which factors here, but also stent was predictive of amputation. Overall, we concluded that patency is lower than historical common femoral interventions. Mortality was pretty much exactly the same
that has been reported previously. And long term analysis is needed to access durability. There's also a study from France looking at randomizing stenting versus open repair of the common femoral artery. And who needs to get through it quickly?
More or less it showed no difference in outcomes. No different in AVIs. Higher morbidity in the open group most (mumbles) superficial surgical wound infections and (mumbles). The one thing that has hit in the text of the article
a group of mostly (mumbles) was one patient had a major amputation despite having a patent common femoral artery stent. There's no real follow up this, no details of this, I would just caution of both this and VQI paper showing increased risk amputation with stenting.
- [Doctor] Thank you Tom and thanks Dr Veith for the invitation to be here again. These are my disclosures, so hypogastric embolization is not benign, patients can develop buttock claudication, higher after bilateral sacrifice, it can be persistent in up to half of patients. Sexual dysfunction can also occur, and we know that
there can be catastrophic complications but fortunately they're relatively rare. So now these are avoidable, we no longer have to coil and cover in many patients and we can preserve internal iliac's with iliac branch devices like you just heard. We had previously published the results of looking from
the pivotal trial, looking at the Gore IBE device with the six month primary end point showing zero aneurysm-related morality, high rates of technical success, 95% patency of the internal iliac limb, no type one or type three endoleaks and 98% freedom from reintervention. Importantly on the side of the iliac branch device, there
was prevention of new-onset of buttock claudication in all patients, and importantly also on the contralateral side in patients with bilateral aneurysms that were sacrificed, the incidents in a prospect of trial of the development of buttock claudication was 28%, confirming the data from those prior series.
And this is in line with the results of EVAR using iliac branch device published by many others showing low rates of mortality, high rates of technical success and also good patency of the devices. In press now we have results with follow-up out through two years, in the Gore IBE trial, we also compared
those findings to outcomes in a real world experience from the great registry, so 98 patients from the pivotal and continued access arm's of the IBE trial and also 92 patients who underwent treatment with the Gore IBE device in the great registry giving us 190 patients with 207 IBE devices implanted.
Follow-up was up to three years, it was an longer mean follow-up in the IDE study with the IBE device. Looking at outcomes between the clinical trial and the real world experience, they were very similar. There was no aneurysm-related mortality, there was no recorded new-onset ipsilateral buttock claudication,
this is all from the IDE trial since we didn't have that information in the great registry, and looking at the incidence of reinterventions, it was similar both in the IDE clinical trial experience and also in the great registry as well. Looking at patency of the internal iliac limb, it was
93.6%, both at 12 months and 24 months in the prospective US IBE pivotall trial and importantly all the internal iliac limb occlusions occurred very early in the experience likely due to technical or anatomic factors. When we look at the incidence of type two endoleaks, we had previously noted there was a very high incidence of
type two endoleaks, 60% at one month, this did tail off a bit over time but it was still 35% at two years. A total of five patients in the pivotal IBE trial had a reintervention for type two endoleak through two years, and despite that high incidence of type two endoleak, overall the incidence of aortic aneurysm sac expansion
of more than five millimeters has been rare and low at two and nine percent at 12 and 24 months, and there's been no expansions of the treated common iliac artery aneurysm sac's at either 12 or 24 months. Freedom from reintervention has been quite good, 90.4% through two years in the trial and most of these
re-interventions were type two endoleaks. We now have some additional data out through three years in about two thirds of the patients we have imaging data available now through three years in the pivotal IBE trial, there have been no additional events, device related events reported since the two year data and through three years
we have no recorded type one or type three endoleaks, no aneurysm ruptures, no incidences of migration, very high rates of patency of the external and internal iliac arteries, good freedom from re-intervention and good freedom from common iliac artery aneurysm sac enlargement. And I think, in line with these findings, the guidelines
now from the SVS are to recommend preservation of the internal iliac arteries when ever present and that's a grade 1A recommendation, thank you.
- [Nicos] Thanks so much. Good afternoon everybody. I have no disclosures. Getting falsely high velocities because of contralateral tight stenosis or occlusion, our case in one third of the people under this condition, high blood pressure, tumor fed by the carotid, local inflammation, and rarely by arteriovenous fistula or malformation.
Here you see a classic example, the common carotid, on the right side is occluded, also the internal carotid is occluded, and here you're getting really high velocity, it's 340, but if you visually look at the vessel, the vessel is pretty wide open. So it's very easy to see this discordance
between the diameter and the velocity. For occasions like this I'm going to show you with the ultrasound or other techniques, planimetric evaluation and if I don't go in trials, hopefully we can present next year. Another condition is to do the stenosis on the stent.
Typically the error here is if you measure the velocity outside the stent, inside the stent, basically it's different material with elastic vessel, and this can basically bring your ratio higher up. Ideally, when possible, you use the intra-stent ratio and this will give you a more accurate result.
Another mistake that is being done is that you can confuse the external with the internal, particularly also we found out that only one-third of the people internalized the external carotid, but here you should not make this mistake because you can see the branches obviously, but really, statistically speaking, if you take 100
consecutively occluded carotids, by statistical chance 99% of the time or more it will be not be an issue, that's common sense. And of course here I have internalization of the external, let's not confuse there too, but here we don't have any
stenosis, really we have increased velocity of the external because a type three carotid body tumor, let's not confuse this from this issue. Another thing which is a common mistake people say, because the velocity is above the levels we put, you see it's 148 and 47, this will make you with a grand criteria
having a 50% stenosis, but it's also the thing here is just tortuosity, and usually on the outer curve of a vessel or in a tube the velocity is higher. Then it can have also a kink, which can produce the a mild kink like this
on here, it can make the stenosis appear more than 50% when actually the vessel does have a major issue. This he point I want to make with the FMD is consistently chemical gradual shift, because the endostatin velocity is higher
than people having a similar degree of stenosis. Fistula is very rare, some of our over-diligent residents sometimes they can connect the jugular vein with roke last year because of this. Now, falsely low velocities because of proximal stenosis of
the Common Carotid or Brachiocephalic Artery, low blood pressure, low cardiac output, valve stenosis efficiency, stroke, and distal ICA stenosis or occlusion, and ICA recanalization. Here you see in a person with a real tight stenosis, basically the velocity is very low,
you don't have a super high velocity. Here's a person with an occlusion of the Common Carotid, but then the Internal Carotid is open, it flooded vessels from the external to the internal, and that presses a really tight stenosis of the external or the internal, but the velocities are low just because
the Common Carotid is occluded. Here is a phenomenon we did with a university partner in 2011, you see a recanalized Carotid has this kind of diameter, which goes all the way to the brain and a velocity really low but a stenosis really tight. In a person with a Distal dissection, you have low velocity
because basically you have high resistance to outflow and that's why the velocities are low. Here is an occlusion of the Brachiocephalic artery and you see all the phenomena, so earlier like the Common Carotid, same thing with the Takayasu's Arteritis, and one way I want to finish
this slide is what you should do basically when the velocity must reduce: planimetric evaluation. I'll give you the preview of this idea, which is supported by intracarotid triplanar arteriography. If the diameter of the internal isn't two millimeters, then it's 95% possible the value for stenosis,
regardless of the size of the Internal Carotid. So you either use the ICAs, right, then you're for sure a good value, it's a simple measurement independent of everything. Thank you very much.
- Thank you very much. I take over the presentation from Thomas Larzon, we, and different other people have the same approach to a ruptured triple A, trying to extend the advantages we have seen now, of an EVAR procedure in patients with inadequate anatomy, and to extend the limitation,
to patients with the less favorable anatomy. So, the concept of a ruptured EVAR has been already proven, with good research of three years, and I will build up, Thomas built up this presentation, on our so common experience that we published for fourteen years experience of two university centers,
performing EVAR on 100% of ruptured abdominal aortic aneurysms, over a 32 months period. So what we can see, is on the right side, this was the period where a part of the patient was treated by EVAR,
and the one that had not favorable anatomy were opened. On the left side, there is EVAR only, this a period 2009 to 11, you can see the effect of this change, is the operative cohort mortality moved from 26 to 24%, and total cohort mortality,
including to exclude the patient that are on feet, reduced from 33 to 27%. What changed also, is the protocol for anesthesia, so from a few patients that were treated under local anesthesia, actually, there are very few patients treated
just with general anesthesia primarily. What changed is the rejection rate, decreased from 10% to 4%, the age of the population treated increased, the part of women treated increased by 10%, and the amount of patients that are instable,
and treated, increased too. So, how to extend the limitation, the one is by using parallel grafts, or on table physician modified, extend graft to achieve what Benjamin does in his practice, a good seal proximal,
this is a three parallel graft, that worked very well. The other option, is to use Onyx for the distal landing zone, this is a technique that Thomas does use more liberally than we,
but is a good solution for patients where an IBD, for example, would not be possible, it doesn't require any special catheter, there is no contraindications due to tortuosity, and sealing is immediately obtained. Here, an example,
the aortoiliac, the main trunk, has been deployed here, then a (mumbles), the iliac extension is parked, can be deployed later, and as a Buddy catheter,
you can take a Bernstein catheter, you just position it in the origin of the hypogastric, or in the common iliac artery. Then, you deploy the distal extension, there is no more flow, slowly you'll stepwise,
5-10cc of Onyx can be applied, this allows to preserve the distal perfusion of the hypogastric, and to seal it. Sealing can also, with Onyx, can also be used in the proximal landing zone, there are two options,
here, the option with an instable patient that gets two parallel graphs with the remaining type 1 endoleak, you introduce your catheter through the leak, or the catheter inside the sack that is perfused, step wise, you will apply your Onyx.
Here, in another patient, of our experience, this is a suprarenal arteries after a triple A repair with EVAR that comes with the rupture, we combined here a chimney for the SMA, with a double brach device from Biotech,
deploy this, and you can see here there will be some leak. So, three days later, because the leak didn't have to do coagulation correct, once correct it didn't seal, we just very selectively, improvised with Onyx, the gap,
this is a three months outcome. Then, here a case of some Post EVAR with a type 1A endoleak, to extend this on the visceral aorta would have been very complex, this is why doctor Larson decided here just
to fill the whole sac with 60cc of Onyx, which worked very well. So, in Orebro, you can see that the 30-day mortality is 27%, the 90-day mortality is 30%, then the whole cohort,
including the 10% that have been excluded, has a mortality of 37 and 34%. From the different factor that was significant, you can see that local anesthesia works good, Aortic Balloon Occlusion works good, mortality in patients
with abdominal compartment syndrome is increased, mortality of patients in shock is increased, and finally, the mortality of patients having this adjunct procedure is not significantly increased, this holds true for the long-term outcomes.
So, we can see that by using adjuncts, every patient with a ruptured triple A can be offered an EVAR, eventually as a bridging procedure, chimney grafts can extend landing zones, Onyx can offer additional sealing options,
and valid long-term results for adjuncts has been proven. Thank you very much for your attention.
- Thank you, Dr. Ascher. Great to be part of this session this morning. These are my disclosures. The risk factors for chronic ischemia of the hand are similar to those for chronic ischemia of the lower extremity with the added risk factors of vasculitides, scleroderma,
other connective tissue disorders, Buerger's disease, and prior trauma. Also, hemodialysis access accounts for a exacerbating factor in approximately 80% of patients that we treat in our center with chronic hand ischemia. On the right is a algorithm from a recent meta-analysis
from the plastic surgery literature, and what's interesting to note is that, although sympathectomy, open surgical bypass, and venous arterialization were all recommended for patients who were refractory to best medical therapy, endovascular therapy is conspicuously absent
from this algorithm, so I just want to take you through this morning and submit that endovascular therapy does have a role in these patients with digit loss, intractable pain or delayed healing after digit resection. Physical examination is similar to that of lower extremity, with the added brachial finger pressures,
and then of course MRA and CTA can be particularly helpful. The goal of endovascular therapy is similar with the angiosome concept to establish in-line flow to the superficial and deep palmar arches. You can use an existing hemodialysis access to gain access transvenously to get into the artery for therapy,
or an antegrade brachial, distal brachial puncture, enabling you treat all three vessels. Additionally, you can use a retrograde radial approach, which allows you to treat both the radial artery, which is typically the main player in these patients, or go up the radial and then back over
and down the ulnar artery. These patients have to be very well heparinized. You're also giving antispasmodic agents with calcium channel blockers and nitroglycerin. A four French sheath is preferable. You're using typically 014, occasionally 018 wires
with balloon diameters 2.3 to three millimeters most common and long balloon lengths as these patients harbor long and tandem stenoses. Here's an example of a patient with intractable hand pain. Initial angiogram both radial and ulnar artery occlusions. We've gone down and wired the radial artery,
performed a long segment angioplasty, done the same to the ulnar artery, and then in doing so reestablished in-line flow with relief of this patient's hand pain. Here's a patient with a non-healing index finger ulcer that's already had
the distal phalanx resected and is going to lose the rest of the finger, so we've gone in via a brachial approach here and with long segment angioplasty to the radial ulnar arteries, we've obtained this flow to the hand
and preserved the digit. Another patient, a diabetic, middle finger ulcer. I think you're getting the theme here. Wiring the vessels distally, long segment radial and ulnar artery angioplasty, and reestablishing an in-line flow to the hand.
Just by way of an extreme example, here's a patient with a vascular malformation with a chronically occluded radial artery at its origin, but a distal, just proximal to the palmar arch distal radial artery reconstitution, so that served as a target for us to come in
as we could not engage the proximal radial artery, so in this patient we're able to come in from a retrograde direction and use the dedicated reentry device to gain reentry and reestablish in-line flow to this patient with intractable hand pain and digit ulcer from the loss of in-line flow to the hand.
And this patient now, two years out, remains patent. Our outcomes at the University of Pennsylvania, typically these have been steal symptoms and/or ulceration and high rates of technical success. Clinical success, 70% with long rates of primary patency comparing very favorably
to the relatively sparse literature in this area. In summary, endovascular therapy can achieve high rates of technical, more importantly, clinical success with low rates of major complications, durable primary patency, and wound healing achieved in the majority of these patients.
So I think when it comes to distal bypasses and ultra-distal bypasses it's all about how we make our decision. We know now that early intervention these patients have better outcome. We use waveform analysis to make our decision about how critical their skin is
we use different topical anesthesia depending the patient's fitness. I think this is just one important point that patient's with dark skin did not show all the full range of skin changes and patients get this dark foot sign
even before they start necrosing their skin. It's very important how we give our anesthetics we use vascular anesthesia with special interest prevascular disease because these patients are quite labile. We use even sometimes inotropes during the procedure
and post operative to maintain a good blood pressure. We believe that short bypasses have got better outcomes. Dr. Veith, have already published in the 80s about short bypasses also doing now the Tibiotibial bypasses on the look anesthetic. Some patients with very high risk for general anesthesia.
And our study we showed that the majority of our patients, who had ultra-distal bypasses had the bypasses from either popliteal or SFA artery. We use different techniques to improve on how to take our bypasses from the proximal anastomosis distally. So we use hybrid revascularization, we use drug-eluting
balloons, and stenting of the SFA and popliteal artery, so we can perform our bypass from the popliteal level. We even use Remote Endarterectomy to improve on our length of the inflow. So by doing remote endarterectomy of the SFA
and popliteal artery, we can take the bypass quite distally from the popliteal artery to the foot level. This is a patient who got critical leg ischaemia on the right side limited, venous conduit. We did remote endarterectomy of her SFA and popliteal artery. And then we can
easily take the bypass from the popliteal artery down to the foot level. On the left side, she had hybrid revascularization with SFA stenting and ultra-distal bypass. We use venous conduit in almost all our patients with ultra-distal bypass.
In distal bypasses we can PTFE but the majority of our patients have long saphenous veins or even arm veins. We started using Omniflow in our infected patients for distal bypasses with quite good results. We scan all our veins prior to the procedure
to make sure that we got good quality vein and amount to perform the procedure. We have published in our small veins series less than 3mm, we still have a very good outcome in distal bypasses. Especially when we do tibial bypasses
or dorsalis pedis bypasses we turn the grafts anatomically. You can see in this angiogram the graft going through the interosseous membrane down to the foot level. We put our incision a bit immediately on the foot level so if there is necrosis of the wound on the foot level that we don't expose the graft, especially when we
knew the patient was coming from the lateral aspect through the interosseous membrane. We select our bypasses especially in the foot level using the duplic scanogram, angiogram or CT angiogram. During the procedure we don't clamp our arteries we use the Flo-Rester and Flo-Through prothesis
to stop patients from bleeding while we're doing it. And we've never used tourniquet before all this has been published. Hand held doppler is the only quality control that we do we don't do on-table angiograms and we find this quite useful for our patients.
We can do the debridement and at the same time while we're doing the bypass at the ankle level. As for anticoagulation and antiplatelet therapy We do antiplatelet therapy for all patient with distal and ultra-distal bypass. And we use heparin and warfarin for patients
who have got redo surgery. Graft surveillance for all our patients Unfortunately, we can only afford it in the NHS for one year, but if the patient get an intervention they go for another full year. Salvage angioplasty is essential for these patients
and we treat these patients as quite as a emergency when they present. So, conclusion, Mr. Sherman, ladies and gentlemen, distal and ultra-distal bypasses require good planning. We use veins for all our bypasses when it comes to the foot level and ultra-distal bypasses,
and of course selecting the target vessel in the foot is very important. Graft Surveillance is essential to maintain quality and outcome for these patients. Thank you very much.
- 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.
- Thank you very much for the privilege of participating in this iconic symposium. I have no disclosures pertinent to this presentation. The Atelier percutaneous endovascular repair for ruptured abdominal aortic aneurysms is a natural evolution of procedural technique due to the success of fully percutaneous endovascular
aortic aneurysm repair in elective cases. This past year, we had the opportunity to publish our data with regard to 30 day outcomes between percutaneous ruptured aneurysm repairs and surgical cutdown repairs utilizing the American College of Surgeons NSQIP database,
which is a targeted database which enrolls about 800 hospitals in the United States, looking at both the univariate and multivariate analyses comparing preoperative demographics, operative-specific variables and postoperative outcomes. There were 502 patients who underwent
ruptured abdominal aortic aneurysms that were included in this review, 129 that underwent percutaneous repair, whereas 373 underwent cutdown repair. As you can see, the majority were still being done by cutdown.
Over the four years, however, there was a gradual increase in the number of patients that were having percutaneous repair used as their primary modality of access, and in fact a more recent stasis has shown to increase up to 50%,
and there certainly was a learning curve during this period of time. Looking at the baseline characteristics of patients with ruptured aneurysms undergoing both modalities, there was not statistically significant difference
with regard to these baseline characteristics. Likewise, with size of the aneurysms, both were of equal sizes. There was no differences with regard to rupture having hypotension, proximal or distal extension of the aneurysms.
What is interesting, however, that the patients that underwent percutaneous repair tended to have regional anesthesia as their anesthesia of choice, rather than that of having a general. Also there was for some unexplained reason
a more significant conversion to open procedures in the percutaneous group as compared to the cutdown group. Looking at adjusted 30-day outcomes for ruptured endovascular aneurysm repairs, when looking at the 30-day mortality,
the operative time, wound complications, hospital length of stay, that was not statistically significant. However, over that four year period of time, there tended to be decreased hospital length of stay as well as decreased wound complications
over four years. So the summary of this study shows that there was an increased use of fully percutaneous access for endovascular repairs for ruptured aneurysms with noninferiority compared to traditional open femoral cutdown approaches.
There is a trending advantage over conventional surgical exposure with decreased access-related complications, as well as decreased hospital length of stay. Now, I'm going to go through some of the technical tips, and this is really going to be focused upon
the trainees in the room, and also perhaps those clinicians who do not do percutaneous access at this time. What's important, I find, is that the utility of duplex ultrasonography, and this is critical to delineate the common
femoral artery access anatomy. And what's important to find is the common femoral artery between the inguinal ligament and this bifurcation to the profunda femoral and superficial femoral arteries. So this is your target area. Once this target area is found,
especially in those patients presenting with ruptured aneurysm, local anesthesia is preferred over general anesthesia with permissive hypotension. This is a critical point that once you use ultrasound, that you'd want to orient your probe to be
90 degrees to the target area and measure the distance between the skin and the top of that artery. Now if you hold that needle at equidistance to that same distance between the skin and the artery and angle that needle at 45 degrees,
this will then allow you to have the proper trajectory to hit the target absolutely where you're imaging the vessel, and this becomes important so you're not off site. Once micropuncture technique is used, it's always a good idea just to use
a quick fluoroscopic imaging to show that your access is actually where you want it to be. If it's not, you can always re-stick the patient again. Once you have the access in place, what can then happen is do a quick angio to show in fact you have reached the target vessel.
This is the routine instructions for use by placing the percutaneous suture-mediated closure system at 45 degree angles from one another, 90 degrees from one another. Once the sheath is in place for ruptured aneurysm, the placement of a ballon occlusion
can be done utilizing a long, at least 12 French sheath so that they'll keep that balloon up in place. What's also good is to keep a neat operative field, and by doing so, you can keep all of these wires and sutures clean and out of the way and also color code the sutures so that you have
ease and ability to close them later. Finally, it's important to replace the dilator back in the sheath prior to having it removed. This is important just so that if there are problems with your percutaneous closure, you can always very quickly replace your sheath back in.
Again, we tend to color code the sutures so we can know which ones go with which. You can also place yet a third percutaneous access closure device if need be by keeping the guide wire in place. One other little trick that I actually learned
from Ben Starnes when visiting his facility is to utilize a Rumel mediated technique by placing a short piece of IV tubing cut length, running the suture through that, and using it like a Rumel, and that frees up your hand as you're closing up
the other side and final with closure. The contraindications to pREVAR. And I just want to conclude that there's increased use of fully percutaneous access for endovascular repair. There's trending advantages over conventional surgical exposure with decreased
access related complications, and improved outcomes can be attributed to increased user experience and comfort with percutaneous access, and this appears to be a viable first option. Thank you very much.
- Thank you very much for the opportunity to speak carbon dioxide angiography, which is one of my favorite topics and today I will like to talk to you about the value of CO2 angiography for abdominal and pelvic trauma and why and how to use carbon dioxide angiography with massive bleeding and when to supplement CO2 with iodinated contrast.
Disclosures, none. The value of CO2 angiography, what are the advantages perhaps? Carbon dioxide is non-allergic and non-nephrotoxic contrast agent, meaning CO2 is the only proven safe contrast in patients with a contrast allergy and the renal failure.
Carbon dioxide is very highly soluble (20 to 30 times more soluble than oxygen). It's very low viscosity, which is a very unique physical property that you can take advantage of it in doing angiography and CO2 is 1/400 iodinated contrast in viscosity.
Because of low viscosity, now we can use smaller catheter, like a micro-catheter, coaxially to the angiogram using end hole catheter. You do not need five hole catheter such as Pigtail. Also, because of low viscosity, you can detect bleeding much more efficiently.
It demonstrates to the aneurysm and arteriovenous fistula. The other interesting part of the CO2 when you inject in the vessel the CO2 basically refluxes back so you can see the more central vessel. In other words, when you inject contrast, you see only forward vessel, whereas when you inject CO2,
you do a pass with not only peripheral vessels and also see more central vessels. So basically you see the vessels around the lesions and you can use unlimited volumes of CO2 if you separate two to three minutes because CO2 is exhaled by the respirations
so basically you can inject large volumes particularly when you have long prolonged procedures, and most importantly, CO2 is very inexpensive. Where there are basically two methods that will deliver CO2. One is the plastic bag system which you basically fill up with a CO2 tank three times and then empty three times
and keep the fourth time and then you connect to the delivery system and basically closest inject for DSA. The other devices, the CO2mmander with the angio assist, which I saw in the booth outside. That's FDA approved for CO2 injections and is very convenient to use.
It's called CO2mmander. So, most of the CO2 angios can be done with end hole catheter. So basically you eliminate the need for pigtail. You can use any of these cobra catheters, shepherd hook and the Simmons.
If you look at this image in the Levitor study with vascular model, when you inject end hole catheter when the CO2 exits from the tip of catheter, it forms very homogenous bolus, displaces the blood because you're imaging the blood vessel by displacing blood with contrast is mixed with blood, therefore as CO2
travels distally it maintains the CO2 density whereas contrast dilutes and lose the densities. So we recommend end hole catheter. So that means you can do an arteriogram with end hole catheter and then do a select arteriogram. You don't need to replace the pigtail
for selective injection following your aortographies. Here's the basic techniques: Now when you do CO2 angiogram, trauma patient, abdominal/pelvic traumas, start with CO2 aortography. You'll be surprised, you'll see many of those bleeding on aortogram, and also you can repeat, if necessary,
with CO2 at the multiple different levels like, celiac, renal, or aortic bifurcation but be sure to inject below diaphragm. Do not go above diaphragm, for example, thoracic aorta coronary, and brachial, and the subclavian if you inject CO2, you'll have some serious problems.
So stay below the diaphragm as an arterial contrast. Selective injection iodinated contrast for a road map. We like to do super selective arteriogram for embolization et cetera. Then use a contrast to get anomalies. Super selective injection with iodinated contrast
before embolization if there's no bleeding then repeat with CO2 because of low viscocity and also explosion of the gas you will often see the bleeding. That makes it more comfortable before embolization. Here is a splenic trauma patient.
CO2 is injected into the aorta at the level of the celiac access. Now you see the extra vascularization from the low polar spleen, then you catheterize celiac access of the veins. You microcatheter in the distal splenic arteries
and inject the contrast. Oops, there's no bleeding. Make you very uncomfortable for embolizations. We always like to see the actual vascularization before place particle or coils. At that time you can inject CO2 and you can see
actual vascularization and make you more comfortable before embolization. You can inject CO2, the selective injection like in here in a patient with the splenic trauma. The celiac injection of CO2 shows the growth, laceration splenic with extra vascularization with the gas.
There's multiple small, little collection. We call this Starry Night by Van Gogh. That means malpighian marginal sinus with stagnation with the CO2 gives multiple globular appearance of the stars called Starry Night.
You can see the early filling of the portal vein because of disruption of the intrasplenic microvascular structures. Now you see the splenic vein. Normally, you shouldn't see splenic vein while following CO2 injections.
This is a case of the liver traumas. Because the liver is a little more anterior the celiac that is coming off of the anterior aspect of the aorta, therefore, CO2 likes to go there because of buoyancy so we take advantage of buoyancy. Now you see the rupture here in this liver
with following the aortic injections then you inject contrast in the celiac axis to get road map so you can travel through this torus anatomy for embolizations for the road map for with contrast. This patient with elaston loss
with ruptured venal arteries, massive bleeding from many renal rupture with retro peritoneal bleeding with CO2 and aortic injection and then you inject contrast into renal artery and coil embolization but I think the stent is very dangerous in a patient with elaston loss.
We want to really separate the renal artery. Then you're basically at the mercy of the bleeding. So we like a very soft coil but basically coil the entire renal arteries. That was done. - Thank you very much.
- Time is over already? - Yeah. - Oh, OK. Let's finish up. Arteriogram and we inject CO2 contrast twice. Here's the final conclusions.
CO2 is a valuable imaging modality for abdominal and pelvic trauma. Start with CO2 aortography, if indicated. Repeat injections at multiple levels below diaphragm and selective injection road map with contrast. The last advice fo
t air contamination during the CO2 angiograms. Thank you.
- Thank you very much and I would like to thank Dr. Veit for the kind invitation, this is really great meeting. Those are my disclosures. Percutaneous EVAR has been first reported in the late 1990's. However, for many reasons it has not been embraced
by the vascular community, despite the fact that it has been shown that the procedure can be done under local anesthesia and it decreases OR time, time to ambulation, wound complication and length of stay. There are three landmark papers which actually change this trend and make PEVAR more popular.
All of these three papers concluded that failure or observed failure of PEVAR are observed and addressed in the OR which is a key issue. And there was no late failures. Another paper which is really very prominent
is a prospective randomize study that's reported by Endologix and published in 2014. Which revealed that PEVAR closure of the arteriotomy is not inferior to open cut down. Basically, this paper also made it possible for the FDA to approve the device, the ProGlide device,
for closure of large bore arteriotomies, up to 26 in the arterial system and 29 in the venous system. We introduced percutaneous access first policy in our institution 2012. And recently we analyzed our results of 272 elective EVAR performed during the 2012 to 2016.
And we attempted PEVAR in 206 cases. And were successful in 92% of cases. But the question was what happened with the patient that failed PEVAR? And what we found that was significantly higher thrombosis, vessel thrombosis,
as well as blood loss, more than 500 cc in the failed PEVAR group. Similarly, there was longer operative time and post-operative length of stay was significantly longer. However, in this relatively small group of patients who we scheduled for cut-down due to different reasons,
we found that actually there was no difference between the PEVAR and the cut-down, failed PEVAR and cut-down in the terms of blood loss, thrombosis of the vessel, operative time and post-operative length of stay. So what are the predictors of ProGlide failure?
Small vessel calcification, particularly anterior wall calcification, prior cut-down and scarring of the groin, high femoral bifurcation and use of large bore sheaths, as well as morbid obesity. So how can we avoid failures?
I think that the key issue is access. So we recommend that all access now or we demand from our fellow that when we're going to do the operation with them, cut-down during fluoroscopy on the ultra-sound guidance, using micropuncture kits and access angiogram is actually mandatory.
But what happened when there is a lack of hemostasis once we've deployed two PEVARs? Number one, we try not to use more than three ProGlide on each side. Once the three ProGlide failed we use the angioseal. There's a new technique that we can have body wire
and deployed angioseal and still have an access. We also developed a technique that we pack the access site routinely with gelfoam and thrombin. And also we use so-called pull and clamp technique, shown here. Basically what it is, we pull the string of the ProGlide
and clamp it on the skin level. This is actually a very very very good technique. So in conclusion, PEVAR first approach strategy successful in more than 90% of cases, reduced operative time and postoperative length of stay, the failure occurred more commonly when the PEVAR
was completed outside of IFU, and there was no differences in outcome between failed PEVAR and planned femoral cut-down. Thank you.
- Thank you Tim, Manny, Dr. Veith. Again thank you for the kind invitation. Um, here are my disclosures. The Chimney Snorkel Sandwich technique is really one that's been used and discussed many times throughout this great meeting in years past.
I've been asked to kind of see how we expand the use for thoracoabdominal aneurysms. Um, basically it's a matter of putting a parallel graft and then having an inner graft that will help seal the aneurysm sac itself by maintaining
perfusion to the visceral vessels. Um, the number of parallel grafts has been shown to be of note, and generally if you get beyond two parallel grafts at any one location, that tends to dramatically increase the incidence of
gutter leaks and potential for continued perfusion of the aneurysm sac. Here again showing at two, they still keep a reasonable aortic diameter, but once you start going three and four parallel grafts you tend to have significant compression
of the main aortic graft itself, as well as the potential for gutter leaks. Um, the PERICLES Registry certainly looked as I know has been discussed earlier in this meeting, and basically what it showed was that this was a reasonable way of treating
some of these complex aneurysms with a durable outcome going out to two to three years, uh, at a survival rate of over 70 percent. So, to show how we use this for patients with thoracoabdominal aneurysms, this was a 67 year, I use the term is,
a 67-year-old gentleman presented urgently with a sudden onset of back and abdominal pain. Apparently he was, uh, had a new wife and was trying some sexually enhancing medications from the DR. Had a history of coronary artery disease,
erectile dysfunction, and congestive heart failure, and CT scan revealed a type four thoracoabdominal dissection with a eight centimeter juxtarenal aneurysm, and he was in acute pain. Uh, here is the CT scan as we go through,
and you can see obviously the very complex dissection. You had a small segment of perfusion still around the level of the celiac going down into the SMA, uh, and then this rather, again the renals were
also with a small luminal area, and then a large aneurysm going up to eight centimeters going down into the abdominal component, and then reasonable access vessels from below. This shows the dissection extending down
through the thoracoabdominal segment, and again, he was in acute pain. Uh, so we came in and did an angiogram and IVUS, uh, and here we show the area of the dissection going down as well as the take-off of the subclavian artery.
Again, the true lumen being here. This was confirmed with IVUS. The IVUS sash, and this is the true lumen here, the false lumen being around the periphery, and as you go through you can see there's almost complete collapse of that
true lumen throughout the cardiac cycle. Uh, we performed a left carotid subclavian bypass, and embolized the left subclavian artery and put a thoracic endograft in, covering that lead point as you go in and taking it really almost up to the level of the left carotid artery.
There you can see the occluded subclavian. Uh, with that in place we then prepared to do a four vessel sandwich, or double sandwich, technique. Here we came down, we brought the grafts down to about the level of the takeoff of the celiac access with thoracic endografts.
Lateral shows the takeoff of the celiac and the SMA. Uh, we were able to catheterize both those vessels from the axillary region and put stents going out in this two sandwich technique, uh, and then actually put our stents going out from both the celiac and SMA.
We then were able to do that once we had those stents in place with adequate overlap and no real gutter leak, we then came down and similarly put another graft down to the takeoff of the renal vessels and then selectively catheterized
the right and left renal. Here you can see the stenosis near the origin of the right renal artery. With that we then performed balloon angioplasty with covered stents, I believe these were VBX stents going out,
and then covered that further down as we went down into the area of the eight centimeter aneurysm. And here we come in building down from that area and the perivisceral segment down and then to the iliacs showing good perfusion down to the takeoff of the
hypogastric, and then finally angiogram showed we had good perfusion to celiac, SMA, both renal vessels, and then down through the aneurysm sac itself. This is, uh, he remains stable. His postoperative course actually was uneventful.
He was discharged from the hospital at day four. He's been seen back now at one year follow up at six and 12 month follow up and he's remained stable with no evidence of endo-leak. So I appreciate the opportunity to try and present a more novel way of managing
these patients in the acute setting. Thank you very much.
- Thank you very much, Dr. Veith, and thank you to you and the organizing committee for inviting me to participate again this year in, really, the premiere vascular meeting. This morning, I'd like to talk about the contemporary management of carotid artery aneurysms. These are my disclosures.
Extracranial carotid artery aneurysms and pseudoaneurysms may result from a variety of causes, including trauma, fibromuscular dysplasia, atherosclerosis. They're associated with dissection, connective tissue disorders, mycotic aneurysms associated with infection.
We see patch aneurysms from prior carotid endarterectomy, as well as aneurysms associated with radiation, and those that occur spontaneously. Sequelae of these aneurysms are often distal embolization, potential for thrombosis, some patients experience compressive symptoms, and rupture may occur as well.
Treatment has traditionally been through open surgical repair, but there have been advances in endovascular treatments, including covered stents, woven stents, such as the pipeline stent in size-appropriate cases, bare stents with or without adjunctive coil embolization.
Open surgical repair has been time tested and it's proven to be very effective, but there are potential morbidities associated with challenges or surgical exposure, particularly in patients with prior surgery or radiation and those with anatomically-challenging lesions.
A very definitive review of this has been conducted by the surgeons at the Mayo Clinic, including Drs. Money, Bower, and Fowl, and they have described the treatment of 141 aneurysms in 132 patients. In the evolution of treatment with endovascular techniques, covered stents have been employed.
These eliminate aneurysm and pseudoaneurysm perfusion completely and immediately after deployment, but there have been reports of delayed thrombosis of these covered stents when they've been deployed in the cervical distribution. This is a patient of ours who has a large patch aneurysm, nearly four centimeters in size.
If you look on the CAT scan you'll see there's very limited, essentially no overlying soft tissues as a result of the previous radical neck dissection. In this case, we'd elected to use a covered stent to achieve exclusion of this patch aneurysm, and then used a bare metal stent distally to augment the treatment itself.
Our therapies progressed to the use of bare metal stents with associated coil embolization so-called stent, assisted coil embolization. As you can see, there are two sequential, very large, pseudoaneurysms of the internal carotid artery. Here's the carotid bifurcation.
Here, I hope you can see between these green arrows, is the stent that's been deployed. We use closed cell stents typically for these applications, and we can use a microcatheter cannulate that pseudoaneurysm and deploy large neuro-embolic coils to promote flow of cessation.
When we follow up with these patients, here's this patient's one-month post-operative duplex ultrasound, there's no flow in the pseudoaneurysm, and excellent flow in the internal carotid artery without stenosis. We've then progressed to the use of overlapping closed cell stents, and in doing so,
hoped to sort of simulate the pipeline woven stent configuration but have greater applicability in terms of diameter of the internal carotid. Here, you can see this internal carotid artery spontaneous pseudoaneurysm. We then go ahead and bring our initial stent into position
across the origin of the pseudoaneurysm. Here's after initial stent deployment on this static image. Here, after our second stent deployment, you can see very limited static flow within the pseudoaneurysm itself, and that's evidenced by, after the flowed out of the internal carotid artery,
there's still residual contrast within the pseudoanerusym. Here are the individual characteristics of the patients that we've treated using endovascular techniques. To summarize those data, the mean duration of follow up for these patients is 331 days.
But we have followed one patient out to eight years. The study's limited by the relatively small number of patients and the limited duration of follow up in these patients. But our technical success has been 100%, in terms of being able to deploy the endovascular
techniques, and maintain patency. We've had no patients who've experienced neurologic sequelae, including no strokes or TIAs. There've been no cases in which the aneurysm has expanded, in most cases, the aneurysm itself regresses and there's been no flow within those aneurysms or pseudoaneurysms.
Finally, we have been able to maintain 100% patency in these patients, as monitored using our standard follow up protocol with duplex ultrasound being performed every three months for the first year, and annually thereafter. In conclusion, extracranial carotid artery aneurysms and pseudoaneurysms may be treated effectively
using standard open techniques. However, surgical exposure and perioperative morbidity may present challenges for open repair. Endovascular approaches to aneurysm and pseudoaneurysm treatment have evolved progressively. The preliminary results of our analysis with mid-term
follow up suggest that these techniques are effective and durable, with limited procedural morbidity. Thank you very much.
- Thank you very much, Frank, ladies and gentlemen. Thank you, Mr. Chairman. I have no disclosure. Standard carotid endarterectomy patch-plasty and eversion remain the gold standard of treatment of symptomatic and asymptomatic patient with significant stenosis. One important lesson we learn in the last 50 years
of trial and tribulation is the majority of perioperative and post-perioperative stroke are related to technical imperfection rather than clamping ischemia. And so the importance of the technical accuracy of doing the endarterectomy. In ideal world the endarterectomy shouldn't be (mumbling).
It should contain embolic material. Shouldn't be too thin. While this is feasible in the majority of the patient, we know that when in clinical practice some patient with long plaque or transmural lesion, or when we're operating a lesion post-radiation,
it could be very challenging. Carotid bypass, very popular in the '80s, has been advocated as an alternative of carotid endarterectomy, and it doesn't matter if you use a vein or a PTFE graft. The result are quite durable. (mumbling) showing this in 198 consecutive cases
that the patency, primary patency rate was 97.9% in 10 years, so is quite a durable procedure. Nowadays we are treating carotid lesion with stinting, and the stinting has been also advocated as a complementary treatment, but not for a bail out, but immediately after a completion study where it
was unsatisfactory. Gore hybrid graft has been introduced in the market five years ago, and it was the natural evolution of the vortec technique that (mumbling) published a few years before, and it's a technique of a non-suture anastomosis.
And this basically a heparin-bounded bypass with the Nitinol section then expand. At King's we are very busy at the center, but we did 40 bypass for bail out procedure. The technique with the Gore hybrid graft is quite stressful where the constrained natural stint is inserted
inside internal carotid artery. It's got the same size of a (mumbling) shunt, and then the plumbing line is pulled, and than anastomosis is done. The proximal anastomosis is performed in the usual fashion with six (mumbling), and the (mumbling) was reimplanted
selectively. This one is what look like in the real life the patient with the personal degradation, the carotid hybrid bypass inserted and the external carotid artery were implanted. Initially we very, very enthusiastic, so we did the first cases with excellent result.
In total since November 19, 2014 we perform 19 procedure. All the patient would follow up with duplex scan and the CT angiogram post operation. During the follow up four cases block. The last two were really the two very high degree stenosis. And the common denominator was that all the patients
stop one of the dual anti-platelet treatment. They were stenosis wise around 40%, but only 13% the significant one. This one is one of the patient that developed significant stenosis after two years, and you can see in the typical position at the end of the stint.
This one is another patient who develop a quite high stenosis at proximal end. Our patency rate is much lower than the one report by Rico. So in conclusion, ladies and gentlemen, the carotid endarterectomy remain still the gold standard,
and (mumbling) carotid is usually an afterthought. Carotid bypass is a durable procedure. It should be in the repertoire of every vascular surgeon undertaking carotid endarterectomy. Gore hybrid was a promising technology because unfortunate it's been just not produced by Gore anymore,
and unfortunately it carried quite high rate of restenosis that probably we should start to treat it in the future. Thank you very much for your attention.
- Yeah now, I'm talking about another kind of vessel preparation device, which is dedicated to prevent the occurrence of embolic events and with these complications. That's a very typical appearance of an occluded stent with appositional stent thrombosis up to the femur bifurcation.
If you treat such a lesion simply with balloon angioplasty, you will frequently see some embolic debris going downstream, residing in this total occlusion of the distal pocket heel artery as a result of an embolus, which is fixed at the bifurcation of
the anterior tibial and the tibial planar trunk, what you can see over here. So rates of macro embolization have been described as high as 38% after femoral popliteal angioplasty. It can be associated with limb loss.
There is a risk of limb loss may be higher in patients suffering from poor run-off and critical limb ischemia. There is a higher rate of embolization for in-stent restenosis, in particular, in occluded stents and chronic total occlusions.
There is a higher rate of cause and longer lesions. This is the Vanguard IEP system. It's an integrated balloon angioplasty and embolic protection device. You can see over here, the handle. There is a rotational knob, where you can,
a top knob where you can deploy, and recapture the filter. This is the balloon, which is coming into diameters and three different lengths. This is the filter, 60 millimeter in length. The pore size is 150 micron,
which is sufficient enough to capture relevant debris going downstream. The device is running over an 80,000 or 14,000 guide-wire. This is a short animation about how the device does work. It's basically like a traditional balloon.
So first of all, we have to cross the lesion with a guide-wire. After that, the device can be inserted. It's not necessary to pre-dilate the lesion due to the lower profile of the capture balloon. So first of all, the capture filter,
the filter is exposed to the vessel wall. Then you perform your pre-dilatation or your dilatation. You have to wait a couple of second until the full deflation of the balloon, and then you recapture the filter, and remove the embolic debris.
So when to use it? Well, at higher risk for embolization, I already mentioned, which kind of lesions are at risk and at higher risk of clinical consequences that should come if embolization will occur. Here visible thrombus, acute limb ischemia,
chronic total occlusion, ulceration and calcification, large plaque volume and in-stent reocclusion of course. The ENTRAP Study was just recently finished. Regarding enrollment, more than 100 patients had been enrolled. I will share with you now the results
of an interim analysis of the first 50 patients. It's a prospective multi-center, non-randomized single-arm study with 30-day safety, and acute performance follow-up. The objective was to provide post-market data in the European Union to provide support for FDA clearance.
This is the balloon as you have seen already. It's coming in five and six millimeter diameter, and in lengths of 80, 120 and 200 millimeters. This is now the primary safety end point at 30 days. 53 subjects had been enrolled. There was no event.
So the safety composite end point was reached in 100%. The device success was also 100%. So all those lesions that had been intended to be treated could be approached with the device. The device could be removed successfully. This is a case example with short lesion
of the distal SFA. This is the device in place. That's the result after intervention. That's the debris which was captured inside the filter. Some more case examples of more massive debris captured in the tip of the filter,
in particular, in longer distance total occlusions. Even if this is not a total occlusion, you may see later on that in this diffused long distance SFA lesion, significant debris was captured. Considering the size of this embolus,
if this would have been a patient under CLI conditions with a single runoff vessel, this would have potentially harmed the patient. Thank you very much.
- Thank you, good morning everybody. Thank you for the kind invitation, Professor Veith, it's an honor for me to be here again this year in New York. I will concentrate my talk about the technical issues and the experience in the data we have already published about the MISACE in more than 50 patients.
So I have no disclosure regarded to this topic. As you already heard, the MISACE means the occlusion of the main stem of several segmental arteries to preserve the capability of the collateral network to build new arteries. And as a result, we developed
the ischemic preconditioning of the spinal cord. Why is this so useful? Because it's an entirely endovascular first stage of a staged approach to treat thoracoabdominal aortic aneurysm in order to reduce the ischemic spinal cord injury.
How do you perform the MISACE? Basically, we perform the procedure in local anesthesia, through a percutaneous trans-femoral access using a small-bore sheath. The patient is awake, that means has no cerebrospinal fluid damage
so we can monitor the patient's neurological for at least 48 hours after the procedure. So, after the puncture of the common femoral artery, using a technique of "tower of power" in order to cannulate the segmental arteries. As you can see here, we started with a guiding catheter,
then we place a diagnosis catheter and inside, a microcatheter that is placed inside the segmental artery. Then we started occlusion of the ostial segment of the segmental artery. We use coils or vascular plugs.
We don't recommend the use of fluids due to the possible distal embolization and the consequences. Since we have started this procedure, we have gained a lot of experience and we have started to ask,
what is a sufficient coilembolization? As you can see here, this artery, we can see densely packed coils inside, but you can see still blood flowing after the coil. So, was it always occluding, or is it spontaneous revascularization?
That, we do not know yet. The question, is it flow reduction enough to have a ischemic precondition of the spinal cord? Another example here, you can see a densely packed coil in the segmental artery at the thoracic level. There are some other published data
with some coils in the segm the question is, which technique should we use, the first one, the second one? Another question, is which kind of coil to use? For the moment, we can only use the standard coils
in our center, but I think if we have 3-D or volume coils or if you have microvascular plugs that are very compatible with the microcatheter, we have a superior packing density, we can achieve a better occlusion of the segmental artery, and we have less procedure time and radiation time,
but we have to think of the cost. We recommend to start embolization of the segmental artery, of course, at the origin of it, and not too far inside. Here, you can see a patient where we have coiled a segmental artery very shortly after the ostium,
but you can see here also the development of the collaterals just shortly before the coils, leading to the perfusion of segmental artery that was above it. As you can see, we still have a lot of open question. Is it every patent segmental artery
a necessary to coil? Should we coil only the large ones? I show you an example here, you can see this segmental artery with a high-grade stenotic twisted ostium due to aortic enlargement.
I can show you this segmental artery, six weeks after coiling of a segmental artery lower, and you can see that the ostium, it's no more stenotic and you can see also the connection between the segmental artery below to the initial segmental artery.
Another question that we have, at which level should we start the MISACE? Here, can see a patient with a post-dissection aneurysm after pedicle technique, so these are all uncovered dissection stent, and you can see very nicely the anterior spinal artery
feeded by the anterior radiculomedullary artery from the segmental artery. So, in this patient, in fact, we start the coiling exactly at the seat of this level, we start to coil the segmental artery that feeds the anterior spinal artery.
So, normally we find this artery of the Th 9 L1, and you can see here we go upwards and downwards. We have some challenges with aneurysm sac enlargement, in this case, we use this technique to open the angle of the catheter, we can use also deflectable steerable sheath
in order to reach the segmental artery. And you can see here our results, again, I just will go fast through those, we have treated 57 patients, most of them were Type II, Type III aortic aneurysms. We have found in median nine patent segmental artery
at the level of the aorta to be treated, between 2 and 26, and we have coiled in multiple sessions with a mean interval of 60 days between the sessions. No sooner than seven days we perform the complete exclusion of the aneurysm
in order to let the collateral to develop, and you can see our result: at 30 days we had no spinal cord ischemia. So I can conclude that our first experience suggest that MISACE is feasible, safe, and effective, but segmental artery coiling in thoracoabdominal aneurysm
can be challenging, it's a new field with many open questions, and I looking forward for the results with PAPA_ARTiS study. Thank you a lot.
- Thank you Mr. Chairman. Ladies and gentleman, first of all, I would like to thank Dr. Veith for the honor of the podium. Fenestrated and branched stent graft are becoming a widespread use in the treatment of thoracoabdominal
and pararenal aortic aneurysms. Nevertheless, the risk of reinterventions during the follow-up of these procedures is not negligible. The Mayo Clinic group has recently proposed this classification for endoleaks
after FEVAR and BEVAR, that takes into account all the potential sources of aneurysm sac reperfusion after stent graft implant. If we look at the published data, the reported reintervention rate ranges between three and 25% of cases.
So this is still an open issue. We started our experience with fenestrated and branched stent grafts in January 2016, with 29 patients treated so far, for thoracoabdominal and pararenal/juxtarenal aortic aneurysms. We report an elective mortality rate of 7.7%.
That is significantly higher in urgent settings. We had two cases of transient paraparesis and both of them recovered, and two cases of complete paraplegia after urgent procedures, and both of them died. This is the surveillance protocol we applied
to the 25 patients that survived the first operation. As you can see here, we used to do a CT scan prior to discharge, and then again at three and 12 months after the intervention, and yearly thereafter, and according to our experience
there is no room for ultrasound examination in the follow-up of these procedures. We report five reinterventions according for 20% of cases. All of them were due to endoleaks and were fixed with bridging stent relining,
or embolization in case of type II, with no complications, no mortality. I'm going to show you a couple of cases from our series. A 66 years old man, a very complex surgical history. In 2005 he underwent open repair of descending thoracic aneurysm.
In 2009, a surgical debranching of visceral vessels followed by TEVAR for a type III thoracoabdominal aortic aneurysms. In 2016, the implant of a tube fenestrated stent-graft to fix a distal type I endoleak. And two years later the patient was readmitted
for a type II endoleak with aneurysm growth of more than one centimeter. This is the preoperative CT scan, and you see now the type II endoleak that comes from a left gastric artery that independently arises from the aneurysm sac.
This is the endoleak route that starts from a branch of the hepatic artery with retrograde flow into the left gastric artery, and then into the aneurysm sac. We approached this case from below through the fenestration for the SMA and the celiac trunk,
and here on the left side you see the superselective catheterization of the branch of the hepatic artery, and on the right side the microcatheter that has reached the nidus of the endoleak. We then embolized with onyx the endoleak
and the feeding vessel, and this is the nice final result in two different angiographic projections. Another case, a 76 years old man. In 2008, open repair for a AAA and right common iliac aneurysm.
Eight years later, the implant of a T-branch stent graft for a recurrent type IV thoracoabdominal aneurysm. And one year later, the patient was admitted again for a type IIIc endoleak, plus aneurysm of the left common iliac artery. This is the CT scan of this patient.
You will see here the endoleak at the level of the left renal branch here, and the aneurysm of the left common iliac just below the stent graft. We first treated the iliac aneurysm implanting an iliac branched device on the left side,
so preserving the left hypogastric artery. And in the same operation, from a bowl, we catheterized the left renal branch and fixed the endoleak that you see on the left side, with a total stent relining, with a nice final result on the right side.
And this is the CT scan follow-up one year after the reintervention. No endoleak at the level of the left renal branch, and nice exclusion of the left common iliac aneurysm. In conclusion, ladies and gentlemen, the risk of type I endoleak after FEVAR and BEVAR
is very low when the repair is planning with an adequate proximal sealing zone as we heard before from Professor Verhoeven. Much of reinterventions are due to type II and III endoleaks that can be treated by embolization or stent reinforcement. Last, but not least, the strict follow-up program
with CT scan is of paramount importance after these procedures. I thank you very much for your attention.
- Again, I think I'm going to continue the theme here on talking about REBOA technologies and techniques, so thank you, Dr. Veith, again for allowing us this format. No disclosures on my part. Everyone by now has heard this term multiple times and I think this is a community that understands
Resuscitative Endovascular Balloon Occulsion of the Aorta. Not new technology, very familiar to everyone in this audience who frequently is called upon to deal with the ultimate model of noncompressible hemorrhage,
that of the rupturing abdominal aortic aneurysm. Dr. Veith showed us many years ago that we could get appreciable outcomes improvement with endovascular balloon occlusions here, and the military was certainly listening. Colonel Rasmussen developed this paper
describing the first techniques. The diagram on your left, one of our first civilian centers, in a classic military-civilian collaboration, that we rolled this out at at Shock Trauma, this is the algorithm that is utilized there and it has been exported to countless trauma centers
for incorporation into their own protocols. And, as it was also mentioned, the American Association for the Surgery of Trauma AORTA Registry is capturing these prospectively. We now have 34 centers and over 568 REBOAs captured as of November 2018.
And this hopefully will continue to provide us some of the data that we need to better differentiate optimal patient selection and optimal practices. So, again, another encouraging anyone in the audience to likewise contribute to those 34 centers. And we have evolving advances in technology, clearly,
some of that has been discussed about here already. And better understanding through the Endovascular Resuscitation Trauma Management Society, and other meetings like that, to look at procedural approaches that work and share knowledge across the full spectrum.
We have lower profile devices. We have the ability to monitor the patients to step up care in a stepwise fashion to optimize the survival of bleeding patients. The old Coda balloon we initially utilized for this approach for REBOA back when I started doing this in about 2008 was,
or 2009, was has largely been replaced by these military specific civilian and trauma specific technologies that Colonel Rasmussen mentioned briefly. The REBOA in 2018, the majority of centers coming on board from the trauma center perspective or utilizing the prime time ER REBOA catheter,
this is FDA approved for floroscopic, for use. It is 7 French compatible, has a distal arterial pressure monitoring port distal to the balloon, does not require a guide wire, and is exceedingly user-friendly for the majority of the people who are going to be putting these in,
which is the acute care trauma surgeon who's at bedside when these patients arrive. The techniques that we utilize and we teach in our American College of Surgeons Basic Endovascular Skills for Trauma course, our best course, which is our current standard for training of REBOA
to trauma and acute care providers and, increasingly a larger subset of providers, utilizes external landmarks. And this has been shown through both CT morphometric studies and clinical applications to be a very reliable modality in that patient who is actively
attempting to code in front of you. And Colonel Rasmussen also touched on our growing experience here. The Northern paper was really a banner presentation and an eye-opening report for we, as military providers, and the trauma community, with their 100 percent
survival to the next echelon of care. We've learned a lot from these groups and their ability to employ this device effectively in really a resource-limited environment where they don't have blood providers become a resource that is very limited.
It's a challenging environment and they were able to deploy this quite effectively. And, more recently, the Tactical Combat Casualty Care committee has released guidelines for utilizations technology across a wider spectrum of small, not just surgical teams,
but also resuscitative teams. These are some of the pictures of some of the crews that I deployed with recently. And we are small team living out of a backpack with very limited blood utilization. And having this capability in your backpack,
to get that patient to more of a hard stand definitive surgical facility is a game-changer for all of these types of providers put in these situations across huge geographic footprints including Africa and parts of the Middle East.
Refinement of techniques is also continuing to evolve. Tal Horer talked briefly about partial REBOLA, this is how I utilize this technology. In a more refined fashion, utilizing a manual compression of the balloon to titrate a blood pressure that keeps the heart and the brain happy
with normal tension and keeps the operative field until definitive surgical control's obtained in hypotensive resuscitation state. So we're not disrupting clot, we're not causing more bleeding and propagating the deadly triad with ongoing cuagulopathy.
It's a wonderful tool, wonderful approach, I think. This is how it works. To some degree you can see the surgeon, the REBOA catheter in place, that was placed before the abdomen was opened. The surgeon actively working to obtain definitive control.
And we have here the balloon, the pressure in the balloon, the monitoring port above the balloon. This is the pressure below the balloon, as measured off the side port of the 7 French sheath. So now I'm able to titrate a pressure that minimizes the risk of hypotension
for the brain, the heart, those critical organs, yet perfuses the distal organs to a safe degree so that we don't have that reperfusion payback after subsequent definitive surgical control's obtained. And this technology continues to grow across a wide spectrum of indications,
non-trauma hemorrhage indications. When you look at global health burden, post-partum hemorrhage is more likely, in 10 years, to benefit from the further integration of REBOA, than any trauma bleeding that we encounter. That's really just a huge global health burden
and there's an active community in both the U.S. and South America developing registries for implementation there and partnerships across multiple specialties. And there's now actually an NIH funded, clinical research project in development
to look at the use of these balloons in CPR, those patients in Vfib that are not refractory to electroshock, and to see if we can salvage some of those patients. So that is also in effect. Some conclusions, REBOA continues to evolve
for applications for trauma and has evolving opportunities, as well, in non-trauma areas and wider utilization is going to continue to be facilitated by continued device improvements, training and research. Thank you.
- 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.
- Thanks Dr. Weaver. Thank you Dr. Reed for the invitation, once again, to this great meeting. These are my disclosures. So, open surgical repair of descending aortic arch disease still carries some significant morbidity and mortality.
And obviously TEVAR as we have mentioned in many of the presentations has become the treatment of choice for appropriate thoracic lesions, but still has some significant limitations of seal in the aortic arch and more techniques are being developed to address that.
Right now, we also need to cover the left subclavian artery and encroach or cover the left common carotid artery for optimal seal, if that's the area that we're trying to address. So zone 2, which is the one that's,
it is most commonly used as seal for the aortic arch requires accurate device deployment to maximize the seal and really avoid ultimately, coverage of the left common carotid artery and have to address it as an emergency. Seal, in many of these cases is not maximized
due to the concern of occlusion of the left common carotid artery and many of the devices are deployed without obtaining maximum seal in that particular area. Failure of accurate deployment often leads to a type IA endoleak or inadvertent coverage
of the left common carotid artery which can become a significant problem. The most common hybrid procedures in this group of patients include the use of TEVAR, a carotid-subclavian reconstruction and left common carotid artery stenting,
which is hopefully mostly planned, but many of the times, especially when you're starting, it may be completely unplanned. The left common carotid chimney has been increasingly used to obtain a better seal
in this particular group of patients with challenging arches, but there's still significant concerns, including patients having super-vascular complications, stroke, Type A retrograde dissections and a persistent Type IA endoleak
which can be very challenging to be able to correct. There's limited data to discuss this specific topic, but some of the recent publications included a series of 11 to 13 years of treatment with a variety of chimneys.
And these publications suggest that the left common carotid chimneys are the most commonly used chimneys in the aortic arch, being used 76% to 89% of the time in these series. We can also look at these and the technical success
is very good. Mortality's very low. The stroke rate is quite variable depending on the series and chimney patency's very good. But we still have a relatively high persistent
Type IA endoleak on these procedures. So what can we do to try to improve the results that we have? And some of these techniques are clearly applicable for elective or emergency procedures. In the elective setting,
an open left carotid access and subclavian access can be obtained via a supraclavicular approach. And then a subclavian transposition or a carotid-subclavian bypass can be performed in preparation for the endovascular repair. Following that reconstruction,
retrograde access to left common carotid artery can be very helpful with a 7 French sheath and this can be used for diagnostic and therapeutic purposes at the same time. The 7 French sheath can easily accommodate most of the available covered and uncovered
balloon expandable stents if the situation arises that it's necessary. Alignment of the TEVAR is critical with maximum seal and accurate placement of the TEVAR at this location is paramount to be able to have a good result.
At that point, the left common carotid artery chimney can be deployed under control of the left common carotid artery. To avoid any embolization, the carotid can be flushed, primary repaired, and the subclavian can be addressed
if there is concern of a persistent retrograde leak with embolization with a plug or other devices. The order can be changed for the procedure to be able to be done emergently as it is in this 46 year old policeman with hypertension and a ruptured thoracic aneurism.
The patient had the left common carotid access first, the device deployed appropriately, and the carotid-subclavian bypass performed in a more elective fashion after the rupture had been addressed. So, in conclusion, carotid chimney's and TEVAR
combination is a frequently used to obtain additional seal on the aortic arch, with pretty good results. Early retrograde left common carotid access allows safe TEVAR deployment with maximum seal,
and the procedure can be safely performed with low morbidity and mortality if we select the patients appropriately. Thank you very much.
- First of all let me thank Dr. Veith for the kind invitation to be here again and it's my great pleasure to share with you the preliminary result of our Indian registry. So these are my disclosures. So as vascular surgeon we have to admit that the Fogarty embolectomy has many possibility
but also some limitation. You can see here in this short video that we were able to remove thrombus, but thrombus was mixed up with plaque, hyperplasia and the final result was a very poor backflow from this vessel.
So already a couple of years ago we published our experience comparing the Fogarty embolectomy with the hybrid treatment that at that time was Fogarty plus a lot of endovascular rescue maneuver and of course hybrid was better, but we were very surprised by this.
What we found that the introvert in geography after Fogarty we had a number of chronic disease this is normal, but we also found a number of residual thrombus because firmly adherent to the arterial wall or just not appropriately reached by the Fogarty balloon embolectomy.
Even the over the Y Fogarty balloon embolectomy cannot work enough well. And then finally we also had a number of case with the injuries. Probably from inappropriate Fogarty balloon maneuver into the vessels so we had to find something more.
We had to find something less traumatic and so we realized that at the same time our colleagues from stroke unit, the neurologist had already a very nice tool in their hands. It's the Penumbra system which has began the market leader in stroke because it's very atraumatic,
dedicated for intracranial vessel navigation and then has a very high aspiration power system. So a couple of years later the company came on the market with the family dedicated to peripheral artery, the Indigo System from three to eight French catheter
designed for peripheral artery. So really improved trackability and atraumatic tip of this catheter. So how does the system work? You have already seen this video, but anyway you have first to engage the clot then you switch on
the aspiration power and then from proximal to distal you can remove all the thrombus, you can use the separator guide wire that breaks up the clot when ingested into the catheter and so the final result is that the tip of catheter is all we part and that you can remove all the thrombus
in very few minutes. Now I want to show to you my very first case it was four years ago and the system was not yet available and I for prefer I had some conflicting result with the other with competitors. I have incomplete reperfusion or hemolysis.
I have very positive feedback from my colleagues from the stroke unit at my University. I had the possibility to borrow the neuro catheters. So in this very first patients, unfit for lysis with a lot of thrombus, fresh thrombus in a vein popliteal area and the tibial artery I used
neural catheters, separate was very easy even at the beginning of our experience and we were able to engage the clot use the separator and removing in a couple of passage old thrombus even from the very distal localizations. So up to now we have used the Indigo family,
Indigo system in a lot of situation I can go through all this the one, but I want to show you how far we can go and it's a very challenging situation within dialysis dependent patients with the calcify kink and tibial artery and thrombus in the plantar arch
we were able to reach the plantar arch with the CAT 3 device and remove all the thrombus. Since then we have decided to collect data in a prospective national registry, the Indian registry. We want to collect 150 case in this prospective registry. We started last year and we actually included any kind
of acute lower limb ischemia embolism, thrombosis, graft endograft thrombosis, distal emboli and secondary to preceding intervention or even incomplete reperfusion after Fogarty and lysis. We evaluated the vessel patency by TIMI score of course we have now 136 patients enrolled by 17 centers active
and Ethiological hypothesis of the ischemia was in the 3/4 of case thrombotic, so the most challenging case. Acute and chronic ischemia mainly in very popliteal area or even below the knee or below the ankle in arteries. And here are preliminary result available for 120 patients.
After the Indigo use we already have a 90% TIMI two or three flow restoration will raise up to 96% after additional PTA or stent or additional lysis. So in conclusion these are only the preliminary result I hope to share with you our final result next year,
but at that moment we can already say that the Indigo is safe and effective option for acute lower limb ischemia, technical success is high even in small arteries, and up to now adverse event related to the device is very low and bleeding and hemolysis are not reported.
- Lymphatic, so it's fun, actually, not to talk on venous interventions for once. And, naturally, the two systems are very different. But, on the other hand, they're also related in several ways and I will come back to that later. I have no disclosures, maybe only my gratitude to this man, Dr. Maxim Itkin,
who actually got me started in the field, and was gracious enough to supply me some of his material. And who is also responsible for making our lives way easier over the last years. Because in former times, we needed to do, to visualize the lymphatic system,
we needed to do pedal lymphangiography and that was very, very cumbersome. It took a long time and was very painful for the patient. And he introduced the ultrasound guided intranodal lymphangiography,
and that's fairly easy for most of us. With ultrasound you find a lymph node in the groin, you puncture that and you can control the needle position with contrast enhanced ultrasound and once you establish that position, you might do a MR lymphangiography.
Thereby showing, in this case, a beautiful, normal anatomy of the thoracic duct. I need to say, the variations in lymphatics are extreme. So, you can also visualize, naturally, the pathology, like for example, pulmonary lymphatic perfusion syndrome.
What's going on there. Normally, lymph courses up through thoracic duct, but in this case, you kind of have a reflux in the bronchial tree and lymph leakage. And you can image that again, beautifully with MR, which you can show extensive leakage
of lymph in the lung parenchyma. So you can treat that. How can you treat that? By embolization of the thoracic duct. But first we need to get into there, and that's not a very easy thing to do.
But now, again, with access to a lymph node in the groin, you can push lipiodol, and then visualize the cisterna chyli and access that transcutaneously with a 21/22 gauge needle and then push up a O-18 wire high up in the thoracic duct.
First you deploy some coils to prevent any leakage of glue inside the venous system, and then by microcatheter, you infuse glue all the way down, embolizing the thoracic duct. So, complete different group of lymphatic disorders is oriented in the liver and hepatic lymphatic disorders.
And maybe not everybody knows that, but 80% of the flow in the thoracic duct is caused by the liver and by the intestine. And many times in lymphatic disorders, there needs to be a combination of two factors. One factor is a venous variation of a,
sorry, an anatomical variation in lymph vessels and the other one is that we have an increase in lymph flow. And in the liver, that can be caused by a congestion of the liver, for example, cirrhosis, or a right side, that's congested heart failure.
What happens then is you increase the flow, the lymph flow, tremendously and if you also have a variation like in this case, when the vessels do not directly course towards the cisterna chyli, but in very close contact to the abdomen,
then you can have leakage of the lymph and leakage of proteins, which is a serious problem. So, what is then, to do next? You can access the lymph vessels in the liver by percutaneous access in the periportal space,
and induce some contrast and then later, visualize that one back, visualize that with dye that you can see with an endoscopy, thereby proving your diagnosis, and then, in a similar way,
you can induce lipiodol again with glue, embolizing the lymph vessels in the liver, treating the problem. In summary, popularity of lymphatic interventions really increased over the last years mainly because novel imaging,
novel interventional techniques, new approaches, and we all gained more experience. If you would like, I would guess that, we are at a phase where we were at venous, like 10, 15 years ago. If we are a little bit positive,
then the future is very bright. And within 10, 15 years, we find new indications and probably have much more to tell you. Thank you for your attention.
- So my charge is to talk about using band for steal. I have no relevant disclosures. We're all familiar with steal. The upper extremity particularly is able to accommodate for the short circuit that a access is with up to a 20 fold increase in flow. The problem is that the distal bed
is not necessarily as able to accommodate for that and that's where steal comes in. 10 to 20% of patients have some degree of steal if you ask them carefully. About 4% have it bad enough to require an intervention. Dialysis associated steal syndrome
is more prevalent in diabetics, connective tissue disease patients, patients with PVD, small vessels particularly, and females seem to be predisposed to this. The distal brachial artery as the inflow source seems to be the highest risk location. You see steal more commonly early with graft placement
and later with fistulas, and finally if you get it on one side you're very likely to get it on the other side. The symptoms that we are looking for are coldness, numbness, pain, at the hand, the digital level particularly, weakness in hand claudication, digital ulceration, and then finally gangrene in advanced cases.
So when you have this kind of a picture it's not too subtle. You know what's going on. However, it is difficult sometimes to differentiate steal from neuropathy and there is some interaction between the two.
We look for a relationship to blood pressure. If people get symptomatic when their blood pressure's low or when they're on the access circuit, that is more with steal. If it's following a dermatomal pattern that may be a median neuropathy
which we find to be pretty common in these patients. Diagnostic tests, digital pressures and pulse volume recordings are probably the best we have to assess this. Unfortunately the digital pressures are not, they're very sensitive but not very specific. There are a lot of patients with low digital pressures
that have no symptoms, and we think that a pressure less than 60 is probably consistent, or a digital brachial index of somewhere between .45 and .6. But again, specificity is poor. We think the digital pulse volume recordings is probably the most useful.
As you can see in this patient there's quite a difference in digital waveforms from one side to the other, and more importantly we like to see augmentation of that waveform with fistula compression not only diagnostically but also that is predictive of the benefit you'll get with treatment.
So what are our treatment options? Well, we have ligation. We have banding. We have the distal revascularization interval ligation, or DRIL, procedure. We have RUDI, revision using distal inflow,
and we have proximalization of arterial inflow as the approaches that have been used. Ligation is a, basically it restores baseline anatomy. It's a very simple procedure, but of course it abandons the access and many of these patients don't have a lot of good alternatives.
So it's not a great choice, but sometimes a necessary choice. This picture shows banding as we perform it, usually narrowing the anastomosis near the artery. It restricts flow so you preserve the fistula but with lower flows.
It's also simple and not very morbid to do. It's got a less predictable effect. This is a dynamic process, and so knowing exactly how tightly to band this and whether that's going to be enough is not always clear. This is not a good choice for low flow fistula,
'cause again, you are restricting flow. For the same reason, it's probably not a great choice for prosthetic fistulas which require more flow. So, the DRIL procedure most people are familiar with. It involves a proximalization of your inflow to five to 10 centimeters above the fistula
and then ligation of the artery just below and this has grown in popularity certainly over the last 10 or 15 years as the go to procedure. Because there is no flow restriction with this you don't sacrifice patency of the access for it. It does add additional distal flow to the extremity.
It's definitely a more morbid procedure. It involves generally harvesting the saphenous vein from patients that may not be the best risk surgical patients, but again, it's a good choice for low flow fistula. RUDI, revision using distal inflow, is basically
a flow restrictive procedure just like banding. You're simply, it's a little bit more complicated 'cause you're usually doing a vein graft from the radial artery to the fistula. But it's less complicated than DRIL. Similar limitations to banding.
Very limited clinical data. There's really just a few series of fewer than a dozen patients each to go by. Finally, a proximalization of arterial inflow, in this case rather than ligating the brachial artery you're ligating the fistula and going to a more proximal
vessel that often will accommodate higher flow. In our hands, we were often talking about going to the infraclavicular axillary artery. So, it's definitely more morbid than a banding would be. This is a better choice though for prosthetic grafts that, where you want to preserve flow.
Again, data on this is very limited as well. The (mumbles) a couple years ago they asked the audience what they like and clearly DRIL has become the most popular choice at 60%, but about 20% of people were still going to banding, and so my charge was to say when is banding
the right way to go. Again, it's effect is less predictable than DRIL. You definitely are going to slow the flows down, but remember with DRIL you are making the limb dependent on the patency of that graft which is always something of concern in somebody
who you have caused an ischemic hand in the first place, and again, the morbidity with the DRIL certainly more so than with the band. We looked at our results a few years back and we identified 31 patients who had steal. Most of these, they all had a physiologic test
confirming the diagnosis. All had some degree of pain or numbness. Only three of these patients had gangrene or ulcers. So, a relatively small cohort of limb, of advanced steal. Most of our patients were autogenous access,
so ciminos and brachycephalic fistula, but there was a little bit of everything mixed in there. The mean age was 66. 80% were diabetic. Patients had their access in for about four and a half months on average at the time of treatment,
although about almost 40% were treated within three weeks of access placement. This is how we do the banding. We basically expose the arterial anastomosis and apply wet clips trying to get a diameter that is less than the brachial artery.
It's got to be smaller than the brachial artery to do anything, and we monitor either pulse volume recordings of the digits or doppler flow at the palm or arch and basically apply these clips along the length and restricting more and more until we get
a satisfactory signal or waveform. Once we've accomplished that, we then are satisfied with the degree of narrowing, we then put some mattress sutures in because these clips will fall off, and fix it in place.
And basically this is the result you get. You go from a fistula that has no flow restriction to one that has restriction as seen there. What were our results? Well, at follow up that was about almost 16 months we found 29 of the 31 patients had improvement,
immediate improvement. The two failures, one was ligated about 12 days later and another one underwent a DRIL a few months later. We had four occlusions in these patients over one to 18 months. Two of these were salvaged with other procedures.
We only had two late recurrences of steal in these patients and one of these was, recurred when he was sent to a radiologist and underwent a balloon angioplasty of the banding. And we had no other morbidity. So this is really a very simple procedure.
So, this is how it compares with DRIL. Most of the pooled data shows that DRIL is effective in 90 plus percent of the patients. Patency also in the 80 to 90% range. The DRIL is better for late, or more often used in late patients,
and banding used more in earlier patients. There's a bigger blood pressure change with DRIL than with banding. So you definitely get more bang for the buck with that. Just quickly going through the literature again. Ellen Dillava's group has published on this.
DRIL definitely is more accepted. These patients have very high mortality. At two years 50% are going to be dead. So you have to keep in mind that when you're deciding what to do. So, I choose banding when there's no gangrene,
when there's moderate not severe pain, and in patients with high morbidity. As promised here's an algorithm that's a little complicated looking, but that's what we go by. Again, thanks very much.
- Thank you very much. I'm going to talk on Improper and Suboptimal Antiplatelet Therapy which is probably currently the standard on most carotid angioplasty stent trials and I'm going to show you how it could potentially affect all of the results we have seen so far. I have nothing to disclose.
So introduction, based on the composite end point of stroke/death in our technical trials, they're always, in all randomized trials Endarterectomy always did marginally better than Carotid angioplasty and stenting. However, a small shift, just about a one person shift
could make carotid artery stenting better could shift the results of all these carotid stent trials. Let's just look at CREST. I think it's the gold standard for randomized trial comparing endarterectomy with stenting. You can see the combined death, streak and MI rate.
For endarterectomy, it's 6.8%, for CAS, 7.2%. For stroke, again 2.3, 4.1. Again, it's a one person shift in a direction of making stents better could actually show that stents were favorable, but comparable to it, not just inferior.
Now if you look at the data on CREST, it's very interesting that the majority of the strokes, about 80% of the strokes happened after about 24 hours. In fact, most of them happened on the third day period. So it wasn't a technical issue. You know, the biggest issue with current stenting
that we find is that we have filters, we have floor reversal. They're very worried about the time we place the stent, that we balloon, pre- and post-, but it wasn't a technical issue. Something was happening after 24 hours.
Another interesting fact that no one speaks about is if you look at the CREST data a little bit in more detail, most of the mortality associated with the stenting was actually associated with an access site bleed.
So if you could really decrease the late strokes, if you can decrease the access site bleeds, I think stents can be performed better than endarterectomies. The study design for all stent trials, there was a mandatory dual antiplatelet therapy.
Almost all patients had to be on aspirin and Plavix and on CREST, interestingly, they had to be on 75 milligrams BID for Plavix so they were all on very high dose Plavix. Now here's the interesting thing about Plavix that most people don't know.
Plavix is what is called a pro-drug. It requires to be converted to its active component by the liver for antiplatelet effect. And the particular liver enzyme that converts Plavix to its active metabolic enzyme is very variable patient to patient
and you're born that way. You're either born where you can convert its active metabolite or you can't convert it to its active metabolite and a test that's called 2C19 is actually interesting approved and covered by Medicare and here's the people
that read the black box warning for Plavix, that looked at the package insert. I just cut and paste this on the package that said for Plavix. I'm just showing you a few lines from the package insert. Now next to aspirin, it's the commonest prescribed drug
by vascular specialists, but most people probably have not looked at the package insert that says effectiveness of Plavix depends on activation by a liver enzyme called 2C19 and goes on to say that tests are available to identify to 2C19 genotype.
And then they go on to actually give you a recommendation on the package insert that says consider alternative treatment strategies in patients identified as 2C19 poor metabolizers. Now these are the people who cannot metabolize Plavix and convert them to its active metabolite.
So let's look at the actual incidents. Now we know there is resistance to, in some patients, to aspirin, but the incident is so small it doesn't make worth our time or doesn't make it worth the patient's outcome to be able to test everyone for aspirin resistance,
but look at the incidents for Plavix resistance. Again, this is just a slide explaining what does resistance mean so if you're a normal metabolizer, which we hope that most of us would be, you're going to expect advocacy from Plavix at 75 milligrams once a day.
Other hand, let's say you're a rapid or ultrarapid metabolizer. You have a much higher risk of bleeding. And then if you go to the other side where you are normal, intermediate or poor metabolizer, you're not going to convert Plavix to its active metabolite
and poor metabolizers, it's like giving a placebo. And interestingly, I'm a poor metabolizer. I got myself tested. If I ever have a cardiac interventionalist give me Plavix, they're giving me a placebo. So let's look at the actual incidents
of all these subsets in patients and see whether that's going to be an issue. So we took this from about 7,000 patients and interestingly in only about 40%, NM stands for nominal metabolizer or normal metabolizers. So only 40% get the expected efficacy of Plavix.
Let's look at just the extremes. Let's just assume people with normal metabolizers, normal intermediate and the subgroup between the ultra rapid, the normals, they're all going to respond well to Plavix. Let's just look at the extremes.
Ultra rapid and poor metabolizers. So these are the people who are going to convert Plavix to a much higher concentration of its active metabolite, but have a much higher risk of bleeding. Ultra rapid metabolizers. Poor metabolizers, Plavix doesn't work.
4%, 3%. That's not a small incidence. Now in no way am I saying that carotid stent trials itselves are totally based on Plavix resistance, but just look at the data from CREST. Let's say the patients with poor metabolizers,
that's 3%, so these people did not get Plavix. Plavix does not affect you in doses of up to 600 milligram for people with poor metabolizers. Incidents of embolic events in CREST trial for carotid stents was 4%. This happened after three days.
I believe it's possibly related to platelet debris occurring in the stent on people who did not receive a liquid anti-platelet therapy. How about the people who had the groin bleed? Remember I told you that access site bleeds were most highly predictable mortality.
If you're the ultra rapid metabolizers, that incidence was 4%. So these were the people that convert Plavix with a very high dose of active metabolite, very high risk of bleeding. Access site bleed rate,
if you look at the major/minor rates, 4.1%, very close to the ultra rapid metabolizers. So fact remains that carotid angioplasty stenting post procedure events are highly dependent on appropriate antiplatelet therapy to minimize embolic events and to decrease groin bleeds.
So in conclusion, if we just included 2C19 normal metabolizers, as was recommended by the packaging insert, so just test the people, include the people on normal metabolizers, exclude the rest, we are probably going to shift the results in favor of carotid angioplasty and stenting.
Results of all carotid angioplasty stent trials need to be questioned as a significant number of patients in the carotid angioplasty stent arm did not receive appropriate antiplatelet therapy. Thank you very much.
- Thank you. We've all heard that hypogastric artery occlusion can be not so benign as Dr. Snyder mentioned. It's not advancing, there we go. There's the systematic meta-analysis of 61 papers and showing that when you have bilateral occlusion you actually can have worse symptoms
of claudication, even erectile dysfunction. There are these known commercially available devices but should we be doing bilateral cases? There's certainly increased complexity inherent in this and anatomic limitations and cost. We choose to look at a multicenter experience
of 24 centers, 47 patients. Here are the contributing contributors. When we published our experience these are the 47 patients using the GORE IBE device both in Europe and the United States with 6.5 month follow up. The aortic diameters, some of the characteristics.
You can see here that 23% had exclusive iliac aneurysm treatment in the absence of a AAA. Four had aneurysmal or ectatic internal iliac arteries. These are sometimes treated by coil embolizing the first branch and extending the internal branch into a first order branch, there you can see.
But anatomic limitations persist and you can see especially with lengths. You need quite a long length for that ipsilateral side with its device in order to do the bilateral case. These are the IFUs, 165 for the contra and 195 for the ipsi. In our experience you can see that actually 194 on the ipsi
and 195 is what we found as a mean. This seems prohibitive. Some of the tips and tricks to accommodate the shorter lengths are shown here. We can maximize overlap, and we can see that from 195 we can drop this
by maximizing the overlap to 175. We can certainly cross the limbs, that eats up some length. Intrinsic tortuosity can eat up the distance. We can see we can recreate the flow divider, bring up the flow divider higher, match the two limbs. That also can cut down the distance.
Finally in some of these patients we had shorter bridging stents, the endurant stent in particular is a little shorter instead of the 100 millimeter Gore limb and that can also shorten the distance. More about the procedural outcomes. You can see here great technical success.
There were no type one or type three endoleaks. There were some adjunctive stenting in some patients, four patients, because of some kinking and distal dissection. One technical failure's worth pointing out. This is a patient who has heavy calcification
in the iliac system here. Couldn't cannulate, the internal iliac artery required coil embolization. You can see this patient, we had to sacrifice that internal and extend into the external. Complications at 30 days are very acceptable.
One groin infection. You can see that radiographing clinical follow up. One patient with new buttock claudications, a patient who lost the internal iliac artery as I'll mention to you in a minute. The other one was asymptomatic
but also one internal iliac artery lost. No aneurysm related deaths. You can see there's some type two endoleaks but not type one or three endoleaks. More about limb occlusions. This is the external iliac limb.
You can see there were three external iliac limb occlusions, two in the perioperative period and one at six months which presented with claudication requiring a Fem-Fem. The two in the perioperative period, one was a thrombectomy and stent that was treated nicely. The other one was really an iatrogenic limb occlusion
because the internal branch was deployed inadvertently high jailing the external and causing the operators to have to go back and essentially sacrifice that internal in order to preserve flow to the external. You can see that this a patient who in fact did have the claudication symptoms, this is that one patient.
As far as internal iliac limb occlusion in addition to the one we just described there was one asymptomatic incidental find of a limb occlusion at six months. This is a comparison of what Dr. Snyder just discussed, the pivotal trial with expanded access to the global experience I just presented.
You can see when you look at fluoroscopy time, for instance, contrast media used or procedural duration that there is, of course, some increase requirement in the bilateral cases but I would argue that this is not prohibitive. Cost, however, may in fact be an issue.
Certainly this can be a quite costly procedure when we start doing bilateral cases. There are, in fact, new procedure codes that Gore has provided that can offset some of this cost especially for the hospital cost, but nonetheless this is something to be considered.
So in conclusion, preservation of bilateral internal iliac artery with a Gore IBE can be performed safely with excellent technical results and short term patency rates. Only one new onset of buttock claudication occurred in that inadvertent limb jailing. Limb and branch occlusions are rare but can be treated
successfully with stenting most of the time. Some anatomic limitations exist but a number of maneuvers can permit technical success even in shorter length aortoiliac segments. Contrast fluoroscopy and length of case do not appear to be prohibitive.
However, cost remains an issue. Thank you.
- Thank you very much again. Thank you very much for the kind invitation. The answer to the question is, yes or no. Well, basically when we're talking about pelvic reflux, we're talking really, about, possibly thinking about two separate entities. One symptoms relate to the pelvis
and issues with lower limb varicose veins. Really some time ago, we highlighted in a review, various symptoms that may be associated with the pelvic congestion syndrome. This is often, either misdiagnosed or undiagnosed. The patients we see have had multiple investigations
prior to treatment. I'm not really going to dwell on the anatomy but, just really highlight to you it is incompetence in either the renal pelvic and ovarian veins. What about the patterns of reflux we've heard from both Mark and Nicos what the pattern are
but, basically if you look a little more closely you can see that not only the left ovarian vein is probably effected in a round-about 60%. But, there is incompetence in many of the other veins. What does this actually have implication for with respect to treatment.
Implications are that you probably, if you only treat an isolated vein. There is a suggestion, that the long term outcomes are not actually as good. Now this is some work from Mark Whiteley's group because, we've heard about the diagnosis
but, there is some discussion as to whether just looking at ovarian vein diameter is efficient and certainly the Whiteley group suggests that actually diameter is relatively irrelevant in deciding as to whether there is incompetence in the actual vein itself.
That diameter should not be used as a single indicator. You may all well be aware, that there are reporting standards for the treatment of pelvic venous insufficiency and this has been high-lighted in this paper. What of the resuts, of pelvic embolization and coiling? The main standard is used, is a visual analog scale
when you're looking at pelvic symptoms to decide what the outcome may be. This is a very nice example of an article that was... A review that was done in Niel Khilnani's group and you can see if you look at the pre
and post procedural visual analog scales there is some significant improvement. You can see that this is out at one year in the whole. Now, this is a further table from the paper. Showing you their either, there's a mixture
of glue, coils, scleroses and foam. The comments are that, there are significant relief and some papers suggest its after 100% and others up to 80%. If you look at this very nice review that Mark Meissner did with Kathy Gibson,
you will see that actually no improvement in worse. There's quite a range there for those patients 53% of patients in one study, had no improvement or the symptoms were potentially worse. We know that those patients who have coil embolization will have reoccurrence of symptomatology
and incompetence up to about a quarter of the patients. What about varicose veins? The answer is there is undoubtedly evidence to suggest that there is physiological/anatomical incompetence in some of the pelvic veins in patients
who have recurrent varicose veins. Whether this is actually a direct cause or an association, I think it's something we need to have some further consideration of. As you know, there are many people who now would advicate actually treating
the pelvic veins prior to treating the leg veins. You can maybe discuss that in the question time. If we then look at a comparative trial. Comparing coils and plugs, you can see over all there really isn't no particular difference. If we then look again to highlight this,
which comes again from the Whiteley group. You can see that 20% of patients will have some primary incompetence but, it'll go up to around 30% if they are re-current. There is no randomized control data looking at this. What are the problems with coils?
Actually, a bit like (mumbling) you can find them anywhere. You can find them in the chest and also you can find that there are patients now who are allergic to nickel and the very bottom corner is a patient who's coils I took out by open laparotomy because they were allergic to nickel.
So, ladies and gentlemen I would suggest to you certainly, for continuing with pelvic embolization when doubtedly it needs some more RCT data and some much better registry data to look where we're going. Thank you very much.
- 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.
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