- Good afternoon to everybody, this is my disclosure. Now our center we have some experience on critical hand ischemia in the last 20 years. We have published some papers, but despite the treatment of everyday, of food ischemia including hand ischemia is not so common. We had a maximum of 200 critical ischemic patients
the majority of them were patient with hemodialysis, then other patients with Buerger's, thoracic outlet syndrome, etcetera. And especially on hemodialysis patients, we concentrate on forearms because we have collected 132 critical ischemic hands.
And essentially, we can divide the pathophysiology of this ischemic. Three causes, first is that the big artery disease of the humeral and below the elbow arteries. The second cause is the small artery disease
of the hand and finger artery. And the third cause is the presence of an arterial fistula. But you can see, that in active ipsillateral arteriovenous fistula was present only 42% of these patients. And the vast majority of the patients
who had critical hand ischemia, there were more concomitant causes to obtain critical hand ischemia. What can we do in these types of patients? First, angioplasty. I want to present you this 50 years old male
with diabetes type 1 on hemodialysis, with previous history of two failed arteriovenous fistula for hemodialysis. The first one was in occluded proximal termino-lateral radiocephalic arteriovenous fistula. So, the radial artery is occluded.
The second one was in the distal latero-terminal arteriovenous fistula, still open but not functioning for hemodialysis. Then, we have a cause of critical hand ischemia, which is the occlusion of the ulnar artery. What to do in a patient like this?
First of all, we have treated this long occlusion of the ulnar artery with drug-coated ballooning. The second was treatment of this field, but still open arteriovenous fistula, embolized with coils. And this is the final result,
you can see how blood flow is going in this huge superficial palmar arch with complete resolution of the ischemia. And the patient obviously healed. The second thing we can do, but on very rarely is a bypass. So, this a patient with multiple gangrene amputations.
So, he came to our cath lab with an indication to the amputation of the hand. The radial artery is totally occluded, it's occluded here, the ulnar artery is totally occluded. I tried to open the radial artery, but I understood that in the past someone has done
a termino-terminal radio-cephalic arteriovenous fistula. So after cutting, the two ends of the radial artery was separated. So, we decided to do a bypass, I think that is one of the shortest bypass in the world. Generally, I'm not a vascular surgeon
but generally vascular surgeons fight for the longest bypass and not for the shortest one. I don't know if there is some race somewhere. The patient was obviously able to heal completely. Thoracic sympathectomy. I have not considered this option in the past,
but this was a patient that was very important for me. 47 years old female, multiple myeloma with amyloidosis. Everything was occluded, I was never able to see a vessel in the fingers. The first time I made this angioplasty,
I was very happy because the patient was happy, no more pain. We were able to amputate this finger. Everything was open after three months. But in the subsequent year, the situation was traumatic. Every four or five months,
every artery was totally occluded. So, I repeated a lot of angioplasty, lot of amputations. At the end it was impossible to continue. After four years, I decided to do something, or an amputation at the end. We tried to do endoscopic thoracic sympathectomy.
There is a very few number of this, or little to regard in this type of approach. But infected, no more pain, healing. And after six years, the patient is still completely asymptomatic. Unbelievable.
And finally, the renal transplant. 36 years old female, type one diabetes, hemodialysis. It was in 2009, I was absolutely embarrassed that I tried to do something in the limbs, inferior limbs in the hand.
Everything was calcified. At the end, we continued with fingers amputation, a Chopart amputation on one side and below the knee major amputation. Despite this dramatic clinical stage, she got a double kidney and pancreas transplant on 2010.
And then, she healed completely. Today she is 45 years old, this summer walking in the mountain. She sent to me a message, "the new leg prostheses are formidable". She's driving a car, totally independent,
active life, working. So, the transplant was able to stop this calcification, this small artery disease which was devastating. So, patients with critical high ischemia have different pathophysiology and different underlying diseases.
Don't give up and try to find for everyone the proper solution. Thank you very much for your attention.
- Good morning. It's a pleasure to be here today. I'd really like to thank Dr. Veith, once again, for this opportunity. It's always an honor to be here. I have no disclosures. Heel ulceration is certainly challenging,
particularly when the patients have peripheral vascular disease. These patients suffer from significant morbidity and mortality and its real economic burden to society. The peripheral vascular disease patients
have fivefold and increased risk of ulceration, and diabetics in particular have neuropathy and microvascular disease, which sets them up as well for failure. There are many difficulties, particularly poor patient compliance
with offloading, malnutrition, and limitations of the bony coverage of that location. Here you can see the heel anatomy. The heel, in and of itself, while standing or with ambulation,
has tightly packed adipose compartments that provide shock absorption during gait initiation. There is some limitation to the blood supply since the lateral aspect of the heel is supplied by the perforating branches
of the peroneal artery, and the heel pad is supplied by the posterior tibial artery branches. The heel is intolerant of ischemia, particularly posteriorly. They lack subcutaneous tissue.
It's an end-arterial plexus, and they succumb to pressure, friction, and shear forces. Dorsal aspect of the posterior heel, you can see here, lacks abundant fat compartments. It's poorly vascularized,
and the skin is tightly bound to underlying deep fascia. When we see these patients, we need to asses whether or not the depth extends to bone. Doing the probe to bone test
using X-ray, CT, or MRI can be very helpful. If we see an abcess, it needs to be drained. Debride necrotic tissue. Use of broad spectrum antibiotics until you have an appropriate culture
and can narrow the spectrum is the way to go. Assess the degree of vascular disease with noninvasive testing, and once you know that you need to intervene, you can move forward with angiography. Revascularization is really operator dependent.
You can choose an endovascular or open route. The bottom line is the goal is inline flow to the foot. We prefer direct revascularization to the respective angiosome if possible, rather than indirect. Calcanectomy can be utilized,
and you can actually go by angiosome boundaries to determine your incisions. The surgical incision can include excision of the ulcer, a posterior or posteromedial approach, a hockey stick, or even a plantar based incision. This is an example of a posterior heel ulcer
that I recently managed with ulcer excision, flap development, partial calcanectomy, and use of bi-layered wound matrix, as well as wound VAC. After three weeks, then this patient underwent skin grafting,
and is in the route to heal. The challenge also is offloading these patients, whether you use a total contact cast or a knee roller or some other modality, even a wheelchair. A lot of times it's hard to get them to be compliant.
Optimizing nutrition is also critical, and use of adjunctive hyperbaric oxygen therapy has been shown to be effective in some cases. Bone and tendon coverage can be performed with bi-layered wound matrix. Use of other skin grafting,
bi-layered living cell therapy, or other adjuncts such as allograft amniotic membrane have been utilized and are very effective. There's some other modalities listed here that I won't go into. This is a case of an 81 year old
with osteomyelitis, peripheral vascular disease, and diabetes mellitus. You can see that the patient has multi-level occlusive disease, and the patient's toe brachial index is less than .1. Fortunately, I was able to revascularize this patient,
although an indirect revascularization route. His TBI improved to .61. He underwent a partial calcanectomy, application of a wound VAC. We applied bi-layer wound matrix, and then he had a skin graft,
and even when part of the skin graft sloughed, he underwent bi-layer living cell therapy, which helped heal this wound. He did very well. This is a 69 year old with renal failure, high risk patient, diabetes, neuropathy,
peripheral vascular disease. He was optimized medically, yet still failed to heal. He then underwent revascularization. It got infected. He required operative treatment,
partial calcanectomy, and partial closure. Over a number of months, he did finally heal. Resection of the Achilles tendon had also been required. Here you can see he's healed finally. Overall, function and mobility can be maintained,
and these patients can ambulate without much difficulty. In conclusion, managing this, ischemic ulcers are challenging. I've mentioned that there's marginal blood supply, difficulties with offloading, malnutrition, neuropathy, and arterial insufficiency.
I would advocate that partial or total calcanectomy is an option, with or without Achilles tendon resection, in the presence of osteomyelitis, and one needs to consider revascularization early on and consider a distal target, preferentially in the angiosome distribution
of the posterior tibial or peroneal vessels. Healing and walking can be maintained with resection of the Achilles tendon and partial resection of the os calcis. Thank you so much. (audience applauding)
- 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.
- Well, thank you Frank and Enrico for the privilege of the podium and it's the diehards here right now. (laughs) So my only disclosure, this is based on start up biotech company that we have formed and novel technology really it's just a year old
but I'm going to take you very briefly through history very quickly. Hippocrates in 420 B.C. described stroke for the first time as apoplexy, someone be struck down by violence. And if you look at the history of stroke,
and trying to advance here. Let me see if there's a keyboard. - [Woman] Wait, wait, wait, wait. - [Man] No, there's no keyboard. - [Woman] It has to be opposite you. - [Man] Left, left now.
- Yeah, thank you. Are we good? (laughs) So it's not until the 80s that really risk factors for stroke therapy were identified, particularly hypertension, blood pressure control,
and so on and so forth. And as we go, could you advance for me please? Thank you, it's not until the 90s that we know about the randomized carotid trials, and advance next slide please, really '96 the era of tPA that was
revolutionary for acute stroke therapy. In the early 2000s, stroke centers, like the one that we have in the South East Louisiana and New Orleans really help to coordinate specialists treating stroke. Next slide please.
In 2015, the very famous HERMES trial, the compilation of five trials for mechanical thrombectomy of intracranial middle and anterior cerebral described the patients that could benefit and we will go on into details, but the great benefit, the number needed to treat
was really five to get an effect. Next slide. This year, "wake up" strokes, the extension of the timeline was extended to 24 hours, increase in potentially the number of patients that could be treated with this technology.
Next please. And the question is really how can one preserve the penumbra further to treat the many many patients that are still not offered mechanical thrombectomy and even the ones that are, to get a much better outcome because not everyone
returns to a normal function. Next, so the future I think is going to be delivery of a potent neuroprotection strategy to the penumbra through the stroke to be able to preserve function and recover the penumbra from ongoing death.
Next slide. So that's really the history of stroke. Advance to the next please. Here what you can see, this is a patient of mine that came in with an acute carotid occlusion that we did an emergency carotid endarterectomy
with an neuro interventionalist after passage of aspiration catheter, you can see opening of the middle cerebral M1 and M2 branches. The difference now compared to five, eight, 10 years ago is that now we have catheters in the middle cerebral artery,
the anterior cerebral artery. After tPA and thrombectomy for the super-selective, delivery of a potent neuroprotective agent and by being able to deliver it super-selectively, bioavailability issues can be resolved, systemic side effects could be minimized.
Of course, it's important to remember that penumbra is really tissue at risk, that's progression towards infarction. And everybody is really different as to when this occurs. And it's truly all based on collaterals.
So "Time is brain" that we hear over and over again, at this meeting there were a lot of talks about "Time is brain" is really incorrect. It's really "Collaterals are brain" and the penumbra is really completely based on what God gives us when we're born, which is really
how good are the collaterals. So the question is how can the penumbra be preserved after further mechanical thrombectomy? And I think that the solution is going to be with potent neuroprotection delivery to the penumbra. These are two papers that we published in late 2017
in Nature, in science journals Scientific Reports and Science Advances by our group demonstrating a novel class of molecules that are potent neuroprotective molecules, and we will go into details, but we can discuss it if there's interest, but that's just one candidate.
Because after all, when we imaged the penumbra in acute stroke centers, again, it's all about collaterals and I'll give you an example. The top panel is a patient that comes in with a good collaterals, this is a M1 branch occlusion. In these three phases which are taken at
five second intervals, this patient is probably going to be offered therapy. The patients that come in with intermediate or poor collaterals may or may not receive therapy, or this patient may be a no-go. And you could think that if neuroprotection delivery
to the penumbra is able to be done, that these patients may be offered therapy which they currently are not. And even this patient that's offered therapy, might then leave with a moderate disability, may have a much better functional
independence upon discharge. When one queries active clinical trials, there's nothing on intra arterial delivery of a potent neuroprotection following thrombectomy. These are two trials, an IV infusion, peripheral infusion, and one on just verapamil to prevent vasospasm.
So there's a large large need for delivery of a potent neuroprotection following thrombectomy. In conclusion, we're in the door now where we can do mechanical thrombectomy for intracranial thrombus, obviously concomitant to what we do in the carotid bifurcation is rare,
but those patients do present. There's still a large number of patients that are still not actively treated, some estimate 50 to 60% with typical mechanical thrombectomy. And one can speculate how ideally delivery of a potent neuroprotection to this area could
help treat 50, 60% of patients that are being denied currently, and even those that are being treated could have a much better recovery. I'd like to thank you, Frank for the meeting, and to Jackie for the great organization.
- 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.
- 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.
- [Professor Veith] Laura, Welcome. - Thank you Professor Veith, thank you to everybody and good morning. It's a great pleasure, to have the possibility to present the result of this randomized trial we performed near Rome in Italy.
Risk of CAS-related embolism was maximal during the first phases of the second procedure, the filter positioning predilation and deployment and post dilatation. But it continues over time with nithinol expansion so that we have an interaction between the stent struts
and the plaque that can last up to 28 or 30 days that is the so called plaque healing period. This is why over time different technique and devices have been developed in order to keep to a minimum the rate of perioperative neurological embolization.
This is why we have, nowadays, membrane-covered stent or mesh-covered stent. But a question we have to answer, in our days are, "are mesh covered stents able to capture every kind of embolism?" Even the off-table one.
This is why they have been designed. That is to say the embolism that occurs after the patient has left the operating room. This is why we started this randomized trial with the aim of comparing the rate of off-table subclinical neurological events
in two groups of patients submitted to CAS with CGuard or WALLSTENT and distal embolic protection device in all of them. We enrolled patient affected by asymptomatic carotid stenosis more than 70% and no previous brain ischemic lesion
detected at preoperative DW-MRI. The primary outcome was the rate of perioperative up to 72 hour post peri operatively in neurological ischemic events detected by DW-MRI in the two CAS group. And secondary outcome measure were the rise of (mumbles)
neuro biomarker as one on the better protein in NSE and the variation in post procedural mini mental state examination test in MoCA test score We enrolled 29 patients for each treatment group. The study protocol was composed by a preoperative DW-MRI and neuro psychometrics test assessment
and the assessment of blood levels of this two neuro biomarkers. Then, after the CAS procedure, we performed an immediate postoperative DW-MRI, we collect this sample up to 48 hours post operatively to assess the level of the neuro biomarkers
then assess 72 hour postoperatively we perform a new DW-MRI and a new assessment of neuro psychometric tests. 58 patient were randomized 29 per group. And we found one minor stroke in the CGuard group together with eight clinically silent lesion detected at 72 hours DW-MRI.
Seven patient presented in WALLSTENT group silent 72 DW-MRI lesion were no difference between the two groups but interestingly two patients presented immediately postoperatively DW-MRI lesions. Those lesion were no more detectable at 72 hours
this give doubts to what we are going to see with DW-MRI. When analyzing the side of the lesion, we found four ipsilateral lesion in the CGuard patient and four contra or bilateral lesion in this group while four ipsilateral were encountered in WALLSTENT patient and three contra or bilateral lesion
in the WALLSTENT group were no difference between the two groups. And as for the diameter of the lesion, there were incomparable in the two groups but more than five lesion were found in five CGuard patients, three WALLSTENT patient
with no significant difference within the two groups. A rise doubled of S1 of the better protein was observed at 48 hours in 24 patients, 12 of them presenting new DW-MRI lesions. And this was statistically significant when comparing the 48 level with the bars of one.
When comparing results between the two groups for the tests, we found for pre and post for MMSE and MoCA test no significant difference even if WALLSTENT patients presented better MoCA test post operatively and no significant difference for the postoperative score for both the neuro psychometric test between the two groups.
But when splitting patients not according to the treatment group but according to the presence of more or less than 5 lesion at DW-MRI, we found a significant difference in the postoperative score for both MMSE and MoCA test between both group pf patients.
To conclude, WALLSTENT and CGuard stent showed that not significant differences in micro embolism rate or micro emboli number at 72 postoperative hours DW-MRI, in our experience. 72 hour DW-MMRI lesion were associated to an increase in neuro biomarkers
and more than five lesion were significantly associated to a decrease in neuro psychometric postoperative score in both stent groups. But a not negligible number of bilateral or contralateral lesions were detected in both stent groups This is very important.
This is why, probably, (mumbles) are right when they show us what really happened into the arch when we perform a transfer more CAS and this is why, maybe,
the future can be to completely avoid the arch. I thank you for your attention.
- These are my disclosures. So central venous access is frequently employed throughout the world for a variety of purposes. These catheters range anywhere between seven and 11 French sheaths. And it's recognized, even in the best case scenario, that there are iatrogenic arterial injuries
that can occur, ranging between three to 5%. And even a smaller proportion of patients will present after complications from access with either a pseudoaneurysm, fistula formation, dissection, or distal embolization. In thinking about these, as you see these as consultations
on your service, our thoughts are to think about it in four primary things. Number one is the anatomic location, and I think imaging is very helpful. This is a vas cath in the carotid artery. The second is th
how long the device has been dwelling in the carotid or the subclavian circulation. Assessment for thrombus around the catheter, and then obviously the size of the hole and the size of the catheter.
Several years ago we undertook a retrospective review and looked at this, and we looked at all carotid, subclavian, and innominate iatrogenic injuries, and we excluded all the injuries that were treated, that were manifest early and treated with just manual compression.
It's a small cohort of patients, we had 12 cases. Eight were treated with a variety of endovascular techniques and four were treated with open surgery. So, to illustrate our approach, I thought what I would do is just show you four cases on how we treated some of these types of problems.
The first one is a 75 year-old gentleman who's three days status post a coronary bypass graft with a LIMA graft to his LAD. He had a cordis catheter in his chest on the left side, which was discovered to be in the left subclavian artery as opposed to the vein.
So this nine French sheath, this is the imaging showing where the entry site is, just underneath the clavicle. You can see the vertebral and the IMA are both patent. And this is an angiogram from a catheter with which was placed in the femoral artery at the time that we were going to take care of this
with a four French catheter. For this case, we had duel access, so we had access from the groin with a sheath and a wire in place in case we needed to treat this from below. Then from above, we rewired the cordis catheter,
placed a suture-mediated closure device, sutured it down, left the wire in place, and shot this angiogram, which you can see very clearly has now taken care of the bleeding site. There's some pinching here after the wire was removed,
this abated without any difficulty. Second case is a 26 year-old woman with a diagnosis of vascular EDS. She presented to the operating room for a small bowel obstruction. Anesthesia has tried to attempt to put a central venous
catheter access in there. There unfortunately was an injury to the right subclavian vein. After she recovered from her operation, on cross sectional imaging you can see that she has this large pseudoaneurysm
coming from the subclavian artery on this axial cut and also on the sagittal view. Because she's a vascular EDS patient, we did this open brachial approach. We placed a stent graft across the area of injury to exclude the aneurism.
And you can see that there's still some filling in this region here. And it appeared to be coming from the internal mammary artery. We gave her a few days, it still was patent. Cross-sectional imaging confirmed this,
and so this was eventually treated with thoracoscopic clipping and resolved flow into the aneurism. The next case is a little bit more complicated. This is an 80 year-old woman with polycythemia vera who had a plasmapheresis catheter,
nine French sheath placed on the left subclavian artery which was diagnosed five days post procedure when she presented with a posterior circulation stroke. As you can see on the imaging, her vertebral's open, her mammary's open, she has this catheter in the significant clot
in this region. To manage this, again, we did duel access. So right femoral approach, left brachial approach. We placed the filter element in the vertebral artery. Balloon occlusion of the subclavian, and then a stent graft coverage of the area
and took the plasmapheresis catheter out and then suction embolectomy. And then the last case is a 47 year-old woman who had an attempted right subclavian vein access and it was known that she had a pulsatile mass in the supraclavicular fossa.
Was noted to have a 3cm subclavian artery pseudoaneurysm. Very broad base, short neck, and we elected to treat this with open surgical technique. So I think as you see these consults, the things to factor in to your management decision are: number one, the location.
Number two, the complication of whether it's thrombus, pseudoaneurysm, or fistula. It's very important to identify whether there is pericatheter thrombus. There's a variety of techniques available for treatment, ranging from manual compression,
endovascular techniques, and open repair. I think the primary point here is the prevention with ultrasound guidance is very important when placing these catheters. Thank you. (clapping)
- Thank you 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.
- 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.
- 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.
- I'd like to thank Dr. Veith and the committee for the privilege of presenting this. I have no disclosures. Vascular problems and the type of injuries could be varied. We all need to have an awareness of acute and chronic injuries,
whether they're traumatic, resulting with compression, occlusion, tumoral and malformation results, or vasospastic. I'd like to present a thoracoscopic manipulation of fractured ribs to prevent descending aortic injury
in a patient with chest trauma. You know, we don't think about this but they can have acute or delayed onset of symptoms and the patient can change and suddenly deteriorate with position changes or with mechanical ventilation,
and this is a rather interesting paper. Here you can see the posterior rib fracture sitting directly adjacent to the aorta like a knife. You can imagine the catastrophic consequences if that wasn't recognized and treated appropriately.
We heard this morning in the venous session that the veins change positions based on the arteries. Well, we need to remember that the arteries and the whole vascular bundle changes position based on the spine
and the bony pieces around them. This is especially too when you're dealing with scoliosis and scoliotic operations and the body positioning whether it's supine or prone the degree of hypo or hyperkyphosis
and the vertebral angles and the methods of instrumentation all need to be considered and remembered as the aorta will migrate based on the body habits of the patient. Screws can cause all kinds of trouble.
Screws are considered risky if they're within one to three millimeters of the aorta or adjacent tissues, and if you just do a random review up to 15% of screws that are placed fall into this category.
Vertebral loops and tortuosity is either a congenital or acquired anomaly and the V2 segment of the vertebral is particularly at risk, most commonly in women in their fifth and sixth decades,
and here you can see instrumentation of the upper cervical spine, anterior corpectomy and the posterior exposures are all associated with a significant and lethal, at times, vertebral artery injuries.
Left subclavian artery injury from excessively long thoracic pedicle screws placed for proximal thoracic scoliosis have been reported. Clavicular osteosynthesis with high neurovascular injury especially when the plunge depth isn't kept in mind
in the medial clavicle have been reported and an awareness and an ability to anticipate injury by looking at the safe zone and finding this on the femur
with your preoperative imaging is a way to help prevent those kinds of problems. Injuries can be from stretch or retraction. Leave it to the French. There's a paper from 2011 that describes midline anterior approach
from the right side to the lumbar spine, interbody fusion and total disc replacement as safer. The cava is more resistant to injury than the left iliac vein and there's less erectile dysfunction reported. We had a patient present recently
with the blue bumps across her abdomen many years after hip complicated course. She'd had what was thought to be an infected hip that was replaced, worsening lower extremity edema, asymmetry of her femoral vein on duplex
and her heterogeneous mask that you can see here on imaging. The iliac veins were occluded and compressed and you could see in the bottom right the varicosities that she was concerned about. Another case is a 71-year-old male who had a post-thrombotic syndrome.
It was worsened after his left hip replacement and his wife said he's just not been the same since. Initially imaging suggests that this was a mass and a tumor. He underwent biopsy
and it showed ghost cells. Here you can see the venogram where we tried to recanalize this and we were unsuccessful because this was actually a combination of bone cement and inflammatory reaction.
Second patient in this category, bless you, is a 67-year-old female who had left leg swelling again after a total hip replacement 20 plus years ago. No DVTs but here you can see the cement compressing the iliac vein.
She had about a 40% patency when you put her through positioning and elected not to have anything done with that. Here you could see on MR how truly compressed this is. IVA suggested it was a little less tight than that.
So a vascular injury occurs across all surgical specialties. All procedures carry risk of bleeding and inadvertent damage to vessels. The mechanisms include tearing, stretching, fracture of calcific plaques,
direct penetration and thermal injury. The types of injuries you hear are most common after hip injuries, they need to be recognized in the acute phase as looking for signs of bleeding or ischemia. Arterial lesions are commonly prone then.
Bone cement can cause thermal injury, erosion, compression and post-implant syndrome. So again, no surgery is immune. You need to be aware and especially when you look at patients in the delayed time period
to consider something called particle disease. This has actually been described in the orthopedic literature starting in the 70s and it's a complex interaction of inflammatory pathways directed at microparticles that come about
through prosthetic wear. So not only acute injury but acute and chronic symptoms. Thank you for the privilege of the floor.
- Now we are delighted that there's apparently two things that we came up with years ago proved useful. This is the Near-Infrared Spectroscopy slide by Joe Bavaria from UPENN providing patient data on delayed paraplegia. That's a problem that we see in open NN (mumbles) very frequently.
How does the NIRS work? And again to this illustrative picture and now imagine the spinal cord sitting here in the spine canal and there's no more blood flow and this is the end result. When you know the oxygenation in the collateral network
and there was the problem with this technology that had been attempted 12 years back already, in Houston, I bet they put the NIRS optodes in the midline and the light cannot penetrate bone so it didn't work. But if you put it on the collateral network
and you measure the oxygen in this area, you obviously know it in the spinal canal. Dorsal view, again, so this is position of the optodes and this is oxygen content way interested in it. This is another cast just to illustrate
how these segmentals are regionally connected into the spinal canal, obviously. Experimental validation and pilot series in the next two minutes. Experimental cross clamping, this is the setup so years mentoring Laser Doppler Flow
to a real time evaluation of what you measure with your infrared setup in the animal lab and we see here, correlation is very nice between the lumbar NIRS, optodes, and the actual lumbar spinal cord oxygenation measured by Laser Doppler which is evaluated
with other techniques. Very nice to see the corelation between the two. So lumbar collateral network NIRS directly reflects spinal cord tissue oxygenation. After we have proven that step, next step was serial segmental artery occlusion.
As this is a technology that we or the strategy that we using, obviously want to know with our monitoring works for that. You see here, experimental setup basically the same. Starts with anesthesia, exposure of the segmentals. Now an open approach
and then you get 120 minutes surveillance period. You got a drop or dip in the NIRS measurements. Interestingly in the experimental setup in the recovery group, you see here that the new logical function comes back after the procedure and the NIRS comes back after the procedure.
Paraplegic group, all segmentals sacrificed NIRS, drops after the procedure in the first couple days, and the neurologic function does not recover. So experimental evidence that actually works. Nice corelation, again, so the experimental validation proves that lumbar NIRS
reflects lumbar spinal cord oxygenation and reacts to occlusion, of segmental arteries in real-time, but careful it's only regional so where ever you put your optodes, this is the area where you can monitor
your collateral network associated dip when you coil or include the segmental arteries. First clinical results published a couple years ago, I think you have all seen this video. Optodes are putting in the back of the patient, same setup for endo and open
and then we take the monitors theory and we have real-time monitoring on oversights midline here, this is (mumbles). Concept validation from 2016 with the first clinical data and now we're working on the clinical evaluation
of the use of this technology in EVAR and in clinical coil-embolization. 11 patients have been included so far for the EVAR group and you see here, it is very sensitive when you put stent in, stent deployment, but we have to still work so to speak
on the area that we have to monitor. There's a lot of work to do and probably also device modifications are necessary. MISACE, last couple words, on this you see pretty stable, NIRS all over the time course and actually this is nothing we wouldn't have expected
because the patient obviously were protected from spine cord anesthesia. So also here but sometimes we see a significant drop and this is when you should be careful and that's when you usually stop the procedure. So in conclusion, minor changes
in Collateral Network oxygenation have been seen in EVAR in this preliminary results using the nearest technology and to establish one very nice ... Nicely how clinical practice is already guided at his institution.
There's no immediate complete occlusion of covered segmental arteries and there's ongoing study in very heterogeneous patient group. There's no relevant changes with the chlorine technology so far,
but that, just to remind you, is the purpose of this technology, that we do not harm the patient during the preparation period. Thank you very much for your attention.
- Thank you Dr. Albaramum, it's a real pleasure to be here and I thank you for being here this early. I have no disclosures. So when everything else fails, we need to convert to open surgery, most of the times this leads to partial endograft removal,
complete removal clearly for infection, and then proximal control and distal control, which is typical in vascular surgery. Here's a 73 year old patient who two years after EVAR had an aneurism growth with what was thought
to be a type II endoleak, had coiling of the infermius mesenteric artery, but the aneurism continued to grow. So he was converted and what we find here is a type III endoleak from sutures in the endograft.
So, this patient had explantations, so it is my preference to have the nordic control with an endovascular technique through the graft where the graft gets punctured and then we put a 16 French Sheath, then we can put a aortic balloon.
And this avoids having to dissect the suprarenal aorta, particularly in devices that have super renal fixation. You can use a fogarty balloon or you can use the pruitt ballon, the advantage of the pruitt balloon is that it's over the wire.
So here's where we removed the device and in spite of the fact that we tried to collapse the super renal stent, you end up with an aortic endarterectomy and a renal endarterectomy which is not a desirable situation.
So, in this instance, it's not what we intend to do is we cut the super renal stent with wire cutters and then removed the struts individually. Here's the completion and preservation of iliac limbs, it's pretty much the norm in all of these cases,
unless they have, they're not well incorporated, it's a lot easier. It's not easy to control these iliac arteries from the inflammatory process that follows the placement of the endograft.
So here's another case where we think we're dealing with a type II endoleak, we do whatever it does for a type II endoleak and you can see here this is a pretty significant endoleak with enlargement of the aneurism.
So this patient gets converted and what's interesting is again, you see a suture hole, and in this case what we did is we just closed the suture hole, 'cause in my mind,
it would be simple to try and realign that graft if the endoleak persisted or recurred, as opposed to trying to remove the entire device. Here's the follow up on that patient, and this patient has remained without an endoleak, and the aneurism we resected
part of the sack, and the aneurism has remained collapsed. So here's another patient who's four years status post EVAR, two years after IMA coiling and what's interesting is when you do delayed,
because the aneurism sacks started to increase, we did delayed use and you see this blush here, and in this cases we know before converting the patient we would reline the graft thinking, that if it's a type III endoleak we can resolve it that way
otherwise then the patient would need conversion. So, how do we avoid the proximal aortic endarterectomy? We'll leave part of the proximal portion of the graft, you can transect the graft. A lot of these grafts can be clamped together with the aorta
and then you do a single anastomosis incorporating the graft and the aorta for the proximal anastomosis. Now here's a patient, 87 years old, had an EVAR,
the aneurism grew from 6 cm to 8.8 cm, he had coil embolization, translumbar injection of glue, we re-lined the endograft and the aneurism kept enlarging. So basically what we find here is a very large type II endoleak,
we actually just clip the vessel and then resected the sack and closed it, did not remove the device. So sometimes you can just preserve the entire device and just take care of the endoleak. Now when we have infection,
then we have to remove the entire device, and one alternative is to use extra-anatomic revascularization. Our preference however is to use cryo-preserved homograft with wide debridement of the infected area. These grafts are relatively easy to remove,
'cause they're not incorporated. On the proximal side you can see that there's a aortic clamp ready to go here, and then we're going to slide it out while we clamp the graft immediately, clamp the aorta immediately after removal.
And here's the reconstruction. Excuse me. For an endograft-duodenal fistula here's a patient that has typical findings, then on endoscopy you can see a little bit of the endograft, and then on an opergy I series
you actually see extravasation from the duodenal. In this case we have the aorta ready to be clamped, you can see the umbilical tape here, and then take down the fistula, and then once the fistula's down
you got to repair the duodenal with an omental patch, and then a cryopreserved reconstruction. Here's a TEVAR conversion, a patient with a contained ruptured mycotic aneurysm, we put an endovascular graft initially, Now in this patient we do the soraconomy
and the other thing we do is, we do circulatory support. I prefer to use ECMO, in this instances we put a very long canula into the right atrium, which you're anesthesiologist can confirm
with transassof forgeoligico. And then we use ECMO for circulatory support. The other thing we're doing now is we're putting antibiotic beads, with specific antibiotic's for the organism that has been cultured.
Here's another case where a very long endograft was removed and in this case, we put the device offline, away from the infected field and then we filled the field with antibiotic beads. So we've done 47 conversions,
12 of them were acute, 35 were chronic, and what's important is the mortality for acute conversion is significant. And at this point the, we avoid acute conversions,
most of those were in the early experience. Thank you.
- 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 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.
- Relevant disclosures are shown in this slide. So when we treat patients with Multi-Segment Disease, the more segments that are involved, the more complex the outcomes that we should expect, with regards to the patient comorbidities and the complexity of the operation. And this is made even more complex
when we add aortic dissection to the patient population. We know that a large proportion of patients who undergo Thoracic Endovascular Aortic Repair, require planned coverage of the left subclavian artery. And this also been demonstrated that it's an increase risk for stroke, spinal cord ischemia and other complications.
What are the options when we have to cover the left subclavian artery? Well we can just cover the artery, we no that. That's commonly performed in emergency situations. The current standard is to bypass or transpose the artery. Or provide a totally endovascular revascularization option
with some off-label use , such as In Situ or In Vitro Fenestration, Parallel Grafting or hopefully soon we will see and will have available branched graft devices. These devices are currently investigational and the focus today's talk will be this one,
the Valiant Mona Lisa Stent Graft System. Currently the main body device is available in diameters between thirty and forty-six millimeters and they are all fifteen centimeters long. The device is designed with flexible cuff, which mimics what we call the "volcano" on the main body.
It's a pivotal connection. And it's a two wire pre-loaded system with a main system wire and a wire through the left subclavian artery branch. And this has predominately been delivered with a through and through wire of
that left subclavian branch. The system is based on the valiant device with tip capture. The left subclavian artery branch is also unique to this system. It's a nitinol helical stent, with polyester fabric. It has a proximal flare,
which allows fixation in that volcano cone. Comes in three diameters and they're all the same length, forty millimeters, with a fifteen french profile. The delivery system, which is delivered from the groin, same access point as the main body device. We did complete the early feasibility study
with nine subjects at three sites. The goals were to validate the procedure, assess safety, and collect imaging data. We did publish that a couple of years ago. Here's a case demonstration. This was a sixty-nine year old female
with a descending thoracic aneurysm at five and a half centimeters. The patient's anatomy met the criteria. We selected a thirty-four millimeter diameter device, with a twelve millimeter branch. And we chose to extend this repair down to the celiac artery
in this patient. The pre-operative CT scan looks like this. The aneurysm looks bigger with thrombus in it of course, but that was the device we got around the corner of that arch to get our seal. Access is obtained both from the groin
and from the arm as is common with many TEVAR procedures. Here we have the device up in the aorta. There's our access from the arm. We had a separate puncture for a "pigtail". Once the device is in position, we "snare" the wire, we confirm that we don't have
any "wire wrap". You can see we went into a areal position to doubly confirm that. And then the device is expanded, and as it's on sheath, it does creep forward a bit. And we have capture with that through and through wire
and tension on that through and through wire, while we expand the rest of the device. And you can see that the volcano is aligned right underneath the left subclavian artery. There's markers there where there's two rings, the outer and the inner ring of that volcano.
Once the device is deployed with that through and through wire access, we deliver the branch into the left subclavian artery. This is a slow deployment, so that we align the flair within the volcano and that volcano is flexible. In some patients, it sort of sits right at the level of
the aorta, like you see in this patient. Sometimes it protrudes. It doesn't really matter, as long as the two things are mated together. There is some flexibility built in the system. In this particular patient,
we had a little leak, so we were able to balloon this as we would any others. For a TEVAR, we just balloon both devices at the same time. Completion Angiogram shown here and we had an excellent result with this patient at six months and at a year the aneurysm continued
to re-sorb. In that series, we had successful delivery and deployment of all the devices. The duration of the procedure has improved with time. Several of these patients required an extension. We are in the feasibility phase.
We've added additional centers and we continue to enroll patients. And one of the things that we've learned is that details about the association between branches and the disease are critical. And patient selection is critical.
And we will continue to complete enrollment for the feasibility and hopefully we will see the pivotal studies start soon. Thank you very much
- So in terms of overcoming difficult access, when we're doing parallel grafting, and we're going to use more than one branch or parallel graft, typically we come in from the axillary artery. It gives good pushability, it decreases the length for what you need to get from you access point
down to the branch vessels. We find that no conduit is needed. We typically just access this in three offset manners. We'll put a purse string in at each site, so that there's limited bleeding. When you come in, you have to think about
what the aortic arch construct looks like. You can have a type one, a type two or type three arch, which can make things more difficult. As you can see here, this sheath takes quite a significant bend to get down to the renal visceral segment.
You also can have tortuosity within the thoracic aorta, which can compromise your ability to cannulate. So when we think about the arch, you want to think about coming in from the right or left, which ever one makes it better. Typically, if all things are equal,
we'll come in from the left side. When you get your sheaths down one at a time, we leave the stiff wire in to try to straighten out the anatomy. Sometimes you have to snare and get through and through access.
And then you want to think about where your sheaths position is. You want it to be high enough so that you can allow your catheters to form, but also low enough so that you can reach the vessel of interest.
There are a couple of things, I think from a pre-planning perspective that are very important to try to set up, to allow yourself the optimal chance of cannulating these vessels. Appropriate C-arm projections, you want to think about
whether or not your going to use a cephalad or caudad parallel graft. Think about the tortuosity as well as the composition of the branch. What type of stent are you going to use in that? How much purchase is needed?
How much purchase can you get? And, How difficult is it going to be to cannulate these vessels? And also whether or not there's orifice stenosis. So, here's an example of a patient we did. You can see that left renal artery
is actually quite anterior. If you look at the AP view here, you can see how it would be quite difficult to cannulate, 'cause the orifice basically runs into the aneurysm in the AP view, if you just move your II to a 30 degree RAO,
then it becomes very perpendicular and very easy to cannulate and see. This is a situation where you think about periscoping or caudad parallel graft. It's much easier coming from below, it's an upwards approaching renal artery.
Coming from above, you can see it can bow out towards that large aneurysm and also potentially reflux down into infra-renal segment. This is a patient with a very short branch of main renal artery, and you can see if you just put
a typical self expanding stent, there's a higher chance that this thing's just going to pull out into the aneurysm, and what we did here is, we put a balloon mounted stent, followed by a self expanding stent
to lengthen afterwards and it worked out really nicely. And this is just the patient that has significant orifice stenosis and these patients will be hard to cannulate. Sometimes you have to pre dilate before you introduce your stents into the vessels.
You also want to think about the aorta and what configuration of the aorta is. What's the tortuosity, the calcification. Are you in a situation where you're trying to cannulate within the aneurysm and how much thrombus is there as well.
So, you can see here in the first picture, the aorta's somewhat tortuous, and going after that left renal artery probably would be easier, but going after that right renal artery becomes potentially difficult
as the catheters and sheaths are going to be pushing you away, and may make that more challenging. You may want to think about things, and certainly catheters selection before approaching. And definitely, any time you have an aneurysm
and your in a big space without a lot of thrombus, that makes things a little more difficult, 'cause you're flopping around in a large open space trying to cannulate a vessel. When you're accessing the vessel sometimes from above, what will happen is the tendency is
for the catheters and the wires, to reflux down into that infrarenal space. This is a no not well known trick, where you put a coda balloon and you can have your wires and catheters bounce off of that coda balloon
to help you navigate into that branch vessel. Sometimes that doesn't work, and it still continues to reflux, and what we've done more recently is, we'll come in from below, put a four millimeter balloon
in the distal renal artery, and then we'll pin our soft wire, be able to do a catheter exchange, exchange for our stiff wire, and ultimately, there's the catheter, ultimately in the stiff wire.
And then ultimately bring in your stent graft, all with that balloon still in place to hold and pin that wire in position, and allow things to track over that wire, rather than reflux down. Just some general thoughts, again,
thinking about the appropriate catheters, what length catheter do you need, what kind of angulation do you need, stiff versus angle glide wires. We typically use Rosen and Amplatz wires for our stiff wires to track our stents in.
And then different platforms, depending upon what your anatomy ultimately looks like. So in conclusion, a lot of pre-planning is important, I think to optimize your accessing of these vessels. And there's a lot of techniques and technology, that currently exist to help assist with this.
- You already heard about different devices which can finish the treatment of acute DVT in the lab and I would like to add one of the devices which is quite widespread in Europe. And share the first study on this device. This is called the Aspirex device. So what is the objective?
Post traumatic syndrome after proximal DVT, I think that's clear. 25% of the patient are at risk for developing post traumatic syndrome. I think that is clear and some of these patient even expect severe post traumatic syndrome.
We already saw this ATTRACT trial outcome and we learned that especially patient with Iliofemoral DVT might benefit from treatment, invasive treatment of Iliofemoral DVT but of course, we need to know that is catheter-directed thrombolysis causes issues
and therefore our way should be to go away from thrombolytic therapy to a pure mechanical thrombectomy approach. This is a typical case example of a patient, 20 year old female patient who came to the emergency room with that leg on the left side in the morning,
back pain in the evening and this is clear that it is a descending Iliofemoral DVT in that patient caused by May-Thurner syndrome. So, with modern devices like this Aspirex, mechanical thrombectomy device, the 10 French device is able to aspirate up to 130 millimeter,
ml per minute of clots. You see that this can be effectively treated and then stinted within the May-Thurner syndrome within one session approach. So, but, what is clear of course that we need to get data
for these modern Mechanical Thrombectomy devices and therefore, we conducted clinical follow-up study to evaluate safety and efficiency of that Aspirex Mechanical Thrombectomy device. This device is based on the Archimedic principle which you can see here it comes with six up
to 10 French systems and with that you are able, as I already showed to sac 130ml of thrombus per minute. So these are the study details I want to show you. We treated 50 psychs, 56 patients with acute, subacute and acute on chronic which means up to 3 months of symptoms patients with Iliofermal DVT.
We performed IVIS on all these patients. We found May-Thurner syndrome in at least half of these patients as a reason for the Iliofermal DVT. You see the patient demographics. Some of the patients had even malignancy condition. A lot of patients were on oral contraceptives.
Here are the clinical symptoms within our cohort. Most of the patients came with swelling and rest pain. The rVCSS at the beginning was 4.5 within this cohort. Most of the traumatic lesions were on the left side involving even the profunda and the common femoral vein in this cohort.
You see here the excess which we used for treating these Iliofermal DVT, we used in the main part of the cohort, the left popliteal vein access or left femoral vein access. 84% were treated with 10 French system, the Aspirex device. As I mentioned we used IVIS
to analyze underlying pathologies. We found in most of the patients underlying pathologies and this explains why we implanted stents in 100% of the patients. You see the treatment duration which was in mean 94 minutes within this treatment cohort.
These are the patency analysis within one year. You see patency at 12 months, 87% percent in these patients, which we could follow up after 12 months. Here you see the Post-thrombotic syndrome analysis after 12 months so only low PTS
and some kind of moderate PTS were seen in these patients. There were no severe Post-thrombotic syndrome. Most of the patients just had a little bit of swelling after that procedure. Of course, it's important to mention safety and those end points.
There were just some small punctures associated, site being complicationS. Of course re-hospitalization is a severe adverse event which you can see here. But there were of course no bleeding events in this cohort. And to follow up
on this much more multicentric perspective trial, we just started a multicenter trial on this and we'll follow up patients up to five years within this just initiated multicenter registry. And I think we can show some preliminary data next year. Thank you very much.
- Thank you very much for the kind introduction, and I'd like to thank the organizers, especially Frank Veith for getting back to this outstanding and very important conference. My duty is now to talk about the acute status of carotid artery stenting is acute occlusion an issue? Here are my disclosures.
Probably you might be aware, for sure you're aware about pore size and probably smaller pore size, the small material load might be a predisposing factor for enhanced thrombogenicity in these dual layer stents, as you're probably quite familiar with the CGUARD, Roadsaver and GORE, I will focus my talk a little bit
on the Roadsaver stent, since I have the most experience with the Roadsaver stent from the early beginning when this device was on the market in Europe. If you go back a little bit and look at the early publications of CGUARD, Roadsaver and GORE stent, then acute occlusion the early reports show that
very clearly safety, especially at 30 days in terms of major cardiac and cerebrovascular events. They are very, very safe, 0% in all these early publications deal with these stents. But you're probably aware of this publication, released end of last year, where a German group in Hamburg
deals with carotid artery stenosis during acute stroke treatment. They used the dual layer stent, the Roadsaver stent or the Casper stent in 20 cases, in the same time period from 2011 to 2016, they used also the Wallstent and the VIVEXX stent,
in 27 cases in total and there was a major difference, in terms of acute stent occlusion, and for the Roadsaver or Casper stent, it was 45%, they also had an explanation for that, potential explanations probably due to the increase of thrombogenic material due to the dual layer
insufficient preparation with antiplatelet medication, higher patient counts in the patients who occluded, smaller stent diameters, and the patients were not administered PTA, meaning Bridging during acute stroke patient treatment, but it was highlighted that all patients received ASA of 500mg intravenously
during the procedure. But there are some questions coming up. What is a small stent diameter? Post-dilatation at what diameter, once the stent was implanted? What about wall apposition of the stent?
Correct stent deployment with the Vicis maneuver performed or not and was the ACT adjusted during the procedure, meaning did they perform an adequate heparinization? These are open questions and I would like to share our experience from Flensburg,
so we have treated nearly 200 patients with the Roadsaver stent from 2015 until now. In 42 patients, we used this stent exclusively for acute stroke treatment and never, ever observed in both groups, in the symptomatic and asymptomatic group and in the group of acute stroke treatment,
we never observed an acute occlusion. How can we explain this kind of difference that neither acute occlusion occurred in our patient group? Probably there are some options how we can avoid stent thrombosis, how we can minimize this. For emergency treatment, probably this might be related
to bridging therapies, though in Germany a lot of patients who received acute stroke treatment are on bridging therapy since the way to the hospital is sometimes rather long, there probably might be a predisposing factor to re-avoid stent thrombosis and so-called tandem lesions if the stent placement is needed.
But we also take care of antiplatelet medication peri-procedurally, and we do this with ASA, as the Hamburg group did and at one day, we always start, in all emergency patients with clopidogrel loading dose after positive CT where we could exclude any bleeding and post-procedurally we go
for dual anti-platelet therapy for at least six months, meaning clopidogrel and ASA, and this is something probably of utmost importance. It's quite the same for elective patients, I think you're quite familiar with this, and I want to highlight the post-procedural clopidogrel
might be the key of success for six months combined with ASA life-long. Stent preparation is also an issue, at least 7 or 8 diameters we have to choose for the correct lengths we have to perform adequate stent deployment and adequate post-dilatation
for at least 5mm. In a lot of trials the Roadsaver concept has been proven, and this is due to the adequate preparation of the stent and ongoing platelet preparation, and this was also highlight in the meta-analysis with the death and stroke rate of .02% in all cases.
Roadsaver study is performed now planned, I am a member of the steering committee. In 2000 patients, so far 132 patients have been included and I want to rise up once again the question, is acute occlusion and issue? No, I don't think so, since you keep antiplatelet medication
in mind and be aware of adequate stent sizing. I highly appreciated your attention, thank you very much.
- Thank you, I've changed the title little bit, instead changes in AA neck morphology after standard EVAR and CHEVAS and they can be subtle and missed. And I'm a co-founder of endovascular diagnostics and my background of my slides is black because yesterday, Teo Fleugus passed away. Teo has served the endovascular fields
for more than two decades and Teo is an iconic and humorous Dutch giant and it's always been a pleasure and honor to work with him. The background of this presentation, slight changes in apposition and position of endograft in aortic neck can be missed
with standard imaging techniques like CT scans and duplex and the follow up imaging nowadays should prevent and should predict complications and not only show complications. That's why we, well we developed software, homemade software for precise determination
of the endograft position and apposition in the aortic neck post EVAR. And it serves, we transport the mesh of the aorta from a standard CT scan and use the 3D coordinates of a 3Mensio workstation and we definitely are able to calculate
and determine almost all the positional changes of the endograft in the neck post EVAR and also calculate the apposition of the endograft in the aortic neck. Well here, you can see some of the changes. The yellow bar is the apposition,
the circumferential apposition of the endograft in the aortic neck and during follow up, you can see that there is a loss of apposition, and of course, you want to avoid there is a complete loss in the patient coming with a type 1A endoleak and a rupture.
But to prove the concept of course, we had to prove that the software could really predict endografts' failure like migration and type 1A endoleak, so we had a co-ord of four groups of patients patients with type 1A endoleak,
patients with migration more than 1 centimeter, and those included 45 patients, then we had control patients without any endoleak or migration. We did a software analysis, so the determination of the apposition and position of the endograft in the aortic neck and we compared in the first
post-EVAR CTA scan and the late CTA scans, and here you can see what we mean with late CTA scan in the patients with type 1A endoleak and migration, it was the CT scan before the CT scan where the complication occurred.
Well, with the new software this is all on the CT scans before the complication in the patient with type 1A endoleak and migration, there is significantly loss of apposition, length, and also in the patient group with migration and the CTs
come before the complication really occurs the apposition is significantly lower. And also, there is more endograft expansion in the patients with migration, the endografts almost have expanded to 100%, and of course then
you will have a seal failure. What about EVAS? It is more challenging to calculate the apposition, so in the software we don't calculate the apposition but the non-apposition surface post
EVAS and post chimney EVAS. Here you can see one of the examples, the red area is the non-apposition, post-EVAS and also here you can see that sometimes it can be very subtle changes if you compare the one month and the
one year CT scan for these graft migrates because there is an increase in non-apposition. There are some different kind of migrations we call it displacement, post EVAS because it's not only a real migration but sometimes the endo backs and the stent frames bow,
and that causes also a kind of migration. And loss of apposition in inter-renal neck. And what is another important thing is you really have to determine the 3D position of the stent frames because here again we have the software usually in red
in the six months follow up, a slight displacement of the stent frames, and during one year, and 18 months here, you can see complete displaced stent frame, well of course again you want to have dealt complication before the complication
really occurs so you want to see it after 6 months. We have 20 patients with chimney EVAS. Five of them suffer a type 1A endoleak during follow up and again, we calculated the non apposition surface but also the other stent frames displacement and as you can see
here on this figure, there is a correlation between the displacement of the stent frames and the chimney grafts itself. Can we also predict (unclear), yes the five patients on the right is at a one-year CT scan, slight movement and displacement,
and here at more than one year, all those patients have type 1A endoleak and even one had a rupture. So to conclude, determination of the position and apposition of the stent grafts post-EVAR is, well it's necessary and we can
miss that with the standard CT scans so we advise to use them, the new software, which can really predict complications post-EVAR and EVAS, thank you very much.
- Dear Chairman, Ladies and Gentlemen, Thank you Doctor Veith. It's a privilege to be here. So, the story is going to be about Negative Pressure Wound Non-Excisional Treatment from Prosthetic Graft Infection, and to show you that the good results are durable. Nothing to disclose.
Case demonstration: sixty-two year old male with fem-fem crossover PTFE bypass graft, Key infection in the right groin. What we did: open the groin to make the debridement and we see the silergy treat, because the graft is infected with the microbiology specimen
and when identified, the Enterococcus faecalis, Staphylococcus epidermidis. We assess the anastomosis in the graft was good so we decided to put foam, black foam for irrigation, for local installation of antiseptics. This our intention-to treat protocol
at the University hospital, Zurich. Multi-staged Negative Pressure for the Wound Therapy, that's meets vascular graft infection, when we open the wound and we assess the graft, and the vessel anastomosis, if they are at risk or not. If they are not at risk, then we preserve the graft.
If they are at risk and the parts there at risk, we remove these parts and make a local reconstruction. And this is known as Szilagyi and Samson classification, are mainly validated from the peripheral surgery. And it is implemented in 2016 guidelines of American Heart Association.
But what about intracavitary abdominal and thoracic infection? Then other case, sixty-one year old male with intracavitary abdominal infection after EVAR, as you can see, the enhancement behind the aortic wall. What we are doing in that situation,
We're going directly to the procedure that's just making some punctures, CT guided. When we get the specimen microbiological, then start with treatment according to the microbiology findings, and then we downgrade the infection.
You can see the more air in the aneurism, but less infection periaortic, then we schedule the procedure, opening the aneurysm sac, making the complete removal of the thrombus, removing of the infected part of the aneurysm, as Doctor Maelyna said, we try to preserve the graft.
That exactly what we are doing with the white foam and then putting the black foam making the Biofilm breakdown with local installation of antiseptics. In some of these cases we hope it is going to work, and, as you see, after one month
we did not have a good response. The tissue was uneager, so we decided to make the removal of the graft, but, of course, after downgrading of this infection. So, we looked at our data, because from 2012 all the patients with
Prostetic Graft infection we include in the prospective observational cohort, known VASGRA, when we are working into disciplinary with infectious disease specialist, microbiologists, radiologist and surgical pathologist. The study included two group of patients,
One, retrospective, 93 patient from 1999 to 2012, when we started the VASGRA study. And 88 patient from April 2012 to Seventeen within this register. Definitions. Baseline, end of the surgical treatment and outcome end,
the end of microbiological therapy. In total, 181 patient extracavitary, 35, most of them in the groin. Intracavitary abdominal, 102. Intracavitary thoracic, 44. If we are looking in these two groups,
straight with Negative Pressure Wound Therapy and, no, without Negative Pressure Wound Therapy, there is no difference between the groups in the male gender, obesity, comorbidity index, use of endovascular graft in the type Samson classification,
according to classification. The only difference was the ratio of hospitalization. And the most important slide, when we show that we have the trend to faster cure with vascular graft infection in patients with Negative Pressure Wound Therapy
If we want to see exactly in the data we make uni variant, multi variant analysis, as in the initial was the intracavitary abdominal. Initial baseline. We compared all these to these data. Intracavitary abdominal with no Pressure Wound Therapy
and total graft excision. And what we found, that Endovascular indexoperation is not in favor for faster time of cure, but extracavitary Negative Pressure Wound Therapy shows excellent results in sense of preserving and not treating the graft infection.
Having these results faster to cure, we looked for the all cause mortality and the vascular graft infection mortality up to two years, and we did not have found any difference. What is the strength of this study, in total we have two years follow of 87 patients.
So, to conclude, dear Chairman, Ladies and Gentlemen, Explant after downgrading giving better results. Instillation for biofilm breakdown, low mortality, good quality of life and, of course, Endovascular vascular graft infection lower time to heal. Thank you very much for your attention.
- 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.
- Thank you very much and thank you Frank for giving me the opportunity to speak. And I will adapt my talk because I saw some of the slides, I will have to comment of course. So I have no financial disclosures. In many, many papers we know that Endovascular Treatment needs a word
of caution for long-term follow-up and we can see many, many pictures with very good results of viaven or other devices but when you look at the long-term follow-up for this patient, it's quite awful.
So we have late thrombosis just like this, we have curves that goes down and down after 40 or 60 months and much of the patients are very young and so I think it's not a good option. On the contrary, the durability
of open popliteal aneurysm repair has been showed and it's been showed by another of the panelist there and of course I think it's the good way to do and there are several options. The first one, this one, is quite rare
just to make resection with direct anastomosis like this, but it could happen and in this kind of patient, mostly when they are young patients, you don't have to make interposition of any graft.
I mean no vein, no SFA, and no prosthetic grafts. When you have to make some of the conventional open repair just like this, you have to choose between an exclusion graft like this,
I don't like it really much because it can leave a very important aneurysm and it takes a lot of place and it is prone to growing after due to the collaterals
going to the aneurysm sac. Most of the times I like to do something which is a combination of both these two pictures. I mean I like to open the sac to make the aneurysm or if you have the collaterals and then to make a end-to-end
anastomosis at both sides. Of course, when you go to the segment in the gonoral approach you have to make a venous bypass and venous bypass is probably
better when the run-off is awful just like this, but for this patient this was something needing a venous graft and this for me can be treated by synthetic graft because it ends at this level
that mean retroarticular level. So, for the venous graft, I go to venous graft only when I have to make the anastomosis directly on lower-leg vessel just like this and then you mention this
specific paper and if you could read this paper, I'm not one of the first author of this paper because I don't follow this thing because as you say, I think it's not good at all
to section all the muscles and this patient, I know this patient, they can't walk anymore for probably two months, it's not a good option but I'm part of that team and I don't want to defend it for now. Prosthetic bypass is I prefer
because this is very ancient, I agree with you, it's not modern situation, it is very ancient situation but the main thing is that you don't have to cut all the muscles, you have to select patients
with distal neck or retroarticular popliteal artery with good arterial runoff, aminolytic vessels and you have to select the patient and the Angio-CT rather than the angiogram except for
selecting the quality of the run-off. So who should be selected, this kind of patient can be selected because the prosthetic graft will end only here.
And this one could be also, but you can s there is origin of the arteritica artery.
And you have to think at the level of cutting the lower knee popliteal artery. And most of the time you can just externalize the lower knee popliteal artery to make
anastomosis. And then when you make the distal anastomosis, first you can reintegrate after there is the graft. And then the graft in the anastomotic sides goes just below
the level of the endoarticular line just like this. So for me, this is a go even if
you see that it goes just right to the condyles like this. And if you make some pictures with the reflection of the knees, there is no problem for the space. And even when there is a large
length beneath the artery like this. So when (unidentifiable phrase) where there's no vein and no below knee extension. So these are the technique that I expect I already talk about.
This is a small surveys we did I did finally. 20 popliteal arteries, this is the mean diameters. All the patients had good run-off as you can see. And there were only five long bypasses from the common femoral artery.
The other one from the popliteal or distal SFA. This is the mean Length of Stay 4 days only. The limb salvage rate is 100%. Primary patency rates were at one, two and three as 10
and secondary rates were 100% with mean follow-up 2 30 months. So prosthetic bypass is our simple, safe durable options.
I don't cut any muscles for this kind of option. Results compare favorably with our other open and endovascular techniques. And the French survey is going on for now. Thank you very much. (Audience applauds)
- Good morning everybody. Here are my disclosures. So, upper extremity access is an important adjunct for some of the complex endovascular work that we do. It's necessary for chimney approaches, it's necessary for fenestrated at times. Intermittently for TEVAR, and for
what I like to call FEVARCh which is when you combine fenestrated repair with a chimney apporach for thoracoabdominals here in the U.S. Where we're more limited with the devices that we have available in our institutions for most of us. This shows you for a TEVAR with a patient
with an aortic occlusion through a right infracrevicular approach, we're able to place a conduit and then a 22-french dryseal sheath in order to place a TEVAR in a patient with a penetrating ulcer that had ruptured, and had an occluded aorta.
In addition, you can use this for complex techniques in the ascending aorta. Here you see a patient who had a prior heart transplant, developed a pseudoaneurysm in his suture line. We come in through a left axillary approach with our stiff wire.
We have a diagnostic catheter through the femoral. We're able to place a couple cuffs in an off-label fashion to treat this with a technically good result. For FEVARCh, as I mentioned, it's a good combination for a fenestrated repair.
Here you have a type IV thoraco fenestrated in place with a chimney in the left renal, we get additional seal zone up above the celiac this way. Here you see the vessels cannulated. And then with a nice type IV repaired in endovascular fashion, using a combination of techniques.
But the questions always arise. Which side? Which vessel? What's the stroke risk? How can we try to be as conscientious as possible to minimize those risks? Excuse me. So, anecdotally the right side has been less safe,
or concerned that it causes more troubles, but we feel like it's easier to work from the right side. Sorry. When you look at the image intensifier as it's coming in from the patient's left, we can all be together on the patient's right. We don't have to work underneath the image intensifier,
and felt like right was a better approach. So, can we minimize stroke risk for either side, but can we minimize stroke risk in general? So, what we typically do is tuck both arms, makes lateral imaging a lot easier to do rather than having an arm out.
Our anesthesiologist, although we try not to help them too much, but it actually makes it easier for them to have both arms available. When we look at which vessel is the best to use to try to do these techniques, we felt that the subclavian artery is a big challenge,
just the way it is above the clavicle, to be able to get multiple devices through there. We usually feel that the brachial artery's too small. Especially if you're going to place more than one sheath. So we like to call, at our institution, the Goldilocks phenomenon for those of you
who know that story, and the axillary artery is just right. And that's the one that we use. When we use only one or two sheaths we just do a direct puncture. Usually through a previously placed pledgeted stitch. It's a fairly easy exposure just through the pec major.
Split that muscle then divide the pec minor, and can get there relatively easily. This is what that looks like. You can see after a sheath's been removed, a pledgeted suture has been tied down and we get good hemostasis this way.
If we're going to use more than two sheaths, we prefer an axillary conduit, and here you see that approach. We use the self-sealing graft. Whenever I have more than two sheaths in, I always label the sheaths because
I can't remember what's in what vessel. So, you can see yes, I made there, I have another one labeled right renal, just so I can remember which sheath is in which vessel. We always navigate the arch first now. So we get all of our sheaths across the arch
before we selective catheterize the visceral vessels. We think this partly helps minimize that risk. Obviously, any arch manipulation is a concern, but if we can get everything done at once and then we can focus on the visceral segment. We feel like that's a better approach and seems
to be better for what we've done in our experience. So here's our results over the past five-ish years or so. Almost 400 aortic interventions total, with 72 of them requiring some sort of upper extremity access for different procedures. One for placement of zone zero device, which I showed you,
sac embolization, and two for imaging. We have these number of patients, and then all these chimney grafts that have been placed in different vessels. Here's the patients with different number of branches. Our access you can see here, with the majority
being done through right axillary approach. The technical success was high, mortality rate was reasonable in this group of patients. With the strokes being listed there. One rupture, which is treated with a covered stent. The strokes, two were ischemic,
one hemorrhagic, and one mixed. When you compare the group to our initial group, more women, longer hospital stay, more of the patients had prior aortic interventions, and the mortality rate was higher. So in conclusion, we think that
this is technically feasible to do. That right side is just as safe as left side, and that potentially the right side is better for type III arches. Thank you very much.
- Thank you very much. I appreciate the opportunity to present and I'd like to thank the program committee and Doctor Veith. I have no disclosures. So Traumatic Limb Ischemia is uncommon. Demtriades looked at this with the national trauma database and found that it only occurred in about one point six
percent of patients. And the majority, or 51 percent, are penetrating injuries. These are often managed by the trauma surgeons at tertiary centers. But with the change in training paradigms, with general surgeons not doing as much vascular procedures
and open vascular surgery not being done as much by many of the trauma surgeons. Vascular surgeons are being called upon to do this, more and more often. The objective of our study is to describe a contemporary series of patients with acute limb ischemia
secondary to trauma that were managed by the vascular surgeon. In identified factors that were accossiated with limb salvage and functional outcomes. We did a retrospective review of our institution over a three year period and looked at several factors,
including the preoperative imaging the level of aclusion, limb salvage, and functional limb outcomes. We identified 68 patients in our study and the majority of these patients had moderate ISS scores and Rutherford Class two ischemia. 53 percent were from an outside hospital
and 62 percent had blunt injury, while 38 percent suffered penetrating injury. If you look at the mechanism again, the majority were motor vehicle accidents for the blunt and gunshot wounds and stab wounds for the penetrating injuries.
Median ages would be expected as fairly young with at 36 and 46 and the majority of these people are males. As is the cases with most trauma series. 58 percent were transferred from an upper, from another hospital in the upper extremity series and 51 percent in the lower extremity series.
With a median time of transfer about three hours. The median time to the operating room was about four and a half hours in this patient population. And most of these patients did receive some kind of preoperative imaging, either a CAT scan with 55 percent of the upper extremity
and 68 in the lower extremity. And the Rutherford classification of ischemia was, generally, two B and below. We looked at the location and the majority in the lower extremity were the Femoropopliteal region and in the upper extremity where the Axillary
and Brachial artery region. So, looking at the number of operations these patients underwent, and the upper extremity and lower extremity both of them underwent a median number of three operations and 84 percent of the patients upper extremity injuries went an open procedure
and 69 percent in the lower extremity. So, open procedures are the modality of choice for repair of these injuries. 58 percent of the lower extremities went on to have Fasciotomies, as well. In some of the details, the open repair
was a dominant treatment as stated. Shunts were only utilized in two of our patients, with Fasciotomies only occurring in 25 percent 58 percent of the lower extremity injuries. And we think about some of the details, we had eight patients who underwent Fasciotomies
during the first operation with dead muscle encountered in three of those patients. Three patients underwent a delayed Fasciotomy with dead muscle encountered in one of those patients. Limb salvagery overall is 94 percent in the upper extremity and 78 percent in the lower extremity.
And again, with the amputation patients, we had 12 patients that underwent an amputation, one primary amputation. The overall limb salvage was 94 percent for upper extremity and 78 percent for lower extremity. The predictors or amputation of functional limb,
in a functional limb where the number was a Rutherford Classification and the number of procedures these patients undergo. The length of stay was 11 days, 25 percent were discharged to a skilled nursing facility and follow up occurred in 59 percent of the patients, as the case
with many of the trauma type studies. When you think about functional deficits, the patients that had no functional deficits in the upper extremity were about 57 percent and the lower extremity 68 percent. But major deficits occurred in one third of the patients
with an upper extremity injury versus six percent. Whereas amputation occurs much more frequently in the lower extremity versus the upper extremity. So, Traumatic Acute Limb Ischemia is uncommon outside of trauma centers, vascular surgeons are extremely well equipped
to deal with this, majority of extremities can be salvaged, transfer times to a tertiary center may explain some of the correlation with limb salvage, and rehabilitation and follow up can be difficult in this patient population. Again, we only had 59 percent follow up, you know,
in the literature it's around 60 and 66 percent in this patient population. It can be managed with very high rates as limb salvage by vascular surgeons. So I think that we can do this and we do it quite well. Limb salvage doesn't equate to functional outcomes,
particularly in the upper extremity. And in the future, I think that we need to probably get better about the follow up and identify some patient centered functional status and quality of life questionnaries post salvage, to see truly what the outcome is and the functional status
is of these patients. Thank you very much. (applause)
- Thanks Fieres. Thank you very much for attending this session and Frank for the invitation. These are my disclosures. We have recently presented the outcomes of the first 250 patients included in this prospective IDE at the AATS meeting in this hotel a few months ago.
In this study, there was no in-hospital mortality, there was one 30-day death. This was a death from a patient that had intracranial hemorrhage from the spinal drain placement that eventually was dismissed to palliative care
and died on postoperative day 22. You also note that there are three patients with paraplegia in this study, one of which actually had a epidural hematoma that was led to various significant and flacid paralysis. That prompted us to review the literature
and alter our outcomes with spinal drainage. This review, which includes over 4700 patients shows that the average rate of complications is 10%, some of those are relatively moderate or minor, but you can see a rate of intracranial hemorrhage of 1.5% and spinal hematoma of 1% in this large review,
which is essentially a retrospective review. We have then audited our IDE patients, 293 consecutive patients treated since 2013. We looked at all their spinal drains, so there were 240 placement of drains in 187 patients. You can see that some of these were first stage procedures
and then the majority of them were the index fenestrated branch procedure and some, a minority were Temporary Aneurysm Sac Perfusions. Our rate of complication was identical to the review, 10% and I want to point out some of the more important complications.
You can see here that intracranial hypotension occurred in 6% of the patients, that included three patients, or 2%, with intracranial hemorrhage and nine patients, or 5%, with severe headache that prolonged hospital stay and required blood patch for management.
There were also six patients with spinal hematomas for a overall rate of 3%, including the patient that I'll further discuss later. And one death, which was attributed to the spinal drain. When we looked at the intracranial hypotension in these 12 patients, you can see
the median duration of headache was four days, it required narcotics in seven patients, blood patch in five patients. All these patients had prolonged hospital stay, in one case, the prolongation of hospital stay was of 10 days.
Intracranial hemorrhage in three patients, including the patient that I already discussed. This patient had a severe intracranial hemorrhage which led to a deep coma. The patient was basically elected by the family to be managed with palliative care.
This patient end up expiring on postoperative day 21. There were other two patients with intracranial hemorrhage, one remote, I don't think that that was necessarily related to the spinal drain, nonetheless we had it on this review. These are some of the CT heads of the patients that had intracranial hemorrhage,
including the patient that passed away, which is outlined in the far left of your slide. Six patients had spinal hematoma, one of these patients was a patient, a young patient treated for chronic dissection. Patient evolved exceptionally well, moving the legs,
drain was removed on postoperative day two. As the patient is standed out of the bed, felt weakness in the legs, we then imaged the spine. You can see here, very severe spinal hematoma. Neurosurgery was consulted, decided to evacuate, the patient woke up with flacid paralysis
which has not recovered. There were two other patients with, another patient with paraplegia which was treated conservatively and improved to paraparesis and continues to improve and two other patients with paraparesis.
That prompted changes in our protocol. We eliminated spinal drains for Extent IVs, we eliminated for chronic dissection, in first stages, on any first stage, and most of the Extent IIIs, we also changed our protocol of drainage
from the routine drainage of a 10 centimeters of water for 15 minutes of the hours to a maximum of 20 mL to a drainage that's now guided by Near Infrared Spectroscopy, changes or symptoms. This is our protocol and I'll illustrate how we used this in one patient.
This is a patient that actually had this actual, exact anatomy. You can see the arch was very difficult, the celiac axis was patent and provided collateral flow an occluded SMA. The right renal artery was chronically occluded.
As we were doing this case the patient experienced severe changes in MEP despite the fact we had flow to the legs, we immediately stopped the procedure with still flow to the aneurysm sac. The patient develops pancreatitis, requires dialysis
and recovers after a few days in the ICU with no neurological change. Then I completed the repair doing a subcostal incision elongating the celiac axis and retrograde axis to this graft to complete the branch was very difficult to from the arm
and the patient recovered with no injury. So, in conclusion, spinal drainage is potentially dangerous even lethal and should be carefully weighted against the potential benefits. I think that our protocol now uses routine drainage for Extent I and IIs,
although I still think there is room for a prospective randomized trial even on this group and selective drainage for Extent IIIs and no drainage for Extent IVs. We use NIRS liberally to guide drainage and we use temporary sac perfusion
in those that have changes in neuromonitoring. Thank you very much.
- Thank you Tal. It's a privilege again to take the podium here. No disclosures. Everyone in here in this audience understands how important Traumatic Aortic Injury is, the second leading cause of death, primarily due to blunt mechanisms,
that are well known to the trauma and vascular community. And, we've learned a lot about how to care for these patient's in the transition in the vascular age. And, that began with the American Association for the Surgery of Trauma Studies in 2008 and 2009, which showed that TEVAR was associated
with an improved mortality and decreased paraplegia compared to older modalities. And, these are the graphs at my old training grounds at UT Houston, which, I'm sure would be the same at most other centers. A gradual transition to almost completely TEVAR
for every patient who has appropriate anatomy. And, we now have over a decade worth of survival data to show the outcome comparisons are the same as the older modalities. But the question has become now, are we over treating some of these injuries?
We need an optimal algorithm and an optimal algorithm requires an optimal grading system. And, that grading system should determine the treatment we utilize, it should guide the timing of the treatment. And, should provide some prediction of the natural history
in those patient's that we do not immediately treat. The SVS in 2011 developed a very nice anatomical based grading system, however, this is a lesionology type algorithm if you will, and not incorporating any of the valuable information that the patient also may possess
in terms of associated injuries. There have been alternative proposals: Vancouver, the Harborview "Minimal Aortic Injuries" is one that is very familiar and commonly utilized in the literature. And, even the Baltimore Classification which includes some physiology elements.
And the reality is, there are also other elements of ongoing issues Blunt Thoracic Aortic Injury, including not only how to manage those Grade 1/Grade 2 injuries but the timing of repair. How do we prioritize repair in the context of other sev
rain Injury and other bleeding solid organs and what's the optimal follow up regimen for these patients? It was with those questions in mind that 3 years ago we developed the Aortic Trauma Foundation. This is a non-profit organization with a Multispecialty
International Medical Advisory Board and a Board of Directors. We really wanted to improve outcomes of patient's with Traumatic Aortic Injury through education and research. We started with several initial, kind of low hanging fruit exercises, the first of which was a practice pattern survey
from members of the SVS, trauma organization, thoracic surgery organizations in interventional radiology and we found that there were some contingents here, and some very interesting findings in this survey. In fact, a majority of providers who care for these injuries don't rely on any guidelines at all.
Just their own personal knowledge of literature and their experience over their practice lifespan. Likewise, these mid-grade injuries represent some significant controversy with almost half the providers thinking that these just need medical therapy and observation as an outpatient.
And the remainder treating them emergently with TEVAR. Or, urgently with TEVAR. And we also conducted a large Retrospective Multicenter Study, 382 patient's from US Level 1 Trauma Centers and we found the at TEVAR compared to Open Repair
was associated with lower transfusion, lower overall mortality, lower aortic related mortality. None of these were surprising findings. But again, this study identified some controversy here, particularly with the, there's no difference in outcomes with those Minimal BTAI patient's if they're treated
with TEVAR or undergo medical non-operative management. Which suggests at least that in some of these patient's we are actually over-treating them. We have, as ongoing effort, our Aortic Trauma Foundation International, Multicenter PROSPECTIVE Blunt Thoracic Aortic Injury Registry
designed to identify predictors of early rupture, develop some multi-specialty consensus guidelines on treatment and management and establish long term outcomes. Anyone in this audience can join this effort, we have always gotten good contribution from VEITH.
We have a region based involvement, mechanism to promote the not only ATF involvement but the prospective registry in the US and abroad. And, we've had some good results. This initial registry went live in 2016, as of 2018, we have 381 patient's
in 23 centers internationally. And we plan to do a feasibility report when we cross the 500 patient threshold. And we invite anyone who seeks to become a member of the Aortic Trauma Foundation and actively contributes to utilize this data.
We all want to as a community, identify and define optimal care practices. We are going to actively solicit and review proposals for use and we hope that this data will produce a foundational platform upon which we can develop some really meaningful multi-specialty guidelines
that are evidence and practice based. Thank you.
- I'm going to take it slightly beyond the standard role for the VBX and use it as we use it now for our fenestrated and branch and chimney grafts. These are my disclosures. You've seen these slides already, but the flexibility of VBX really does give us a significant ability to conform it
to the anatomies that we're dealing with. It's a very trackable stent. It doesn't, you don't have to worry about it coming off the balloon. Flexible as individual stents and in case in a PTFE so you can see it really articulates
between each of these rings of PTFE, or rings of stent and not connected together. I found I can use the smaller grafts, the six millimeter, for parallel grafts then flare them distally into my landing zone to customize it but keep the gutter relatively small
and decrease the instance of gutter leaks. So let's start with a presentation. I know we just had lunch so try and shake it up a little bit here. 72-year-old male that came in, history of a previous end-to-side aortobifemoral bypass graft
and then came in, had bilateral occluded external iliac arteries. I assume that's for the end-to-side anastomosis. I had a history of COPD, coronary artery disease, and peripheral arterial disease, and presented with a pseudoaneurysm
in the proximal juxtarenal graft anastomosis. Here you can see coming down the thing of most concern is both iliacs are occluded, slight kink in the aortofemoral bypass graft, but you see a common iliac coming down to the hypogastric, and that's really the only blood flow to the pelvis.
The aneurysm itself actually extended close to the renal, so we felt we needed to do a fenestrated graft. We came in with a fenestrated graft. Here's the renal vessels here, SMA. And then we actually came in from above in the brachial access and catheterized
the common iliac artery going down through the stenosis into the hypogastric artery. With that we then put a VBX stent graft in there which nicely deployed that, and you can see how we can customize the stent starting with a smaller stent here
and then flaring it more proximal as we move up through the vessel. With that we then came in and did our fenestrated graft. You can see fenestrations. We do use VBX for a good number of our fenestrated grafts and here you can see the tailoring.
You can see where a smaller artery, able to flare it at the level of the fenestration flare more for a good seal. Within the fenestration itself excellent flow to the left. We repeated the procedure on the right. Again, more customizable at the fenestration and going out to the smaller vessel.
And then we came down and actually extended down in a parallel graft down into that VBX to give us that parallel graft perfusion of the pelvis, and thereby we sealed the pseudoaneurysm and maintain tail perfusion of the pelvis and then through the aortofemoral limbs
to both of the common femoral arteries, and that resolved the pseudoaneurysm and maintained perfusion for us. We did a retrospective review of our data from August of 2014 through March of 2018. We had 183 patients who underwent endovascular repair
for a complex aneurysm, 106 which had branch grafts to the renals and the visceral vessels for 238 grafts. When we look at the breakdown here, of those 106, 38 patients' stents involved the use of VBX. This was only limited by the late release of the VBX graft.
And so we had 68 patients who were treated with non-VBX grafts. Their other demographics were very similar. We then look at the use, we were able to use some of the smaller VBXs, as I mentioned, because we can tailor it more distally
so you don't have to put a seven or eight millimeter parallel graft in, and with that we found that we had excellent results with that. Lower use of actual number of grafts, so we had, for VBX side we only had one graft
per vessel treated. If you look at the other grafts, they're anywhere between 1.2 and two grafts per vessel treated. We had similar mortality and followup was good with excellent graft patency for the VBX grafts.
As mentioned, technical success of 99%, mimicking the data that Dr. Metzger put forward to us. So in conclusion, I think VBX is a safe and a very versatile graft we can use for treating these complex aneurysms for perfusion of iliac vessels as well as visceral vessels
as we illustrated. And we use it for aortoiliac occlusive disease, branch and fenestrated grafts and parallel grafts. It's patency is equal to if not better than the similar grafts and has a greater flexibility for modeling and conforming to the existing anatomy.
Thank you very much for your attention.
- Thank you very much and thank you Dr. Veith for the kind invite. Here's my disclosures, clearly relevant to this talk. So we know that after EVAR, it's around the 20% aortic complication rate after five years in treating type one and three Endoleaks prevents subsequent
secondary aortic rupture. Surveillance after EVAR is therefore mandatory. But it's possible that device-specific outcomes and surveillance protocols may improve the durability of EVAR over time. You're all familiar with this graph for 15 year results
in terms of re-intervention from the EVAR-1 trials. Whether you look at all cause and all re-interventions or life threatening re-interventions, at any time point, EVAR fares worse than open repair. But we know that the risk of re-intervention is different
in different patients. And if you combine pre-operative risk factors in terms of demographics and morphology, things are happening during the operations such as the use of adjuncts,
or having to treat intro-operative endoleak, and what happens to the aortic sac post-operatively, you can come up with a risk-prediction tool for how patients fare in the longer term. So the LEAR model was developed on the Engage Registry and validated on some post-market registries,
PAS, IDE, and the trials in France. And this gives a predictive risk model. Essentially, this combines patients into a low risk group that would have standard surveillance, and a higher risk group, that would have a surveillance plus
or enhanced surveillanced model. And you get individual patient-specific risk profiles. This is a patient with around a seven centimeter aneurysm at the time of repair that shows sac shrinkage over the first year and a half, post-operatively. And you can see that there's really a very low risk
of re-intervention out to five years. These little arrow bars up here. For a patient that has good pre-operative morphology and whose aneurysm shrinks out to a year, they're going to have a very low risk of re-intervention. This patient, conversely, had a smaller aneurysm,
but it grew from the time of the operation, and out to two and a half years, it's about a centimeter increase in the sac. And they're going to have a much higher risk of re-intervention and probably don't need the same level of surveillance as the first patient.
and probably need a much higher rate of surveillance. So not only can we have individualized predictors of risk for patients, but this is the regulatory aspect to it as well.
Multiple scenario testing can be undertaken. And these are improved not only with the pre-operative data, but as you've seen with one-year data, and this can tie in with IFU development and also for advising policy such as NICE, which you'll have heard a lot about during the conference.
So this is just one example. If you take a patient with a sixty-five millimeter aneurysm, eighteen millimeter iliac, and the suprarenal angle at sixty degrees. If you breach two or more of these factors in red, we have the pre-operative prediction.
Around 20% of cases will be in the high risk group. The high risk patients have about a 50-55% freedom from device for related problems at five years. And the low risk group, so if you don't breach those groups, 75% chance of freedom from intervention.
In the green, if you then add in a stent at one year, you can see that still around 20% of patients remain in the high risk group. But in the low risk group, you now have 85% of patients won't need a re-intervention at five years,
and less of a movement in the high risk group. So this can clearly inform IFU. And here you see the Kaplan-Meier curves, those same groups based pre-operatively, and at one year. In conclusion, LEAR can provide
a device specific estimation of EVAR outcome out to five years. It can be based on pre-operative variables alone by one year. Duplex surveillance helps predict risk. It's clearly of regulatory interest in the outcomes of EVAR.
And an E-portal is being developed for dissemination. Thank you very much.
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