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Portal Vein Occlusion, Portal Hypertension | Percutaneous Mesocaval Shunt | 16 | Female
Portal Vein Occlusion, Portal Hypertension | Percutaneous Mesocaval Shunt | 16 | Female
2016arteryavoidballoonbleedingcommoncompletedilateddrainduodenumendoscopygramguidehepaticliverobliterationpatientportalpuncturepuncturedscanSIRsplenicstentveinveinswire
New Developments In The Treatment Of Venous Thoracic Outlet Syndromes
New Developments In The Treatment Of Venous Thoracic Outlet Syndromes
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Routine Use Of Ultrasound To Avoid Complications During Placement Of Tunneled Dialysis Catheters: Analysis Of 2805 Cases
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How Best To Treat Pediatric Vascular Injuries
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Right Axillary Access For Complex EVARs And TEVARs: Advantages, Technical Tips And Preventing Strokes
Right Axillary Access For Complex EVARs And TEVARs: Advantages, Technical Tips And Preventing Strokes
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New Devices For False Lumen Obliteration With TBADs: Indications And Results
New Devices For False Lumen Obliteration With TBADs: Indications And Results
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Single Branch Carotid Ch/TEVAR With Cervical Bypasses: A Simple Solution For Some Complex Aortic Arch Lesions: Technical Tips And Results
Single Branch Carotid Ch/TEVAR With Cervical Bypasses: A Simple Solution For Some Complex Aortic Arch Lesions: Technical Tips And Results
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Results Of A Multicenter Italian Registry Of Real World CAS With The C-Guard Mesh Covered Stent: The IRONGUARD 2 Study
Results Of A Multicenter Italian Registry Of Real World CAS With The C-Guard Mesh Covered Stent: The IRONGUARD 2 Study
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Cloud Based System For Image Fusion Techniques With Mobile C-Arms (The Cydar System): How Does It Work And Advantages For All Vascular Interventions
Cloud Based System For Image Fusion Techniques With Mobile C-Arms (The Cydar System): How Does It Work And Advantages For All Vascular Interventions
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Surgical vs. Endovascular Management Of Cephalic Arch Syndrome
Surgical vs. Endovascular Management Of Cephalic Arch Syndrome
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Challenges And Solutions In Complex Dialysis Access Cases
Challenges And Solutions In Complex Dialysis Access Cases
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Surgical Creation Of A Moncusp Valve
Surgical Creation Of A Moncusp Valve
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With Complex AAAs, How To Make Decisions Re Fenestrations vs. Branches: Which Bridging Branch Endografts Are Best
With Complex AAAs, How To Make Decisions Re Fenestrations vs. Branches: Which Bridging Branch Endografts Are Best
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Gutter Endoleaks On Completion Angiography With Ch/EVAR: When To Ignore; How To Prevent; When And How To Treat
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Imaging Tools To Increase The Safety/Accuracy Of Endovascular Procedures And Reduce Radiation And Contrast Media
Imaging Tools To Increase The Safety/Accuracy Of Endovascular Procedures And Reduce Radiation And Contrast Media
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Technical Tips For Maintaining Carotid Flow During Branch Revascularization When Performing Zone 1 TEVARs
Technical Tips For Maintaining Carotid Flow During Branch Revascularization When Performing Zone 1 TEVARs
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Vascular Injuries From Orthopedic Operations: How To Prevent Catastrophes: Beware The Dangers Of Orthopedic Cement: What Are They
Vascular Injuries From Orthopedic Operations: How To Prevent Catastrophes: Beware The Dangers Of Orthopedic Cement: What Are They
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Status Of Aortic Endografts For Occlusive Disease: Indications, Precautions, Technical Tips And Value
Status Of Aortic Endografts For Occlusive Disease: Indications, Precautions, Technical Tips And Value
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Technical Tips To Make Distal Bypasses Work
anastomosisanesthesiaanestheticsangiogramangioplastyanticoagulationantiplateletarterybypassbypassesconduitdebridementdistaldistallydopplerdorsalisendarterectomyfootgrafthybridincisioninterventionischaemiaLeMaitrelevelOmniflow II Ovine graftsOrthograde graftspatientpatientspedisPeroneal BypasspoplitealprocedureproximalptferemoteRemote EndarterectomyrevascularizationsaphenousskinstentingSurveillancetherapytibialveinsvenouswaveform
Inari CloTriever Device For Acute DVT
Inari CloTriever Device For Acute DVT
anteriorbonecatheterclotCloTriever CatheterCloTriever ProcedureCloTriever SheathcompressibleCorpectomy with interbody Cage / Local Bone Graft with Local Bone PowderduplexenrollextravasationfemoralhardwareiliacinsertedLumbar Interbody fusion Via Anteriro approachlyticmaterialobstructedorthopedicoutcomespatientpatientsphasicpoplitealregistrysegmentsheathspondylolisthesisSpondylolisthesis L5-S1 / Post- Operat Acute extensive Lt Lower Limb DVTstentsubclavianswellingtherapythrombectomythrombosedthrombustibialtpaveinvenous
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Italian National Registry Results With Inner Branch Devices For Aortic Arch Disease
aortaaorticarcharteriesarteryascendingavailabilitybarbsbranchcarotidcatheterizedcommondecreasedevicesdissectiondoublr branch stent graftendoleakendovascularevarexcludinggraftguptalimbmajormidtermmorphologicalmortalityoperativepatientpatientsperioperativeproximalregistryrepairretrogradestentStent graftstentingstrokesupraterumotherapeutictibialvascular
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Treating Venous Thromboembolism Without Lytic Medications
amountaspirateaspirationassistedcatheterclotcreatedevicedevicesfocalfrenchiliacmechanicalpatientpulmonaryrheolyticstentsuctionthrombustypetypesvacuumveinvenous
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Value Of CO2 DSA For Abdominal And Pelvic Trauma: Why And How To Use CO2 Angiography With Massive Bleeding And When To Supplement It With Iodinated Contrast
abdominalangiographyanterioraortaaorticarteriogrambasicallybleedingcarboncatheterceliaccoilcontrastdiaphragmdioxideembolizationholeimaginginjectinjectioninjectionsiodinatedliverlowmultiplepatientpelvicrenalruptureselectivesolublesplenictraumavascularizationveinvesselvesselsvolumes
Elevation Or Retunneling For Second Stage Basilic Vein Transposition
Elevation Or Retunneling For Second Stage Basilic Vein Transposition
anastomosisarterialbasiliccomparablecomparedcumulativedatafavoredFistulafistulasgraftsjournalmaturationOne & Two Stage procedurespatenciespatencyprimaryrangeratesstagestagedstratifiedSuperficializationsuperiorTrans-positiontransectiontransposedtranspositiontunnelingvascularveinveinsversus
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Value Of Intraprocedural Completion Cone Beam CT After Standard EVARs And Complex EVARs (F/B/EVARs): What To Do If One Does Not Have The Technology
4-Vessel FEVARangiographyaortoiliacarchaxialbeamBEVARbifurcatedcalcificationcatheterizecatheterizedcompletionconecone beamcoronaldetectablediagnosticdilatordissectionDissection FlapendoleakevaluatesevarfemorofenestratedFEVARfindingsfusionGE HealthcareinterventionmesentericocclusionoperativelypositiveproceduresprospectiveproximalradiationRadiocontrast agentrotationalstentstudytechnicalthoracoabdominaltriggeredunnecessaryVisipaque
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Technical Tips For The Management Of Cervical And Mediastinal Iatrogenic Artery Injuries: How To Avoid Disasters
9F Sheath in Lt SCAAbbottaccessarterybrachialcarotidcatheterCordisDual Access (Rt Femora + SC sheath) ttt with suture mediated proglid over 0.035 inch wireendovascularfemoralfrenchgraftiatrogenicimaginginjuriesleftPer-Close suture mediated ProgliderangingsheathstentsubclaviantreatedvarietyvascularvenousvertebralVessel Closure Devicewire
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Current Management Of Bleeding Hemodialysis Fistulas: Can The Fistula Be Salvaged
accessaneurysmalapproachArtegraftavoidbleedingbovineBovine Carotid Artery Graft (BCA)carotidcentersDialysisemergencyexperiencefatalFistulafistulasflapgraftgraftshemodialysishemorrhageinfectioninterpositionlesionLimberg skin flapnecrosispatencypatientpatientsptfeskinStent graftsubsequentsuturetourniquetulceratedulcerationsvascular
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What Morphological Changes On CT After EVAR Predict The Need For Re-Interventions: From The DREAM Trial
analysisaneurysmangulationaorticdiameterendograftendoleakendoleaksendovascularevariliaclengthlimbmaximalneckpatientspredictpredictivepredictspreoperativeproximalreinterventionsscanssecondaryshrinkagestenosisstenttherapeuticthrombus
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Why Open Endarterectomy Is The Best Treatment For Common Femoral Artery Lesions: It Is Still The Gold Standard In Most Cases Despite What You May Read And Hear
amputationarterycommoncommon femoralembolizationendarterectomyendovascularfemoralfemoral arteryhematomaInterventionsmehtamorbiditymortalitypatencypatientsperioperativeprimaryrestenosisrevascularizationrotationalstentstentingstentssuperficialsurgicalsurvivalTECCO
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Estimation Of Long-Term Aortic Risk After EVAR: The LEAR Model: How Can It Guide And Modulate Surveillance Protocols
aneurysmaorticcentimeterdeviceendoleaksevarlearlowoutcomespatientpatientspredictorsregulatoryriskshrinkagestentsuprarenalSurveillanceVeith
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Importance Of Maintaining Or Restoring Deep Femoral Artery Flow In Open And Endo Revascularizations For CLTI
amputationangioplastyarteryballoonclaudicationcombinedconfigurationsdeependovascularextremityfemoralfemoral arterygroinhealhybridiliacinflowinfrainguinalischemicisolatedlimbocclusionOcclusion of DFApainpatencypatientpercutaneousperfusionpoplitealpreventprofundaproximalrestrevascularizesalvageseromastenosisstentingstumpsystemictransluminaltreatableVeithwound
Transcript

Allergies cause a 16 year old, very young female patient. She underwent a season of claricasister/g in 2004 when she was four or five years old.

However, she had weak anitgi/g bleeding since 2006 and endoscopy Was done one about two times every year for nearly 10 years we do our read out homeostasis but no that need bleeding [INAUDIBLE] and are not identified but she had recently a grow of AT the J bleeding but let Profile shows completely normal liver but the hemoglobin leather

was 6.3. This is a CT scan [BLANK_AUDIO] [BLANK_AUDIO] Is a little bit late. [BLANK_AUDIO]

[BLANK_AUDIO] Does it look, [INAUDIBLE] >> Okay while we are waiting, you have the app for the audience system ARS For the voting so if you have a mobile phone please turn on the ARS.

>> Okay actually the [INAUDIBLE] is complete obliteration of intra hepatic and Istra/g hepatic portal veins and The carbon transformation. But the [UNKNOWN] are patent. Our catheter endoscopy revealed the actual bleeding in proximal duodenum and large amounts of blood clots in small bowel. So The variceal bleeding in duodenum due to [UNKNOWN] hypertension

was diagnosed due to [UNKNOWN] So treatment plan was tips through the [UNKNOWN] with a split vein access So I punctured the splenic vein and you can see the [UNKNOWN] transformation and complete obliteration of the [UNKNOWN]. This is SMB angiogram. So I try to To advance the guide wire through the collaterals.

With all three, five even micro wire but I couldn't. So what options left for this patient? Please vote. [BLANK_AUDIO] Surgery and liver transplant process, [UNKNOWN]

[UNKNOWN] Actually my answer is four because surgery of a [UNKNOWN] creation has more than 50%of a mortality and considering Transform a patient, this patient has complete normal liver, and portal veins they'll [INAUDIBLE] and there may be a chance of [INAUDIBLE] I think it makes it very difficult to the surgery. And the [INAUDIBLE] because see there's [INAUDIBLE] was totally

obliterated. This is impossible I think. So I look at the CT scan in detail but I found a small window between IVC and SME [UNKNOWN] like this. But the problem one is I have to avoid common hepatic artery and duodenum and dilate

the left gatric vein and you can see the duodenum here. In [UNKNOWN] this is the dilated common hepatic artery and this is dilated gastric vein, In addition when I puncture the SMV's successfully, the SMV's totally is to a hepatic free space. Do I need the free dilation?

Why not. And it seems to be More difficult to avoid the bullet like this. So anyway I'd like to avoid puncturing the common hepatic artery, I put the guide wire in the common hepatic artery and this is the guide wire in the common hepatic artery and I put the Level meeting with the wetting balloon in SMV.

And we're using colapinto nido and ten french keeps issues, was placed through the jewelry and there is target, and I punctured the a balloon at one time, so this is a portal gram to identify

where I am, the portal gram is this, so here the question, do I need the pre-dilation or no. Please vote. Okay, click here. [BLANK_AUDIO].

Although is it 13 and the answer is 550. My answer is yes. Because without predilation I may have difficulty during [INAUDIBLE] which I would like to avoid. Second reason is There maybe a adhesion in this patient and so even

if pre-dilate with the small balloons like four millimeter bllons, if you are okay I agree. So I pre-dilate with the four milliliter balloon, absolutely the strength up was ready to be placed So I kept a trichogram with a tip of sheaths, you can see the small extravization here,

so [INAUDIBLE] eight millimeters [INAUDIBLE] to less placed in the balloon. It's final [INAUDIBLE]. It's pressure gradient/g is decreased from 16 mm mercury to 16 mm mercury.

So it looks fantastic so far but the spleen pressure is not decreased. It's a splenic venous pool did not drain through the shunt because I think the stent graft occlude the drain of the [UNKNOWN]. So I advanced the guide wire again. And put this balloon [UNKNOWN] with stent. And this is the final angiogram.

And this the CT scan after a stent graft. You can see they're here. the common hepatic artery. Yeah. The patient was in good condition for two years and this is the CT scan.

It's really reconstruction. Two years later she had recurrent GI bleeding and the photogram demonstrated short segment on stanosis in intrahepatic segment. So I put a 10 mm balloon [UNKNOWN] stent and the patient is okay [UNKNOWN] so far. I found two similar cases of a percutaneous nasal [UNKNOWN] creation

and one case is published in JVR 2012, it's nearly same case like me and in this case they use the intravascular ultrasound but I use the balloon as target with the stent graft. Here and the other case was we pulled/g the transseptal puncture of the IVC under the CT guidance through the SMV and snare the

guide wire and put the stent. So this case is teaching us that don't give up any cases, a desperate disease must have a desperate remedies. Thank you. >> [APPLAUSE]

- So I'm just going to talk a little bit about what's new in our practice with regard to first rib resection. In particular, we've instituted the use of a 30 degree laparoscopic camera at times to better visualize the structures. I will give you a little bit of a update

about our results and then I'll address very briefly some controversies. Dr. Gelbart and Chan from Hong Kong and UCLA have proposed and popularized the use of a 30 degree laparoscopic camera for a better visualization of the structures

and I'll show you some of those pictures. From 2007 on, we've done 125 of these procedures. We always do venography first including intervascular intervention to open up the vein, and then a transaxillary first rib resection, and only do post-operative venography if the vein reclots.

So this is a 19 year old woman who's case I'm going to use to illustrate our approach. She developed acute onset left arm swelling, duplex and venogram demonstrated a collusion of the subclavian axillary veins. Percutaneous mechanical thrombectomy

and then balloon angioplasty were performed with persistent narrowing at the thoracic outlet. So a day later, she was taken to the operating room, a small incision made in the axilla, we air interiorly to avoid injury to the long thoracic nerve.

As soon as you dissect down to the chest wall, you can identify and protect the vein very easily. I start with electrocautery on the peripheral margin of the rib, and use that to start both digital and Matson elevator dissection of the periosteum pleura

off the first rib, and then get around the anterior scalene muscle under direct visualization with a right angle and you can see that the vein and the artery are identified and easily protected. Here's the 30 degree laparoscopic image

of getting around the anterior scalene muscle and performing the electrocautery and you can see the pulsatile vein up here anterior and superficial to the anterior scalene muscle. Here is a right angle around the first rib to make sure there are no structures

including the pleura still attached to it. I always divide, or try to divide, the posterior aspect of the rib first because I feel like then I can manipulate the ribs superiorly and inferiorly, and get the rib shears more anterior for the anterior cut

because that's most important for decompressing the vein. Again, here's the 30 degree laparoscopic view of the rib shears performing first the posterior cut, there and then the anterior cut here. The portion of rib is removed, and you can see both the artery and the vein

are identified and you can confirm that their decompressed. We insufflate with water or saline, and then perform valsalva to make sure that they're hasn't been any pneumothorax, and then after putting a drain in,

I actually also turn the patient supine before extirpating them to make sure that there isn't a pneumothorax on chest x-ray. You can see the Jackson-Pratt drain in the left axilla. One month later, duplex shows a patent vein. So we've had pretty good success with this approach.

23 patients have requires post operative reintervention, but no operative venous reconstruction or bypass has been performed, and 123 out of 125 axillosubclavian veins have been patent by duplex at last follow-up. A brief comment on controversies,

first of all, the surgical approach we continue to believe that a transaxillary approach is cosmetically preferable and just as effective as a paraclavicular or anterior approach, and we have started being more cautious

about postoperative anticoagulation. So we've had three patients in that series that had to go back to the operating room for washout of hematoma, one patient who actually needed a VATS to treat a hemathorax,

and so in recent times we've been more cautious. In fact 39 patients have been discharged only with oral antiplatelet therapy without any plan for definitive therapeutic anticoagulation and those patients have all done very well. Obviously that's contraindicated in some cases

of a preoperative PE, or hematology insistence, or documented hypercoagulability and we've also kind of included that, the incidence of postop thrombosis of the vein requiring reintervention, but a lot of patients we think can be discharged

on just antiplatelets. So again, our approach to this is a transaxillary first rib resection after a venogram and a vascular intervention. We think this cosmetically advantageous. Surgical venous reconstruction has not been required

in any case, and we've incorporated the use of a 30 degree laparoscopic camera for better intraoperative visualization, thanks.

- I want to thank the organizers for putting together such an excellent symposium. This is quite unique in our field. So the number of dialysis patients in the US is on the order of 700 thousand as of 2015, which is the last USRDS that's available. The reality is that adrenal disease is increasing worldwide

and the need for access is increasing. Of course fistula first is an important portion of what we do for these patients. But the reality is 80 to 90% of these patients end up starting with a tunneled dialysis catheter. While placement of a tunneled dialysis catheter

is considered fairly routine, it's also clearly associated with a small chance of mechanical complications on the order of 1% at least with bleeding or hema pneumothorax. And when we've looked through the literature, we can notice that these issues

that have been looked at have been, the literature is somewhat old. It seemed to be at variance of what our clinical practice was. So we decided, let's go look back at our data. Inpatients who underwent placement

of a tunneled dialysis catheter between 1998 and 2017 reviewed all their catheters. These are all inpatients. We have a 2,220 Tesio catheter places, in 1,400 different patients. 93% of them placed on the right side

and all the catheters were placed with ultrasound guidance for the puncture. Now the puncture in general was performed with an 18 gauge needle. However, if we notice that the vein was somewhat collapsing with respiratory variation,

then we would use a routinely use a micropuncture set. All of the patients after the procedures had chest x-ray performed at the end of the procedure. Just to document that everything was okay. The patients had the classic risk factors that you'd expect. They're old, diabetes, hypertension,

coronary artery disease, et cetera. In this consecutive series, we had no case of post operative hemo or pneumothorax. We had two cut downs, however, for arterial bleeding from branches of the external carotid artery that we couldn't see very well,

and when we took out the dilator, patient started to bleed. We had three patients in the series that had to have a subsequent revision of the catheter due to mal positioning of the catheter. We suggest that using modern day techniques

with ultrasound guidance that you can minimize your incidents of mechanical complications for tunnel dialysis catheter placement. We also suggest that other centers need to confirm this data using ultrasound guidance as a routine portion of the cannulation

of the internal jugular veins. The KDOQI guidelines actually do suggest the routine use of duplex ultrasonography for placement of tunnel dialysis catheters, but this really hasn't been incorporated in much of the literature outside of KDOQI.

We would suggest that it may actually be something that may be worth putting into the surgical critical care literature also. Now having said that, not everything was all roses. We did have some cases where things didn't go

so straight forward. We want to drill down a little bit into this also. We had 35 patients when we put, after we cannulated the vein, we can see that it was patent. If it wasn't we'd go to the other side

or do something else. But in 35%, 35 patients, we can put the needle into the vein and get good flashback but the wire won't go down into the central circulation.

Those patients, we would routinely do a venogram, we would try to cross the lesion if we saw a lesion. If it was a chronically occluded vein, and we weren't able to cross it, we would just go to another site. Those venograms, however, gave us some information.

On occasion, the vein which is torturous for some reason or another, we did a venogram, it was torturous. We rolled across the vein and completed the procedure. In six of the patients, the veins were chronically occluded

and we had to go someplace else. In 20 patients, however, they had prior cannulation in the central vein at some time, remote. There was a severe stenosis of the intrathoracic veins. In 19 of those cases, we were able to cross the lesion in the central veins.

Do a balloon angioplasty with an 8 millimeter balloon and then place the catheter. One additional case, however, do the balloon angioplasty but we were still not able to place the catheter and we had to go to another site.

Seven of these lesions underwent balloon angioplasty of the innominate vein. 11 of them were in the proximal internal jugular vein, and two of them were in the superior vena cava. We had no subsequent severe swelling of the neck, arm, or face,

despite having a stenotic vein that we just put a catheter into, and no subsequent DVT on duplexes that were obtained after these procedures. Based on these data, we suggest that venous balloon angioplasty can be used in these patients

to maintain the site of an access, even with the stenotic vein that if your wire doesn't go down on the first pass, don't abandon the vein, shoot a little dye, see what the problem is,

and you may be able to use that vein still and maintain the other arm for AV access or fistular graft or whatever they need. Based upon these data, we feel that using ultrasound guidance should be a routine portion of these procedures,

and venoplasty should be performed when the wire is not passing for a central vein problem. Thank you.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

- 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 (mumbles) and thank you Dr. Veith for the kind invitation to participate in this amazing meeting. This is work from Hamburg mainly and we all know that TEVAR is the first endovascular treatment of choice but a third of our patients will fail to remodel and that's due to the consistent and persistent

flow in the false lumen over the re-entrance in the thoracoabdominal aorta. Therefore it makes sense to try to divide the compartments of the aorta and try to occlude flow in the false lumen and this can be tried by several means as coils, plug and glue

but also iliac occluders but they all have the disadvantage that they don't get over 24 mm which is usually not enough to occlude the false lumen. Therefore my colleague, Tilo Kolbel came up with this first idea with using

a pre-bulged stent graft at the midportion which after ballooning disrupts the dissection membrane and opposes the outer wall and therefore occludes backflow into the aneurysm sac in the thoracic segment, but the most convenient

and easy to use tool is the candy-plug which is a double tapered endograft with a midsegment that is 18 mm and once implanted in the false lumen at the level of the supraceliac aorta it occludes the backflow in the false lumen in the thoracic aorta

and we have seen very good remodeling with this approach. You see here a patient who completely regressed over three years and it also answers the question how it behaves with respect to true and false lumen. The true lumen always wins and because once

the false lumen thrombosis and the true lumen also has the arterial pressure it does prevail. These are the results from Hamburg with an experience of 33 patients and also the international experience with the CMD device that has been implanted in more than 20 cases worldwide

and we can see that the interprocedural technical success is extremely high, 100% with no irrelevant complications and also a complete false lumen that is very high, up to 95%. This is the evolvement of the candy-plug

over the years. It started as a surgeon modified graft just making a tie around one of the stents evolving to a CMD and then the last generation candy-plug II that came up 2017 and the difference, or the new aspect

of the candy-plug II is that it has a sleeve inside and therefore you can retrieve the dilator without having to put another central occluder or a plug in the central portion. Therefore when the dilator is outside of the sleeve the backflow occludes the sleeve

and you don't have to do anything else, but you have to be careful not to dislodge the whole stent graft while retrieving the dilator. This is a case of a patient with post (mumbles) dissection.

This is the technique of how we do it, access to the false lumen and deployment of the stent graft in the false lumen next to the true lumen stent graft being conscious of the fact that you don't go below the edge of the true lumen endograft

to avoid (mumbles) and the final angiography showing no backflow in the aneurysm. This is how we measure and it's quite simple. You just need about a centimeter in the supraceliac aorta where it's not massively dilated and then you just do an over-sizing

in the false lumen according to the Croissant technique as Ste-phan He-lo-sa has described by 10 to 30% and what is very important is that in these cases you don't burn any bridges. You can still have a good treatment

of the thoracic component and come back and do the fenestrated branch repair for the thoracoabdominal aorta if you have to. Thank you very much for your attention. (applause)

- Thanks Dr. Weaver. Thank you Dr. Reed for the invitation, once again, to this great meeting. These are my disclosures. So, open surgical repair of descending aortic arch disease still carries some significant morbidity and mortality.

And obviously TEVAR as we have mentioned in many of the presentations has become the treatment of choice for appropriate thoracic lesions, but still has some significant limitations of seal in the aortic arch and more techniques are being developed to address that.

Right now, we also need to cover the left subclavian artery and encroach or cover the left common carotid artery for optimal seal, if that's the area that we're trying to address. So zone 2, which is the one that's,

it is most commonly used as seal for the aortic arch requires accurate device deployment to maximize the seal and really avoid ultimately, coverage of the left common carotid artery and have to address it as an emergency. Seal, in many of these cases is not maximized

due to the concern of occlusion of the left common carotid artery and many of the devices are deployed without obtaining maximum seal in that particular area. Failure of accurate deployment often leads to a type IA endoleak or inadvertent coverage

of the left common carotid artery which can become a significant problem. The most common hybrid procedures in this group of patients include the use of TEVAR, a carotid-subclavian reconstruction and left common carotid artery stenting,

which is hopefully mostly planned, but many of the times, especially when you're starting, it may be completely unplanned. The left common carotid chimney has been increasingly used to obtain a better seal

in this particular group of patients with challenging arches, but there's still significant concerns, including patients having super-vascular complications, stroke, Type A retrograde dissections and a persistent Type IA endoleak

which can be very challenging to be able to correct. There's limited data to discuss this specific topic, but some of the recent publications included a series of 11 to 13 years of treatment with a variety of chimneys.

And these publications suggest that the left common carotid chimneys are the most commonly used chimneys in the aortic arch, being used 76% to 89% of the time in these series. We can also look at these and the technical success

is very good. Mortality's very low. The stroke rate is quite variable depending on the series and chimney patency's very good. But we still have a relatively high persistent

Type IA endoleak on these procedures. So what can we do to try to improve the results that we have? And some of these techniques are clearly applicable for elective or emergency procedures. In the elective setting,

an open left carotid access and subclavian access can be obtained via a supraclavicular approach. And then a subclavian transposition or a carotid-subclavian bypass can be performed in preparation for the endovascular repair. Following that reconstruction,

retrograde access to left common carotid artery can be very helpful with a 7 French sheath and this can be used for diagnostic and therapeutic purposes at the same time. The 7 French sheath can easily accommodate most of the available covered and uncovered

balloon expandable stents if the situation arises that it's necessary. Alignment of the TEVAR is critical with maximum seal and accurate placement of the TEVAR at this location is paramount to be able to have a good result.

At that point, the left common carotid artery chimney can be deployed under control of the left common carotid artery. To avoid any embolization, the carotid can be flushed, primary repaired, and the subclavian can be addressed

if there is concern of a persistent retrograde leak with embolization with a plug or other devices. The order can be changed for the procedure to be able to be done emergently as it is in this 46 year old policeman with hypertension and a ruptured thoracic aneurism.

The patient had the left common carotid access first, the device deployed appropriately, and the carotid-subclavian bypass performed in a more elective fashion after the rupture had been addressed. So, in conclusion, carotid chimney's and TEVAR

combination is a frequently used to obtain additional seal on the aortic arch, with pretty good results. Early retrograde left common carotid access allows safe TEVAR deployment with maximum seal,

and the procedure can be safely performed with low morbidity and mortality if we select the patients appropriately. Thank you very much.

- Thank you Professor Veith. Thank you for giving me the opportunity to present on behalf of my chief the results of the IRONGUARD 2 study. A study on the use of the C-Guard mesh covered stent in carotid artery stenting. The IRONGUARD 1 study performed in Italy,

enrolled 200 patients to the technical success of 100%. No major cardiovascular event. Those good results were maintained at one year followup, because we had no major neurologic adverse event, no stent thrombosis, and no external carotid occlusion. This is why we decided to continue to collect data

on this experience on the use of C-Guard stent in a new registry called the IRONGUARD 2. And up to August 2018, we recruited 342 patients in 15 Italian centers. Demographic of patients were a common demographic of at-risk carotid patients.

And 50 out of 342 patients were symptomatic, with 36 carotid with TIA and 14 with minor stroke. Stenosis percentage mean was 84%, and the high-risk carotid plaque composition was observed in 28% of patients, and respectively, the majority of patients presented

this homogenous composition. All aortic arch morphologies were enrolled into the study, as you can see here. And one third of enrolled patients presented significant supra-aortic vessel tortuosity. So this was no commerce registry.

Almost in all cases a transfemoral approach was chosen, while also brachial and transcervical approach were reported. And the Embolic Protection Device was used in 99.7% of patients, with a proximal occlusion device in 50 patients.

Pre-dilatation was used in 89 patients, and looking at results at 24 hours we reported five TIAs and one minor stroke, with a combined incidence rate of 1.75%. We had no myocardial infection, and no death. But we had two external carotid occlusion.

At one month, we had data available on 255 patients, with two additional neurological events, one more TIA and one more minor stroke, but we had no stent thrombosis. At one month, the cumulative results rate were a minor stroke rate of 0.58%,

and the TIA rate of 1.72%, with a cumulative neurological event rate of 2.33%. At one year, results were available on 57 patients, with one new major event, it was a myocardial infarction. And unfortunately, we had two deaths, one from suicide. To conclude, this is an ongoing trial with ongoing analysis,

and so we are still recruiting patients. I want to thank on behalf of my chief all the collaborators of this registry. I want to invite you to join us next May in Rome, thank you.

- Thank you. 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.

- So I'd like to thank Dr. Ascher, Dr. Sidawy, Dr. Veith, and the organizers for allowing us to present some data. We have no disclosures. The cephalic arch is defined as two centimeters from the confluence of the cephalic vein to either the auxiliary/subclavian vein. Stenosis in this area occurs about 39%

in brachiocephalic fistulas and about 2% in radiocephalic fistulas. Several pre-existing diseases can lead to the stenosis. High flows have been documented to lead to the stenosis. Acute angles. And also there is a valve within the area.

They're generally short, focal in nature, and they're associated with a high rate of thrombosis after intervention. They have been associated with turbulent flow. Associated with pre-existing thickening.

If you do anatomic analysis, about 20% of all the cephalic veins will have that. This tight anatomical angle linked to the muscle that surrounds it associated with this one particular peculiar valve, about three millimeters from the confluence.

And it's interesting, it's common in non-diabetics. Predictors if you are looking for it, other than ultrasound which may not find it, is calcium-phosphate product, platelet count that's high, and access flow.

If one looks at interventions that have commonly been reported, one will find that both angioplasty and stenting of this area has a relatively low primary patency with no really discrimination between using just the balloon or stent.

The cumulative patency is higher, but really again, deployment of an angioplasty balloon or deployment of a stent makes really no significant difference. This has been associated with residual stenosis

greater than 30% as one reason it fails, and also the presence of diabetes. And so there is this sort of conundrum where it's present in more non-diabetics, but yet diabetics have more of a problem. This has led to people looking to other alternatives,

including stent grafts. And in this particular paper, they did not look at primary stent grafting for a cephalic arch stenosis, but mainly treating the recurrent stenosis. And you can see clearly that the top line in the graph,

the stent graft has a superior outcome. And this is from their paper, showing as all good paper figures should show, a perfect outcome for the intervention. Another paper looked at a randomized trial in this area and also found that stent grafts,

at least in the short period of time, just given the numbers at risk in this study, which was out after months, also had a significant change in the patency. And in their own words, they changed their practice and now stent graft

rather than use either angioplasty or bare-metal stents. I will tell you that cutting balloons have been used. And I will tell you that drug-eluting balloons have been used. The data is too small and inconclusive to make a difference. We chose a different view.

We asked a simple question. Whether or not these stenoses could be best treated with angioplasty, bare-metal stenting, or two other adjuncts that are certainly related, which is either a transposition or a bypass.

And what we found is that the surgical results definitely give greater long-term patency and greater functional results. And you can see that whether you choose either a transposition or a bypass, you will get superior primary results.

And you will also get superior secondary results. And this is gladly also associated with less recurrent interventions in the ongoing period. So in conclusion, cephalic arch remains a significant cause of brachiocephalic AV malfunction.

Angioplasty, across the literature, has poor outcomes. Stent grafting offers the best outcomes rather than bare-metal stenting. We have insufficient data with other modalities, drug-eluting stents, drug-eluting balloons,

cutting balloons. In the correct patient, surgical options will offer superior long-term results and functional results. And thus, in the good, well-selected patient, surgical interventions should be considered

earlier in this treatment rather than moving ahead with angioplasty stent and then stent graft. Thank you so much.

- I think by definition this whole session today has been about challenging vascular access cases. Here's my disclosures. I went into vascular surgery, I think I made the decision when I was either a fourth year medical student or early on in internship because

what intrigued me the most was that it seemed like vascular surgeons were only limited by their imagination in what we could do to help our patients and I think these access challenges are perfect examples of this. There's going to be a couple talks coming up

about central vein occlusion so I won't be really touching on that. I just have a couple of examples of what I consider challenging cases. So where do the challenges exist? Well, first, in creating an access,

we may have a challenge in trying to figure out what's going to be the best new access for a patient who's not ever had one. Then we are frequently faced with challenges of re-establishing an AV fistula or an AV graft for a patient.

This may be for someone who's had a complication requiring removal of their access, or the patient who was fortunate to get a transplant but then ended up with a transplant rejection and now you need to re-establish access. There's definitely a lot of clinical challenges

maintaining access: Treating anastomotic lesions, cannulation zone lesions, and venous outflow pathology. And we just heard a nice presentation about some of the complications of bleeding, infection, and ischemia. So I'll just start with a case of a patient

who needed to establish access. So this is a 37-year-old African-American female. She's got oxygen-dependent COPD and she's still smoking. Her BMI is 37, she's left handed, she has diabetes, and she has lupus. Her access to date - now she's been on hemodialysis

for six months, all through multiple tunneled catheters that have been repeatedly having to be removed for infection and she was actually transferred from one of our more rural hospitals into town because she had a infected tunneled dialysis catheter in her femoral region.

She had been deemed a very poor candidate for an AV fistula or AV graft because of small veins. So the challenges - she is morbidly obese, she needs immediate access, and she has suboptimal anatomy. So our plan, again, she's left handed. We decided to do a right upper extremity graft

but the plan was to first explore her axillary vein and do a venogram. So in doing that, we explored her axillary vein, did a venogram, and you can see she's got fairly extensive central vein disease already. Now, she had had multiple catheters.

So this is a venogram through a 5-French sheath in the brachial vein in the axilla, showing a diffusely diseased central vein. So at this point, the decision was made to go ahead and angioplasty the vein with a 9-millimeter balloon through a 9-French sheath.

And we got a pretty reasonable result to create venous outflow for our planned graft. You can see in the image there, for my venous outflow I've placed a Gore Hybrid graft and extended that with a Viabahn to help support the central vein disease. And now to try and get rid of her catheters,

we went ahead and did a tapered 4-7 Acuseal graft connected to the brachial artery in the axilla. And we chose the taper mostly because, as you can see, she has a pretty small high brachial artery in her axilla. And then we connected the Acuseal graft to the other end of the Gore Hybrid graft,

so at least in the cannulation zone we have an immediate cannualation graft. And this is the venous limb of the graft connected into the Gore hybrid graft, which then communicates directly into the axillary vein and brachiocephalic vein.

So we were able to establish a graft for this patient that could be used immediately, get rid of her tunneled catheter. Again, the challenges were she's morbidly obese, she needs immediate access, and she has suboptimal anatomy, and the solution was a right upper arm loop AV graft

with an early cannulation segment to immediately get rid of her tunneled catheter. Then we used the Gore Hybrid graft with the 9-millimeter nitinol-reinforced segment to help deal with the preexisting venous outflow disease that she had, and we were able to keep this patient

free of a catheter with a functioning access for about 13 months. So here's another case. This is in a steal patient, so I think it's incredibly important that every patient that presents with access-induced ischemia to have a complete angiogram

of the extremity to make sure they don't have occult inflow disease, which we occasionally see. So this patient had a functioning upper arm graft and developed pretty severe ischemic pain in her hand. So you can see, here's the graft, venous outflow, and she actually has,

for the steal patients we see, she actually had pretty decent flow down her brachial artery and radial and ulnar artery even into the hand, even with the graft patent, which is usually not the case. In fact, we really challenged the diagnosis of ischemia for quite some time, but the pressures that she had,

her digital-brachial index was less than 0.5. So we went ahead and did a drill. We've tried to eliminate the morbidity of the drill bit - so we now do 100% of our drills when we're going to use saphenous vein with endoscopic vein harvest, which it's basically an outpatient procedure now,

and we've had very good success. And here you can see the completion angiogram and just the difference in her hand perfusion. And then the final case, this is a patient that got an AV graft created at the access center by an interventional nephrologist,

and in the ensuing seven months was treated seven different times for problems, showed up at my office with a cold blue hand. When we duplexed her, we couldn't see any flow beyond the AV graft anastomosis. So I chose to do a transfemoral arteriogram

and what you can see here, she's got a completely dissected subclavian axillary artery, and this goes all the way into her arterial anastomosis. So this is all completely dissected from one of her interventions at the access center. And this is the kind of case that reminded me

of one of my mentors, Roger Gregory. He used to say, "I don't wan "I just want out of the trap." So what we ended up doing was, I actually couldn't get into the true lumen from antegrade, so I retrograde accessed

her brachial artery and was able to just re-establish flow all the way down. I ended up intentionally covering the entry into her AV graft to get that out of the circuit and just recover her hand, and she's actually been catheter-dependent ever since

because she really didn't want to take any more chances. Thank you very much.

- Thank you (mumbles). The purpose of deep venous valve repair is to correct the reflux. And we have different type of reflux. We know we have primary, secondary, the much more frequent and the rear valve agenesia. In primary deep venous incompetence,

valves are usually present but they are malfunctioning and the internal valvuloplasty is undoubtedly the best option. If we have a valve we can repair it and the results are undoubtedly the better of all deep vein surgery reconstruction

but when we are in the congenital absence of valve which is probably the worst situation or we are in post-thrombotic syndrome where cusps are fully destroyed, the situation is totally different. In this situation, we need alternative technique

to provide a reflux correction that may be transposition, new valve or valve transplants. The mono cuspid valve is an option between those and we can obtain it by parietal dissection. We use the fibrotic tissue determined by the

sickening of the PTS event obtaining a kind of flap that we call valve but as you can realize is absolutely something different from a native valve. The morphology may change depending on the wall feature and the wall thickness

but we have to manage the failure of the mono cuspid valve which is mainly due to the readhesion of the flap which is caused by the fact that if we have only a mono cuspid valve, we need a deeper pocket to reach the contralateral wall so bicuspid valve we have

smaller cusps in mono cuspid we have a larger one. And how can we prevent readhesion? In our first moment we can apply a technical element which is to stabilize the valve in the semi-open position in order not to have the collapse of the valve with itself and then we had decide to apply an hemodynamic element.

Whenever possible, the valve is created in front of a vein confluence. In this way we can obtain a kind of competing flow, a better washout and a more mobile flap. This is undoubtedly a situation that is not present in nature but helps in providing non-collapse

and non-thrombotic events in the cusp itself. In fact, if we look at the mathematical modeling in the flow on valve you can see how it does work in a bicuspid but when we are in a mono cuspid, you see that in the bottom of the flap

we have no flow and here there is the risk of thrombosis and here there is the risk of collapse. If we go to a competing flow pattern, the flap is washed out alternatively from one side to the other side and this suggest us the idea to go through a mono cuspid

valve which is not just opens forward during but is endovascular and in fact that's what we are working on. Undoubtedly open surgery at the present is the only available solution but we realized that obviously to have the possibility

to have an endovascular approach may be totally different. As you can understand we move out from the concept to mimic nature. We are not able to provide the same anatomy, the same structure of a valve and we have to put

in the field the possibility to have no thrombosis and much more mobile flap. This is the lesson we learn from many years of surgery. The problem is the mobile flap and the thrombosis inside the flap itself. The final result of a valve reconstruction

disregarding the type of method we apply is to obtain an anti-reflux mechanism. It is not a valve, it is just an anti-reflux mechanism but it can be a great opportunity for patient presenting a deep vein reflux that strongly affected their quality of life.

Thank you.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

- Thank you, Tim, and thank you, Frank, for giving me the opportunity to address this specific problem of the gutter endoleaks, which has been described up to 30% after ChEVAR and parallel grafting. But I have to say that in the most papers, not only gutter endoleaks were included,

but also new onset of type Ia endoleak. One paper coming from Stanford addressed specifically the question, how we should deal with the gutter-related type Ia endoleak, and they conclude that in the vast majority of the cases, these gutter endoleaks disappear

and the situation is benign. And based on my own experience, I can confirm this. This is one of the first cases treated with parallel grafts for symptomatic thoracoabdominal aneurysm. And I was a bit concerned as I saw this endoleak at the end of the angiography,

but the lady didn't have any pains and also no option for open or for other type of repair, so we waited. We waited and we saw that the endoleak disappeared after one month. And we saw also shrinkage of the aneurysm after one year.

So now, the next question was how to prevent this. And from the PERICLES registry, but also from the PROTAGORAS, we learned how to deal with this and how to prevent. And it's extremely important to oversize enough the aortic stent graft,

more than treating with the EVAR, normal EVAR. We should reach a sealing zone of at least 15, 20 millimeters. And we should avoid also to use more than two chimney grafts in such patients. The greater the number of the chimney used,

the higher is the risk of type Ia endoleak. And last but not least, we should use the right stent graft. And you see here the CT scan after using a flexible nitinol skeleton endograft on the left, and the gutters if you use a very stiff,

stainless steel skeleton in such situations. The last question was how to treat these patients. And based on the PERICLES, again, we should distinguish three different patterns. One is due to an excessive oversizing of the graft with infolding.

I have only one case, one professor of pathology, treated six years ago now without any endoleak due to this problem. The most are due to an undersized aortic endograft. And in the pattern C, we have an insufficient sealing zone and migration of the graft.

Now, we should consider the pattern B. And with an undersized aortic endograft and if the gutter is small, one possible solution would be to treat this patient with coiling, using coils or Onyx to occlude this gutter endoleaks,

like in this patient. And for the pattern C, if the sealing zone is insufficient, well, we should extend the sealing zone using the chimney parallel technique, as you can see in this case. So in conclusion, ladies and gentle,

gutters are usually benign and more than 95% disappeared in the follow-up. But in case of persistence, we should evaluate the CT scan exactly. And in case of oversizing and not enough oversizing and not enough length,

we should treat this patient accordingly. Thank you very much for your attention.

- I'd like to share with you our experience using tools to improve outcomes. These are my disclosures. So first of all we need to define the anatomy well using CTA and MRA and with using multiple reformats and 3D reconstructions. So then we can use 3D fusion with a DSA or with a flouro

or in this case as I showed in my presentation before you can use a DSA fused with a CT phase, they were required before. And also you can use the Integrated Registration like this, when you can use very helpful for the RF wire

because you can see where the RF wire starts and the snare ends. We can also use this for the arterial system. I can see a high grade stenosis in the Common iliac and you can use the 3D to define for your 3D roadmapping you can use on the table,

or you can use two methods to define the artery. Usually you can use the yellow outline to define the anatomy or the green to define the center. And then it's a simple case, 50 minutes, 50 minutes of ccs of contrast,

very simple, straightforward. Another everybody knows about the you know we can use a small amount of contrast to define the whole anatomy of one leg. However one thing that is relatively new is to use a 3D

in order to map, to show you the way out so you can do in this case here multiple segmental synosis, the drug-eluting-balloon angioplasty using the 3D roadmap as a reference. Also about this case using radial fre--

radial access to peripheral. Using a fusion of image you can see the outline of the artery. You can see where the high grade stenosis is with a minimum amount of contrast. You only use contrast when you are about

to do your angiogram or your angioplasty and after. And that but all everything else you use only the guide wires and cathers are advanced only used in image guidance without any contrast at all. We also been doing as I showed before the simultaneous injection.

So here I have two catheters, one coming from above, one coming from below to define this intravenous occlusion. Very helpful during through the and after the 3D it can be helpful. Like in this case when you can see this orange line is where

the RF wire is going to be advanced. As you can see the breathing, during the breathing cycle the pleura is on the way of the RF wire track. Pretty dangerous stuff. So this case what we did we asked the anesthesiologist

to have the patient in respiratory breath holding inspiration. We're able to hyperextend the lungs, cross with the RF wire without any complication. So very useful. And also you can use this outline yellow lines here

to define anatomy can help you to define where you need to put the stents. Make sure you're covering everything and having better outcomes at the end of the case without overexposure of radiation. And also at the end you can use the same volt of metric

reconstruction to check where you are, to placement of the stent and if you'd covered all the lesion that you had. The Cone beam CT can be used for also for the 3D model fusion. As you can see that you can use in it with fluoro as I

mentioned before you can do the three views in order to make sure that the vessels are aligned. And those are they follow when you rotate the table. And then you can have a pretty good outcome at the end of the day at of the case. In that case that potentially could be very catastrophic

close to the Supra aortic vessels. What about this case of a very dramatic, symptomatic varicose veins. We didn't know and didn't even know where to start in this case. We're trying to find our way through here trying to

understand what we needed to do. I thought we need to recanalize this with this. Did a 3D recan-- a spin and we saw ours totally off. This is the RFY totally interior and the snare as a target was posterior in the ASGUS.

Totally different, different plans. Eventually we found where we needed to be. We fused with the CAT scan, CT phase before, found the right spot and then were able to use

Integrated registration for the careful recanalization above the strip-- interiorly from the Supraaortic vessels. As you can see that's the beginning, that's the end. And also these was important to show us where we working.

We working a very small space between the sternal and the Supraaortic vessels using the RF wire. And this the only technology would allowed us to do this type of thing. Basically we created a percutaneous in the vascular stent bypass graft.

You can you see you use a curved RF wire to be able to go back to the snare. And that once we snare out is just conventional angioplasty recanalized with covered stents and pretty good outcome. On a year and a half follow-up remarkable improvement in this patient's symptoms.

Another patient with a large graft in the large swelling thigh, maybe graft on the right thigh with associated occlusion of the iliac veins and inclusion of the IVC and occlusion of the filter. So we did here is that we fused the maps of the arterial

phase and the venous phase and then we reconstruct in a 3D model. And doing that we're able to really understand the beginning of the problem and the end of the problem above the filter and the correlation with the arteries. So as you can see,

the these was very tortuous segments. We need to cross with the RF wire close to the iliac veins and then to the External iliac artery close to the Common iliac artery. But eventually we were able to help find a track. Very successfully,

very safe and then it's just convention technique. We reconstructed with covered stents. This is predisposed, pretty good outcome. As you can see this is the CT before, that's the CT after the swelling's totally gone

and the stents are widely open. So in conclusion these techniques can help a reduction of radiation exposure, volume of contrast media, lower complication, lower procedure time.

In other words can offer higher value in patient care. Thank you.

- Thank you. Here are my disclosures. Our preferred method for zone one TAVR has evolved to a carotid/carotid transposition and left subclavian retro-sandwich. The technique begins with a low transverse collar incision. The incision is deepened through the platysma

and subplatysmal flaps are then elevated. The dissection is continued along the anterior border of the sternocleidomastoid entering the carotid sheath anteromedial to the jugular vein. The common carotid artery is exposed

and controlled with a vessel loop. (mumbling) The exposure's repeated for the left common carotid artery and extended as far proximal to the omohyoid muscle as possible. A retropharyngeal plane is created using blunt dissection

along the anterior border of the cervical vertebra. A tunneling clamp is then utilized to preserve the plane with umbilical tape. Additional vessel loops are placed in the distal and mid right common carotid artery and the patient is systemically anticoagulated.

The proximal and distal vessel loops are tightened and a transverse arteriotomy is created between the middle and distal vessel loops. A flexible shunt is inserted and initially secured with the proximal and middle vessel loops. (whistling)

It is then advanced beyond the proximal vessel loop and secured into that position. The left common carotid artery is then clamped proximally and distally, suture ligated, clipped and then transected. (mumbling)

The proximal end is then brought through the retropharyngeal tunnel. - [Surgeon] It's found to have (mumbles). - An end-to-side carotid anastomosis is then created between the proximal and middle vessel loops. If preferred the right carotid arteriotomy

can be made ovoid with scissors or a punch to provide a better shape match with the recipient vessel. The complete anastomosis is back-bled and carefully flushed out the distal right carotid arteriotomy.

Flow is then restored to the left carotid artery, I mean to the right carotid artery or to the left carotid artery by tightening the middle vessel loop and loosening the proximal vessel loop. The shunt can then be removed

and the right common carotid artery safely clamped distal to the transposition. The distal arteriotomy is then closed in standard fashion and flow is restored to the right common carotid artery. This technique avoids a prosthetic graft

and the retropharyngeal space while maintaining flow in at least one carotid system at all times. Once, and here's a view of the vessels, once hemostasis is assured the platysma is reapproximated with a running suture followed by a subcuticular stitch

for an excellent cosmetic result. Our preferred method for left subclavian preservation is the retro-sandwich technique which involves deploying an initial endograft just distal to the left subclavian followed by both proximal aortic extension

and a left subclavian covered stent in parallel fashion. We prefer this configuration because it provides a second source of cerebral blood flow independent of the innominate artery

and maintains ready access to the renovisceral vessels if further aortic intervention is required in the future. Thank you.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

- Thank you for asking me to speak. Thank you Dr Veith. I have no disclosures. I'm going to start with a quick case again of a 70 year old female presented with right lower extremity rest pain and non-healing wound at the right first toe

and left lower extremity claudication. She had non-palpable femoral and distal pulses, her ABIs were calcified but she had decreased wave forms. Prior anterior gram showed the following extensive aortoiliac occlusive disease due to the small size we went ahead and did a CT scan and confirmed.

She had a very small aorta measuring 14 millimeters in outer diameter and circumferential calcium of her aorta as well as proximal common iliac arteries. Due to this we treated her with a right common femoral artery cutdown and an antegrade approach to her SFA occlusion with a stent.

We then converted the sheath to a retrograde approach, place a percutaneous left common femoral artery access and then placed an Endologix AFX device with a 23 millimeter main body at the aortic bifurcation. We then ballooned both the aorta and iliac arteries and then placed bilateral balloon expandable

kissing iliac stents to stent the outflow. Here is our pre, intra, and post operative films. She did well. Her rest pain resolved, her first toe amputation healed, we followed her for about 10 months. She also has an AV access and had a left arterial steel

on a left upper extremity so last week I was able to undergo repeat arteriogram and this is at 10 months out. We can see that he stent remains open with good flow and no evidence of in stent stenosis. There's very little literature about using endografts for occlusive disease.

Van Haren looked at 10 patients with TASC-D lesions that were felt to be high risk for aorta bifem using the Endologix AFX device. And noted 100% technical success rate. Eight patients did require additional stent placements. There was 100% resolution of the symptoms

with improved ABIs bilaterally. At 40 months follow up there's a primary patency rate of 80% and secondary of 100% with one acute limb occlusion. Zander et all, using the Excluder prothesis, looked at 14 high risk patients for aorta bifem with TASC-C and D lesions of the aorta.

Similarly they noted 100% technical success. Nine patients required additional stenting, all patients had resolution of their symptoms and improvement of their ABIs. At 62 months follow up they noted a primary patency rate of 85% and secondary of 100

with two acute limb occlusions. The indications for this procedure in general are symptomatic patient with a TASC C or D lesion that's felt to either be a high operative risk for aorta bifem or have a significantly calcified aorta where clamping would be difficult as we saw in our patient.

These patients are usually being considered for axillary bifemoral bypass. Some technical tips. Access can be done percutaneously through a cutdown. I do recommend a cutdown if there's femoral disease so you can preform a femoral endarterectomy and

profundaplasty at the same time. Brachial access is also an alternative option. Due to the small size and disease vessels, graft placement may be difficult and may require predilation with either the endograft sheath dilator or high-pressure balloon.

In calcified vessels you may need to place covered stents in order to pass the graft to avoid rupture. Due to the poor radial force of endografts, the graft must be ballooned after placement with either an aortic occlusion balloon but usually high-pressure balloons are needed.

It usually also needs to be reinforced the outflow with either self-expanding or balloon expandable stents to prevent limb occlusion. Some precautions. If the vessels are calcified and tortuous again there may be difficult graft delivery.

In patients with occluded vessels standard techniques for crossing can be used, however will require pre-dilation before endograft positioning. If you have a sub intimal cannulation this does put the vessel at risk for rupture during

balloon dilation. Small aortic diameters may occlude limbs particularly using modular devices. And most importantly, the outflow must be optimized using stents distally if needed in the iliac arteries, but even more importantly, assuring that you've

treated the femoral artery and outflow to the profunda. Despite these good results, endograft use for occlusive disease is off label use and therefor not reimbursed. In comparison to open stents, endograft use is expensive and may not be cost effective. There's no current studies looking

into the cost/benefit ratio. Thank you.

So I think when it comes to distal bypasses and ultra-distal bypasses it's all about how we make our decision. We know now that early intervention these patients have better outcome. We use waveform analysis to make our decision about how critical their skin is

we use different topical anesthesia depending the patient's fitness. I think this is just one important point that patient's with dark skin did not show all the full range of skin changes and patients get this dark foot sign

even before they start necrosing their skin. It's very important how we give our anesthetics we use vascular anesthesia with special interest prevascular disease because these patients are quite labile. We use even sometimes inotropes during the procedure

and post operative to maintain a good blood pressure. We believe that short bypasses have got better outcomes. Dr. Veith, have already published in the 80s about short bypasses also doing now the Tibiotibial bypasses on the look anesthetic. Some patients with very high risk for general anesthesia.

And our study we showed that the majority of our patients, who had ultra-distal bypasses had the bypasses from either popliteal or SFA artery. We use different techniques to improve on how to take our bypasses from the proximal anastomosis distally. So we use hybrid revascularization, we use drug-eluting

balloons, and stenting of the SFA and popliteal artery, so we can perform our bypass from the popliteal level. We even use Remote Endarterectomy to improve on our length of the inflow. So by doing remote endarterectomy of the SFA

and popliteal artery, we can take the bypass quite distally from the popliteal artery to the foot level. This is a patient who got critical leg ischaemia on the right side limited, venous conduit. We did remote endarterectomy of her SFA and popliteal artery. And then we can

easily take the bypass from the popliteal artery down to the foot level. On the left side, she had hybrid revascularization with SFA stenting and ultra-distal bypass. We use venous conduit in almost all our patients with ultra-distal bypass.

In distal bypasses we can PTFE but the majority of our patients have long saphenous veins or even arm veins. We started using Omniflow in our infected patients for distal bypasses with quite good results. We scan all our veins prior to the procedure

to make sure that we got good quality vein and amount to perform the procedure. We have published in our small veins series less than 3mm, we still have a very good outcome in distal bypasses. Especially when we do tibial bypasses

or dorsalis pedis bypasses we turn the grafts anatomically. You can see in this angiogram the graft going through the interosseous membrane down to the foot level. We put our incision a bit immediately on the foot level so if there is necrosis of the wound on the foot level that we don't expose the graft, especially when we

knew the patient was coming from the lateral aspect through the interosseous membrane. We select our bypasses especially in the foot level using the duplic scanogram, angiogram or CT angiogram. During the procedure we don't clamp our arteries we use the Flo-Rester and Flo-Through prothesis

to stop patients from bleeding while we're doing it. And we've never used tourniquet before all this has been published. Hand held doppler is the only quality control that we do we don't do on-table angiograms and we find this quite useful for our patients.

We can do the debridement and at the same time while we're doing the bypass at the ankle level. As for anticoagulation and antiplatelet therapy We do antiplatelet therapy for all patient with distal and ultra-distal bypass. And we use heparin and warfarin for patients

who have got redo surgery. Graft surveillance for all our patients Unfortunately, we can only afford it in the NHS for one year, but if the patient get an intervention they go for another full year. Salvage angioplasty is essential for these patients

and we treat these patients as quite as a emergency when they present. So, conclusion, Mr. Sherman, ladies and gentlemen, distal and ultra-distal bypasses require good planning. We use veins for all our bypasses when it comes to the foot level and ultra-distal bypasses,

and of course selecting the target vessel in the foot is very important. Graft Surveillance is essential to maintain quality and outcome for these patients. Thank you very much.

- Thank you very much, so my disclosures, I'm one of the co-PIs for national registry for ANARI. And clearly venous clot is different, requires different solutions for the arterial system. So this is a device that was built ground up to work in the venous system. And here's a case presentation of a 53 year old male,

with a history of spondylolisthesis had a lumbar inner body fusion, he had an anterior approach and corpectomy with application of an inner body cage. And you can see these devices here. And notably he had application of local bone graft and bone powder

and this is part of what happened to this patient. About seven days later he came in with significant left leg swelling and venous duplex showed clot right here, and this extended all the way down to the tibial vessels. And if you look at the CT

you can see extravasation of that bone powder and material obstructing the left iliac vein. And had severe leg swelling so the orthopedic people didn't want us to use TPA in this patient so we considered a mechanical solution. And so at this day and age I think goals of intervention

should be to maximize clot removal of course and minimize bleeding risk and reduce the treatment or infusion time and go to single session therapy whenever possible. Our ICUs are full all the time and so putting a lytic patient in there

reduces our ability to get other patients in. (mouse clicks So this is the ClotTriever thrombectomy device. It has a sheath that is a 13 French sheath and they're developing a 16 French, that opens up with a funnel

after it's inserted into the poplitiel. So the funnel is in the lower femoral vein and this helps funnel clot in when it's pulled down. The catheter has this coring element that abuts the vein wall and carves the thrombus off in a collecting bag

that extends up above to allow the thrombus to go into the bag as you pull it down. So you access the popliteal vein, cross the thrombosed segments with standard techniques and you need to then put an exchange length wire up into the SVC

or even out into the subclavian vein for stability. And then the catheter's inserted above the clot and is gradually pulled down, sort of milking that stuff off of the wall and into the bag that is then taken down to the funnel and out of the leg.

So this is the patient we had, we had thrombus in the femoral and up into the IVC. Extensive, you can see the hardware here. And it was very obstructed right at that segment where it was, had the bone material pushing on the vein it was quite difficult to get through there

but finally we did and we ballooned that to open a channel up large enough to accommodate ClotTriever catheter. We then did multiple passes and we extracted a large amount of thrombus. Some looking like typically acute stuff

and then some more dense material that may have been a few days worth of build up on the wall there. We then stinted with an 18 by 90 across the obstructed segment and this was our completion run.

It's not perfect but it looks like a pretty good channel going through. This is the hardware not obstruction at that level. Hospital course, the patient had significant improvement in their swelling by post-op day one. Was discharged on compression and anti-coagulation.

He returned about two months ago for his three month follow-up and really had very minimal symptoms in the left leg. Venous duplex showed that the left common femoral was partially compressible but did have phasic flow and the stent appeared to be open through it's course.

So of course this is an anecdote, this is early in the experience with this catheter. There have been numerous improvements made to ease the use of it and do it in fewer steps. And so we're starting a ClotTriever outcomes registry

to enroll up to 500 patients to begin to define outcomes with this device. It does offer the promise of single session therapy without lytic administration and we'll see how it performs and which patients it works best in through the registry.

Thank you very much.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

- Great, thank-you very much, a pleasure to be here. My disclosures. So, we've talked a little bit about obviously percutaneous and thrombectomy techniques. Obviously we have catheter-directed thrombolysis with TPA, but what happens when we can't use TPA

mechanical techniques? We've discussed several of them already in this session, I'm going to try to kind of bring them together and note the differences and how they evolved. And really look at fragmentation, rheolytic therapy, vacuum assisted devices, and vacuum and suction devices.

So when do we need these? Patients that can't tolerate thrombolysis, can't get TPA, that have a high risk of TPA, or maybe there is a situation we need a rapid response. We're trying to create flow and establish flow as much as possible and a lot of times we use this

in combination therapy if we've already hurt. What's the ideal device? I think there are multiple different characteristic's that could define the ideal device. Obviously we want it simple to use, We want it to be reproducible,

we want it to remove a lot of thrombus, but minimize blood loss and trauma to the vessels and to the blood cell. These are just some of them. There's a lot of mechanical thrombectomy devices right now on the market continuing to grow,

both in the arterial and venous system so I think this is going to be an evolution. We started really using mechanical fragmentation with a pig tail and spinning a pig tail. We used that. A lot of times the patient with severe massive pulmonary embolism.

These we're really small antidotes, small case reports. Will Kuo, looked at these in the 2009 and basically saw over all clinical success, about 86% using these mechanical devices. Then we had some that were even more automated.

All these did was break up the clot. So you have the Trerotola Device , Cleaner Device, really almost in the dialysis space. Rheolytic Throbectomy, we've already heard about. Some of how it works and the advantages. Really I think this is the first time we've saw

a system which would try to aspirate and remove some of that thrombus as it got broken up. The PEARL registry really showed for the first time, maybe we can get this done within 24 hours, can we get this done in one session? Unfortunately in this registry only about three or

four percent of patients actually had just rheolytic therapy alone without any TPA. We've discussed a little bit about the use of Ango and this type of device in terms of bradyarrhythmia's and that may be a limitation. But I think we can still use it particularly

outside of the chest. So What about suction devices? You can have a catheter, I think a catheter suction device is very limited. We use that in the arterial tree when there is a small thrombus, a small embolus, I think

we're very limited, not only in the amount of thrombus we can remove but the amount of suction we can apply. Other types like almost mechanical, very simple to use systems is the aspire device. Well you can basically create and suction a

limited area and then help you aspirate the thrombus. And then to the other extreme. We're going to hear my next speaker talk about Angiovac, again a different system, a different system requires a patient on bypass large 26 french devices.

Where we can actually go in and deal with a large amount of thrombus, like this patient had a thrombus cave on both iliac veins. And to be able to basically come with this vacuum aspiration system over wires and kind of pulling them out and you get these little canisters,

seeing what you've actually removed. Very gratifying. But takes a lot of work to get it going. We've heard a little bit about vacuum assisted with the Indigo system. With a system of creating a constant continuous vacuum.

We now have eight french catheters with incredible aspiration volume, almost 20cc's, I'm sorry you can get up to 140cc's of thrombus in a minute can be aspirated quickly. Here is a patient, 80 years old, colorectal CA. You can see the thrombus in the right leg.

There was actually a mass invading this vein. That is where we wanted to use thrombolysis, really went a head and you can see the amount of thrombus. Cleared this out with some passage. You can see this here, the separator. You started seeing thrombus especially when

its acute it kind of looks like this. It's kind of gelatinous, things that we've already seen, and then went ahead and placed a stent, dilated that stent. Had to clean up some more with the device

on top of the stent, but with a good result without needing any TPA. Other types of extraction devices we've seen the Inari device, again this is like a stent Triever device, a nitinol ring we can use this in the pulmonary arteries.

And we've already seen previous and talked about the ClotTriever device Again remove that thrombus, put it into a bag and remove it. So again, capture and removal of thrombus. And this is a solution without the need of TPA. New kid in the block the JETi device

Again very similar to aspiration Indego device, but at the same time it has a jet to macerate the clot and kind of break up the clot a little to smaller areas so we can able to thromb and take more out. I think really here what I've seen and Dr. Razavi

showed me this case. Being able to treat a patient quickly, treat that patient very quickly you can see the amount of thrombus being able to, within about an hour and 15 minutes, get all that thrombus, then create patency in that vein and he showed

some early initial good data. Over the last year we did have a paper that was presented here and published this year in the Journal of Vascular Surgery, venous and lymphatic disorders and again pulled multiple patient's, again showing that

it affective and safe. We still need better data. We need to figure out which patients are best treated with which devices and which again will be affective. Thank-you very much.

- Thank you very much for the opportunity to speak carbon dioxide angiography, which is one of my favorite topics and today I will like to talk to you about the value of CO2 angiography for abdominal and pelvic trauma and why and how to use carbon dioxide angiography with massive bleeding and when to supplement CO2 with iodinated contrast.

Disclosures, none. The value of CO2 angiography, what are the advantages perhaps? Carbon dioxide is non-allergic and non-nephrotoxic contrast agent, meaning CO2 is the only proven safe contrast in patients with a contrast allergy and the renal failure.

Carbon dioxide is very highly soluble (20 to 30 times more soluble than oxygen). It's very low viscosity, which is a very unique physical property that you can take advantage of it in doing angiography and CO2 is 1/400 iodinated contrast in viscosity.

Because of low viscosity, now we can use smaller catheter, like a micro-catheter, coaxially to the angiogram using end hole catheter. You do not need five hole catheter such as Pigtail. Also, because of low viscosity, you can detect bleeding much more efficiently.

It demonstrates to the aneurysm and arteriovenous fistula. The other interesting part of the CO2 when you inject in the vessel the CO2 basically refluxes back so you can see the more central vessel. In other words, when you inject contrast, you see only forward vessel, whereas when you inject CO2,

you do a pass with not only peripheral vessels and also see more central vessels. So basically you see the vessels around the lesions and you can use unlimited volumes of CO2 if you separate two to three minutes because CO2 is exhaled by the respirations

so basically you can inject large volumes particularly when you have long prolonged procedures, and most importantly, CO2 is very inexpensive. Where there are basically two methods that will deliver CO2. One is the plastic bag system which you basically fill up with a CO2 tank three times and then empty three times

and keep the fourth time and then you connect to the delivery system and basically closest inject for DSA. The other devices, the CO2mmander with the angio assist, which I saw in the booth outside. That's FDA approved for CO2 injections and is very convenient to use.

It's called CO2mmander. So, most of the CO2 angios can be done with end hole catheter. So basically you eliminate the need for pigtail. You can use any of these cobra catheters, shepherd hook and the Simmons.

If you look at this image in the Levitor study with vascular model, when you inject end hole catheter when the CO2 exits from the tip of catheter, it forms very homogenous bolus, displaces the blood because you're imaging the blood vessel by displacing blood with contrast is mixed with blood, therefore as CO2

travels distally it maintains the CO2 density whereas contrast dilutes and lose the densities. So we recommend end hole catheter. So that means you can do an arteriogram with end hole catheter and then do a select arteriogram. You don't need to replace the pigtail

for selective injection following your aortographies. Here's the basic techniques: Now when you do CO2 angiogram, trauma patient, abdominal/pelvic traumas, start with CO2 aortography. You'll be surprised, you'll see many of those bleeding on aortogram, and also you can repeat, if necessary,

with CO2 at the multiple different levels like, celiac, renal, or aortic bifurcation but be sure to inject below diaphragm. Do not go above diaphragm, for example, thoracic aorta coronary, and brachial, and the subclavian if you inject CO2, you'll have some serious problems.

So stay below the diaphragm as an arterial contrast. Selective injection iodinated contrast for a road map. We like to do super selective arteriogram for embolization et cetera. Then use a contrast to get anomalies. Super selective injection with iodinated contrast

before embolization if there's no bleeding then repeat with CO2 because of low viscocity and also explosion of the gas you will often see the bleeding. That makes it more comfortable before embolization. Here is a splenic trauma patient.

CO2 is injected into the aorta at the level of the celiac access. Now you see the extra vascularization from the low polar spleen, then you catheterize celiac access of the veins. You microcatheter in the distal splenic arteries

and inject the contrast. Oops, there's no bleeding. Make you very uncomfortable for embolizations. We always like to see the actual vascularization before place particle or coils. At that time you can inject CO2 and you can see

actual vascularization and make you more comfortable before embolization. You can inject CO2, the selective injection like in here in a patient with the splenic trauma. The celiac injection of CO2 shows the growth, laceration splenic with extra vascularization with the gas.

There's multiple small, little collection. We call this Starry Night by Van Gogh. That means malpighian marginal sinus with stagnation with the CO2 gives multiple globular appearance of the stars called Starry Night.

You can see the early filling of the portal vein because of disruption of the intrasplenic microvascular structures. Now you see the splenic vein. Normally, you shouldn't see splenic vein while following CO2 injections.

This is a case of the liver traumas. Because the liver is a little more anterior the celiac that is coming off of the anterior aspect of the aorta, therefore, CO2 likes to go there because of buoyancy so we take advantage of buoyancy. Now you see the rupture here in this liver

with following the aortic injections then you inject contrast in the celiac axis to get road map so you can travel through this torus anatomy for embolizations for the road map for with contrast. This patient with elaston loss

with ruptured venal arteries, massive bleeding from many renal rupture with retro peritoneal bleeding with CO2 and aortic injection and then you inject contrast into renal artery and coil embolization but I think the stent is very dangerous in a patient with elaston loss.

We want to really separate the renal artery. Then you're basically at the mercy of the bleeding. So we like a very soft coil but basically coil the entire renal arteries. That was done. - Thank you very much.

- Time is over already? - Yeah. - Oh, OK. Let's finish up. Arteriogram and we inject CO2 contrast twice. Here's the final conclusions.

CO2 is a valuable imaging modality for abdominal and pelvic trauma. Start with CO2 aortography, if indicated. Repeat injections at multiple levels below diaphragm and selective injection road map with contrast. The last advice fo

t air contamination during the CO2 angiograms. Thank you.

- Thank you so much. We have no disclosures. So I think everybody would agree that the transposed basilic vein fistula is one of the most important fistulas that we currently operate with. There are many technical considerations

related to the fistula. One is whether to do one or two stage. Your local criteria may define how you do this, but, and some may do it arbitrarily. But some people would suggest that anything less than 4 mm would be a two stage,

and any one greater than 4 mm may be a one stage. The option of harvesting can be open or endovascular. The option of gaining a suitable access site can be transposition or superficialization. And the final arterial anastomosis, if you're not superficializing can either be

a new arterial anastomosis or a venovenous anastomosis. For the purposes of this talk, transposition is the dissection, transection and re tunneling of the basilic vein to the superior aspect of the arm, either as a primary or staged procedure. Superficialization is the dissection and elevation

of the basilic vein to the superior aspect of the upper arm, which may be done primarily, but most commonly is done as a staged procedure. The natural history of basilic veins with regard to nontransposed veins is very successful. And this more recent article would suggest

as you can see from the upper bands in both grafts that either transposed or non-transposed is superior to grafts in current environment. When one looks at two-stage basilic veins, they appear to be more durable and cost-effective than one-stage procedures with significantly higher

patency rates and lower rates of failure along comparable risk stratified groups from an article from the Journal of Vascular Surgery. Meta-ana, there are several meta-analysis and this one shows that between one and two stages there is really no difference in the failure and the patency rates.

The second one would suggest there is no overall difference in maturation rate, or in postoperative complication rates. With the patency rates primary assisted or secondary comparable in the majority of the papers published. And the very last one, again based on the data from the first two, also suggests there is evidence

that two stage basilic vein fistulas have higher maturation rates compared to the single stage. But I think that's probably true if one really realizes that the first stage may eliminate a lot of the poor biology that may have interfered with the one stage. But what we're really talking about is superficialization

versus transposition, which is the most favorite method. Or is there a favorite method? The early data has always suggested that transposition was superior, both in primary and in secondary patency, compared to superficialization. However, the data is contrary, as one can see,

in this paper, which showed the reverse, which is that superficialization is much superior to transposition, and in the primary patency range quite significantly. This paper reverses that theme again. So for each year that you go to the Journal of Vascular Surgery,

one gets a different data set that comes out. The final paper that was published recently at the Eastern Vascular suggested strongly that the second stage does consume more resources, when one does transposition versus superficialization. But more interestingly also found that these patients

who had the transposition had a greater high-grade re-stenosis problem at the venovenous or the veno-arterial anastomosis. Another point that they did make was that superficialization appeared to lead to faster maturation, compared to the transposition and thus they favored

superficialization over transposition. If one was to do a very rough meta-analysis and take the range of primary patencies and accumulative patencies from those papers that compare the two techniques that I've just described. Superficialization at about 12 months

for its primary patency will run about 57% range, 50-60 and transposition 53%, with a range of 49-80. So in the range of transposition area, there is a lot of people that may not be a well matched population, which may make meta-analysis in this area somewhat questionable.

But, if you get good results, you get good results. The cumulative patency, however, comes out to be closer in both groups at 78% for superficialization and 80% for transposition. So basilic vein transposition is a successful configuration. One or two stage procedures appear

to carry equally successful outcomes when appropriate selection criteria are used and the one the surgeon is most favored to use and is comfortable with. Primary patency of superficialization despite some papers, if one looks across the entire literature is equivalent to transposition.

Cumulative patency of superficialization is equivalent to transposition. And there is, appears to be no apparent difference in complications, maturation, or access duration. Thank you so much.

- [Speaker] Good morning everybody thanks for attending the session and again thanks for the invitation. These are my disclosures. I will start by illustrating one of the cases where we did not use cone beam CT and evidently there were numerous mistakes on this

from planning to conducting the case. But we didn't notice on the completion of geography in folding of the stent which was very clearly apparent on the first CT scan. Fortunately we were able to revise this and have a good outcome.

That certainly led to unnecessary re intervention. We have looked at over the years our usage of fusion and cone beam and as you can see for fenestrated cases, pretty much this was incorporated routinely in our practice in the later part of the experience.

When we looked at the study of the patients that didn't have the cone beam CT, eight percent had re intervention from a technical problem that was potentially avoidable and on the group that had cone beam CT, eight percent had findings that were immediately revised with no

re interventions that were potentially avoidable. This is the concept of our GE Discovery System with fusion and the ability to do cone beam CT. Our protocol includes two spins. First we do one without contrast to evaluate calcification and other artifacts and also to generate a rotational DSA.

That can be also analyzed on axial coronal with a 3D reconstruction. Which essentially evaluates the segment that was treated, whether it was the arch on the arch branch on a thoracoabdominal or aortoiliac segment.

We have recently conducted a prospective non-randomized study that was presented at the Vascular Annual Meeting by Dr. Tenario. On this study, we looked at findings that were to prompt an immediate re intervention that is either a type one

or a type 3 endoleak or a severe stent compression. This was a prospective study so we could be judged for being over cautious but 25% of the procedures had 52 positive findings. That included most often a stent compression or kink in 17% a type one or three endoleak

in 9% or a minority with dissection and thrombus. Evidently not all this triggered an immediate revision, but 16% we elected to treat because we thought it was potentially going to lead to a bad complication. Here is a case where on the completion selective angiography

of the SMA this apparently looks very good without any lesions. However on the cone beam CT, you can see on the axial view a dissection flap. We immediately re catheterized the SMA. You note here there is abrupt stop of the SMA.

We were unable to catheterize this with a blood wire. That led to a conversion where after proximal control we opened the SMA. There was a dissection flap which was excised using balloon control in the stent as proximal control.

We placed a patch and we got a good result with no complications. But considerably, if this patient was missed in the OR and found hours after the procedure he would have major mesenteric ischemia. On this study, DSA alone would have missed

positive findings in 34 of the 43 procedures, or 79% of the procedures that had positive findings including 21 of the 28 that triggered immediate revision. There were only four procedures. 2% had additional findings on the CT

that were not detectable by either the DSA or cone beam CT. And those were usually in the femoro puncture. For example one of the patients had a femoro puncture occlusion that was noted immediately by the femoro pulse.

The DSA accounts for approximately 20% of our total radiation dose. However, it allows us to eliminate CT post operatively which was done as part of this protocol, and therefore the amount of radiation exposed for the patient

was decreased by 55-65% in addition to the cost containment of avoiding this first CT scan in our prospective protocol. In conclusion cone beam CT has allowed immediate assessment to identify technical problems that are not easily detectable by DSA.

These immediate revisions may avoid unnecessary re interventions. What to do if you don't have it? You have to be aware that this procedure that are complex, they are bound to have some technical mistakes. You have to have incredible attention to detail.

Evidently the procedures can be done, but you would have to have a low threshold to revise. For example a flared stent if the dilator of the relic gleam or the dilator of you bifurcated devise encroach the stent during parts of the procedure. Thank you very much.

(audience applauding)

- 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)

- We are talking about the current management of bleeding hemodialysis fistulas. I have no relevant disclosures. And as we can see there with bleeding fistulas, they can occur, you can imagine that the patient is getting access three times a week so ulcerations can't develop

and if they are not checked, the scab falls out and you get subsequent bleeding that can be fatal and lead to some significant morbidity. So fatal vascular access hemorrhage. What are the causes? So number one is thinking about

the excessive anticoagulation during dialysis, specifically Heparin during the dialysis circuit as well as with cumin and Xarelto. Intentional patient manipulati we always think of that when they move,

the needles can come out and then you get subsequent bleeding. But more specifically for us, we look at more the compromising integrity of the vascular access. Looking at stenosis, thrombosis, ulceration and infection. Ellingson and others in 2012 looked at the experience

in the US specifically in Maryland. Between the years of 2000/2006, they had a total of sixteen hundred roughly dialysis death, due to fatal vascular access hemorrhage, which only accounted for about .4% of all HD or hemodialysis death but the majority did come

from AV grafts less so from central venous catheters. But interestingly that around 78% really had this hemorrhage at home so it wasn't really done or they had experienced this at the dialysis centers. At the New Zealand experience and Australia, they had over a 14 year period which

they reviewed their fatal vascular access hemorrhage and what was interesting to see that around four weeks there was an inciting infection preceding the actual event. That was more than half the patients there. There was some other patients who had decoags and revisional surgery prior to the inciting event.

So can the access be salvaged. Well, the first thing obviously is direct pressure. Try to avoid tourniquet specifically for the patients at home. If they are in the emergency department, there is obviously something that can be done.

Just to decrease the morbidity that might be associated with potential limb loss. Suture repairs is kind of the main stay when you have a patient in the emergency department. And then depending on that, you decide to go to the operating room.

Perera and others 2013 and this is an emergency department review and emergency medicine, they use cyanoacrylate to control the bleeding for very small ulcerations. They had around 10 patients and they said that they had pretty good results.

But they did not look at the long term patency of these fistulas or recurrence. An interesting way to kind of manage an ulcerated bleeding fistula is the Limberg skin flap by Pirozzi and others in 2013 where they used an adjacent skin flap, a rhomboid skin flap

and they would get that approximal distal vascular control, rotate the flap over the ulcerated lesion after excising and repairing the venotomy and doing the closure. This was limited to only ulcerations that were less than 20mm.

When you look at the results, they have around 25 AV fistulas, around 15 AV grafts. The majority of the patients were treated with percutaneous angioplasty at least within a week of surgery. Within a month, their primary patency was running 96% for those fistulas and around 80% for AV grafts.

If you look at the six months patency, 76% were still opened and the fistula group and around 40% in the AV grafts. But interesting, you would think that rotating an adjacent skin flap may lead to necrosis but they had very little necrosis

of those flaps. Inui and others at the UC San Diego looked at their experience at dialysis access hemorrhage, they had a total 26 patients, interesting the majority of those patients were AV grafts patients that had either bovine graft

or PTFE and then aneurysmal fistulas being the rest. 18 were actually seen in the ED with active bleeding and were suture control. A minor amount of patients that did require tourniquet for a shock. This is kind of the algorithm when they look at

how they approach it, you know, obviously secure your proximal di they would do a Duplex ultrasound in the OR to assess hat type of procedure

they were going to do. You know, there were inciting events were always infection so they were very concerned by that. And they would obviously excise out the skin lesion and if they needed interposition graft replacement they would use a Rifampin soak PTFE

as well as Acuseal for immediate cannulation. Irrigation of the infected site were also done and using an impregnated antibiotic Vitagel was also done for the PTFE grafts. They were really successful in salvaging these fistulas and grafts at 85% success rate with 19 interposition

a patency was around 14 months for these patients. At UCS, my kind of approach to dealing with these ulcerated fistulas. Specifically if they bleed is to use

the bovine carotid artery graft. There's a paper that'll be coming out next month in JVS, but we looked at just in general our experience with aneurysmal and primary fistula creation with an AV with the carotid graft and we tried to approach these with early access so imagine with

a bleeding patient, you try to avoid using catheter if possible and placing the Artegraft gives us an opportunity to do that and with our data, there was no significant difference in the patency between early access and the standardized view of ten days on the Artegraft.

Prevention of the Fatal Vascular Access Hemorrhages. Important physical exam on a routine basis by the dialysis centers is imperative. If there is any scabbing or frank infection they should notify the surgeon immediately. Button Hole technique should be abandoned

even though it might be easier for the patient and decreased pain, it does increase infection because of that tract The rope ladder technique is more preferred way to avoid this. In the KDOQI guidelines of how else can we prevent this,

well, we know that aneurysmal fistulas can ulcerate so we look for any skin that might be compromised, we look for any risk of rupture of these aneurysms which rarely occur but it still needs to taken care of. Pseudoaneurysms we look at the diameter if it's twice the area of the graft.

If there is any difficulty in achieving hemostasis and then any obviously spontaneous bleeding from the sites. And the endovascular approach would be to put a stent graft across the pseudoaneurysms. Shah and others in 2012 had 100% immediate technical success They were able to have immediate access to the fistula

but they did have around 18.5% failure rate due to infection and thrombosis. So in conclusion, bleeding to hemodialysis access is rarely fatal but there are various ways to salvage this and we tried to keep the access viable for these patients.

Prevention is vital and educating our patients and dialysis centers is key. Thank you.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

of iliac limb reinterventions. Thank you very much.

- Thank you. Historically, common femoral endarterectomy is a safe procedure. In this quick publication that we did several years ago, showed a 1.5% 30 day mortality rate. Morbidity included 6.3% superficial surgical site infection.

Other major morbidity was pretty low. High-risk patients we identified as those that were functionally dependent, dyspnea, obesity, steroid use, and diabetes. A study from Massachusetts General Hospital their experience showed 100% technical success.

Length of stay was three days. Primary patency of five years at 91% and assisted primary patency at five years 100%. Very little perioperative morbidity and mortality. As you know, open treatment has been the standard of care

over time the goal standard for a common femoral disease, traditionally it's been thought of as a no stent zone. However, there are increased interventions of the common femoral and deep femoral arteries. This is a picture that shows inflection point there.

Why people are concerned about placing stents there. Here's a picture of atherectomy. Irritational atherectomy, the common femoral artery. Here's another image example of a rotational atherectomy, of the common femoral artery.

And here's an image of a stent there, going across the stent there. This is a case I had of potential option for stenting the common femoral artery large (mumbles) of the hematoma from the cardiologist. It was easily fixed

with a 2.5 length BioBond. Which I thought would have very little deformability. (mumbles) was so short in the area there. This is another example of a complete blow out of the common femoral artery. Something that was much better

treated with a stent that I thought over here. What's the data on the stenting of the endovascular of the common femoral arteries interventions? So, there mostly small single centers. What is the retrospective view of 40 cases?

That shows a restenosis rate of 19.5% at 12 months. Revascularization 14.1 % at 12 months. Another one by Dr. Mehta shows restenosis was observed in 20% of the patients and 10% underwent open revision. A case from Dr. Calligaro using cover stents

shows very good primary patency. We sought to use Vascular Quality Initiative to look at endovascular intervention of the common femoral artery. As you can see here, we've identified a thousand patients that have common femoral interventions, with or without,

deep femoral artery interventions. Indications were mostly for claudication. Interventions include three-quarters having angioplasty, 35% having a stent, and 20% almost having atherectomy. Overall technical success was high, a 91%.

Thirty day mortality was exactly the same as in this clip data for open repair 1.6%. Complications were mostly access site hematoma with a low amount distal embolization had previously reported. Single center was up to 4%.

Overall, our freedom for patency or loss or death was 83% at one year. Predicted mostly by tissue loss and case urgency. Re-intervention free survival was 85% at one year, which does notably include stent as independent risk factor for this.

Amputation free survival was 93% at one year, which factors here, but also stent was predictive of amputation. Overall, we concluded that patency is lower than historical common femoral interventions. Mortality was pretty much exactly the same

that has been reported previously. And long term analysis is needed to access durability. There's also a study from France looking at randomizing stenting versus open repair of the common femoral artery. And who needs to get through it quickly?

More or less it showed no difference in outcomes. No different in AVIs. Higher morbidity in the open group most (mumbles) superficial surgical wound infections and (mumbles). The one thing that has hit in the text of the article

a group of mostly (mumbles) was one patient had a major amputation despite having a patent common femoral artery stent. There's no real follow up this, no details of this, I would just caution of both this and VQI paper showing increased risk amputation with stenting.

Thank you.

- 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.

- Mr. Chairman, ladies and gentlemen, good morning. I'd like to thank Dr. Veith for the opportunity to present at this great meeting. I have nothing to disclose. Since Dr. DeBakey published the first paper 60 years ago, the surgical importance of deep femoral artery has been well investigated and documented.

It can be used as a reliable inflow for low extremity bypass in certain circumstances. To revascularize the disease, the deep femoral artery can improve rest pain, prevent or delay the amputation, and help to heal amputation stump.

So, in this slide, the group patient that they used deep femoral artery as a inflow for infrainguinal bypass. And 10-year limb salvage was achieved in over 90% of patients. So, different techniques and configurations

of deep femoral artery angioplasty have been well described, and we've been using this in a daily basis. So, there's really not much new to discuss about this. Next couple minutes, I'd like to focus on endovascular invention 'cause I lot I think is still unclear.

Dr. Bath did a systemic review, which included 20 articles. Nearly total 900 limbs were treated with balloon angioplasty with or without the stenting. At two years, the primary patency was greater than 70%. And as you can see here, limb salvage at two years, close to, or is over 98% with very low re-intervention rate.

So, those great outcomes was based on combined common femoral and deep femoral intervention. So what about isolated deep femoral artery percutaneous intervention? Does that work or not? So, this study include 15 patient

who were high risk to have open surgery, underwent isolated percutaneous deep femoral artery intervention. As you can see, at three years, limb salvage was greater than 95%. The study also showed isolated percutaneous transluminal

angioplasty of deep femoral artery can convert ischemic rest pain to claudication. It can also help heal the stump wound to prevent hip disarticulation. Here's one of my patient. As you can see, tes-tee-lee-shun with near

or total occlusion of proximal deep femoral artery presented with extreme low-extremity rest pain. We did a balloon angioplasty. And her ABI was increased from 0.8 to 0.53, and rest pain disappeared. Another patient transferred from outside the facility

was not healing stump wound on the left side with significant disease as you can see based on the angiogram. We did a hybrid procedure including stenting of the iliac artery and the open angioplasty of common femoral artery and the profunda femoral artery.

Significantly improved the perfusion to the stump and healed wound. The indications for isolated or combined deep femoral artery revascularization. For those patient presented with disabling claudication or rest pain with a proximal

or treatable deep femoral artery stenosis greater than 50% if their SFA or femoral popliteal artery disease is unsuitable for open or endovascular treatment, they're a high risk for open surgery. And had the previous history of multiple groin exploration, groin wound complications with seroma or a fungal infection

or had a muscle flap coverage, et cetera. And that this patient should go to have intervascular intervention. Or patient had a failed femoral pop or femoral-distal bypass like this patient had, and we should treat this patient.

So in summary, open profundaplasty remains the gold standard treatment. Isolated endovascular deep femoral artery intervention is sufficient for rest pain. May not be good enough for major wound healing, but it will help heal the amputation stump

to prevent hip disarticulation. Thank you for much for your attention.

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