Create an account and get 3 free clips per day.
Background on Interventional Oncology | Interventional Oncology
Background on Interventional Oncology | Interventional Oncology
Why Interventional Oncology | Interventional Oncology
Why Interventional Oncology | Interventional Oncology
The Ablation Concept | Interventional Oncology
The Ablation Concept | Interventional Oncology
Why is Staging Important | Interventional Oncology
Why is Staging Important | Interventional Oncology
Renal Ablation | Interventional Oncology
Renal Ablation | Interventional Oncology
Pulmonary Ablation | Interventional Oncology
Pulmonary Ablation | Interventional Oncology
Muscoskeletal Ablation | Interventional Oncology
Muscoskeletal Ablation | Interventional Oncology
Bland Embolization | Interventional Oncology
Bland Embolization | Interventional Oncology
Radioembolization | Interventional Oncology
Radioembolization | Interventional Oncology
Ablative Radioembolization | Interventional Oncology
Ablative Radioembolization | Interventional Oncology
Cone Beam CT | Interventional Oncology
Cone Beam CT | Interventional Oncology
ablationanatomicangioarteriesarteryartifactbeamchaptercombconecontrastdoseembolicenhancementenhancesesophagealesophagusgastricgastric arteryglucagonhcchepatectomyinfusinglesionliverlysisoncologypatientsegmentstomach
Indirect Angiography | Interventional Oncology
Indirect Angiography | Interventional Oncology

no thanks to the avir we really wouldn't be able to do anything that we can without y'all so I take great great pride in sharing things from our perspective said you folks can start contributing your own thoughts your own opinions and your own vision during

these cases I think it's certainly something that I've appreciated since the first day of doing invention where do you all do so having said that we're just a smidge in the behind side so we'll try to focus today is mainly a

survey to stimulate everyone in terms of what's actually happening on the other end of the catheter with respect to the patient why are we doing these things where's our role and I think that's gonna add hopefully some value the next

time you folks step in on one of these cases alright so as you know dr. daughter first was able to visualize the inside of a blood vessel and find a stenosis and a lady who had limb ischemia and then was able to use a

dilator to fix that so obviously that gave birth to interventional radiology so we started taking pictures of tumors just to diagnose tumors back in the day before we had actual imaging and what we found

was well if tumors have a high demand for blood just like anything else what happens if we take away that blood and this is a 1975 image of renal cell carcinoma is to call them hyper and if Roma's back then but basically the

concept of interventional ecology was born the moment you could do something to make the environment for the tumor less hospitable and to try to palliate patients if they weren't subject to the the gold treatment standards like

resection in this case so fast forward to 2016 there was a huge study was International where they looked at over 3 000 patients who have primary liver cancer or her pata cellular carcinoma and what they found was that regardless

of where but if you sum all the treatment decisions that are related to those patients about 70% will see treatment by an interventional radiologist as you know that was a astounding amount

so si are listened to a lot of these types of messages even outside of obviously oncology basically we realize that there's a tremendous responsibility and the best thing to do is to dedicate ourselves fully to that and that's why I

think with IR now is a separate medical specialty we're going to start seeing more of the clinical involvement of this and certainly think the caseloads going to go up so why interventional oncology

the traditional three pillars are

surgical medical and rad honk which actually was once part of radiology and separated just like interventional radiology has and where is the role for this last column so many patients are not medically operable so if you set the

gold standard you know that the cure for someone has a primary liver mass well about 20 percent of patients who present can undergo resection what you do for the remaining portion so Salvage is what we offer when someone has undergone

standard of care and it didn't work how do we hop back in and try to see how much these folks it's low-risk it's not very expensive at all as compared to things like surgery and the recovery is usually the same date so

this concept here of tests of time is kind of interesting a lot of times when we look at a tumor let's say it's 2 centimeters it's not really the size of the tumor but it's how nasty of a player it is and it's

difficult to find out sometimes so what we do is we'll treat it using an IR technique and watch the patient and if they do well then we can subject them then to the more aggressive therapy and it's more worthwhile because we've found

that that person is going to be someone who's likely going to benefit you can use this in conjunction with other treatments and repeat therapy is well tolerated and finally obviously palliation is very important as we try

to focus on folks quality of life and again this can be done in the outpatient setting so here's a busy slide but if you just look at all the non-surgical options that you have here for liver dominant primary metastatic liver

disease everything that's highlighted in blue is considered an interventional oncology technique this is these the main document that a lot of international centers use to allocate people to treatments when they have

primary liver cancer HCC and if you see if you see at the very bottom corner there in very early-stage HCC actually ablation is a first-line therapy and they made this switch in 2016 but it's the first time that an

intervention illogic therapy was actually recommended in lieu of something like surgery why because it's lesions are very small its tolerated very well and it's the exact same reason why your dermatologists can freeze a

lesion as opposed to having to cut everything off all the time at a certain point certain tumors respond well and it's worth the decrease in morbidity so

the ablation concept in general is to provide an environment that is

completely hostile to tumor minus 40 degrees Celsius 150 degrees Celsius 500 gray which is a radiation dose we say it's very hard for it's about anything to survive but so why is it that it doesn't always work well that's a

function of all those parameters that you see there we got to make sure we pick the right patients we got to make sure that we treat tumor where we think it is and avoid trading things that don't need treatment avoid causing

damage to collateral structures and getting a reasonable margin where we actually get some of the tumor that's microscopic there are a lot of ablation modalities radiofrequency alternates electrical current very rapidly so that

generates friction within the lesion and causes heat it looks like this a lot of times you see these little times that stick out so that you can increase the size of your blasian zone and here's a one of those deployed in a patient who

had a colorectal Curren after hepatectomy cryoablation freezes things and it pushes a gas that once it goes through a pin hole tends to expand and cause rapid freezing he can also push another gas right through it and cause

rapid heating but this is just bringing tumors to that minus 20 degree minus 40 degree threshold the nice part about cryoablation is that you can visualize your ablation zone so we're right up against the bile duct here and it tends

to be a little more respectful of tissues so that's why cryoablation is chosen every once in a while we're do frequency ablation is an excellent tool we have lots of data for it but likes it sometimes it's difficult determine where

the ablation zone is interprocedural e microwave ablation there was just a randomized study that came out that compared microwave ablation to radiofrequency ablation and the results are very similar

it was a very very experienced institution doing it but the whole point here is that a lot of these tools work pretty well there's no clear superiority on them but one thing that microwave offers it's very fast so generates

temperatures to boiling within the tumor in about five minutes and so it's certainly very fast as compared to radiofrequency and you can see boiling happening within this tumor that's been accessed eventually there that gas is

actually literally fluid that is boiling away from the tumor couple of cool ones this one's reversal expiration what we do here is we place probes throughout the lesion and we pulse it to confuse the membrane on the cell to think that

it's a it has holes in it that it cannot close and so what is happening is the contents inside the cell leave and that's pretty much consistent with not being able to survive the nice part is we can accomplish all that without

thermal ablation what do we mean that we don't go over about 40 degrees Celsius so if something is involving a bile duct or involving a critical structure like the ureter it's not actually going to damage it it just basically tells all

the the cells within there to stop stop undergoing the cellular mechanisms responsible for life it's a little more finicky to place you have to place these little parallel probes here's one we did that was directly write on the

bifurcation of the main bile ducts and you can see here afterwards is an immediate post contrast scan how that whole area is ablative it does not take up contrast and this patient never developed biliary strictures that side

so why staging important well when you go to treat someone if I tell you I have a lollipop shaped tumor and you make a lollipop shape ablation zone over it you have to make sure that it's actually a lollipop shaped to begin with so here's

a patient I was asked to ablate at the bottom corner we had a CT scan that showed pretty nice to confined lesion looked a little regular so we got an MRI the MRI shows that white signal that's around there then hyperintensity that's

abnormal and so when we did an angiogram you can see that this is an infiltrate of hepatocellular carcinoma so had I done an ablation right over that center-of-mass consistent with what we saw on the CT it

wouldn't be an ablation failure the blasian was doing its job we just wouldn't have applied it to where the tumor actually was so let's talk about

different applications renal ablation is very common when do we use it

high surgical risk patients primary metastatic lesions some folks are actually refused surgery nowadays and saying I'll have a one centimeter reno lesion actually want this in lieu of surgery people have

familial syndromes they're prone to getting a renal cancer again so we're trying to preserve renal tissue it is the most renal parenchymal sparing modality and obviously have a single kidney and a lot of these are found

incidentally when they're getting a CT scan for something else here's a very sizable one the patient that has a cardiomyopathy can see how big the heart is so it's you know seven centimeter lesion off of the left to superior pole

against the spleen this patient wouldn't have tolerated bleeding very much so we went ahead and embolized it beforehand using alcohol in the pide all in a coil and this is what it looks like when you have all those individual ice probes all

set up within the lesion and you can see the ice forming around I don't know how well it projects but in real time you can determine if you've developed your margin we do encompass little bit of spleen with that and you can see here

that you have a faint rim surrounding that lesion right next to the spleen and that's the necrotic fat that's how you know that you got it all and just this ablation alone caused a very reactive pleural

effusion that you can see up on the CT over there so imagine how this patient would have tolerated surgery pulmonary

blasian it's well tolerated and folks with advanced pulmonary disease there's a prospective trial that showed that

there are pulmonary function does not really change after an ablation but the important part here is a lot of these folks who are not candidates for surgical resection have bad hearts a bad coronary disease and bad lungs to where

a lot of times that's actually their biggest risk not their small little lung cancer and you can see these two lines here the this is someone who dr. du Puy studied ablation and what happens if you recur and how your survival matches that

and turns out that if you recur and in if you don't actually a lot of times this file is very similar because these folks are such high risk for mortality outside or even their cancer so patient selection is really important for this

where do we use it primary metastatic lesions essentially once we feel that someone is not a good surgical candidate and they have maintained pulmonary function they have a reasonable chance for surviving a long

time we'll convert them to being an ablation candidate here's an example of a young woman who had a metastatic colorectal met that was treated with SPRT and it continued to grow and was avid so you can see the little nodule

and then the lower lobe and we paste the placement prone and we'd Vance a cryo plugs in this case of microwave probe into it and you turn off about three to five minutes and it's usually sufficient to burn it it cavitate s-- afterwards

which is expected but if you follow it over time the lesion looks like this and you say okay fine did it even work but if you do a PET scan you'll see that there's no actually activity in there and that's usually pretty definitive for

those small lesions like that about three centimeters is the most that will treat in a lot of the most attic patients but you can certainly go a little bit larger here's her follow-up actually two years

that had no recurrence so what do you do when you have something like this so this is encasing the entire left upper lobe this patient underwent radiation therapy had a low area of residual activity we followed it and it turns out

that ended up being positive on a biopsy for additional cancer so now we're playing cleanup which is that Salvage I mentioned earlier we actually fuse the PET scan with the on table procedural CT so we know which part of all that

consolidated lung to target we place our probes and this is what looks like afterwards it's a big hole this is what happens when you microwave a blade previously radiated tissue having said that this

was a young patient who had no other options and this is the only side of disease this is probably an okay complication for that patient to undergo so if you follow up with a PET scan three months later there's no residual

activity and that patient actually never recurred at that site so what about

ablating things in the bones well musculoskeletal blasian we're fortunate within our practice that we have a doctor councilman Rochester who's

a probably one of the biggest world's experts on this and these are his cases that he shared but you can see when you have small little lesions and bones that are painful you can place probes in them and you freeze them the tumor dies and

musculoskeletal things remain intact what about when you have cases like this where there's a fracture going through the iliac bone on the left with an infiltrate of malignancy well you can cryo blade it and what's cool about is

you can using CT guidance do percutaneous cannulated pins and screws and a cement o plasti ver bladed cavity and when you're done the patient who initially couldn't walk now can and whose pain scale went down to one so I

think that's that's very important to realize the potential of image-guided medicine this is something that previously would have had to been done in the orthopedic lab so you know I think this is extending options where

otherwise it would have been difficult same thing applies to the spine you can ablate and fill them with cement so

we're gonna move on to embolization there a couple different categories of embolization bland embolization is when

you just administering something that is choking off the blood supply to the tumor and that's how it's going to exert its effect here's a patient with a very large metastatic renal cell lesion to the humerus this is it on MRI this is it

per angiogram and this patient was opposed to undergo resection so we bland embolized it to reduce bleeding and I chose this one here because we used sequentially sized particles ranging from 100 to 200 all

the way up to 700 and you can actually if you look closely can see sort of beads stacked up in the vessel but that's all that it's doing it's just reducing the blood supply basically creating a stroke within the tumor that

works a fair amount of time and actually an HCC some folks believe that it were very similar to keep embolization which is where at you're administering a chemo embolic agent that is either l'p hi doll with the chemo agent suspended within it

or drug eluting beads the the Chinese have done some randomized studies on whether or not you can also put alcohol in the pie at all and that's something we've adopted in our practice too so anything that essentially is a chemical

outside of a bland agent can be considered a key mobilization so here's a large segment eight HCC we've all been here before we'll be seeing common femoral angiogram a selective celiac run you can make sure

the portals open in that segment find the anterior division pedicle it's going to it select it and this is after drug living bead embolization so this is a nice immediate response at one month a little bit of gas that's expected to be

within there however this patient had a 70% necrosis so it wasn't actually complete cell death and the reason is it's very hard to get to the absolute periphery of the blood supply to the tumor it is able to rehab just like a

stroke can rehab from collateral blood supply so what happens when you have a lesion like this one it's kind of right next to the cod a little bit difficult to see I can't see with ultrasound or CT well you can go in and tag it with lip

Idol and it's much more conspicuous you can perform what we call dual therapy or combination therapy where you perform a microwave ablation you can see the gas leaving the tumor and this is what it looks like afterwards this patient went

to transplant and this was a complete pathologic necrosis so you do need the concept of something that's ablative very frequently to achieve that complete pathologic necrosis rates very hard to do that with ischemia or chemotherapy

alone so what do you do we have a

patient like this you have a very large left lateral HCC that's invading the left the patek vein and extending into the heart since when we get into things like radioembolisation if you have

multifocal liver disease if you want to apply radiation therapy to that's very difficult to do that because it actually requires more radiation dose to kill HCC than it does the adjacent normal liver the liver is actually that ready

sensitive so you can do things like SBRT and pick an individual lesion you can do things like a imrt which is you know survey 8 non focus generalize low dose but what's interesting Malaysian is that if you administer

particles they only shoot about two millimeters worth of the raishin field around it so of what used is that with one not much but if you put eight to forty million of them within the bloodstream they Auto sort themselves

based off of the vascular flow preferential that exists with tumors tumors actually emit hormones pull in blood supply that you weren't born with and that actually tends to pull beads from the bloodstream preferentially

towards it so this is an example where you stain a tumor with two types of wax one the portal that's blue one the artery that's red and you can see how much that preferential exists so what ends up happening is these spheres

cluster within the tumor and then provide local dose radiation that's very hot where the tumor is and low elsewhere so here's an example of that this is a patient with metastatic neuroendocrine disease multifocal liver lesions you can

see that vascular flow preferential this is what it looks like on the maa when we jecht a protein particle surrogate that has a technician I should have assigned to it just as a visualization of how the particle is

going to sort out and the post y9t bremsstrahlung CT is over there and you can see how intense the necrosis is within the tumor and how much it's spared the normal liver however you do get some radiation damage they don't

live a regardless that's why choosing the timing of when you're gonna do this is important this is a patient that was treated with tastes above and one session of y9u beneath so you can see that they do have different types of

therapeutic mechanisms they're not the same even though they look very similar in terms of when we're administering

them so my particular area of interest is a blade of radium ization and what we'd like to do is to break the liver

down into a bunch of little tiny perfused volumes off of a single vascular pedicle or what we call angio zones and those are those allow us to segment out if you only have small volume disease for example like here in

segment three why do I have to treat the entire left to paddock low I can actually treat just that small portion just like it what it tastes only now I'm administering y9t but since it's expendable liver I

can administer doses that are way higher orders of magnitudes higher than what I could if our infusing into the liver just on its own so here's an example of that if you look at this lesion in the right of panic lobe you'll see these

little lines over them what we want to achieve is around a 205 GRA threshold for these lesions that's the red line everything that's south of red in terms of color orange Holly to blue is not cold enough to kill tumor so if we

administer a dose of a tea grade to the lobe we get this coverage which is to be a partial response if I administer 150 grey suddenly that red line gets larger what happens when you administer 400 grey now you've officially covered the

entire lesion and so you're going to lose the adjacent liver at those kind of doses and as well - what what the real question then is not sort of how much dose you give it's you give what you need to to ablate the tumor in its

entirety and you see what the patient's left with if someone's left with anatomically a lot of remnant liver because of how you've segmented out that lesion then go ahead and dose extremely high and that's essentially what we've

seen in pathologic results it's one of the highest things of high school pathological crosa rates you can achieve with a trans arterial therapy it's highly competitive with thermal ablation in the correctly selected bleezin

so this is an example of what it looks like when you segment out a little lesion like this and this patient ultimately went to resection and this was a complete pathologic necrosis but as you can see even it was a cirrhotic

patient we chose a very small volume of liver that we felt the patient would tolerate so that's a blade of vernalization let's take a look at what looks like in real time so we have a little capsular lesion we felt that

ablating this patient who was a potential transplant candidate we felt we can probably with a blade of radium realization so you go in and this is the comb beam CT that looks at a complete enhancement of the lesion within the NGO

zone this is what the MAA looks like when we administer it you can see how it tends to cluster within the tumor but you can see what the adverse territory is the liver adjacent to it this is what the engine room looks like how highly

selective it is the day of and this is what the wine ID actually looks like is the wine 90 doing its job and you can see how conformal it is there's no risk whatsoever to the liver that's adjacent outside of that field of

a maximum of around 11 millimeters and this is a patient at one month with a complete imaging response and this patient never developed a recurrent to the site and what's actually sole mode of treatment for this person's liver

cancer this is how you get complete pathologic response if you look at those little tiny grey dots in there those are actually the spheres within tiny little vessels within the tumor sometimes they go even to the portal branch but you can

see how they're not clustered uniformly but when you make them super hot that allows them to give range where otherwise they would be fine a little bit short so this also applies to the whole lobe this was a patient that had a

very unusual presentation of colon cancer that was invading the portal II we weren't sure what to do with this patient no one was because a very rare occurrence so we said well we would like

to resect him but there's not enough liver and we're not sure if this person's gonna survive because we've never seen portal cancer invading the portal vein so we said let's treat it with the radiation lobectomy and what's

cool here is if you look at the the arteries even though the tumor is invading the portal vein it's bringing arterial supply along with it like a vagabond and that's the conduit that allows us to treat these patients so

when we saw that we felt this patient we good candidate for irradiation lobectomy which is applying an ablative dose of y9t to the entire low not just a small segment in patients where otherwise cannot because of the anatomy the tumor

or if you're trying to shrink that lobe to get that person ready for surgery why because if you look at the size of the lobe on the left from this first image and compare it here you can see how much larger it got what happens is that part

that the surgeon ultimately tens on resecting in volutes over time and becomes completely vitalized and turns into scar tissue so we know that if a surgeon goes in afterwards to cut it out it's going to not result in liver

failure and that level of security allows people to have sir who otherwise wouldn't this patient is not going to have metastatic disease because we followed their blood level markers let me see how low they are and

is going to have enough liver remnant so the patient went to resection and this is the pathologic specimen and this was also a complete pathologic necrosis so I

know we're running a bit short on time so I want to briefly just touch about

some techniques with comb beam CT which are very helpful to us there are a lot of reasons why you should use comb beam CT it gives us the the most extensive anatomic understanding of vascular territories and the implications for

that with oncology are extremely valuable because of things like margin like we discussed here's an example of a patient who had a high AF P and their bloodstream which tells us that they have a cancer in her liver we can't see

it on the CT there but if you do a cone beam CT it stands up quite nicely why because you're giving levels of contrast that if you were to give them through a peripheral IV it would be toxic to the patient but when you're infusing into a

segment the body tolerates at the problem so patient preparation anxa lysis is key you have them exhale above three seconds prior to that there's a lot of change to how we're doing this people who are introducing radial access

power injection anywhere from about 50 to even sometimes thirty to a hundred percent contrast depends on what phase you're imaging we have a Animoto power injector that allows us to slide what contrast concentration we like a lot of

times people just rely on 30% and do their whole the case with that some people do a hundred percent image quality this is what it looks like when someone's breathing this is very difficult to tell if there's complete

lesion enhancement so if you do your comb beam CT know it looks like this this is trying to coach the patient and try to get them to hold still and then this is the patient after coaching which looks like this so you can tell that you

have a missing portion of the lesion and you have to treat into another segment what about when you're doing an angio and you do a cone beam CT NIT looks like this this is what insufficient counts looks like on comb beam so when you see

these sort of Shell station lines that are going all over the screen you have to raise dose usually in larger patients but this is you know you either slow down the acquisition speed of your comb beam or

you raise dose this is what it looks like after we gave it a higher dose protocol it really changes everything those lines are still there but they're much smaller how do you know if you have enhancement or a narrow artifact you can

repeat with non-contrast CT and give the patient glucagon and you can find the small very these small arteries that pick off the left that commonly profuse the stomach the right gastric artery you can use your comb beam CT to find

non-target evaluation even when your angio doesn't suggest it so this is a patient they have recurrent HCC we didn't angio from here those arteries down there where those coils were looked funny even though the patient was

quote-unquote coiled off we did a comb beam CT and that little squiggly C shape structures that duodenum that's contrast going in it this would be probably a lethal event for the patient or certainly would require surgery if you

treated that much with y9t reposition the catheter deeper towards the lesion and you can repeat your comb beam CT and see that you don't have an hands minh sometimes you have these little accessory left gastric artery this is

where we really need your help you know a lot of times everyone's focused and I think the more eyes the better for these kind of things but we're looking for these little tiny vessels that sometimes hop out of the liver and back into the

stomach or up into the esophagus there's a very very small right gastric artery in this picture here this patient post hepatectomy that rides along the inferior surface of the liver it's a little curly cube so and this is a small

esophageal branch so when you do comb beam TT this is what the stomach looks like when it enhances and this is what the esophagus looks like when it enhances you can do non contrast comb beam CTS to confirm ablation so you have

a lesion this is the comb beam CT for enhancement you treat with your embolic and this is a post to determine that you've had completely shin coverage and you can see how that correlates a response so the last thing we're going

to talk about is indirect angiography this is kind of a neat trick to suggest to your intervention list as a problem solver we were asked to ablate this lesion and it looked kind of funny this patient had a resection for HCC they

thought this was a recurrence so we bring the comb beam CT and we do an angio and it doesn't enhance so this is an image here of indirect port ography so what you can do is an SMA run and see at which point along the

run do you pacify the portal vein and you just set up your cone beam CT for that time so you just repeat your injection and now your pacifying the entire portal vein even though you haven't selected it and what to show

well this was a portal aneurysm after resection with a little bit of clot in it the patient went on some aspirin and it resolved in three months so back to our first patient what do you do for someone who has HCC that's invading the

heart this patient underwent 2y 90s bland embolization microwave ablation chemotherapy and SBRT and he's an eight-year survivor so it's one of those things where certainly with the correct patient selection you can find the right

things to do for someone I think that usually our best results come from our interdisciplinary consensus in terms of trying to use the unique advantages that individual therapies have and IO is just one of those but this is an important

lesson to our whole group that you know a lot of times you get your best results when you use things like a team approach so in summary there are applications to IO prior to surgery to make people surgical candidates there are definitive

treatments ie your cancer will be treated definitively with curative intent a lot of times we can save when people have tried cure intent and weren't able to and obviously to palliate folks to try to buy them time

and quality of life thermal ablation is safe and effective for small lesions but it's limited by the adjacent anatomy y9t is not an ischemic therapy it's an ablative therapy you're putting small ablative radioactive particles within

the lesion and just using the blood supply as a conduit for your brachytherapy and you can use this as a new admin application to make people safer surgical candidates when you apply to the entire ride a panic globe

thanks everyone appreciate it [Applause] [Music]

Disclaimer: Content and materials on Medlantis are provided for educational purposes only, and are intended for use by medical professionals, not to be used self-diagnosis or self-treatment. It is not intended as, nor should it be, a substitute for independent professional medical care. Medical practitioners must make their own independent assessment before suggesting a diagnosis or recommending or instituting a course of treatment. The content and materials on Medlantis should not in any way be seen as a replacement for consultation with colleagues or other sources, or as a substitute for conventional training and study.