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AI and Image Reconstruction, Dr. Lawrence Tanenbaum (5-29-20)

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0:02

Hello and welcome to Noon

0:03

Conferences hosted by MRI Online.

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In response to the changes happening around

0:06

the world right now and the shutting down of in-

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person events, we have decided to provide free daily

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Noon Conferences to all radiologists worldwide.

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Today, we are joined by Dr. Lawrence Tannenbaum.

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He is currently the Vice President, Chief Technology

0:17

Officer, and Director of Advanced Imaging at RAD.

0:21

He previously worked at the Icahn School of

0:23

Medicine at Mount Sinai, New York, and attended

0:25

in neuroradiology while serving as an Associate

0:28

Professor of Radiology, Director of MRI, CT,

0:31

and Outpatient Advanced Imaging Development.

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He's a senior member of the American

0:34

Society of Neuroradiology, and we are

0:36

excited to have him here with us today.

0:38

Reminder that there will be time at the

0:39

end of this hour for a Q&A session.

0:41

Please use that Q&A feature

0:42

to ask all of your questions.

0:44

We'll get to as many as we can before our time is up.

0:46

That being said, thank you so

0:47

much for joining us today, Dr.

0:48

Tannenbaum.

0:48

I will let you take it from here.

0:50

All right, great.

0:51

So we have the opportunity to talk about

0:53

artificial intelligence and image

0:55

reconstruction over the next 40 minutes or so.

0:59

I'm trying to make my slides advance.

1:01

That didn't work.

1:03

That didn't work.

1:06

Maybe.

1:06

There you go.

1:07

So we'll talk a little bit about,

1:09

um, what is artificial intelligence.

1:11

We'll do a little bit of the hype and

1:13

reality that you've heard around this topic.

1:16

We'll spend some time on terminology and

1:19

background, very little in this particular session. And

1:22

we'll talk a little bit about the strengths

1:24

and limitations of the tool in general.

1:27

This talk is largely about the impact that

1:29

these tools can have in terms of influencing,

1:33

uh, image reconstruction for MR and CT,

1:36

uh, reducing dose and improving workflow,

1:40

as well as the patient experience.

1:42

So we'll take it from there.

1:44

Um, I promised you a little bit of definition.

1:47

So what is artificial intelligence?

1:49

It's a branch of computer science, which essentially

1:52

allows machines to do the things that are normally

1:54

associated with human intelligence, things

1:57

like reasoning, learning, and self-improvement.

1:59

It's essentially technology that, in theory, would enable

2:02

machines to sense, comprehend, act, and learn, and you can

2:05

see we're not quite, you know, at the full fruition of

2:09

these goals, but you're starting to see some of the

2:11

things that these machines can do in healthcare. You can

2:14

see it is considered to be one of the key technologies.

2:18

You can see here between big, big data, which is

2:21

essentially an opportunity for AI, um, pattern

2:25

recognition, as well as, you know, the subtopic

2:27

of AI, you know, number one and number two on the

2:29

list of the key technologies to affect healthcare.

2:33

Back in 2018, about 50 percent of healthcare

2:36

organizations were already either involved or

2:39

planning to get involved with artificial intelligence.

2:41

So at this point, I'm not telling you anything

2:44

you don't already know.

2:46

It's a big topic, and you know that it's all around us,

2:49

you know, whether it's ads that follow me around every

2:52

website I hit or, um, crowdsourcing traffic information

2:56

on things like Waze. Um, it's really in every aspect

3:00

of our life—some form of artificial intelligence now.

3:05

I'm sure you've heard of some of the great victories

3:07

that artificial intelligence has had here.

3:10

You see an example of the poor Go champion who was

3:14

beaten by a machine, and frankly, this gave chills

3:17

to all of us and, you know, made us marvel at the

3:19

capabilities of these tools. But in reality, playing

3:22

games is one of the lowest hanging fruits for an

3:25

AI algorithm, for a machine learning algorithm, and it

3:28

frankly is really sort of an entry-level achievement.

3:31

As you'll hear over the course of the presentation, we

3:34

know we have autonomous cars out there, even autonomous

3:37

trucks with a variety of tools enhanced by computer

3:42

vision that assist the operator, uh, uh, in terms

3:47

of, you know, getting around, avoiding accidents,

3:50

and, uh, even, even, um, taking you from A to B,

3:54

you know, while you're doing the crossword puzzle.

3:57

We know, uh, from the literature that, uh, the

4:00

error rate for computers is already better than the

4:03

error rate for humans in terms of image recognition.

4:06

Uh, and it's really the same

4:07

in terms of speech recognition.

4:09

So these tools are really working reasonably well

4:12

so far in terms of these tasks. On the other hand,

4:15

there have been some fairly flamboyant failures. We

4:17

know that none of these autonomous systems is really

4:20

quite ready to be fully autonomous, and accidents have

4:23

happened. And there's certainly a role for humans in

4:26

all of these processes. You know, it's said very

4:29

often, you know, planes can fly themselves, but nobody

4:32

will get on a plane without a pilot. These days,

4:35

without a pilot with a mask on, uh, you can see this

4:38

particular circumstance just outside my office window,

4:41

uh, that, you know, Sully had to take this plane

4:44

down, override the autopilot, and land it safely in the

4:47

Hudson, um, uh, not too long ago. So really, there is

4:52

quite a long way to go in terms of what artificial

4:55

intelligence, you know, will be able to do and can do.

4:59

Uh, you've all seen robots, but with minor challenges,

5:01

they'll fall down. Uh, we talked about driverless

5:04

cars, and, you know, even though computers can do a

5:07

relatively decent job reading, at present they're

5:11

pretty much stuck at the sixth-grade reading level.

5:14

Um, and, uh, you know, not where you would expect, you

5:19

know, for something as powerful as a tool that can beat

5:22

the experts and drive a car down the highway. Really,

5:25

one of the biggest challenges is perspective in

5:28

context, and it really has a very hard time with complex

5:32

visual scenes. See, this picture strikes us all as odd.

5:35

Um, uh, you know, it just looks a little weird.

5:39

Uh, certainly we can recognize a rock, we can

5:41

recognize a tree, but you know, we, uh,

5:45

there's something odd about the picture to

5:47

us. The computer doesn't see anything odd here.

5:49

And in actuality, this is a picture of a rock floating

5:52

in a pond, and you're looking at reflections, and we

5:55

instantly interpret that in a way that computers can't.

5:58

And that really is one of the

6:00

big contextual differences.

6:02

When you see this picture on the left of a bicycle, you

6:04

know, it's easy to recognize a bicycle. For a computer,

6:07

it can recognize grass and sky, but

6:09

it doesn't recognize why that bicycle

6:12

is upside down and has its wheels

6:15

on the grass.

6:16

If you look at the right-hand side of your

6:18

screen, you can see, if you have to move my little

6:20

picture over, you can see there's a duck on a

6:23

roof here watching TV. It recognizes the TV

6:26

and the duck, but it doesn't really understand

6:28

why it's kind of odd to have a television

6:31

on a roof with a duck watching TV.

6:34

Uh, here's a cow on a lounge chair. Again,

6:37

the context is where it really, it really

6:39

starts to fail. You know, what's odd about

6:41

these pictures? Uh, that's a toothbrush.

6:43

That's a dog, but why is it odd that the

6:45

toothbrush is the size of the dog, and

6:47

what's a dog doing using a toothbrush?

6:50

So those contextual pieces

6:53

really are where things fail.

6:56

Now, computer vision works pretty well, right?

6:58

These are examples of ice cream and Dalmatians,

7:00

and, you know, as good a job as it can do

7:04

in differentiating ice cream from dogs,

7:06

sometimes it makes fairly flamboyant failures.

7:08

It does a nice job

7:10

of telling that this is a chihuahua, but every once in

7:12

a while, you know, it thinks a blueberry muffin is a

7:14

chihuahua. So there are definite limitations to these

7:17

tools, and rather than a lot of areas in society, you

7:20

know, we're pushing back now. Um, and facial recognition

7:24

software, because of all the errors that it makes and

7:26

the implications this can have for personal freedom

7:29

as well. So it's powerful, but still relatively early.

7:34

When you look at artificial intelligence out in the

7:37

enterprises, human review seems to still be essential.

7:40

I love to use this picture on the right-hand side.

7:42

This is on posters all over Los Angeles to herald

7:46

the grant that was given to one of the universities.

7:48

Um, but in this particular case, somebody wasn't

7:52

paying attention because the brain is in there

7:54

backwards. So a human would recognize that instantly,

7:57

whereas a computer might not ever recognize

8:00

the fact that there's something wrong with this

8:02

picture contextually, so to speak. Despite the fact

8:05

that AI systems are running at Facebook and Google

8:07

and Twitter, there are lots of humans involved in

8:09

this process to add the human touch and the human

8:12

perspective. Uh, and if you see the same thing

8:15

at the five largest financial institutions as well,

8:18

there are lots of humans involved there, and

8:20

uh, you know, it's not computers alone

8:23

that are doing this censorship in China.

8:24

They have one human censor interpreting

8:27

context and nuance for every 100,000 users.

8:31

So humans are still a big part of this process.

8:34

Overall, if you want to get a sense of what AI

8:37

can do, what machine learning and neural networks

8:39

can do, I think this particular statement by Steven

8:42

Pinker really puts it into perspective: hard problems,

8:45

you know, beating a champion in Go is very easy for

8:48

deep learning, for AI to be able to do. Uh, easy

8:52

problems, like picking up a pencil, recognizing your

8:55

mother, uh, that's a lot harder for computers to

8:59

do, and that really is a good tenet to keep in mind

9:01

when you think about, uh, where machines are and where

9:04

they still have to go. Now, when it comes back to the

9:08

imaging enterprise, which we all care about, we've

9:11

heard some pretty alarming statements back in 2016.

9:14

Jeffrey Hinton, uh, who is the godfather of neural

9:18

networks, the godfather of machine learning,

9:20

um, he came out with a very widely publicized

9:24

statement that radiology is over. You are over,

9:29

you should stop training them right away.

9:30

I mean, they're just like the coyote who's

9:33

already run off the cliff and doesn't

9:35

understand that there's no ground beneath him.

9:37

And you just have to look down to

9:39

realize that, you know, their career is over.

9:42

And the question is, you know, is he right?

9:44

Are the doomsayers right?

9:46

Or is it really more

9:48

that, you know, as we're all starting to realize

9:51

that these tools are going to be, uh, significant

9:55

tools as augmentation, as assistance, as workflow, as

10:00

reassurance, as triage, all kinds of things that these

10:04

tools are going to be able to do for us that are

10:06

going to make us more powerful in the healthcare

10:08

enterprise, as radiologists, as brokers of information,

10:12

uh, as integrators of information, uh, than we've ever

10:16

been before. And that's the opinion, you know,

10:18

that I have right now. If you look at some of the

10:19

statistics about, um, startups in the AI space and

10:25

job loss in radiology, on the left-hand side you

10:27

see the roughly 400 global startups in artificial

10:30

intelligence, and on the right-hand side, the zero

10:32

radiologists have lost their jobs as a result.

10:35

So it may not stay that way forever.

10:37

I think in any industry, you, uh, people have

10:40

to adjust and adapt, but I think this is going

10:43

to be the bird's eye view or the 500-yard

10:45

view for quite some time, if not forever.

10:47

As a matter of fact, I think we, if you look at

10:50

the Gartner Hype Curve in terms of artificial

10:53

intelligence tools, machine learning, deep

10:56

learning, computer vision, computer diagnosis, and

10:59

the like, you can see that we're already getting

11:02

heading towards the trough of disillusionment

11:05

with deep learning of image interpretation, and

11:07

we're just starting to climb the high plateau in

11:10

terms of reading and reading comprehension and

11:13

speech comprehension, uh, and the thing that we're

11:16

we all assume can be done today, which is deep

11:19

understanding, is decades away, and may never actually

11:22

uh, come to fruition, so really interesting stuff.

11:26

So what have we learned over the last four years or so?

11:28

Maybe, you know, just about four years.

11:30

Um, uh, well, what does Geoffrey

11:33

Hinton learn? Well, in 2018,

11:35

he did a deeper dive on what it really takes to replace

11:38

a radiologist, what a radiologist really does in

11:41

the healthcare enterprise, and he realized, well, he

11:43

was a bit, if not a lot, too hasty at that particular

11:46

point. And that brings us to, you know, where are we?

11:49

Artificial intelligence can impact

11:52

the radiology enterprise.

11:54

And this slide was borrowed from

11:56

Dr. Hugh Harvey, that's his Twitter handle.

11:58

If you want to get a feel for what's actually

12:00

going on from one of the wisest, uh, and loquacious

12:04

folks in artificial intelligence and imaging,

12:08

I would follow him at his Twitter handle, Dr. Hugh Harvey.

12:11

Uh, really impressive guy.

12:13

But this slide, which I've seen in various

12:15

shapes and forms, shows the full sense of

12:18

what AI is going to be able to do for us.

12:20

Everything from improving our clinical decision

12:23

support tools, as to which exams are best used in

12:26

which circumstances, optimizing our scheduling.

12:29

Our organization is in the middle of a big

12:32

joint project, project with, with Philips

12:35

Healthcare, looking at tools to optimize our.

12:39

Late cancellation and no-show patients to find ways

12:42

to devote our efforts to reducing those in the most

12:45

efficient fashion. We're going to talk about things

12:49

like dose reduction and scan time reduction today.

12:52

But other things like post-processing segmentation is

12:55

really low-hanging fruit For um artificial intelligence

12:58

probably much of what you've heard is about triage

13:01

and detection Um, particularly with uh, COVID lung

13:04

imaging right now the more impressive apps that I've

13:07

seen are the ones that do quantification Um, I work

13:11

with a company called Icometrics, which has a really

13:13

nice quantification tool, which can give you a sense

13:16

of, uh, of prognosis and perhaps guide intervention.

13:20

Um, we've also talked about

13:22

other things like, um, reporting.

13:25

Uh, that can be optimized and actually tailored to,

13:28

uh, the, the, uh, the audience, maybe giving one report

13:32

and creating many, and even helping with communication

13:36

of urgent results, with lots of opportunities to take

13:39

the massive amounts of data, the, the daunting tasks

13:43

that we do in a repetitive, often mind-numbing way,

13:46

and optimize them and take some of the burden off

13:48

of us. But again, for the rest of our time today,

13:52

we're going to talk about how you can use artificial

13:54

intelligence for image reconstruction. We'll start off

13:57

with sort of the entry-level stuff with compressed

14:00

sensing and sparse data reconstructions. We'll

14:03

transition into iterative reconstruction for the

14:05

most part, uh, an MR-based machine learning-assisted

14:09

iterative reconstruction. Um, we'll highlight the

14:12

work of a company called Medic Vision. And then we'll

14:15

get into the true deep learning neural network-based

14:18

reconstruction that is now on the market, from

14:20

a couple of the big OEMs, as well as some of the

14:23

independent companies attacking newer systems, as well

14:26

as older systems, and essentially changing the

14:30

scan time/patient comfort equation in terms of MR

14:34

imaging. But let's start off with compressed sensing

14:37

and, you know, with typical, uh, spin echo imaging, uh, MRI.

14:41

We've got to count out each line in k-space

14:43

for each TR period. I think this can get very,

14:45

very long. I remember the old days when we tried

14:47

to do, you know, full-resolution fast

14:50

spin echo, full-resolution spin echo brain, it

14:53

would take 15, 17 minutes to get a dual-echo T2.

14:57

Over the years, we've come up with various forms of

14:59

undersampling, from half Fourier transforms to parallel

15:03

imaging with things like SENSE and, uh, um, multi-

15:07

directional SENSE, uh, like ARC and GRAPPA. Uh, the

15:11

pinnacle of where we're heading in this particular

15:13

space right now is compressed sensing, where we're

15:16

doing these pseudo-randomized but balanced sampling

15:19

of k-space, uh, really reducing the number of samples

15:22

we have to get, strikingly, to markedly accelerate.

15:26

Our actual scan times here.

15:28

You can see an application in routine practice.

15:31

We, in our network,

15:32

we have some 340 centers, somewhere in the vicinity

15:36

of 300 magnets. We probably have a hundred magnets or

15:40

so that are running the latest in terms of compressed

15:42

sensing from different manufacturers. And on all

15:45

of them, we're running something like this, where we

15:47

take a 3D mathematical acquisition and run it

15:51

faster and sharper. You, in this particular example,

15:55

we're actually using restricted field of view.

15:57

This is an example from a GE magnet.

15:59

Uh, and you see we get all this done in a

16:01

faster and sharper way by doing much more creative

16:04

sampling and faster scans. In this case, it gives us

16:07

just a little less artifact and actually even

16:09

the opportunity to raise the spatial resolution

16:12

of these studies, which is something

16:14

you should always bear in the back of your mind.

16:15

It isn't always about speed. Sometimes it's about

16:19

better quality at some of the speed trade-off

16:22

with better speed as well. As a matter of fact, some

16:24

of the manufacturers have actually gone to doing

16:26

things that I would best describe as making a

16:28

1.5T work like a 3T, and using these tools to denoise

16:33

and correct the images and get the quality where

16:34

it should be. But to give you a sense of the impact

16:37

of compressed sensing in day-to-day practice.

16:39

I show you some of our protocols from, uh, this

16:43

happens to be a Philips magnet, uh, pre and

16:45

post-implementation of compressed sensing on

16:48

top of our routine day-to-day protocols. You can

16:51

see the cumulative scan times of the current, the

16:53

cumulative scan times under compressed sensing, and

16:56

none of these are limited protocols. This is just

16:58

routine, everyday protocols with everyday quality,

17:01

and you can see just by going to a greater degree

17:04

of undersampling through this enhanced version of

17:08

compressed sensing, we're able to get savings of

17:11

20 to almost 50 percent in routine brain imaging.

17:15

And you can do this to go fast, or, I also mentioned,

17:19

you can start to do these truly isotropic acquisitions

17:23

as the ones, as you might only see in academic

17:26

settings, uh, can now be done in scan times that

17:29

are practical for everyday use.

17:32

On the other hand, you can take an exam like

17:35

this, a routine everyday MRA, which might take

17:39

4 to 6 minutes on your scanners, and get a clear

17:43

50 percent reduction across the board.

17:46

And the data is so sparse.

17:48

And every one of our machines running compressed

17:50

sensing is now doing the brain MRAs in only

17:53

about two minutes, as opposed to where we

17:55

were before, which is really kind of exciting.

17:58

When it comes to the spine, you can again see

18:01

our cumulative diagnostic scan times on the

18:03

left and where we were with compressed sensing.

18:06

And the average savings here is running

18:08

30 to 50 percent in these cases.

18:11

And that's a big boost in terms of patient comfort.

18:13

At our organization, we noticed that.

18:16

We get substantially better ratings on

18:18

our 3T than we get on our 1.5T.

18:21

And you know, all things the same, in

18:22

the same building with the same doctors,

18:24

with the same, you know, protocol goals.

18:27

Uh, and the only way we can explain that, 'cause 3T

18:29

is kind of uncomfortable, Todd, you know, it's loud.

18:33

The only way to explain why people would prefer in a

18:36

substantially, in a statistically significant way, the

18:41

3T over the 1.5T, is that those exams are

18:44

two to three minutes faster over the course of an exam

18:47

experience. So, you know, regardless of whether you're

18:49

busy or not, whether you need the volume or you don't,

18:53

uh, whether you're in, you know, reduced volume as

18:56

we're seeing in New York City due to COVID, or preparing

18:59

to come out of, uh, COVID with a surge of pent-up

19:04

demand for oncology exams that haven't been done,

19:07

the speed benefits will help you there, if not with

19:10

patient experience, at least with throughput. Now, as you

19:14

might imagine, these images are too small, I don't

19:16

think you need to see them unless you really care to,

19:18

but it shows the different approaches. You can choose to

19:20

go faster, you can choose to boost your routine quality,

19:24

or you can change the spatial resolution to compete

19:27

with the 3T across the street when you're running a 1.5T.

19:29

19:30

That's really the key piece. Safety in the lumbar

19:32

spine—take a routine four-sequence protocol, uh, from

19:35

say, seven and a half minutes down to five minutes,

19:38

or up to 11 minutes, you know, getting the better

19:41

quality or the better speed along the way. And these

19:44

are tools that we will apply creatively and perhaps

19:47

selectively depending on the patient demand. When

19:50

it comes to musculoskeletal, you see we get the

19:52

same type of boost, about 30 to 40 across the board.

19:55

So, you know, please, if you have these tools, use them.

19:58

Um, they produce image quality just as you would

20:02

expect, but do it in a way that's going to be more

20:04

resistant to motion, and it is going to be much more

20:07

patient-friendly. And in some cases, well, I'll allow

20:10

you to let your imagination roam and perhaps aim for

20:13

quality that just wasn't practical on your current

20:16

generation machine. For us, in many cases, these tools can

20:20

help with older machines that really couldn't move that

20:23

fast, particularly when I come to the next iterations of

20:26

these tools. And the next one to talk about is iterative

20:29

reconstruction. Some of you may be familiar with

20:31

that term, iterative reconstruction, from CT, and we'll

20:34

address CT, but these tools are also available for MR.

20:37

And this is a machine learning-assisted iterative reconstruction MR tool,

20:41

where they essentially took the routine exam, which

20:43

you see on the left, and created an accelerated exam,

20:50

about 33% faster, and used the tool to reduce the noise,

20:53

maintain the resolution, and put them up side by side.

20:58

We did a trial which we presented

21:00

incrementally depending on what we were doing.

21:02

We ended up doing two spines and one brain

21:05

exam on these patients, and we presented

21:09

these results in a variety of academic meetings.

21:12

But in these cases, you can

21:13

see what we're aiming at here.

21:14

You can see the blue bars on the right-hand

21:15

side. You see the red line at three and three,

21:19

which basically means the accelerated process version

21:22

is the same as the unprocessed state standard

21:25

of care version. You can see in the brain

21:27

there was no statistical significance in

21:31

ratings between the accelerated 33% faster

21:34

process version and the standard of care version.

21:36

That's really pretty cool.

21:38

Here you see an example of a lumbar spine.

21:40

Normal protocol was 249.

21:42

Here, the protocol for the trial was

21:44

1 minute 30, about a 50% reduction.

21:47

And in this particular part of the study, again,

21:50

you see there was no statistical significance.

21:52

Ratings are just about three.

21:54

Comparing the standard of care exam against

21:56

the accelerated exam with the machine

21:58

learning-assisted iterative reconstruction.

22:01

Here you see the cervical part of the exam.

22:03

We went from three minutes down to two minutes,

22:05

a 32% reduction, and again, you can see here no

22:08

statistically significant difference between the

22:12

accelerated version and the standard of care version.

22:14

In this case, the numbers above three mean that the

22:17

accelerated version was actually better, probably

22:19

because we did a better job with noise reduction

22:21

while still preserving edges, but statistically

22:24

non-inferior for all three applications across the board.

22:27

So what's the message here?

22:28

You can use iterative reconstruction commercially

22:31

available, probably adaptable to any of your

22:34

machines that don't have all the bells and whistles.

22:36

Um, maybe it doesn't have the

22:38

greatest coils for acceleration.

22:40

You can find your way to get your

22:41

acceleration, uh, in this image space.

22:46

Now, you know, the question I always ask myself is,

22:48

um, there are noise-reducing filters on our systems.

22:52

A lot of us don't use them.

22:53

We use them extensively, uh,

22:55

because we believe in them.

22:56

I think they produce, you know, entry

22:58

level versions of what you see here.

23:00

Today, uh, but the theory is that these tools

23:04

the ones you'll hear about over the next

23:05

20 minutes or so will take you beyond the ability

23:08

of a system to cope with what's built in. And this

23:11

was a little trial that we presented at RSNA.

23:14

Was it RSNA?

23:15

Uh, uh, yeah, maybe it was RSNA, um.

23:18

Somewhere over the last few months,

23:19

we presented this limited trial at a meeting, and

23:22

this is what we were after for this particular

23:24

demonstration trial. You have a typical five-minute

23:27

T1 on the left-hand side. We, uh, asked

23:30

the manufacturer to create a, uh, compressed sense

23:33

factor for the scan, which reduced the scan time in half.

23:37

If you look at the central portion of the

23:39

image here, you can see there's a little bit

23:41

of noise breakthrough, but to many folks,

23:43

radiologists actually like structured noise.

23:45

They may think this is a perfect image.

23:47

Um, if you ask the, uh, iterative reconstruction

23:52

software to process this accelerated image at two minutes and 30,

23:55

you can see we maintain really excellent edge

23:57

definition, uh, but we also do a very nice job of

24:00

selectively, uh, removing that parallel

24:03

imaging-related model in the center of the image.

24:07

So, producing an excellent image in half the time,

24:10

going beyond what the manufacturer could do in

24:13

the middle. If that wasn't obvious enough, let's

24:15

take it down to compressed sense of eight here.

24:17

You see, with the onboard noise-reducing filters,

24:20

the Philips system just kind of fails. You can't

24:23

go that hard right, and the application people.

24:28

Well, you can't push that hard. Well, it turns out if

24:30

you have this iterative reconstruction tool, you can

24:33

push that hard, and you can see we've maintained

24:35

all of our edge definition. Uh, a pleasing

24:38

relatively pleasing image appearance. You, and

24:41

we've pretty much selectively removed the central

24:43

noise in the image, which is pretty exciting.

24:45

Here's another example, uh, standard image at

24:48

2.15, uh, is that what it is?

24:51

Actually, yeah, uh, here we are at

24:54

1.09 with the Philips filter.

24:55

Here we are with 1.09.

24:57

With the, uh, iterative reconstruction processing, you

25:00

can see, again, a pretty good job reducing the noise

25:03

in the image beyond what the manufacturer can muster,

25:06

uh, taking us to the next level in this particular

25:08

limited demonstration trial. You can see that the

25:11

iterative reconstruction came closest to matching the

25:13

benchmark image quality compared to the, um, compressed

25:18

sensing with the manufacturer's noise-reducing

25:19

filter and compressed sensing with no noise-reducing

25:23

at all. All right, so that's iterative reconstruction.

25:27

Um, where is the world going now?

25:30

Well, the world is moving into, um, deep

25:33

learning reconstruction, and I'll show

25:35

you kind of why we needed to go there.

25:38

You're all familiar with iterative

25:39

reconstruction for CT, right?

25:41

It has allowed us to go to those levels that

25:44

with traditional reconstruction, we would

25:46

call that filtered back projection. We would

25:48

get an image that's non-diagnostic and noisy.

25:50

Right, but using iterative reconstruction techniques,

25:53

this is a model-based iterative reconstruction

25:55

technique, this case from General Electric, you can

25:58

see that we can actually get the image quality to

26:02

uh, restore the normal noise levels and restore the

26:04

normal image quality, yet using a markedly reduced

26:07

dose for an abdomen and pelvis if you're a dose guy.

26:10

This was a CTDI of six, which is a lot lower than

26:13

our traditional techniques would do now.

26:16

The interesting thing about iterative reconstruction

26:19

is that, you know, there are a lot of complaints

26:21

about iterative reconstruction creating an odd image.

26:23

Look, there were some changes

26:25

to the quantitative values.

26:26

We'll talk about all of those.

26:27

But the good news is that

26:29

two major vendors are now

26:31

marketing FDA-cleared CE-mark software

26:35

based on neural networks that will actually

26:37

reduce the noise of CT images but maintain the

26:41

traditional look and integrity of those images.

26:43

This is an example from a GE machine. You can

26:45

see here a noisy filtered back projection, what

26:48

it looks like with traditional manufacturer

26:51

iterative reconstruction on the CT.

26:53

It's basically texture of the image a little odd.

26:56

So some of the noise is coming through at a funny

26:58

texture. When you look at the deep learning-based

27:00

image, it looks a lot more like the CT you know

27:02

your mom and pop used to love. If you look at

27:06

this particular example, um, Dr. Tim Stick gave

27:09

me these images. His Twitter handle is

27:11

on one of these slides. If you really want to

27:13

learn a little bit about CT physics every day,

27:15

please go to his Twitter page and check it out.

27:18

In fact, it's at Professor underscore Tim Stick. You'll

27:21

see that one of the slides coming up, but very nice

27:24

example of what a phantom looks like at full dose.

27:27

Okay, typical structured noise in the image on a CT

27:30

image. You know the way we can do the projections,

27:33

but otherwise, really not very high noise. So

27:35

you measure noise on CT by putting an ROI on and

27:38

looking at the variation, and the noise level here

27:40

would be reflected in the standard deviation of 15.

27:43

If we drop the dose from 80 to 8,

27:48

okay, you see the noise goes up to 32.

27:50

And you can see it in the image.

27:51

There's a lot more noise in that image.

27:53

No one likes this image.

27:54

For some reason, radiologists

27:55

love the structure of this image.

27:57

Now, if we take this image and apply what, in

28:00

this case, is ACER 50, which is a 50 percent

28:03

weighting traditional iterative reconstruction.

28:06

You can see, uh, we're still at the dose of

28:08

eight, but we're able to reduce the noise from

28:11

32 down to 21, not quite 15 of the dose that is

28:15

10 times higher, but really a respectable number

28:18

compared to where we were. Now, if I take the

28:21

same data at 8.2, excuse me, the same data at

28:25

a dose of 8.2 and apply a true deep learning

28:29

method of noise reduction.

28:31

Notice what happens.

28:33

I have an appearance very, very similar to the

28:37

routine image, not different or altered like it

28:41

is with traditional iterative reconstruction.

28:44

And by the way, the noise level is

28:45

coming right back to where it should be.

28:47

So, in this case, we're delivering with deep learning

28:50

the noise levels we expect. Okay, and the image

28:53

appearance we expect, at least in this phantom.

28:56

Now we know that regardless of which tool we use,

29:00

when we do iterative reconstruction with CT with

29:03

traditional methods, we alter the appearance of

29:05

tissue. Things look a little different in terms of

29:07

their density. This particular phantom study, done

29:10

by Dr. Tim Stick, there's his, um, there's his

29:13

handle at, you know, at Professor underscore

29:17

Tim Stick. He shows that all of these dose phantoms

29:20

have exactly the same appearance, whether they're

29:22

done with the deep learning reconstruction on the

29:25

right or the filtered back projection on the left.

29:28

So, tissues will look the same and behave the same.

29:31

The Hounsfield units will be the same here.

29:34

You see a quantitative phantom on the left-hand side.

29:36

You see the behavior of bone, acrylic, and

29:40

another material, which I forget what that is.

29:42

I think it's, um, uh, polyethylene, perhaps.

29:47

You can see that the behaviors that these

29:49

tissues will have with traditional CT reconstruction.

29:53

Look what happens when we do a, uh,

29:55

iterative reconstruction technique on this.

29:57

I'm going to go back up.

29:58

Just trying to move my picture off my slide.

30:01

Uh, whether we use a model-based iterative

30:02

reconstruction or we use the traditional iterative

30:04

reconstruction, you'll notice that there is

30:06

a significant variation in the appearance of

30:09

these tissues, the densities of these tissues,

30:12

um, uh, when it comes to, uh, or appearance

30:17

of these tissues, excuse me, when it comes to

30:19

the gold standard filtered back projection.

30:22

Um, the best way to get a feel for how the

30:25

texture of the image changes is from these slides.

30:27

Here, we're comparing any of these curves

30:29

we'll do, but focus your eyes on one.

30:32

Um, you see the red curve, the

30:33

green curve, and the yellow curve.

30:35

Uh, the blue curve is actually, uh, the curve of

30:38

what we do when we have a filtered back projection.

30:40

The overlying red curve is what we

30:42

have when we're using a deep learning

30:44

form of iterative reconstruction.

30:45

You see there's virtually no variation

30:47

in the texture of that image.

30:49

This is a, uh, a noise power spectrum image, so that's

30:52

how you get texture out of it. But notice the markedly

30:55

different noise power spectrum of the iterative

30:58

reconstruction applied in a heavy fashion with

31:01

traditional techniques. So the lesson here is one, the

31:04

densities of tissues don't change with the deep

31:06

learning tool, and two, the texture spatial for

31:10

the noise power spectrum. It doesn't change as well.

31:12

The message here is it looks the same.

31:14

Here you can see phantoms taking a close look

31:17

at the image texture from the same phantom.

31:19

Look at all that odd texture there on the left

31:22

hand side that just isn't there in the phantom

31:25

and just isn't there with the deep learning.

31:27

Again, thanks to Dr.

31:28

Stick for all these great images.

31:31

Another way that you will see demonstrated with

31:34

by some of the OEMs is something like this

31:38

where they do a subtraction experiment. Imagine

31:40

this is our phantom. Then we've just filtered

31:42

the heck out of it just to make a point, right?

31:45

And we've given up a lot of the spatial resolution

31:47

at least it seems, and then we've processed it

31:49

with deep learning here, and claiming that we

31:51

don't give up any spatial resolution when you

31:53

subtract this from this. Look at all the detail.

31:55

It's gone. It's lost.

31:58

Okay, which you don't see any structure with the

32:00

deep learning reconstruction, which is really one

32:02

of the other key points. Again, taking a, uh, the noisy

32:06

image at ultra, ultra low dose, processing it with deep

32:10

learning, subtracting the two to see if we lose any

32:12

structure, and look, not a single piece of recognizable

32:16

anatomy in there. And that's very reassuring to see

32:18

these tools are going to take us to the next level.

29:57

I'm going to go back up.

29:58

Just trying to move my picture off my slide.

30:01

Uh, whether we use a model-based iterative

30:02

reconstruction or we use the traditional iterative

30:04

reconstruction, you'll notice that there is

30:06

a significant variation in the appearance of

30:09

these tissues, the densities of these tissues,

30:12

um, uh, when it comes to, uh, or appearance

30:17

of these tissues, excuse me, when it comes to

30:19

the gold standard filtered back projection.

30:22

Um, the best way to get a feel for how the

30:25

texture of the image changes is from these slides.

30:27

Here we're comparing any of these curves

30:29

we'll do, but focus your eyes on one.

30:32

Um, you see the red curve, the

30:33

green curve, and the yellow curve.

30:35

Uh, the blue curve is actually, uh, the curve of

30:38

what we do when we have a filtered back projection.

30:40

The overlying red curve is what we

30:42

have when we're using a deep learning

30:44

form of iterative reconstruction.

30:45

You see there's virtually no variation

30:47

in the texture of that image.

30:49

This is a, uh, a noise power spectrum image, so that's

30:52

how you get texture out of it. But notice the markedly

30:55

different noise power spectrum of the iterative

30:58

reconstruction applied in a heavy fashion with

31:01

traditional techniques. So the lesson here is, one, the

31:04

densities of tissues don't change with the deep

31:06

learning tool, and two, the texture spatial for

31:10

the noise power spectrum doesn't change as well.

31:12

The message here is it looks the same.

31:14

Here you can see phantoms taking a close look

31:17

at the image texture from the same phantom.

31:19

Look at all that odd texture there on the left

31:22

hand side that just isn't there in the phantom

31:25

and just isn't there with the deep learning.

31:27

Again, thanks to Dr.

31:28

Stick for all these great images.

31:31

Another way that you will see demonstrated with

31:34

by some of the OEMs is something like this

31:38

where they do a subtraction experiment. Imagine

31:40

this is our phantom. Then we've just filtered

31:42

the heck out of it just to make a point, right?

31:45

And we've given up a lot of the spatial resolution

31:47

at least it seems, and then we've processed it

31:49

with deep learning here and claiming that we

31:51

don't give up any spatial resolution when you

31:53

subtract this from this. Look at all the detail.

31:55

It's gone. It's lost.

31:58

Okay, which you don't see any structure with the

32:00

deep learning reconstruction, which is really one

32:02

of the other key points. Again, taking a, uh, the noisy

32:06

image at ultra, ultra low dose, processing it with deep

32:10

learning, subtracting the two to see if we lose any

32:12

structure, and look, not a single piece of recognizable

32:16

anatomy in there. And that's very reassuring to see

32:18

these tools are going to take us to the next level.

32:21

Again, you can actually look at the spatial resolution

32:24

of these tools, whether you apply the deep learning

32:27

reconstruction on lighter or heavier levels.

32:30

The image doesn't really look much different.

32:32

And the phantom doesn't look much different.

32:34

So you really can use this at the highest

32:36

level without fear of losing any information,

32:39

which is really kind of cool. And here's a nice

32:42

clinical case showing you what the images look

32:44

like with the deep learning reconstruction.

32:46

Nothing at all foreign about this appearance.

32:48

That really is the key thing. Again, here you see a five

32:51

millimeter traditional acer image. When you go down to

32:54

the thinner slice, you start to see the noise breaking

32:56

through, and you see the texture here, you, uh, as well.

33:01

Uh, and here you can see, um, how the deep learning

33:05

tool maintains the low noise levels, uh, and maintains

33:09

the kind of look to the image that you'd expect.

33:12

All right, so, um,

33:16

my primary goal was to talk about tools that

33:18

affect the length of an MR acquisition because

33:21

those are the ones that impact, you know, patient

33:23

comfort as well as, you know, throughput on an

33:26

exam that we do, you know, laborious scanning on.

33:31

And we're going to talk about these

33:33

tools that are now clinically available.

33:34

GE announced their AirDL recon

33:37

was FDA approved this week.

33:39

Canon had their, um, their onboard, uh,

33:42

deep learning reconstruction approved

33:43

just a couple of months before then.

33:45

And SubtleMR, which is, uh,

33:47

which is a, uh, an AI company.

33:51

They have had a iter, they have had their version

33:54

of deep learning, uh, reconstruction available for

33:59

even longer, and I'll show you examples of all three.

34:01

In this particular example, as you can see here,

34:04

you can see we've taken this 2D FASP and Echo to 0.

34:09

9 millimeters, a true 0.

34:10

9, something that you would have thought

34:12

would never possibly work, and used deep

34:15

learning to go ahead and completely denoise

34:17

this image while maintaining the structure.

34:19

Imagine that you could look at your lumbar spine in

34:22

a seamless sort of paging fashion instead of jumping

34:25

by threes or fours, jump by less than a millimeter.

34:28

How would that affect your ability to see

34:30

things like this angular fissure here at L3 4?

34:34

We have some real challenges in MR.

34:37

Sometimes it's about going faster.

34:39

Sometimes it's about raising the spatial resolution.

34:42

Sometimes it's about dealing with

34:43

something that we just struggle with.

34:45

And one of the things we struggle with pretty

34:47

consistently is getting great prostate images.

34:50

Uh, in a reasonable length of time. Uh, and here you see

34:54

this example of a patient being done with a roughly

34:57

three-minute axial scan Uh of the prostate. We

35:01

took the same data. The zeros and ones in this case

35:04

went off to a workstation, processed, sent back to the

35:07

PACS and got you the image on the right-hand side.

35:11

Okay.

35:12

It's exactly the same scan.

35:14

What do you notice first of all?

35:15

The signal-to-noise is much higher. Um, it looks

35:18

a little glossier; that might strike you initially.

35:21

But notice how the edges are actually sharper.

35:25

Look at the prostate capsule; it's sharper.

35:27

Look at these synovial cysts;

35:28

you're not losing any detail.

35:30

When you look into the tissues, you actually

35:32

can see more detail because we reduced

35:34

the background noise of those tissues.

35:36

So, the theme of deep learning reconstruction

35:39

here, now these slides say WIP, but

35:41

this is just the proof this week.

35:42

Is we can improve on routine image quality, and our

35:45

initial investigation is where do we lose anything?

35:48

And to date, we really felt that

35:49

we've lost virtually nothing. Again,

35:51

these can be applied at variable weighting. Here is the

35:53

routine image showing the routine noise levels of a 30-minute exam on the prostate, but applied at 50. You

36:02

can see that the noise levels are markedly reduced.

36:04

The edge definition is, uh, sharp

36:07

or sharper in actuality.

36:10

And look at the bladder.

36:11

Look how uniform the signal is within the

36:13

urinophilic bladder compared to this structured noise here.

36:19

Again, radiologists like structured noise.

36:21

It feels like resolution, but it's not.

36:23

It's actually structured noise.

36:26

Again, taking a closer look, here is

36:28

the zero or essentially the image which

36:29

comes right off the scanner to the PACS.

36:31

And this is the one that went through

36:33

the algorithm and then onto the PACS.

36:35

And you can see, uh, you know, a lot of

36:37

the internal architecture is better seen.

36:39

The contrast between this low signal area

36:41

and this, uh, higher signal area in the

36:45

central zone here, you can see is enhanced, actually.

36:51

Take a look at the colons.

36:52

It's enhanced.

36:53

It's cleaner.

36:54

Everything is again, you know, patient with

36:56

diverticulosis and a uterine leiomyoma. Again, the

36:59

routine image and what it looks like routinely off

37:02

the system with the deep learning reconstruction.

37:04

Like anything else I've showed you

37:06

so far, you can go either way, right?

37:08

You can go with higher quality.

37:10

You know, strain the resolution, make up the noise with

37:14

this tool that recognizes noise and eliminates it while

37:17

preserving resolution, or you can use it to go faster.

37:21

Okay, and that really is the key

37:22

piece for here across the board.

37:24

This is an example from Canon, uh, where they

37:27

actually did an exam that could not possibly

37:30

be supported at this field strength, then

37:32

used the deep learning reconstruction to take

37:34

the noise out while preserving resolution.

37:35

The structure.

37:36

This is another thing that people are

37:37

going to do with these techniques.

37:39

Um, and, uh, we, um, uh, it's another key

37:45

technique that, uh, we and others will

37:48

use to, um, to leverage these tools here.

37:52

You can see another example of the image off

37:55

the scanner on the left, the processed image

37:58

on the right, and, uh, uh, you can see really

38:03

nicely here how clearly the image is enhanced,

38:06

how the spatial resolution is not diminished.

38:09

And the edges actually may be slightly

38:11

improved on the left-hand side.

38:12

You see the example with the routine image

38:17

on the right-hand side. You see the example

38:20

with the deep learning in the bottom center.

38:22

I believe that's a deep learning example as well. Again,

38:26

look at the fifth metatarsal off the routine scanner.

38:28

Look at the fifth metatarsal and fourth metatarsal

38:30

head with the deep learning reconstruction. Again,

38:35

image on the left, image on the right, the same scan.

38:39

Okay, take a look at the articular cartilage.

38:41

Look at the contrast in this area that's denuded.

38:43

Look at the height of the articular cartilage.

38:45

It almost looks like it's bigger.

38:47

You know, our eyes, our brains react to higher spatial

38:50

resolution with the sense that structures are bigger.

38:54

And you can, you can see, you'll see this

38:55

routinely on these examples as we go along.

38:58

Here's another one: a little

38:59

full-thickness chondral defect.

39:01

Are we losing anything with these tools?

39:03

That's the question. We lose all of this, all the

39:06

salt and pepper and the soft tissues in the bone.

39:08

That's not real. Okay, uh, it disappears here.

39:12

Well, that feels odd. Well, we can get used

39:14

to this when we realize we're not losing

39:16

anything, and that's what this trial turned

39:17

up here. You see another example again.

39:20

Look at the articular cartilage here.

39:21

Look at this disease here.

39:22

Your mind might not recognize that, right?

39:25

It might not catch your eye.

39:26

Very hard to miss here.

39:28

First of all, look how much bigger the cartilage looks

39:30

and look how clearly delineated that pathology is.

39:33

And that's really what we're after.

39:34

Make the images, uh, convey the information better.

39:40

Again, you can see this chondromalacia

39:41

here in the sagittal view.

39:43

All of this structure of noise brought on by, you know,

39:45

pushing, maybe pushing the parallel imaging a little

39:47

too hard or getting close to the edges of the coil.

39:50

Notice the performance in terms of

39:52

noise top to bottom, front to back.

39:54

In this coil, it truly is revolutionary here.

39:56

You see another example on the left without

40:00

the tool, on the right with the tool.

40:02

And again, this is a zeros-and-ones processing from

40:05

the raw data. And taking a close look at this, uh,

40:08

of this side of the knee joint space. Look at how

40:10

much thicker this cartilage looks compared to that.

40:13

It looks visually like it's 30-40% thicker.

40:16

It's the same scan. All we've done is apply this tool,

40:20

reduce the noise, enhance the spatial resolution,

40:23

enhance the contrast resolution, and at least in

40:27

our limited studies, I haven't given up anything.

40:30

Here you can see this, this little

40:32

partially attached flap here.

40:34

You might not even see it here

40:36

if you weren't having a good day, but improve the

40:38

signal-to-noise ratio, preserve the spatial resolution, and it

40:41

just pops right out at you. Now, these tools can do a lot

40:46

of cool things and not simply filters. Firstly, nothing

40:49

I've shown you is filters. Um, but they're very clever.

40:52

They can be trained on an artifact

40:55

and learn to remove it. Here,

40:57

you see an example. We've got truncation artifact

40:59

and these multiple amylations in the cord. We can train

41:02

the algorithm to remove this artifact and get this.

41:05

So why would I want to remove that artifact?

41:07

Well, first of all, traditionally, we

41:09

remove the artifact by turning on a

41:12

Fermi filter or an apodization filter.

41:15

We do this on anything that has a rectangular

41:17

view, uh, to avoid the ringing, uh, that goes

41:20

into the image and the overall, uh, deterioration

41:23

of the image. To use these optimization filters,

41:26

we actually throw out the edges of k-space,

41:28

essentially throw spatial resolution in the garbage. If

41:31

I could turn off that filter, I would get the artifacts

41:34

back. But if I use the deep learning algorithm to remove

41:37

the artifact, I could actually win the battle, and that's

41:39

what I've done here. I've turned the Fermi filter off,

41:42

bringing my resolution back up, but then I get all of

41:44

these artifactual ringings. This artifactual ringing,

41:48

when I use the deep learning algorithm,

41:50

even though the filter is off, I can get rid of

41:52

the artifact and maintain the spatial resolution.

41:54

That's what these examples are, by the way.

41:56

Fermi filter off here.

41:59

What the deep learning algorithm does for this scan.

42:01

See all these little echoes: one, two,

42:04

three, they just don't show up when you

42:06

use the tool, when you train them out.

42:07

Here again, a typical image without the optimization

42:10

filter on, and what it looks like with the

42:13

tool, which recognizes that artifact as well,

42:15

as well as denoising and enhancing the spatial

42:17

just a little bit, as I showed you before.

42:20

This is a paper that we were

42:21

going to present to the ASNR.

42:23

If you go online to the ASNR,

42:24

you can see this right now.

42:25

We also presented in a different format

42:27

the artifacts made before we actually looked

42:30

at 93 image pairs of 28 patients at 1.5

42:33

and 3T. We looked at the routine images and

42:37

looked at the deep learning processed images

42:40

with the error recon DL tuned to 75% noise

42:43

reduction, and here are just some examples.

42:45

That's the starter came off the machine

42:46

on the left. There's the stir on the right.

42:51

I'm sorry.

42:53

There's the axial T2 on the left, very respectable.

42:56

Notice, much lower noise, slightly sharper edges.

43:00

And really respectable axial on the left, slightly

43:03

better, slightly sharper image on the right.

43:06

Typical T1 on the left, enhanced T1 on the right.

43:09

Notice all this noise out here, really

43:11

starting to see that structured noise.

43:13

You see how the fat pulses, you

43:14

can see noise shining through.

43:16

You can see how you just don't see that here.

43:18

Air is air, it's black.

43:20

It really is quite nice, and

43:21

again, what are we giving up?

43:22

I don't think we're giving up

43:22

anything of any note here again.

43:25

Look at all of this structured noise. Look at

43:27

how well we manage that noise yet still maintain

43:29

the tiniest little bits of structure in the

43:32

abdominal tissues, and look at this gorgeous, you

43:35

know, sharp image with really a very impressive T1

43:38

contrast. Not bad here. You know, this was a trial

43:40

to see, did we lose anything with this tool again?

43:44

Same type of example without the tool. With the

43:47

tool, you know, if you can do this in the same scan

43:51

time, what could you do in terms of acceleration?

43:54

I mean, that's really the key piece.

43:55

Again, here's just a couple of views of the same thing.

43:59

Off, 25, 50.

44:01

It's going to be 50, 75, and 100.

44:03

I like 100.

44:04

The study was done at 75.

44:06

But what are we losing between here and

44:08

here, other than the noise in the image?

44:10

As a matter of fact, if you look at the

44:11

end plate, see this little jaggedness here?

44:14

We don't see it here.

44:15

Seems like the algorithm recognizes

44:17

these eddy current type artifacts

44:19

and just removes them. Again, taking a closer look.

44:23

What have we lost?

44:24

The end plates are sharper.

44:25

The disc-sack interface is sharper.

44:27

We haven't lost any contrast resolution.

44:30

It doesn't look like we've

44:30

introduced any interesting artifacts.

44:33

Look at this annular fissure here.

44:35

That we see when you take a close look at that annular

44:37

fissure. You can argue clearly bigger here, clearly

44:41

less likely to be missed because of the enhancement,

44:44

spatial resolution, and look at all this noise.

44:48

Okay, it's just gone. So without belaboring the point,

44:52

the abstract would show that there was a statistically

44:55

significant improvement of the routine images when

44:59

the deep learning recon was applied for all of

45:02

these measures that I won't read through here. You

45:05

know, but they're all the things you'd ordinarily look at.

45:07

Now, to be fair to something I don't

45:09

have personal experience with, deep

45:11

learning is also available from Canon.

45:13

They call it ACE.

45:14

Um, you can see that they did the same thing

45:16

where they took a 3D flare, which took, um, in

45:21

100 seconds, the original image had an SNR of 7.

45:25

Um, and you can see it doubled the SNR

45:29

by processing it with their algorithm.

45:32

Uh, and again, it can show you how you

45:34

can start to aim at something on a 3T

45:36

that's closer to what people do on a 7T.

45:40

Well, you can't read that, right?

45:41

Well, what if you could denoise that stir and get that

45:44

kind of internal hippocampal architecture?

45:47

That's the key point.

45:48

So aim at something that's not practical.

45:50

Use the tool to make it so.

45:53

And that really is another thing

45:54

that folks will do with these tools.

45:55

Probably more likely to do those at academic

45:57

sites and sites like the ones where I

45:59

practice, where I'm trying to create, uh,

46:02

superb quality in a patient-friendly way.

46:05

Well, these slides, which are DTI, are just really there

46:08

to tell you that we don't lose any quantitative value

46:12

with these tools. The fractional anisotropy values are

46:15

exactly the same whether they process it with deep

46:17

learning or not. Very much like you had in the CT, in

46:20

the CT data earlier when the household unit stayed

46:23

the same across the board. Now, one last piece that

46:27

really is applicable to any system out there. You, uh,

46:29

that we have a fair amount of experience with in our

46:31

institution is, uh, subtle MRIs, deep learning-based

46:35

image processing, and here you can see it took an

46:37

image that looked pretty crude that was accelerated.

46:40

This is an axial reconstruction of a sagittal 3D

46:42

and turning it into a higher resolution version. So

46:45

for the most part, we really haven't talked about

46:47

resolution enhancement. What SubtleMR can do, which

46:50

is a true convolutional neural network processing

46:53

in the image space, is they can actually train in

46:55

higher spatial resolution with their algorithm.

46:58

You'll see some of that.

46:59

We actually have a pilot going

47:01

on right now, uh, at our centers.

47:03

We're in the middle of designing a financial

47:05

ROI model to determine how we can integrate this

47:08

into our practices, and if it comes through,

47:10

we'll find a way to make this stuff work.

47:12

But in this particular circumstance, um, we

47:15

actually did this particular abstract, which we are

47:18

presenting I think for the second time at the um,

47:23

at the American Society of Neuroradiology meeting

47:25

over the next couple of days. If you log on to

47:27

their servers, you can actually see the data in a more

47:31

meticulous fashion, but these are the highlights.

47:34

We wanted to see how well their aftermarket deep

47:38

learning tool did in terms of matching our routine

47:41

standard of care quality at highly reduced scan times.

47:45

In this particular trial, I

47:46

believe the number is an average of 33%.

47:48

And here you'll see the typical

47:50

triptych of images to evaluate. On the left-hand side,

47:53

you see standard of care; on the right-hand side, you

47:56

see what the images look like with a 30 acceleration.

47:59

And in the middle, what happens when you take the fast

48:01

image on the right and process it, uh, for, you know, and

48:05

process it with deep learning, incorrect, and create

48:08

the middle image. And the real goal of this study was

48:10

to see how well the DL fast emulated the standard of

48:15

care image. Again, fast on the right; standard of care

48:19

on the left. The image on the right, processed with deep

48:21

learning in the middle, uh, to create the same resolution

48:24

and noise levels across the board. Um, we've just done a

48:28

larger set of reads in this particular, um, experiment.

48:32

This is our original reads. Uh, but on the larger

48:35

set of reads with three readers of a larger data

48:37

set, there was, interestingly enough, superiority

48:41

of, uh, the deep learning FAST over

48:45

the standard of care for certain select criteria,

48:49

uh, and no statistical significance for the rest.

48:52

So the key message here, we were aiming

48:54

for non-inferiority; we clearly had it. The

48:56

standard of care was in no

48:58

way superior, uh, to the processed FAST images,

49:04

but in actuality, the processed

49:06

FAST images had a few areas of improvement.

49:08

Minor superiority over what we were

49:10

doing with routine standard of care.

49:12

You see another example: fast image on the right,

49:14

standard of care on the left. You can see the middle

49:17

image is a little lower and a little higher in

49:19

SNR, while not giving up any spatial resolution.

49:22

And the standard of care, maybe this is one of the

49:23

ones that got the higher ratings. Now,

49:29

I mentioned, um, the last piece I want to talk about,

49:32

which is super resolution. Um, these deep learning

49:35

tools, properly trained, I told you can remove

49:38

artifacts, but these deep learning tools, properly

49:41

trained, can actually train in spatial resolution.

49:44

And this is really fascinating.

49:46

Look at this image, which is a routine day-to-day case

49:48

done 30 slices a minute, 39 at one of our facilities.

49:51

If we try to accelerate that scan, we can

49:54

only do it by dropping the spatial resolution.

49:56

We drop the spatial resolution; we

49:57

actually increase the signal to noise,

50:00

but we clearly have a fuzzier image.

50:02

Imagine we could borrow the signal to noise,

50:04

borrow the contrast to noise that makes this

50:06

little lesion stand out more here than here, but

50:09

then train the spatial resolution of this on this.

50:12

That's what this represents.

50:14

Okay.

50:14

This is the subtle MR commercial available software.

50:17

We essentially denoise, accelerate, and maintain spatial

50:22

resolution by training what we've learned from the

50:24

high-res images onto the low-res images of the site,

50:27

allowing us to do arguably a better image than we

50:30

had before in less time than we had used in the past.

50:34

This is an example from an outside institution,

50:36

but the same thing: routine clinical quality

50:38

scan, accelerated low-res, high-contrast res, low

50:41

spatial res. Take the spatial res from the high

50:44

quality scan, train it onto the high-contrast

50:47

resolution scan, and you get the acceleration and

50:50

the quality you're used to. This is from my shop.

50:52

These are 3D FLAREs. The standard of care here is going

50:57

to be a little noisy because, first of all, we're

50:59

looking at thin partitions. Second of all, we're

51:01

trying to create an isotropic scan that makes good

51:03

reformats. So we will get a little noisy when we

51:07

take that scan and make it faster by dropping the

51:09

spatial resolution. In-plane, it looks pretty good.

51:11

But when we go through-plane, it's going to

51:13

suffer. Imagine that we could train the spatial

51:16

resolution of this onto the signal to noise

51:18

and contrast to noise of this, and then come up

51:20

with this, which is pretty, really pretty cool.

51:22

I can't see the scan time here, 346 to 246 in this

51:26

particular example. Here's an example from our

51:30

trial, uh, which we'll talk about in a moment.

51:32

You can see here.

51:33

I'm sorry.

51:33

There it is.

51:34

I'm going to go back up.

51:36

This was the standard of care scan.

51:37

A little noisy.

51:39

Okay.

51:40

This was the fast scan, a little low spatial

51:42

resolution, and this is what happens when you train

51:44

the spatial resolution of this onto this; you get this.

51:47

So a high spatial, high-contrast

51:49

resolution, high SNR example.

51:51

Pretty, pretty impressive stuff, I think.

51:53

So this is the trial we're presenting at the ASNR.

51:55

You can find this on the ASNR website, where we

52:00

essentially went for a 30% acceleration and super

52:03

resolution and aimed for a better result than our

52:05

standard of care. And here you see the examples: the

52:08

clinical standard of care scan, the clearly lower

52:11

resolution fast scan, and the net result with deep

52:14

learning with denoising and super resolution.

52:18

Look at what we get here: a much better result than

52:21

either one of these two alternatives. Again, clinical

52:25

standard of care scan, lower resolution fast scan,

52:30

deep learning fast scan, clearly higher spatial, clearly

52:33

higher SNR. And if you look closely, you know, these

52:36

two are exactly the same scan. This is a different one.

52:38

So there will always be a

52:39

slight difference in position.

52:41

So the fact that it looks bigger, you know, could

52:43

be a reflection of a slight difference in position,

52:46

but clearly, you can see higher SNR, higher spatial

52:49

resolution, and faster than the standard of care scan.

52:53

This is one of my favorites because I've

52:54

now seen this example a couple of times.

52:56

Clinical standard care looks pretty good.

52:58

Clinical, excuse me, fast scan starts to look a little

53:01

rough, and who knows what the reformats could look like.

53:05

Look at what the deep learning scan looks like.

53:07

It's really sharp.

53:08

It's really high SNR.

53:09

Now I want you to take a look.

53:11

There are two lesions here that are clearly seen

53:14

on the fast scan that, even though we raised the

53:16

spatial resolution of the deep learning scan, are still

53:19

beautifully seen, but are really hard to see.

53:22

I mean, we're pretty well registered

53:23

here on this gyrus, and we really

53:25

have a hard time seeing these. Yet,

53:27

we do see them here.

53:29

And I think that's largely due to the fact that

53:31

we have the inherently high contrast resolution of

53:36

the fast scan trained into the higher resolution

53:41

resolution-enhanced process fast scan.

53:44

So in our trial, which you can see the full results

53:46

on, uh, on the web, we found that these

53:51

tools produced a boost in quality, SNR, and resolution.

53:57

Yet allowed us to go roughly 30% faster.

54:01

Now the same tools are also applied to things like

54:04

ASL. You can take an ASL scan from eight minutes

54:07

clinically; we would do four minutes, take it down to

54:09

one minute. And you can actually make the one-minute

54:12

scan look very much like the eight-minute scan

54:13

here. Kind of cool! If you're doing synthetic MRI in

54:17

your practices, you know, there are some trade-offs.

54:19

With synthetic MRI, one complex acquisition, you then

54:22

retrospectively calculate any contrast you like. You see

54:26

just moving the mouse can actually change the contrast.

51:55

You can find this on the ASNR website where we

52:00

essentially went for a 30 acceleration and super

52:03

resolution and aimed for a better result than our

52:05

standard of care. And here you see the examples: the

52:08

clinical standard of care scan, the clearly lower

52:11

resolution fast scan, and the net result with deep

52:14

learning with denoising and super resolution.

52:18

Look at what we get here: a much better result than

52:21

either one of these two alternatives. Again, clinical

52:25

standard of care scan, lower resolution fast scan,

52:30

deep learning fast scan, clearly higher spatial, clearly

52:33

higher SNR. And if you look closely, you know, these

52:36

two are exactly the same scan. This is a different one.

52:38

So there will always be a

52:39

slight difference in position.

52:41

So the fact that it looks bigger, you know, could

52:43

be a reflection of a slight difference in position,

52:46

but clearly you can see higher SNR, higher spatial

52:49

resolution, and faster than the standard of care scan.

52:53

This is one of my favorites because I've

52:54

now seen this example a couple of times.

52:56

Clinical standard care looks pretty good.

52:58

Clinical, excuse me, fast scan starts to look a little

53:01

rough, and who knows what the reformats could look like.

53:05

Look at what the deep learning scan looks like.

53:07

It's really sharp.

53:08

It's really high SNR.

53:09

Now I want you to take a look.

53:11

There are two lesions here that are clearly seen

53:14

on the FAST scan that, even though we raised the

53:16

spatial resolution of the deep learning scan, still

53:19

beautifully seen, that are really hard to see.

53:22

I mean, we're pretty well registered

53:23

here on this gyrus, and we really

53:25

have a hard time seeing these, yet

53:27

we do see them here.

53:29

And I think that's largely due to the fact that

53:31

we have the inherently high contrast resolution of

53:36

the FAST scan trained into the higher resolution,

53:41

resolution enhanced process FAST scan.

53:44

So in our trial, which you can see the full results

53:46

on the web, we found that these

53:51

tools produced a boost in quality, SNR, and resolution,

53:57

yet allowed us to go roughly 30 percent faster.

54:01

Now, the same tools are also applied to things like

54:04

ASL. You can take an ASL scan from eight minutes.

54:07

Clinically, we would do four minutes, take it down to

54:09

one minute, and you can actually make the one minute

54:12

scan look very much like the eight minute scan.

54:13

Here, kind of cool if you're doing synthetic MRI in

54:17

your practices. You know, there are some trade-offs

54:19

with synthetic MRI. One complex acquisition, you then

54:22

retrospectively calculate any contrast you like. You see,

54:26

just moving the mouse can actually change the contrast.

54:28

It's a wonderful tool. We showed in an ASNR paper

54:32

that it essentially can fill in for routine day-to-day

54:34

clinical individual scans. The only real trade

54:38

off is a slightly odd look to the FLAIR. By the way,

54:41

the top row is synthetic and the bottom row

54:43

is the traditional individual example. You

54:47

can see this is a pretty much a FLAIR horror show.

54:50

It gets about this bad. You get some speculation

54:53

in the CSF; you get some hyperintensity of the

54:56

sulfide G. You know, if this is predictable,

54:59

could I use deep learning to get rid of it?

55:01

Well, with subtle medical folks in one of their

55:03

publications show that they actually can take,

55:06

you know, pretty much an awful synthetic MRI scan and

55:10

with a variety of different methods of processing

55:12

it restore the traditional quality we expect. So this

55:16

may be one of the limiting factors. We're removing

55:19

one of the limiting factors to routine implementation.

55:22

Mind you, if you can improve signal to noise,

55:25

in MR, you can improve it in MR functional imaging,

55:28

you can improve it for PET imaging. And this is

55:31

another FDA-approved tool called subtle PET. In this

55:34

particular case, where they actually took a, we did

55:36

a one-minute scan. Noisy compared to the four-minute

55:40

scan standard. Well, they actually didn't do it.

55:42

They actually simulated it through list mode, but

55:45

nevertheless, using list mode simulation, they were

55:47

able to take their tools and make the one-minute scan

55:50

look like the four-minute scan. When you're talking

55:52

about multiple beds for a patient, you can take an

55:54

exam time, you know, down to a very respectable short

55:58

amount of scan time compared to what it normally

56:00

takes. Here's a 20-minute for a beta-PET scan. Here's

56:04

what happens when we simulate five minutes with list

56:06

mode. And this is what happens when we process a list

56:08

mode scan with the subtle PET software. Now, being

56:11

an MR guy more than a PET guy, I'm really kind of

56:14

excited about things like this. And this is not FDA-

56:16

approved as yet. This is some work in progress.

56:19

They published this, so it's coming from the published

56:21

literature. But I'm sharing this under my own volition.

56:25

You can see they've got a conscious enhancing left

56:27

thalamic lesion here. When you use only 10% of the

56:30

contrast, you can't perceive the enhancement.

56:33

But we train the algorithm on full-dose enhancement.

56:36

It learns to bring the enhancement out of this 10%

56:39

and then can synthesize an image that looks

56:41

very much akin to what the routine image looks like,

56:44

essentially allowing you to go to 10% of the dose.

56:47

Here's a full-dose scan. This is what it looks

56:49

like at a tenth of the dose, and here's what

56:51

it looks like when you simulate or synthesize

56:54

using deep learning this image from that image.

56:58

It's pretty impressive, I think.

56:59

Particularly if you're concerned about serial

57:02

administration of gadolinium, the patients who are

57:04

going to get multiple exams over the course of their

57:07

lifetime, pediatric patients, patients who may

57:12

actually be seen outside of the neural area for the

57:15

inflammatory bowel disease, high-risk cancer screens.

57:17

It's, you know, the potential to use less contrast.

57:21

Pretty exciting here.

57:21

One more time.

57:22

I don't see anything here around the right frontal

57:24

horn at 10%, at full dose I see forward

57:27

enhancement, and just using deep learning to take

57:30

this image and make it look into that image. The question

57:33

is what do we miss, and clinical trials need to

57:35

be done to see whether you can fully emulate

57:37

this approach. But it is still pretty exciting.

57:41

So I have no idea where I am on time.

57:42

I expect I'm running long, so I hope I gave you

57:45

some sense of background in AI. But I hope

57:49

you walked away with excitement over what these

57:52

tools can do to get us over the limitations

57:55

of the tools we use today and the limitations of

57:58

scan times and radiation doses we have today.

58:01

Thank you very much for your attention.

58:04

Perfect.

58:04

Thank you so much for that.

58:05

I really appreciate you joining

58:06

us for this noon conference today.

58:07

I do see it's one o'clock.

58:08

I'm not sure what your schedule looks like.

58:09

But if you have time, we do have a

58:10

few questions in this Q&A feature.

58:12

I can stay.

58:14

Okay, perfect.

58:14

Um, if you open up that Q&A feature,

58:16

it might be best if you read it.

58:17

If you move your mouse to the top, you'll,

58:19

oh, now you'll see it at the bottom.

58:21

Okay, uh, under Q&A.

58:23

Got it.

58:24

I gotta hide this little button here.

58:28

Uh, we will change our carriers soon.

58:30

I don't know what that means.

58:31

Okay, I'm looking for a question I can translate.

58:33

Um, okay, a real quick one while I'm

58:36

looking for something else to talk about.

58:38

Are medical school students dropping out

58:40

of radiology, losing interest in radiology?

58:42

Well, I don't have last year's data, but

58:44

over the previous two years, we had essentially

58:47

100% filling of radiology spots, up from

58:51

only about 85% just a few years earlier.

58:54

So while undoubtedly some people may not see

58:56

the field as attractive as they did in the past,

59:00

clearly,

59:01

they are not running away from the field right now.

59:04

And it still is a very, very attractive field. As

59:07

a matter of fact, I think personally it is one of the

59:09

best times to be a radiologist, where you'll be more

59:12

central to everything that goes on. We've always been

59:14

the center of diagnostic information, creating the

59:17

next step in the pathway. But since we're naturally

59:20

suited sitting where we are in the center of all this

59:23

data, uh, and we now have tools and assistance that

59:27

will help us filter through the data, scraping the

59:29

medical record for key points that we need to find,

59:31

I'm bringing it all to our fruition, reminding us that

59:34

hey, you know, this patient has got a high risk of

59:38

cancer. Do you want to take a second look at this?

59:41

You know, non-descript findings—those

59:43

things are going to make it a lot better.

59:45

Um, uh, here's a quick one.

59:48

Can you apply deep learning to cone beam CT?

59:50

I suspect there's no reason you can't. I don't

59:52

have much experience with it. Um, another question

59:56

that says could AI be cleaning up too much?

59:58

That's a great question. Nobody really knows. I would

60:01

say that quoting one of my mentors, good is good.

60:04

Uh, you can recognize it when you see it, um, and, uh

60:08

thus far. In our research work and our clinical work,

60:11

we have not seen loss. As a matter of fact, all of my

60:14

experience in my career suggests that if you reduce the

60:16

noise, you reduce the noise. You actually get a big boost

60:21

in your contrast resolution, and that greatly overwhelms

60:26

any possibility of blurring out any pathology. But

60:30

obviously, you know, ideally, you would have controlled

60:33

trials in large-scale trials and multi-centered trials,

60:37

bearing in mind that we have that to virtually nothing

60:38

in MRI. But I, you know, I love the idea of having it.

60:41

Quick question, is the subtle MRI FDA approved?

60:44

It is.

60:45

Um, I mentioned several times during the talk,

60:47

which ones were approved, which ones weren't.

60:49

I really didn't show you anything except for maybe

60:51

the subtle GAD, uh, today that is not FDA approved.

60:57

Can the software now potentially

60:59

introduce more artifact?

61:00

There have been some phantom demonstrations, you know,

61:03

on ridiculous use cases that have shown the fear, but

61:06

nothing in these commercialized products

61:09

has led any credence to danger using them so far.

61:15

Will there be a learning curve

61:16

in learning to use these images?

61:17

Yeah, you know, it's hard to, you know, when you

61:19

go to, if you've ever experienced going from 1.5 to 3T,

61:22

the first reaction everybody has is suspicion.

61:25

Yeah.

61:26

What have you done to these images?

61:28

They look filtered.

61:29

Okay, I said that myself.

61:31

And why, what is that reaction?

61:33

You are reacting to the absence of noise.

61:36

So, yeah, it took a while to get used to 3D.

61:39

Not just the contrast differences, but you

61:41

actually look and the image is different.

61:43

It's cleaner.

61:43

There's less noise.

61:45

It does take some time to get used to less noise.

61:47

Um, but I imagine it's something I'd be happy

61:51

to get over if the scans were half as long,

61:53

the contrast resolution was

61:54

better, and the noise was lower.

61:56

The curve appeal of these images is extremely high.

62:00

Uh, let's see.

62:02

Uh, I think I've answered most of the other questions

62:04

in one way or the other, looking for another one.

62:08

Um, yeah, all right.

62:11

I think that's basically it.

62:12

I don't see anything else coming

62:13

up that I haven't really answered.

62:15

Um, somebody asked,

62:20

can I describe spatial resolution?

62:22

You know, I'm a Fred Flintstone physicist,

62:23

but I imagine you could describe that as

62:26

the smallest structure you can resolve.

62:28

To me, it's sharpness.

62:30

Um, you have an HDTV at home, you have a 4K TV if

62:33

you're lucky. Um, you know immediately it's better than

62:36

the old 13-inch screen you had on the cathode ray tube.

62:40

You can appreciate the sharpness.

62:42

You see how you feel details better, the image,

62:44

the screen is more intimate, the pictures are more human.

62:48

I think the same thing applies when you look at a

62:49

higher spatial resolution. You can see MR images.

62:52

You don't need to prove to me, at least, that higher

62:54

resolution is better.

62:55

Perfect.

62:56

All right.

62:56

As we bring this to a close, I want to thank you,

62:58

Dr. Tannenbaum, for your time today.

62:59

We really appreciate it.

62:59

And thanks to all of you for

63:00

participating in this Noon Conference.

63:02

A reminder that it will be made available

63:04

on demand, complimentary, at MRIonline.

63:06

com in addition to all previous Noon Conferences.

63:09

Uh, Monday, please join us for a Noon

63:11

Conference on Imaging of the Tinnitus with

63:14

Dr. David Pastel.

63:15

And follow us on social media for updates and

63:16

reminders on all upcoming Noon Conferences.

63:18

Thanks and have a wonderful day.

Report

Faculty

Lawrence Tanenbam, MD, FACR

Chief Technology Officer, Director of Advanced Imaging, Vice President

RadNet

Tags

Non-Clinical