The Peter Attia Drive - #61 - Rajpaul Attariwala, M.D., Ph.D.: Cancer screening with full-body MRI scans and a seminar on the field of radiology
Episode Date: July 8, 2019In this episode, radiologist/engineer, Raj Attariwala, explains how he was able to apply his engineering background to create a unique MRI scanner that is capable of constructing whole-body images wit...h a resolution that is unmatched in the industry. Peter and Raj discuss the implications of such a robust, radiation-free imaging tool on the early detection of cancer. They dive deep into cancer screening and define terms such as sensitivity and specificity that are necessary to really understand this complex space. They then describe the biggest risks involved in this type of screening (false positives) and how Raj’s unique technology and process might drive down this risk substantially. But before that, they discuss all the common imaging technology from X-ray, to CT scan, to PET scans, to ultrasound, to MRI, and more. They touch on the history of each, how they work, the usefulness and limitations of each of them, as well as the varying risks involved such as radiation exposure. If you are interested in cancer screening and/or you’ve ever wondered how any radiology tool works, this episode is for you. We discuss: Raj’s road from engineering to radiology [7:45]; How X-ray works, the risk of radiation exposure, and the varying amounts of radiation associated with the different imaging technologies [18:00]; Computed tomography scans (CT scans): The history of CT, how it works, and why we use contrast [27:45]; Ultrasound: Benefits and limitations, and a special use for the heart [40:45]; Detecting breast cancer with mammography: When is works, when you need more testing, and defining ‘sensitivity’ and ‘specificity’ [51:15]; Magnetic resonance imaging (MRI): How it works, defining terms, and looking at the most common types of MRI [1:03:45]; Brain aneurysms: Using MRI to find them and save lives [1:23:45]; Raj’s unique MRI technology [1:30:00]; The risk of false positives in cancer detection, and how Raj’s MRI can reduce the number of false positives (i.e., increase specificity) [1:43:40]; The unique software Raj created to pair with his MRI machine [1:51:15]; Comparing the radiation exposure of a whole-body PET-CT to Raj’s equipment (DWIBS-MRI) [1:53:40]; How diffusion-weighted magnetic resonance imaging (DW-MRI) has revolutionized cancer screening [1:55:15]; Why a DW-MRI is still not a perfect test [1:59:00]; The potential for advancing MRI technology: Where does Raj think it could improve in the next 5-10 years? [2:03:00]; Are there any commercially available scanners that can match the resolution of Raj’s images? [2:06:00]; Machine learning: When and where might machine learning/AI impact the field of radiology? [2:08:40]; and More. Learn more at www.PeterAttiaMD.com Connect with Peter on Facebook | Twitter | Instagram.
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Hey everyone, welcome to the Peter Atia Drive. I'm your host, Peter Atia.
The drive is a result of my hunger for optimizing performance, health, longevity, critical thinking,
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I guess this week is Dr. Raj Atariwala. Raj is an amazing guy. I've known him for several
years. He's incredibly well-trained. He first actually went down the engineering pathway
doing his PhD in biomedical engineering at Northwestern, then decided he wanted to go into medicine and sort of apply his engineering
approach to that.
So he went back to medical school, did his residency in radiology, and then went on to specialize
in nuclear medicine and spent a great deal of time at some of the top institutions in North
America, Memorial Sloan Kettering, UCLA, USC, etc. He's now back in Vancouver, and what he's been up to for about the past decade
has been effectively creating a new way of doing MRI.
So he's sort of what I think can only be described as an MRI ninja.
And that is to say, he's been able to tinker with the hardware and the software
to create a completely revolutionary product
and process by which to look at the body
using this technology of magnetic resonance.
Now, I think this is a bit of a technical episode,
but I also think it's one that anybody
who's ever had an X-ray CT scan, an ultrasound,
an MR on their life needs to listen to.
Why?
Because truthfully, most doctors don't actually understand
this stuff in great detail.
You have to really go out of your way in medical school and residency to understand radiology.
I was obsessed with it. I went out of my way to learn about it. I learned a little bit about it,
but obviously nothing to the level of what someone like Raj knows. And so what we did in this
episode, which you can sort of divide into two halves is as follows. The first half is sort of a history of radiology.
So we start with talking about what an X-ray is, how it works, what the radiation does and
doesn't mean CT scans, ultrasounds, PET scans, nuclear medicine scans, all of these things.
And I promise, we've done this in a way that is really geared towards the patient.
I think we do a pretty good job of always bringing it back to language that makes sense and we don't get terribly lost in the physics and of all areas in medicine where you can get
lost in the physics. This is head and shoulders above the rest. Second half of this episode,
we really do this deep dive into cancer screening and this particular type of MRI technology that
Raj has almost single-handedly developed, although he would probably bristle at the sound of me saying that because he's just such a modest fellow.
What I enjoy about this episode is it gives me a little bit of a chance to talk about cancer
screening.
This is something I'm incredibly passionate about, and it's something I love talking about
with my patients.
The show notes for this are going to be important because one, radiology is obviously a very
visual field.
You see things and much more than you sort
of hear things. So we're going to do a great job to pair a lot of what we discuss with
images, especially once we get into the confusing MRI stuff and we try to explain the difference
between a T1 weighted image and a T2 weighted image and a diffusion weighted image and things
like that. The second thing is we're going to link to some of the material that we use with our
patients on cancer screening because I know this is a very controversial topic and I suspect
that this episode is going to generate just a lot of controversy.
But I want to be clear that cancer screening is a very personal decision and it comes with
risks.
And the biggest risk, of course, is a false positive, which then leads to subsequent screening,
emotional distress, potential harm.
We talk about all of this stuff, and as I said, we'll link to some of the materials that
we've prepared specifically for our patients that I think just create a nice primer for
how to go through that.
Without further delay, please enjoy my conversation with Dr. Raj atariwala.
Hey, Raj, thanks for carving some time out today in the middle of your busy day. I've probably
done what no one else has done before, which is shut down this clinic, huh?
That's fantastic to see you again and to be here. It's a pleasure as always.
What's the deal with Vancouver and Uber? I got off the plane this morning and tried to
get an Uber to come here and apparently there's no Uber and Vancouver. It's stunning. Everybody
complains. We all complain, but I don't know. Somebody somewhere is not allowing it. It was amazing.
I was in India and you can get Uber in India. Yeah, and it's not a Canadian thing because I ubered in Toronto.
Toronto, Calgary, almost all the country, just Vancouver.
Yeah, very well.
I'll reserve my editorial comments for myself.
Well, I've been looking forward to this for a long time, Raj.
We've known each other for about four years.
I think we were introduced through mutual acquaintance, who's a good friend of mine, and has become
very interested in your technology.
And I'm not sure if you remember the context,
but the context was basically this person
reaching out to me to say,
hey, there's this really fancy MRI scanner up in Vancouver.
Can you go check it out for me?
And at the time,
I was focusing a lot on different technologies
that might be able to aid in the detection of
atherosclerosis.
And he may have misunderstood what I was interested in, but it was sort of pitched to me through
that lens.
You and I hopped on a call.
I still remember where I was sitting actually in my office at the time.
It was probably, it was in January.
By the end of that call, I was really interested.
And you said, look, I mean, I think you should just come up to Vancouver, get scanned, and let's
spend a day discussing it.
The rest is history.
What I wanted to do today was talk a lot about AME, which is the, I guess it's the name
of the company, or is that?
Yeah.
What I did is I actually set up AME as a private MRI company, and we basically put in the MRI
machine, so I could play with it. That's one of the problems of being an engineer. What I did is I actually set up aim as a private MRI company and we basically put in the MRI machine
so I could play with it. That's one of the problems of being an engineer. And so aim is the name of the
scanning company, the clinic, but we've actually now kind of moved it into pre-novo. And what pre-novo
is about is actually to basically sort of put the power of preventative medicine into patient's hands.
Yeah, well, we'll talk a heck of a lot about this. But let's talk a little bit about your background
because that was one of the things that right
off the bat made me realize that this was going to be an interesting discussion.
I, even in medical school, just took a huge interest in radiology.
I never thought for a moment I would become a radiologist, but I knew that whatever type
of medicine you practice, you have a choice, which is basically you can just be confused
and intimidated by all of these scans that your patients get is basically you can just be confused and intimidated by all
of these scans that your patients get, or you can at least try to understand them and
have some hope of appreciating the risks of them, the benefits of them, the subtleties,
etc.
So when I did my radiology rotation, I was probably the most eager student who wasn't going
into radiology.
And I remember, and I still have my notes, but I took,
I mean, maybe 50 pages of notes, drawing coils
and all sorts of things.
So let's start at the beginning.
You have a background in engineering,
which a lot of radiologists seem to have, right?
It's actually common in radiology.
It's like, basically, there's a lot of technology
in radiology, and so as a result, it attracts those of us
who actually are techno-files.
And so my background, actually, I started out in chemical engineering, and then during
that period of time, I realized that I actually kind of liked the body and physiology and
how that works.
And as a result, I then went into biomedical engineering, where I did my masters in PhD
in biomedical engineering in Northwestern.
During that period of time, I was actually working on fluid mechanics.
We're actually looking at blood flow and hemodynamics
and all sorts of complicated things.
And we also actually did what engineers do.
We actually had all these manual systems
that we're using to measure blood flow and blood pressure.
And we decided, okay, let's build a robot to do it instead.
So we did, and this robot that we actually built
allowed us to do keyhole surgery in the
eye that wound up attracting a lot of attention from physicians, from top tier universities
all over the United States, from mass general everywhere.
And as engineers, the attitude was, we can build anything you want, what do you want?
A lot of times physicians can ever answer that.
I was working with a lot of these top tier guys guys like editor-in-chief of the different medical journals and ophthalmology and it was like
they were speaking different language and I just didn't understand what they were talking about.
And so I actually kind of decided, okay well let me apply to medical school and see what happened
so I can actually kind of learn this language and kind of learn more about medicine.
And so I applied and then I actually kind of got accepted and I was like, hmm, do I want to do this? It's like, I'm really an engineer and was born an engineer. So my PhD advisors famous last words were that the
engineering world will always take you back. So I went off to medical school and actually hated every minute of it. And it was kind of like, I need to know more.
I'm one of those kids who's kind of like, why, why, why, why, why?
How does this work? Explain this to me.
I don't get it.
And realize that there's a lot of things in the body and physiology and pathophysiology
that we just don't understand.
Despite the massive amount of literature that's out there in the medical world,
you really couldn't find a lot of the answers of why things go wrong and how they go wrong.
So then I'd wind up sort of exploring, okay, how do we advance understanding of what's
going on in the body, like the simple aging process, what happens, why does everything
change, why people can answer it.
Instead it was like, okay, memorize this list of changes.
I'm like, okay, great.
Let me try and remember all that. And what I would
actually start to boil down to is that I would actually go back to my engineering pathophysiology
texts, and I would actually read them and talk to the PhD guys, and they would actually
say, give me the theories on what they thought was happening. And when you actually got that
theory, it was almost like planting a seed, then you actually kind of understood how the
entire tree would look.
And that's when I said, okay, maybe this is good, but I still need my technology.
Whereas technology going, we worked on, so the very first surgical robotics machines
ever built.
My colleagues presented the first tele robotics, telepresence conference ever held in
the United States at the same time the group that made the Da Vinci was there.
I kind of looked and said, there's not a lot of space for robotics because people don't
want machines operating on them.
As a former surgeon, I'm sure you probably feel the same way.
You don't want a machine operating on you unless it's going to be better.
So that's when I decided, okay, the technology that people understand, doctors understand, is
a picture.
And that picture is radiology.
And that's really where all the technology is.
And so I actually started in an area called Neucicine which is a sort of a small specialty within
radiology which is where you're actually looking at functional imaging, how things work,
how do things change, what happens over time, and really enjoy that area because it was sort of
showing you what's happening when things are normal and then when things become abnormal.
And it was actually one of these other amazing fields that in medicine there's a lot of shades of grey, of showing you what's happening when things are normal, and then when things become abnormal,
and it's actually one of these other amazing fields that in medicine there's a lot of shades
of gray, whereas in nuclear medicine it's almost black and white.
It's there or it's not.
It's one of these very few areas where you actually get a binary choice of what's happening.
Is there a problem?
Yes or no, as opposed to, well, it might be.
So that's actually what I liked about it.
But then I also kind of realized that radiology is basically very much like anatomy. You actually see what's going on, you actually see
the changes, and you see the shapes of things. And you use that very much as a blueprint for a building
to actually kind of see what it does. Whereas nuclear medicine is kind of, instead of the blueprint,
you actually kind of know there's all these people carrying letters moving in and out of this building.
We don't really know the detail of where the building walls are, but we know that there must be something happening there.
And, hey, when you put the radiology with the architecture together of the blueprint of
the building, then you combine that with the people going in and out of it, you realize
it's the post office. And you realize that these are postal workers carrying things. And
here's the geometry of the building. So that power really is actually quite useful in the fact that it's really that there's
its famous equation when people actually realize to put functional imaging or
nucleomedicine imaging together.
The first device that I said did that was positron emission tomography and CT or pet CT.
And the famous equation is that one plus one equals three.
These two separate modalities of functional imaging and anatomic imaging come together to actually make something better than each part individually.
And so that's what really attracted me to the whole field just because you could see what's going on and you can actually see the power of what's happening.
That was certainly one of the more powerful lessons I remember as a medical student when I went sort of had long into radiology,
which was what I really liked about this rotation. I remember, I wish I could remember the names of the residents, but they took me under
their wing, even though they knew I wasn't going to be a radiologist.
And as you know, from being in medical school, that's a little unusual.
Typically, the residents tend to gravitate to the students that are going to follow in
their footsteps.
But I think they saw in me a genuine curiosity and they thought, well, look, the smarter we
can make this surgeon, the better down the line for us radiologists.
And so I remember them taking me aside and saying, look, Peter, anytime you order a test,
in the back of your mind, you have to be asking yourself, do you want anatomical information
or functional information or both?
And the example you gave is a great one.
And in the show notes for this podcast, we'll link to tons of pictures so that people
understand what is meant by anatomic
imaging.
And the way I would explain this to a person is an anatomic image has nice sharp edges.
It looks like what it is you're trying to take a picture of.
So the anatomic image of the brain shows all of the substructures.
And when the radiologist looks at it here, she can make out every little blip and bend and crevice
inside of the brain. And they can comment on different structures, while there's a tumor here,
or there's a blood vessel that's slightly dilated there. If you contrast that with the PET scan,
as you pointed out, that's looking at a function of the brain, which is how much glucose does it
uptake. And instead, it lights up darker, the more glucose that's being taken there. And that's
so you're near analogy, the CT scan is showing the architecture of the post office, but the PET scan
is showing you the distribution of people moving into different areas of it. And by putting it
together, that gives you a really powerful picture. Exactly. And that's actually exactly how it works.
And you know one of the things that might be useful as well is if we kind of look at the different sort of
techniques that are used between nucleomedicine and radiology, we all know that imaging started
with the simple x-ray, but that was actually groundbreaking for the field of medicine.
Well, let's start with that. So everybody has seen an x-ray. And I think most people,
if they can close their eyes and picture it now or look at an image,
kind of no directionally that an X-ray is nothing more than a series of contrasts going
from black to white and everything in between.
So at the highest level, how do we take an X-ray?
What are we doing with those little electrons going through someone?
How does it produce that image?
For sure, and it's quite amazing actually how it was discovered by run.
And effectively, what it is is we're taking these high energy wave length
and it actually penetrates right through the body.
And anywhere where there's something dense, very hard like bone,
the x-ray beam can't make it through.
We've all sort of taken like a flashlight and sort of shown it through our finger
and we can actually see the red light coming through.
Well, effectively, that's what an x-ray is. We're just taking higher energy wavelength that we
can't see where our eyes and it's actually allowing the areas where there's things like air or
soft tissues that actually penetrate right through it and goes right through, shines through.
Whereas in place of where there's bones the x-rays can't make it through so they actually get
left behind and that's what gives us like the white pictures of the bone because the film that's exposed on the other side, soft tissues, the x-rays have gone
through, they turn it from white to black, whereas in bones, the x-ray doesn't make it through,
because it gets left behind in the person, and therefore on the film on the other side, it stays
white. And back in the days of Rankin, did they appreciate the damage of ionizing radiation,
or were there a number of
casualties along the way from people being far too exposed to this type of energy?
Unfortunately, there were lots of casualties and actually our understanding of radiation has
actually been moved by really traumatic events such as Hiroshima and Nagasaki and things like
that where there's been real radiation damage and we've actually been able to watch people over time.
where there's been real radiation damage, and we've actually been able to watch people over time.
And recently in the past 10 to 15 years,
in imaging, we've actually realized the danger
of this high powered ionizing radiation
and how it can damage cells.
And when the DNA of the cells get damaged,
there's a risk of inducing cancers with that.
And so we're actually starting to understand that more and more.
And we're actually starting to see that a lot of patients,
individuals are like, look, I know about the potential damaging effects of x-ray radiation. Therefore, I don't
want a lot of x-rays, CT-type scans. Now, the way I generally talk about this with my patients,
I have a graph that I show them that on the x-axis lists a number of different technologies. So,
a chest x-ray, an abdominal x-ray, a mammogram, and they're generally in increasing amounts of radiation.
So at the top end of that spectrum,
you'd have a whole body pet CT,
just for if you wanted to go as ionizing as possible.
And then the Y-axis, I use these units
called millicieverts.
Can you explain what a millicievert is?
Exactly, so a millicievert is actually
the unit of measurement of radiation.
And it's actually set by the standards group,
system, international, and France,
that actually sets what a standard dose of radiation is.
And now, it's actually important
that a lot of people really don't understand radiation.
There's good radiation, there's bad radiation,
but radiation is any time you actually have any ion
that's actually releasing a component of its energy
that energy has to get deposited somewhere.
It actually comes off as a component of its energy, that energy has to get deposited somewhere. It actually comes off as a photon of energy that
has to buy, I guess, energy effects go from it's never created, it's never destroyed, but it's actually transferred. And so that
energy, if it doesn't go through you, it's actually going to deposit in you. And if it actually deposits in you,
that's where it can actually cause the damage. And now when we look at all the different types of imaging as you talked about, on one
end you have the mammogram, which actually has a very low amount of gradation in milisee
verts.
It's usually about 0.05, which is quite negligible.
Whereas on the other end of the scale, you'll have the PET CT.
And now the PET CT basically couples the radiation from the CT, and the CT scanner is basically
a powerful x-ray that's spinning around the body and creating a three-dimensional view
of you combined with the PET, which is the positron emission tomography where you're
taking radioactive glucose, and you're actually labeling with fluorine, and that fluorine
is a radioactive fluorine 18, which actually now gives off a positron, and that positron
has tremendous amount of energy.
It's the highest energy that you can actually have in imaging for radiation.
And that's 511 kiloelectron volts, so very, very high.
And so when you combine those two together, you wind up getting typically, when we actually
give somebody radioactive glucose for a whole body scan for, let's say they have cancer,
it's roughly one milisevert per megabacerel, but I guess I'm trying to convert the
Canadian. Oh, that's okay. Yeah, we've got an international audience
here. You don't have to make it Americanized. Right. So we do it in
megabackerels up here in Canada. And so it's typically about 35 megaback
crawls per milisever. So typically somebody will actually get the US
dose would be about 12 millimoles. And so that's about the 12 miliceeverts of radiation,
in addition to what they get on the CT scan. So they could easily get 30, 40 miliceeverts in total
in that scan, if they were doing chest abdomen pelvis, for example. It's possible, yeah, and a lot
of that radiation would come from the CT, whereas with nuclear medicine, what we typically do,
since we're actually going to inject somebody with the radioactive material,
as a result, we've exposed them to that radiation to all parts of the body.
So as a result, as it circulates through the entire body, we want to take pictures of
everything from head to foot.
Because if we're going to give somebody radiation, we want to maximize the amount of data we're
going to extract from that exposure.
Now, I don't know in Canada what the number is, but in the United States, the NRC recommends that
no one receives more than 50 milli-severts in a year. But, of course, not all of that can be
assigned to radiography because living at sea level exposes you to what two milli-severts a year,
maybe three. I mean, I think even if you live at elevation, people in Denver are getting probably six or seven millisieverts a year at background. I'm probably a bit off on that. It might
be a bit less. That's right. Yep. So the higher you go, actually get more cosmic radiation. And then
as well, certain geographies will actually have radon, which is another exposure to the
millisieverts. And as well, when you actually travel, when you actually go up in altitude and planes,
we actually get a lot more radiation exposure. So that's why pilots, for example, well, when you actually travel, when you actually go up in altitude and planes, you actually get a lot more radiation exposure.
So that's why pilots, for example, actually, when they wear glasses, they actually have
to block the UV radiation, the UVA, UVB, and also the x-ray radiation, which is much
more prevalent at higher altitude.
The route matters.
I know I've calculated this for myself doing a lot of east west coast travel.
Fortunately, not very much exposure.
I believe it's less than 0.1 mA severt per round trip.
But if you do L.A. over the pole, all of a sudden, it goes up by, again, I don't want
to misquote it because we have the data so I could just post it.
But it goes up by a non-linear amount.
It's much more radiation when you cross the North Pole than just the extra distance you
travel.
Exactly.
And that's because of the ozone, the less ozone you have at the poles, the more exposure
you're going to get because the ozone actually absorbs the radiation.
So there's actually a calculator available online for people to actually determine how much
radiation they're getting from exposure.
And it's actually required that pilots and flight attendants calculate their dose.
We'll make sure we find that in link to that.
I just, because the NRC says 50 is the limit,
I've never really thought of that as we should go up to 50.
I've thought of that as they probably have some reason
to believe that successive years with exposure
to 50 milli-severses is not a good idea.
Do we have a sense of what the implication of that is
in terms of normal physiology? We do and we don idea. Do we have a sense of what the implication of that is in terms of normal physiology?
We do and we don't, and actually a lot of the time,
our understanding of that really comes from,
like I said, the tragedies of Hiroshima and Nagasaki,
as well as other people like in Fuji reactor
who actually got exposed.
And that's where understanding of the damage comes from.
Now, there's actually a landmark paper out of Columbia
that actually looked at the amount of radiation
that people actually received from CT scanners, and it actually a landmark paper out of Columbia that actually looked at the amount of radiation that people actually receive from CT scanners.
And it actually forced radiologies of field to actually look at the potential damaging
effect of x-ray radiation.
And what they actually kind of found is that the younger you are, the greater the risk
of cancer induction from CT scanners, which is why in the pediatric world, we actually
try and really minimize the amount of dose that children in particular are getting.
And the sex, as well, matters. So females are actually more sensitive to radiation than men.
Meaning if you took a 20 year old male and a 20 year old female, so both in their reproductive prime,
are you saying that the ovaries of the woman are more sensitive to DNA damage in the egg than the sperm
are in the testes of the male?
Exactly. I didn't know that. Why is that? And that actually has to do with the fact that the egg
was actually produced during embryonic stage. And as a result, that DNA is effectively frozen in time.
And so as women are getting older and older, they're releasing these DNA in the eggs. So therefore,
the young you are, the fresher, the DNA, whereas when they're prime sort
of round 12, which is when this DNA comes out of the, I guess frozen state during the
beginning of menstruation, that's when these eggs start to be released.
So actually 12 is sort of the worst time for females.
Which is really sad because of course anybody who's spent time in a hospital knows that
there are invariably kids that need to undergo radiographic studies.
They only need to spend a few days in a cancer ward to realize all these poor children that
are right at that age and they're being exposed to it.
And unfortunately, there's not much of a choice.
And trauma is another area where the child comes in having sustained a bad injury and a car
accident.
You go out of your way to use ultrasound whenever possible, but invariably sometimes patients
do require x-ray and CT radiographic
study. So let's go back to the x-ray because I like I like where you started there historically and then
You alluded to the fact that basically if you understand how an x-ray works if you truly understand what's happening
Then you understand what a CT scan is doing because it's just doing it in three dimensions
spirally. So the other thing about X-ray that I think is very interesting for anyone who spends
time looking at it, just to appreciate it even though it seems so simple, is nothing
in the body is too dimensional.
So you talked about how this photon is going through the body and if it hits a rib, well,
that's going to show up as white, whereas if it's passing through the lung between the
ribs, it's going to show up as black. But of course, you could hit a rib on the front, but not on the back. You can
hit a rib on the back and not on the front. You can hit the sternum. So when you look at an X-ray,
even to this day, I'm still constantly amazed at what the collage looks like of overlapping layers
of tissue. And I mean, I just don't think I ever got good
at reading X-rays.
It's actually easier for me to,
I think, because we just spent more time reading CT scans,
and there's so much more anatomic detail,
but when I look at these old time radiologists,
look at X-rays and the stuff that they could pull out of it,
I was blown away.
Exactly, it's true.
It's an amazing skill to actually be able to pull
that 3D information of a 2D picture. And if we actually kind of think about it, our brain is designed to always
imagine in 3D, always think in 3D. Even if you actually somebody lost an eye, they can still
see in 3D. And that actually has to do with the fact that that's how our brain was wired
or I was wired. And so the amount of information and x-ray is phenomenal, but the biggest problem is that
sometimes you're actually overlapping different things and you just can't see.
So quite often, the reason we do two X-rays, when you do a chest X-ray, you do a frontal
PA as well as a lateral, is so you can actually try and mimic those two together and become
a three-dimensional object.
And so when CT came around, that's when it actually really allowed us to look at things
in 3D, and that's where surgeons actually really allowed us to look at things in 3D.
And that's where surgeons and everybody else who actually operates and deals with people
in 3D, they can actually start to look at these and actually start to imagine what they're
going to be operating on.
They actually kind of get the power of where the 3D image comes in.
And so a simple way to think about an X-ray is I try to tell people, it's almost like
an X-ray is based like a flash.
Take a single flash and you get a picture, whereas a CT scan is really like a search light
and a boat kind of going around an island to actually get all the images the whole way
around.
And then the equipment, what it does, it actually sort of sees how the intensity passes
through, let's say, two panes of glass and comes out the other side.
And then you can actually start to evaluate what's going on inside that entire building.
The police officers use this all the time when they actually need to stake out a building
or a site.
They actually use it to determine where the occupants are.
And that's exactly what the next rate does.
It's triangulation effectively by spinning around in multiple different cycles by going
around 360 degrees.
So we should clarify our semantics for people.
We use the term CT very loosely, but it stands for commuted demography.
And sometimes people back in the illness used to refer to it as CAT scan or CAT and the A was for axial, of course, because it's going up and down the axial dimension of the person.
Right. When was the first CT scan put into clinical practice? I mean, would it have been in the early 80s or something like that or earlier? Earlier than that, it was actually a EMI, the phonographic company that actually built the
very first CT or CAT scanner.
And I believe it was in the 70s or even earlier.
It's actually been around for quite a while.
Realistically, that three-dimensional image really revolutionized medicine, has did all
imaging.
And the other thing that people will often hear about, and I guess maybe patients don't
hear about it as often, but it certainly gets touted to them as a feature, is they talk about the speed of these things.
They say this is this many bits or that many bits, and presumably the first one was a four bit.
I think it was actually even less than that. It might have been too bit, and it actually just took
a long time to go around, and it was actually first used in the brain.
So, let's explain what that means. So, two bit means you really only have two flashlights.
Exactly.
Or one flashlight, one detector.
One exactly, yeah.
It'll be easier.
I think when people look at pictures and we'll make this clear,
but you have this cylinder that goes around the patient
who's laying down and there's one place
where you shine the ionizing radiation
and on the backside of the cylinder is where you read it.
And then that thing has to rotate. so it's moving in its rotational plane, but also
moving up and down the Z plane in time, correct? Right. It makes so much more sense
when I can use my hands, by the way. And so it's exactly like that. Basically
180 degrees apart, you have the X-ray and the detector, and then it actually
starts to spin around and rapid revolution. So when you actually look at a machine, there is the donut hole in the middle, but around
it, there's actually the casing and these two parts, the detector and the machine, they're
actually spinning around the body very, very quickly.
It's actually quite fascinating.
Maybe we can find a picture of one of these actually with the cover off.
We'll find one.
And I feel like even when I got to residency,
which is, so let's just say directionally 20 years ago, I mean, I still think people were using 16
and 32-bit scanners, right?
Yeah, they were.
So 16-bit means you've got eight years spaced out,
equally eight units,
and then you've got your eight detecting surfaces.
Right, and so what it winds up doing is,
so if you started that, let's say the top of your head
and go to the bottom, we'll call that the axial dimension. What
the 8-bit would mean is that or 8-slice I guess is probably the more correct
term is that you basically have like one slice and then you're actually
measuring immediately below it and immediately below that and so as a result as
you're circulating around that person or the patient you're actually doing 8-slices
at a time or 16 slices at a time or eight slices at a time, or 16 slices at
time, or 32 slices at time.
So what that means is as you're rotating around, the amount of coverage you get is more
the higher the number of slices, or you can actually also have thinner and thinner slices.
And the more thin you get, the more detail you can get from an imaging perspective, but
the more radiation you required to overcome the signal
and the noise background. Yeah, so what you're trading off is an optimization problem, which is speed,
resolution, radiation. Now, where are we today? I assume 256 is pretty common.
256 is one of the common ones that it's actually used for things that are rapidly moving,
typically the heart. The heart. Do we have a 512 yet? In research.
Really?
Yeah.
You can actually make them as high as you want.
The problem is you eventually sort of get to these diminishing
returns of how then the slices are and how many images you need.
So if someone needed to scan a part of the body with a CT scan that wasn't moving
functionally, so something that's anatomically complicated like the pancreas,
but it's not moving like the heart.
Are you good enough
at 128 or 64? Like does 256 offer an advantage? Doesn't really offer any advantage, no. You can actually
eight slices work quite well. As long as the person can hold their breath and there's not a lot of
movement, eight slices work well. One of the things I remember at Hopkins, there was a radiologist
there. I don't know if he's still there. His, I think his name was Elliot Fishman, and he was sort of
the god of pancreatic reconstruction.
And of course, this was important at Hopkins because at the time Hopkins was the epicenter
of pancreatic cancer surgery.
And as important as it was to have a great surgeon, John Cameron, Charlie, O, etc.
that could do this operation, it was as important to have an exceptional radiologist.
Because as you know, and maybe some of the
listeners know, many patients with pancreatic cancer technically shouldn't be operated on.
And you'd really like to know that before you enter the patient's abdomen, which is
not always possible.
But I remember that Elliott Fishman's images, he would have these 3D reconstructions
of the pancreas at a time.
I mean, today that's pretty common, but at the time like nobody was contemplating this kind of resolution, and we would sit there on rounds and look at these
images when they were still printed out on that sort of vellum, whatever the hell that plastic paper is,
and you just couldn't believe it. So to think that he was doing that with relatively few slices,
right? Exactly. And like the whole power of that is again, as I mentioned at the very beginning,
is that our brain thinks in 3D, right? And so the power of that, as opposed to looking
slice by slice at a 2D image, became very useful because now it became real. It became what
our eyes could see, what our brains could see. And it actually really helped everybody plan
their surgery. And so it really was a revolutionary to actually start to look at things in three
dimensions. Now there's another element that we're going to introduce to this, which is contrast.
So what is contrast?
Why do we use it?
What contrast is, and for the CT world, it's actually an iodinated material.
And so what iodine does is actually absorbs the photons, and so therefore makes things
look white on a CT scan.
So it's like having liquid bone in your bloodstream.
Pretty much.
A liquid photon absorber.
And so what it does is we actually inject it into the vein and then we actually the heart
pumps it around.
And so that means we're actually able to time when we actually take the CT image in
order to be able to see what type of organ we're looking for.
So you can think of it if you actually get the arterial phase, you'll actually see
whether arteries are connecting to an organ or else you can wait for the venous phase, or when the veins are returning blood flow from that organ,
and you actually see the entire detail of the organ. And what contrast really is, is
base your way to light up the blood vessels, and light up the capillary net, and everything in
between between the artery and the vein, to allow us to see the anatomic detail from the perspective
of adding blood to it. And the name, of course, explains exactly why it's to create contrast.
Exactly.
In the absence of contrast, blood looks functionally like water.
I feel like I just want to go into this in so much detail, but I'm also trying to be mindful
of not going deeper than we need to.
But I guess we can talk about a Houndsfield unit, because that will allow us to explain this
contrast thing and tissue differences, right?
Exactly.
So what actually happened in CT is that Houndsfield came along and kind of said, okay, how do we
calibrate this?
And so there's a range of Houndsfield units from minus a thousand zero to two thousand.
And what that actually has to do with is density.
And so zero is defined as water.
A thousand is basically air.
And so as a result, we can actually see the difference between the density of
bone and air with water effectively in the middle.
So you have at plus 1,000, it is black.
Right. At minus 1,000, it is pure white.
Pretty much. Yeah. And the biggest problem is that the eye actually can't see that range.
So on our computer, as we actually will narrow down and look at,
we'll actually look at the higher-hounds field units and we'll actually see lung.
Then we go down, we look at the denser material, and that becomes bone.
But we can't see the whole thing.
Right. So you could technically specify multiple parameters.
You could specify the width of your window and where it is centered, for example.
So if you wanted to look at lung, you would center it much closer to positive
numbers, and you don't need a very wide range, do you?
Nope, not at all.
So what's a typical lung window, like 800 plus or minus a hundred or something
to that? I mean, I have no idea.
I don't even remember anymore, but it's, that's the gist of it, right?
Exactly. Yeah.
And actually, I don't even remember because you push a preset.
Yeah, exactly. What you said, you never really change it much.
I had committed all of these to memory in medical school.
I was so obsessed with knowing the window for optimizing the viewing of every tissue.
As did I.
When you actually start to practically use it, you wing it.
What happens is that every person is actually slightly different appreciation for contrast.
Also, it's like the amount of photons lost based on patients body size, the amount of absorption,
changes things.
So the number is actually kind of move around and you wind up building a database in your
mind of actually what you're looking at.
And so when you first start, you actually push the buttons and it's like 6040 for the abdomen
and you actually know all these numbers.
And then as you kind of go through, you're like, nah, I just need to see what I need to
see. What you said a moment ago, you're like, no, I just need to see what I need to see.
What you said a moment ago, it really brought back those memories of how horrible it looked
if you tried to set the window to be the entire plus minus 1,000.
You could appreciate nothing.
And that sort of struck me as a metaphor for life at times, which is like at a thousand
feet, sometimes you can tell, I'm looking at a human, but that was about the limits
of detection, but you could appreciate so many different things by zeroing in on the capillaries of
the lung, but you had to be in the right resolution versus if you wanted to look and see if they actually
had a fracture. People forget CTs are great for bones, right? And we're going to talk about how MRI,
for example, is less great for bones. So now we've got the CT thing. So what we've established is that X-ray is a purely anatomic study.
There's nothing functional about it.
As you go into CT by itself, it's also a very anatomic study.
You can add contrast to get even better information about the vasculature.
And you now have so much information that you can basically titrate or calibrate the
window in which you look into that collection of radiation and specify your tissues.
CT scans are generally pretty quick, right?
People who are claustrophobic don't tend to struggle that much in a CT scanner, correct?
Exactly.
And that's actually the real power of CT is the speed.
So for example, in trauma settings, that's what you want.
Basically if patients not doing well in a trauma, you want to put them through the CT scanner
as fast as possible to get the information out as fast as possible.
And they're very fast.
So, something that's even faster than CT and comes without at least one of its most significant
drawbacks, which is radiation is ultrasound.
So how does ultrasound work?
Where does it fit into this and what are its limitations?
The way ultrasound works is basically it's a high frequency.
So higher than what our ears can hear.
And effectively it's penetrating solid tissue.
So it's a high frequency sound wave
versus an ionizing wave of energy.
Exactly.
And so then it's actually going at every tissue interface that actually reflects back.
So it's very much like an echo.
So if you're standing in a mountain range and you yell out, you actually hear the echo
coming back and you can actually from that time, you can determine how deep that tissue
is.
And so with ultrasound, we're just doing that very, very fast.
And so at every tissue interface or every mountain range, if we could, you actually hear that reflection coming back.
You actually are able to then composite that as a representative of how deep things are
away from you.
Now, there are animals that do this, right, including some of our closest relatives,
right?
They do, and bats also do them.
That's actually how they see.
And the bats resolution on this is what compared to say a dolphin.
I've read and I feel like I read this in the journal science many years ago,
so I'm almost assuredly not remembering this correctly,
that the resolution with which a whale or a dolphin could undergo
sonography rivaled that of our finest medical equipment.
I mean, their ability to discern was remarkable.
I found that amazing.
And of course, in part, that's because they're the medium through which they travel as water,
as opposed to what the bat has to do, which is go through this poorly, poorly dense air, right?
Exactly. So traveling through the different material actually makes a very good way to explain
it, because in the air, actually ultrasound doesn't penetrate very far because it's
this high frequency, and it just you you lose it because there's no reflection
coming back, whereas in more solid material like water or even dense material
like organs in the body, it actually reflects back easier.
And so it's actually that reflection that actually allows you to discern
the different tissue types based on how quickly it reflects back.
Now ultrasound can't harm you, right? You don't have ionized,
you could ultrasound yourself all day every day
for the rest of your life
and you're not increasing your risk of cancer
whereas if you did a CT scan of yourself every month,
you're gonna be in trouble after several months.
Exactly.
The drawback of ultrasound is the resolution
doesn't seem to be as high.
Right, with ultrasound, you're only looking at one slice.
Right, so you're only looking at one slice in time and you're basically kind of sweeping through
an organ, trying to composite those slices together in your brain to try and build that
3D model.
Because like I said, our brain always wants to build a 3D model.
So with ultrasound, as you sweep through, you get one layer, then you get another layer,
then you get another layer, and then eventually that's composited together to see what's
going on.
And ultrasound also seems to really struggle when it encounters air inside the body.
So if you're trying to do an ultrasound of someone's aorta,
but their bowel is in front of it,
it becomes difficult to see.
For the same reason, the bat can't really use
high frequency ultrasound to fly.
Exactly.
And so that's why when, for example, you look at a female pelvis,
you want their bladder to be full,
because then they're bladder being full of fluid.
It actually acts as a nice window to allow the ultrasound beam to pass right through, to
be able to see the uterus behind it.
I think any woman listening to this who's been pregnant, that's got to be one of their
most vexing parts of prenatal ultrasound, as they always had to sit there in a waiting
room with a full bladder waiting to have that ultrasound.
Of course, that's why we like to do ultrasound on a fetus, right?
Is you're not causing any harm.
I mean, certainly one thing I came to appreciate in the hospital was the skill that was required
on the part of the person doing it.
So if you gave me the best ultrasound device money could buy today, like you literally
when bought whatever ultrasound was at the absolute
limit of technology. And then you walked down to the local hospital here, Vancouver,
general, and you grabbed just a middle of the road radiology ultrasound tech, someone
who's maybe been out of school for a year. And you gave him or her the worst ultrasound
machine on the market. There's no comparison who would be able to see more.
This is where skill and experience isn't valuable. Basically also, doing with a difficult
patient body type is really critical and you can't replace that experience.
Now there's a special subset of ultrasound that we do on the heart. Where did that idea come about?
Who figured that idea out? Again, the value was like once you could actually find like a nice window
that would actually allow you to
miss the air in the lungs and actually kind of look
at the heart, you realize that boy, you can actually start
to see this two-dimensional plane in the heart quite well.
And as a result, you can actually see where things were moving
such as the valves in the heart or the walls of the heart.
And then as well, you actually add something called Doppler,
which is basically the frequency bouncing off of blood vessel if it's going or coming, the frequency is going to be different.
And so as a result, you can actually now start to see how blood is moving.
And so that's what Echo does.
And so it actually allows you to look at the heart in detail with a very, very thin window,
usually underneath the chest and around along.
Yeah, so anybody listening to this who's had an echocardiogram, they know that the person
doing it is really pressing quite hard.
It's somewhat uncomfortable for you, the person getting the echo done.
And the reason is they've got that jelly on you, which again is doing everything to eliminate
even a drop of air between the interface.
And secondly, they're pushing and they're grinding it in between the ribs and they want
to get that view versus... So that's a trans-therasic echo where you're doing it over
the chest. In surgery, often, if we needed to look at the heart, you would have... The anesthesiologist
would actually put the echocardiogram in the esophagus, and you get an even better view of the heart.
The esophagus sits right underneath it, and there's nothing in between. It's a beautiful view, and the patient obviously, because they're asleep, they don't have to
worry about having this huge probe stuck in the esophagus.
Right, and because you're closer to the organ you want to see, being the heart, the
detail is going to be fantastic, because one of the other things with ultrasound is that
the deep ego, the beam effectively fans out and gets thinner and thinner, so you actually
get less sort of detail on the edges.
Whereas right in the center, right underneath the probe is where your maximum amount of detail
is going to be.
So by having it right in the esophagus, which is right beside the heart, you're going to
get fantastic detail.
As important as the CT scanner was in trauma, the ultrasound was actually the most important
radiographic tool we had in trauma.
And that was the one thing that even the surgical residents
needed to know how to do.
And it was called a fast ultrasound.
There was an algorithm for this.
Because in a busy trauma center like Hopkins,
you're gonna see trauma so often penetrating trauma,
in particular, where you have to know,
does this person need to go up to surgery?
Is there fluid in the abdominal cavity?
That's generally one of the things you care about.
You certainly also care if there's fluid around the paracardium,
this non-stretchy sac that surrounds the heart.
These are surgical emergencies, especially fluid
around the paracardium.
So I think sometime in our second year of residency,
we would go off and do this course where on pigs,
we would have to practice this over and over again until you learn the four places that you were looking for fluid
inside the abdomen.
I guess we got pretty good at it.
I think I got okay at it, but I still always felt like a little nervous when push came
to shove because I always felt like I wish I could go and spend a year just being an
ultrasound tech to really, really dial this in
Because the stakes are so high especially if you miss the slight amount of fluid in the paracardium
That's a lethal injury and one of the real tricks as well is that
Depending on the composition of the fluid. There's like frank blood or coagulating blood
It can be really tricky to actually pick it out
And so a lot of times you'd actually see the vast ultrasound would be done.
And if people weren't 100% confident
that there's a problem or not a problem,
they go straight to CT scan
because you just couldn't make that error.
And that happens time and time again.
Yeah, and it's funny.
One of the last traumas I was ever involved in as a resident
was just one of those cases where the patient came in
and he was responsive.
He had the tiniest, tiniest stab wound.
So less than a centimeter wide under the zyfoid, that's it.
So this is a guy who walks in who has a sub-centimeter,
sub-zyfoid incision.
I mean, it could have been a shaving cut,
but he's been stabbed, and he's more or less,
seems pretty normal.
Vital signs are more or less what you would expect.
When I lay him down and do this ultrasound of his heart,
it really looks like there's something there,
but I can't quite figure it out.
And now the question is, well, he's obviously
too responsive to warrant cutting his chest open,
which was what you would do in the emergency situation.
So you have to do the CT scan.
But of course, the risk in the CT scanner is as fast as the CT scanner is, he is still laying down
on a scanner, potentially ready to have a cardiac arrest for at least a minute and a half. And usually
what would happen is, I don't know a call in this case, but a lot of times if you're going to go
through the trouble of doing that, you're going to do a contrast
CT scan as well.
You're not just going to do what we would call a dry scan with no contrast.
So now you've got the fumbling around of getting the iodine machine hooked up to them, et
cetera, et cetera.
And Eddie Cornwell, who was the chairman of surgery at Hopkins, he's now the chairman of
surgery at Howard and just an incredible human being.
I remember one of the things that he told us when we were junior residences, beware of the patient who gets wildly anxious
when you lay them down. And sure enough, when we go and lay this guy down in the scanner,
he just starts freaking out. And when you sat him up, he sort of calmed down a little
bit. It was do not pass go, do not collect $200 and took him to the OR, opened him up, he sort of calmed down a little bit. It was do not pass go, do not collect $200.
And took him to the OR, opened him up immediately,
and sure enough, that knife had actually hit his pulmonary vein.
And so that pulmonary vein was bleeding into his paracardium.
And so he would have had a cardiac tamponade
if we'd left him on that table.
And amazingly, that patient went home three days later.
Yeah, no exactly.
And you can see like the power of the clinical scale,
as well as like just the basic imaging, right? The power of imaging plus clinical is pretty much
where medicine is right now and how we actually are able to diagnose things quickly and efficiently.
So we've talked about two technologies that most women are very familiar with when it comes to
breast cancer, which is of the cancers where screening is done vis-a-vis imaging technology,
breast cancer is head and shoulders above the others in terms of the frequency and ubiquity
of the scan.
So let's talk a little bit about, because you've already explained what an ultrasound and
an X-ray is, so now explain what mammography is and why we would sometimes say mammography
is sufficient versus insufficient, and why do some women get told, well, you also need
an ultrasound.
Right. So basically, mammography is a lower attenuation x-ray. We're actually taking x-ray, but a weaker strength of it,
because we never have to penetrate bone, and actually now it shines through the breast tissue, which is all soft tissue.
And so one of the things that actually is maybe stepping back is to actually kind of look at breast tissue in particular.
So breast tissue is composed of normal subcutaneous tissue, which is mainly fat, and as well as
glandular tissue. And so when women are in their childbearing age, it's almost all glandular tissue
to produce milk for eventually feeding a baby. And as women then go through menopause, that
glandular tissue can invariably involute. So it's one of these things, you don't use it,
it gets replaced with fat. But in some women it actually doesn't get replaced with fat. And that is
what we call the dense breast tissue. So mammograms are very, very good at shining through
fat, and it actually allows you to see very, very simple things like calcification in fat
because they are just so dense and it actually stands out. Whereas in glandular tissue, sometimes
that photon of low energy x-ray doesn't make
it through, and as a result, the tissue is very, very hard to see through, and that's what
we call the dense breast tissue.
And the reason it's hard to see through is because of all that glandular tissue that
in some women over menopause or even older, they just retain, and nobody really knows
why they retain that extra glandular tissue, why in some women it gets replaced with fat.
In other women, it doesn't.
We don't know why.
So many states, and I think they're actually over 38, and possibly soon to become a federal
law in the United States, is going to require that the very first line on a mammogram report
is going to be that the women's breast tissue is dense, limiting mammographic sensitivity,
or the breast tissue is almost entirely fat, in which case mammograms are helpful. Because that actually will really allow women to determine
was this test good enough. And so for women who actually have dense breast tissue, so they
for some reason, if they're postmenopausal, or if they're premenopausal in their child
bearing age, they still have a lot of glandular tissue. That means a mammogram might not be
enough, and therefore they need another second imaging modality
to look through the tissue.
And that's where ultrasound comes in.
And as well as MRI would come in as well
to be able to see through that dense glandular tissue
that the mammogram can't see through.
Now, the last time I looked at these data
could be, they could just be simply dated,
but I think directionally this is right.
A mammogram had a sensitivity of about 80, call it 84, 85%, and a specificity
of about 90, 91%. Does that still sound about right to you?
It depends, actually.
Yeah, that was like all-comers was the point I was going to make, which is it becomes
almost impossible to interpret what that means, because what you need to know is what
if I had a thousand women that looked exactly
like the women I'm scanning right now. Exactly. And so that's where it actually becomes really
critical and the fact that depending on the breast density and that's why it's important from women
to know what that is, you're going to know how helpful the mammogram is or may not be. But one of
the other things that becomes actually very, very powerful in the mammogram is to actually use
comparison over time.
So that's why they recommend screening intervals of either one or two years, and it's a matter of academic debate.
And because if you actually have like a mammogram taken, and then let's say two years later you do another one,
it's actually far more sensitive to see that subtle change over time than it is to actually look at an individual mammogram on its own. So, a single mammogram on a dense woman, its sensitivity is about 55%, it's actually
quite poor.
Whereas on a woman who actually has fatty tissue, it's very high.
How high?
It can actually be over 95%.
So let me explain what sensitivity and specificity mean so that a person understands what this
is about.
Let's just use the numbers 80 and 90, because those are generally accepted
as unaggregate. So when we say a mammogram has an 80% sensitivity, here's what we mean.
If there are a hundred women who have breast cancer, so there's a hundred women, and we absolutely
know that they have breast cancer, and we subject them to a mammogram, 80 of them will test positive. 80 of them will have a true positive, and 20 of them will test falsely negative.
So the sensitivity is the true positive rate over the true positives plus the false negatives.
Correct?
Exactly.
So the higher the sensitivity, the less likely you are to take someone who has the cancer and miss them.
That's the juice on sensitivity.
Let's now talk about specificity.
So, moment ago, you gave a staggeringly sad example, so we'll come back to that.
But let's use the better one, right?
Let's say 90%.
So, now, what does it mean to have 90% specificity? So that means you take 100 women who we absolutely know do not have breast cancer and you scan
them.
90 of them will correctly identify as not having breast cancer.
10 of them will incorrectly identify as having breast cancer.
So 10 will be false positives.
90 will be true negatives.
So the sensitivity is the number of true negatives over the true negatives plus the false
positives. And so the example you gave a moment ago is if you have a woman whose breasts
are very fatty, not glandular, therefore she's the poster child from mammography, you're driving that specificity up, which means you
are reducing the number of false positives. But in the example
you gave earlier, which is a woman who might have very, very dense
breast tissue, imagine what it means to take 100 women who have
very, very dense breast tissue and drive your specificity down to 50%.
That means on a given day, half the women that walk into your clinic are going to be told
they have cancer if they don't. Exactly. So it's like flipping a coin. And by the way,
one of the greatest examples of this, and I mean, I attribute it to Bob Kaplan, but maybe he heard
it somewhere else, but I love it, is You can make a test that is 100% sensitive if you're willing to have 0%
specificity. And vice versa, for example, you could send a letter. You could have a little
card that says you have cancer and you show it to every single person you meet. You have
a 100% sensitivity. Right? You will never have a false negative.
The problem is that's so clinically useless because you have no specificity.
And similarly, you could have a little magic card that you show everyone you ever meet
for the rest of your life that says you do not have cancer.
Yes, what?
You have a 100 percent specific test.
It just has zero sensitivity, so it's as useful as a warm bucket of hamster vomit.
And so it's this trade-off between sensitivity and specificity, which I'm teeing this up, because I know
we're going to come and talk about this when we get into the more advanced MRI stuff, but the
example of mammography is amazing to me, because it makes you realize you can't just rely on one
test, especially when that test has such low sensitivity and specificity depending on
the individual. Exactly. And I think that that's the real important lesson is that it's actually
very individually tailored. Right? And so if you have one test and you don't know what your fingerprint
or what the tissue that your breast is made of, you really have no idea what you're looking for. So
you always need the one to kind of find out is this good enough. People always talk about machine
learning and AI and how invariably it has to infiltrate
medicine. And it seems to me that one of the best places for it to do so is in at least
comparative radiology. So given the ubiquity of mammograms, hopefully every woman above
a certain age in the United States, Canada is getting regular mammography, there's no
shortage of data.
Are there companies out there that are working on
basically doing that once you have a baseline,
which would be almost impossible for a machine to read,
but once you have that baseline,
longitudinally comparing it.
There are actually a lot of companies
that are actually doing that.
And even in some states that are actually
using machine learning techniques to actually
help the radiologist and actually can be used as even a second reader.
There are a fair number of companies working on that, but it's not perfect.
What do you think that could improve the sensitivities and specificities of mammography, too?
Can we get to the point where I don't know?
Most people would say you've got to be north of 97, 98% on both to really feel confident.
I think that's a pretty high target to achieve.
And the reason that would be is just because of the way the tests are done and the individual
variability of people, it's going to be tough.
Can't machine learning get that good?
It'll take a while.
It's going to need volumes and volumes of data that's actually reproduced the exact same
way.
And I think that's the biggest problem is because we're unique.
The way the rest is compressed, the way everything is done,
when a mammogram is taken, is somewhat different each time.
So the amount of coverage is a little bit different each time.
It's possible, are we there yet?
No, we're nowhere near a close, but we're getting better.
And that's also one of the challenges that we have
when we look at the data on mammography,
is it's so backwards looking.
And so if you wanna look at the most comprehensive study
of mammography and breast cancer screening,
by definition, you were looking at a trial
that was enrolling patients 15 to 20 years ago,
and therefore you have to be able to say,
well, how relevant is the technology
that was being used then relative to today? And in the case of mammography, it shouldn't be able to say, well, how relevant is the technology that was being used
then relative to today?
And in the case of an emography,
it shouldn't be changing that much,
but I mean, things do get better.
I mean, we're reading pure digital now.
We have much better capacity to read even an X-ray
than we did 20 years ago, don't we?
We do.
And basically now what's actually happening
is we're actually doing a floral scopic version
of a mammogram where we're basically sort of trying
to slice through this three-dimensional object and actually get the detail of it at
a three-dimensional layer. Whereas before the mammogram were typically just like the chest
x-ray was done, two different views compositing that three-dimensional picture together. So
that three-dimensional view of the mammogram is actually better than it was.
Now, there's something else that I've never actually seen done clinically, but I've read
about it called MBI, molecular breast imaging.
Is that used any longer?
And what is it?
The reason it came across my radar was many years ago when I was just trying to get the
landscape on ionizing radiation.
This came up as a test that was done as a follow-up to a mammogram, but I thought there must be a typo based on how much,
it had like something like 20 million severs of radiation.
I mean, it was 40% of your annual radiation limit.
What that is now, that's a functional test
in the realm of nuclear medicine.
And so what that is doing is we're actually taking
radioactive material and then we're actually injecting
into the body.
And so tissues that actually have increased mitochondria actually concentrate this
radio tracer and so that typically happens in breast cancer so it's actually
used with a radio tracer called Sesta Mibi. You've heard of this Mibi scan which is
where we actually inject this into the heart and we actually look at whether
not the heart is being properly perfused and so areas that aren't being
perfused so therefore the muscle is not alive, basically
don't take up the radio tracer.
Whereas muscle that is alive does take up the radio tracer.
And that muscle that's alive, that's moving, has a very high mitochondrial rate, so therefore
it actually concentrates this material.
So breast cancer, it's actually doing very similar thing, they'd actually have a high metabolism.
And so this tissue would actually concentrate or this rate of trace would concentrate
in that tissue. So that was the MPI exam for breast.
Is that test still done?
Rarely.
But it can be done in women who actually have very, very dense breast tissue and you actually
need to see what's going on. It can be done. But a lot of it's actually been replaced
with positron emission tomography scans.
So right now, how many young women,
if we just say because the young women
are gonna be more likely to have dense breast tissue,
do we have a sense of what percentage of them
really are being uncovered,
meaning they're not getting adequate sort of surveillance
with just mammography and would require at least ultrasound?
Is that a third of women, I mean,
do we have a sense of what that number is?
Depending on the jurisdiction,
so the guideline for when you actually start screening
for mammography can now be the age of 40 and higher or 50 and higher.
Each jurisdiction is a little bit different. So what that means is that basically
anybody under the age of 40 unless you have a family history of somebody having
breast cancer in early age, they're not getting screened at all. So everything we've
talked about from a technology standpoint in some ways pales in comparison to
what we're about to talk about,
which is about as complicated a set of physics as you're going to find within the walls of
a hospital, right? I mean, it doesn't get a lot more complicated than an MRI, doesn't?
No, it doesn't. It's really an engineer at the light.
Yeah. And I certainly, again, thinking back to my brief, the six weeks of doing radiology,
I feel like more of my notes were scribbling down
an explanation of how this thing worked or anything else.
So let's go back to the beginning.
Who the heck thought of this?
There are actually three people actually thought about it,
but the Mansfield is actually one of the main creators
of it in UK.
And so the MRI machine really,
it's actually quite an amazing tool.
And it actually wasn't initially
developed for imaging.
It was actually just sort of developed on a bench top where they're actually just kind
of looking to see what the effect of electromagnetic waves does to anything.
And somebody wind up sticking tissue and it's saying, hey, look, it's like we can actually
what goes in one side comes out a little bit differently on the other side.
And as a result, we can actually determine what that composition of material was.
So does that mean like the NMR that we were looking at
when we did organic chemistry was really the precursor
to the MRI that we're sitting outside of right now
listening to it, huh?
It's the exact same device,
that the NMR basically is just a two-dimensional version
of MRI, which is three dimensions,
because our brain likes three dimensions.
So let's go back to organic chemistry.
So again, we'll link to a picture of an NMR spec so that people can see what we're talking
about.
But I guess there's also no easy way around this, right?
I think you have to sort of roll your sleeves up a little bit on physics to understand
how an MRI works.
There is no, I'm sure there's a kid's book out there waiting to be written on the topic, which would be amazing,
but it's pretty tough.
So you take a molecule like alcohol, okay?
So it's got these two carbons that are joined.
The first carbon has three hydrogens around it.
The next carbon has a hydrogen and a hydrogen,
but then instead of the third hydrogen,
it gets an oxygen, which is bound to a hydrogen and a hydrogen, but then instead of the third hydrogen, it gets an oxygen,
which is bound to a hydrogen. That is the stuff that people drink and get drunk on.
Now, put that into a nuclear magnetic resonance machine and you're going to see different peaks,
right? It's going to show you that there is a methyl group somewhere. It's going to say,
it can't tell you what it sees, but it tells you that there's a carbon bound
to three hydrogens, right?
Right.
How does it do that?
Perhaps I might actually take up the challenge
of a children's book, but problem is I dislike writing,
but maybe for children I'll be okay.
The way it actually does is actually quite fascinating,
and it's actually relatively simple.
So what it actually does is the hydrogen in particular.
So, we're going to sort of fixate on hydrogen because that's the atom that we're really interested
in.
And I'm just going to say one thing because you're going to do this anyway and I just want
to preface it.
You're going to use hydrogen and proton interchangeably, aren't you?
I will.
Can you just tell someone why you're going to use hydrogen and proton interchangeably?
Sure.
So, the atom basically of the hydrogen is you have one proton and one electron.
And in the hydrogen proton, we don't really care about the electron.
It just sort of disappears.
So the hydrogen, I guess, nucleus is a proton.
And it has no neutron.
Its mass is one.
Its mass is determined by the one and only proton.
It carries, correct?
Exactly.
Okay. So now hydrogen and proton, they're the same thing for proton it carries, correct? Exactly. Okay.
So now hydrogen and proton, they're the same thing for the purpose of this discussion.
Exactly.
So when we look at the NMR, so you actually have hydrogen bound to an oxygen or hydrogen
bound to a carbon.
And so the behavior of that nucleus is going to be a little different.
So there's basically a magnet that's creating a field and somehow through that we can see how the hydrogen is bonded to
either the oxygen or the carbon in the ethanol molecule.
Right. So we were talking about the NMR and so what the NMR does is that it really is a
hydrogen or proton imager or actually just detector. And so the way the magnetic field
of hydrogen behaves if it's attached to either the oxygen
and OH of alcohol or the CH3 of carbon is completely different, it actually gives off a different
wavelength.
And so as a result, that's how we're actually able to get this what we call NMR spectra.
And so what happened is that from there, there's a person named Damadian who many consider
to be the father of MRI.
He actually said, well, you know, look, if we can actually take what men's field in
Lauterberg did on a bench top, can we actually put a human in it and actually start to see
the soft tissue?
Because we know that our body's composed of roughly 70% water.
There's a lot of hydrogen on fats, so can we see that frequency difference?
We can see it on a bench top, but what about in people?
So we have more hydrogen in us.
If we were just going to count up the atoms in us,
hydrogen wins all day long,
because as you said, if we're 70% water,
that's two to one hydrogen over oxygen there,
and then all the fat that's in us
is all the hydrogen to the carbon there.
And there's basically hydrogen in protein as well.
I mean, so if you have a hydrogen detector,
that's basically the way you would describe
an MRI.
An MRI is exactly that. It's a hydrogen imager. So basically, we're looking at hydrogen
nuclei, which is a proton. And so a lot of times as well, people actually talk about protons
spectroscopy, which is NMR. An MRI is just basically a simple hydrogen imager.
So I think anyone who's had an MRI
knows that there's a magnet involved.
And it's generally a non-trivial magnet.
Some people have probably heard of some of these real horror stories
where accidentally in the hospital, a patient's wheeled in.
And there's a loose oxygen tank under the gurney that's
wheeling the men.
And it goes flying across the room and hits somebody
and can kill someone.
So how strong is the magnet?
And why does it need to be so strong?
Right, so the magnets, they come in different flavors. So typically it's regarded as a Tesla.
And so Tesla is roughly 10,000 ghosts. And so a ghost is effectively what the North Pole can produce.
And it's actually the typical measurement for most magnets. But when we actually into the MRI, field it becomes so much stronger.
And the reason we actually kind of need
that high tens of field strength
is because we're actually taking hydrogen,
which is typically not that magnetic
compared to like a magnet that we think about,
like a bar magnet.
And what we're trying to do is we're actually trying
to orient that little dipole of the water molecule
or fat molecule a certain direction.
And that's what this static field does, and that's why it has to be so strong.
So they come in flavors 1.5 Tesla, 3 Tesla, which is double the strength, 7 Tesla.
And so the higher the Tesla they go, the more it's actually able to pull all of the hydrogens
in orient them in one direction.
Because as we're sitting here or anywhere, normally our hydrogen molecules are on water, we're just kind of bouncing around randomly, kind of
pointing at any which direction, and that there is no kind of magnetic component to us.
The hydrogens are spinning around just based on brownian motion. And so when you actually
go into a magnet, that strong magnet of field, these hydrogens basically kind of turn and orient
themselves in that direction.
And so that's what actually provides the initial basis for an MRI.
And that's why contrary to what we see on TV, that magnet is always on.
You can never turn it off, because that magnetic field always has to be there
in order to provide that orientation.
And as well, the way it works is you actually have a superconducting wire
that's actually running just above absolute zero degrees Kelvin. So it's roughly two Kelvin and so you can't turn that
off. This is superconducting wire. It has like pumps that are pumping all the time to keep it that
cold so that when you actually put an electric field in like a loop of wire that electric field is
what actually generates the magnetic field in a perpendicular direction.
So you have a generator that backs up if you lose power, which invariably you're going to lose at some point.
Exactly. You have to have that backup power to always keep this pump moving this liquid helium.
That's surrounding the wires. Always keep that liquid helium floating around, circulating around that wire
to keep that wire in your absolute zero Kelvin.
Now, if we were to walk in the scanner today and everyone can sort of picture
this, there's a bed running through a donut.
What is the direction right now that that magnet is being oriented?
The donut.
So that's where that loop of superconducting wire is sitting in.
And so depending on how it's put in, most of the times the North will actually
face away from the control center.
And that's the direction of North.
Got it.
And if I recall, there's like a right hand rule on this, isn't there?
There is. Very nice. So I can tell you which way the power and the coil is going.
It's actually going, I guess, if you're looking from the foot of the bed,
it's actually going in a clockwise circle, and that's the right hand rule.
The right hand rule, it's pointing in the axis. Okay.
Now, aside from the fact, let's pretend we weren't wearing anything metal.
If you walked into a room where there was a 10
or a 20 Tesla magnet, would you feel anything
and would it do anything to you that is harmful?
The actual magnetic field won't do that much.
Now, when you get very, very strong
to a moving magnetic field, you can actually start to feel it
because it can actually trigger your nerve impulses to start moving. So sometimes people actually, if the magnetic field, you can actually start to feel it because it can actually trigger your nerve impulses to start moving.
So sometimes people actually, if the magnetic field is too strong, they'll actually get twitching.
And sometimes the people who are actually around magnets all the time, they actually become
more and more attuned to this type of a thing.
And so if you have MRI technologists or people who are working with the high fields all the
time, they can say, you know, when I go to the head of the magnet or like the north side, I actually kind of feel something pulling.
And sometimes people describe getting temporary headaches and as soon as they step away from
the field, it all goes away.
Usually when patients ask me if there are any side effects or harm of an MRI, I mean,
our lib answer is to say, no, no, no, no, no, no, especially with a non-contrast, like
if there's, I mean, not that the risk of gadolinium is high, but if you're just having a dry MRI, you say nothing, nothing, nothing,
but I actually had a patient who had very, very, very severe migraine headaches,
and she actually had a migraine triggered by an MRI, and I truly believe that wasn't just a
coincidence. I mean, I think her headaches were so severe, so I now sort of always couch my
response as there's virtually no short term or long term
consequence that can come from an MRI, but at least in the case of that person, you could
trigger a headache.
You can, because what it does is it can actually stimulate the nervous response.
And depending on how strong the field is, so for example, if you're to do a seven Tesla
magnet, you're definitely going to notice it.
And as a result, they'll tell people, look, you can't be in this too long because of
the fact that you're actually going to stimulate.
So I remember going back to learning about this.
One of the other things that sort of strikes anybody who's had an MRI is they take a long
time.
So why is it that if you wanted to get an MRI, let's never mind whole body, which will
come to, but you just wanted to get an MRI of the abdomen.
That could easily take 40 minutes, whereas a CT scan of the abdomen can take two minutes.
Yeah, and it's basically the way the images are acquired
to completely different mechanism.
So if we go back and talk about X-ray,
it's basically like a single flash,
we're actually looking through everything.
The CT is basically this X-ray
that's constantly on, spinning around,
and basically sort of circulating around you,
whereas MRI behaves completely differently.
And during the period of time of that acquisition, what it's doing is everything that's inside the center of that donut
is being pulled in a certain direction, all the hydrogens on your water and fat.
And then the loud part of the MRI is actually a temporary magnetic field, which is countering that static field.
And so it's actually now pulling all the hydrogens in the opposite direction.
And then in that opposite direction, it actually turns off. And then the hydrogens
reorient to where they were in that static field. And as a reorient, they actually give off a different frequency.
And that different frequency takes a while together. And that's what we call the TR, or repetition time, or the TE of the equitime. And that you can't speed up. So let's talk about TR and TE because it's the TR and the TE
that determine what sequence you are looking at.
So again, I think the average person probably won't recognize these terms,
but certainly anyone in the medical profession will know the difference between a T1 weighted
versus a T2 weighted image versus a spin versus an echo versus all of these things.
So let's just talk about the difference between TR, that repetition pulse time, and then TE,
is TE the time it takes to relax back to its original position.
So just discussing TR and TE, how do they differ in acquiring a T1 weighted image, which
is the one that's really anatomically beautiful.
It's the closest thing you see to, wow, I know what I'm looking at, if not, I'm not a radiologist.
Versus the T2 weighted image, which seems to highlight water more, so things that are water
look more white, but it doesn't have the anatomic resolution. How do you differentiate those?
Right, so the simplest thing to do, and it's actually quite fascinating, is I went through
residency, people are always sort of stunned with, is this a T1 image or a T2 image? And it
went through all that and was kind of like, sort of a bit obscure. And then when I started to
do MRI much more, it's like it became actually pretty simple. On the T1 image, we actually see nothing
but fat. So fat gives a lot of signal, which is what makes it nice and bright.
So we see a single element, or I guess a single element that the hydrogen would be bonded to that we're looking at.
Whereas a T2, we're actually now seeing two elements.
We're seeing fat and water.
And so those two elements are actually coming off at different frequencies from the MRI machine.
And you have to wait a longer echo time to be able to pick up the water
because it returns back to normal much more slowly than the fat does. So that's our T2 weighted images
take longer to acquire because the TE is long because you have to wait to get both fat and water.
What's the difference in the TR between the T1 and T2? It's all going to be entirely dependent on the machine. So you actually have to customize those parameters for every single machine.
And so that actually kind of takes a while to actually kind of go and calibrate and kind of get
used to what your eyes used to seeing. And it's also going to be dependent on the signal, the overall
magnetic field as well as overall signal noise for that coil set that you're using. So each one
has to be effectively tuned.
And then what does it mean when you have these other things that come out and
it's been so long since I've done it that I don't even remember when we would look at
spin, spin, echo, flare, all of these. I vaguely remember all of these other sequences we would
order. I don't actually recall what they were. Give us a brief rundown of that.
One of the things that MRI actually loves is just the different acronyms for everything.
It's almost got to have it.
It's almost like a whoever can come up with the coolest acronym wins like lava and all
these other things.
But effectively, there's three main categories of MRI sequencing.
One is what we'll call conventional.
So conventional spin echo.
And so that's basically as weighting as long as you can for the hydrogen
to completely relax and give off both its water and fat signal.
And then we have what's called gradient imaging.
And so that's actually you're not waiting for it to completely return back to normal, but
somewhere in the middle you're actually kind of repulsing again.
So you're basically hearing that noise of the machine turning back on and saying, you know,
we're not going to wait till it completely relax, we're going to fire up again. And just give us a sense of the machine turning back on and saying, you know, we're not going to wait till it completely relax. We're going to fire up again and just give us a sense
of the actual time.
How many milliseconds, if you're trying to get a T2 signal
and you're waiting for that full relaxation,
how many milliseconds is that?
Directionally.
It's actually going to be, it can be up as high as like 60
milliseconds, even longer for some of them.
Okay.
And when you do these gradient based tests
where you're going to repulse, how quickly are you repulsing?
You can actually repulse in like two milliseconds or even faster. And then there's actually the third category,
which is actually called EPI or echoplane or imaging. And this is actually amazing. So this part actually
allows you not just to be looking at a single slice of a person, but you're actually going and you're
actually now running multiple slices simultaneously where you're actually putting two different
fields on the person at the same time.
And so as a result, and it kind of gets complicated because we use the word gradient all the time.
And so what a gradient basically means, it's effective like a ramp from a low number
to a high number.
And so if I was kind of looking at you and I said we're going to start to image from your
top down, first we're going to put a gradient on from top to bottom.
So it's going to be a little bit of a higher frequency at the top, a little bit of a lower
frequency lower down.
And then we're actually also going to look at phase from right to left.
And depending on how your body is oriented and where the blood flow is going to be, we're
going to look at phase and frequency, which now bring us into the realm of a Fourier transform.
So these are now with the pulses, we're effectively looking at all these repetitive sine waves,
and we're actually plotting that in frequency and phase domain.
Right, and for the listener, we always talk that the plas was only half the man Fourier was.
That's like the nerdiest math joke I'm going to tell today.
All kidding aside, how does one get into MRI radiology without a background in mathematics
and physics?
It seems it would be impossible.
It's a struggle.
I can actually remember with the group of residents that I was with training and great
people that we actually had a physicist come in and was talking about MRI physics for a couple of days and trying to teach us all.
And I thought, boy, this guy's really watering it down.
I can barely hang on to what this guy's saying.
Then I kind of looked and talked to all my colleagues and they were just bewildered.
They had no idea what he was talking about because as far as an engineer is concerned,
it's like four-year domain.
It's kind of like that's sort of like the alphabet.
Yeah, that's our bread and butter back from the day. Yeah. The difference with the MRI is that you start in this four- Fourier domain. It's kind of like that's sort of like the alphabet. Yeah, that's our bread and butter back in the day. Yeah.
The difference with the MRI is that you start in this Fourier domain. And because we're a three-dimensional
object, when you're looking at a two-dimensional plane, that's the Fourier transform.
When you now add that third dimension, it becomes what we call case space. So it's effectively a two-dimensional
Fourier transform, which is what the MRI world operates on. It's called case space.
So what we're going to do in the show notes here
is we're going to link to some very common types of MRIs
that people have, right?
The most common ones that people have is you've tweaked your knee,
you're gonna get the knee MRI.
You've heard your back, you're gonna get the MRI of your back.
You're having headaches, they're gonna do the MRI
of the head, those sorts of things.
So when you think about the bread and butter,
clinical practice of medicine, what types of MRIs the head, those sorts of things. So when you think about the bread and butter, clinical practice of medicine,
what types of MRIs describe what those three would be?
What sequences would be run to it?
If you wanted to evaluate someone's ACL,
the ligament in the knee, what are you gonna look at?
The first thing you're gonna do,
and this sort of relates back to the plane X-ray,
you're always gonna look at things in two dimensions,
you're gonna look at two planes, and in this case,
and so you'll be slicing from right to left, top to bottom, side to side.
And the beauty of the MRI is that based on how you orient
your gradients, you can easily slice those three directions,
or actually in any direction you want,
which is why we call it multi-planar.
And so if we were to look at a simple thing,
like a simple image, like an E,
so we always like our anatomy image,
so that's our plane T1 because
fat is beautiful. And it actually allows us to see everything really well. And it looks like
what we're actually accustomed to seeing. And so we do a T1 sequence. Then we'd also look at a T2
sequence or a T2 fat set sequence. And what that actually allows us to do is on a T2 fat set,
we actually go... That's fat saturation. Yeah, so T2 fat saturation, what we're doing is we're taking T2.
So now the T2 looks at two things, so fat and water.
And then we actually suppress the fat.
So really all we're seeing is water.
And why that's most interesting is because edema.
So when there's something going wrong in the body,
almost anywhere, edema happens.
It's like if you bang your hand and it swells up,
that swelling is edema.
You injure your knee, it swells up, that's a dima.
And so if you actually bang the bones on your knee, so you've actually injured the cartilage,
you're going to get a dima happening in the heads of the bone as well as in the cartilage.
So that's why the T2 with fat saturation or removing the fat signal becomes so powerful
because it effectively now turns into a dima imager.
And when we know when there's a DEMA, there's a problem.
And that's kind of a simple concept in MRI.
That is quite often lost, but it's very, very important.
And then when you look at somebody's brain, for example,
we just reviewed my MRI recently.
So one thing that stands out, I think, is the exquisite
anatomic detail you're getting that seems to look far better
than it does in CT scan.
And secondly, it's the fact that without any contrast, you're able to see as though you
did an angiogram on all the vessels in my brain.
Now, is that something that any MRI can do or is that just something that the MRI here
can do?
Most MRIs should be able to do that.
And so when we've, again, sort of think back to what an MRI is,
so again, hydrogen imager, but it's also a big powerful magnet.
And so what makes our blood red is actually the iron that's contained within it.
So what you can actually do is you can take all the blood that's, let's say,
flowing to a particular organ like the head, so anything that's flowing up,
and you say, okay, I'm going to actually excite anything going up north to the brain, and so therefore
that's arteries. And so then you'll actually get to see all the exquisite arteries in your
brain just by exciting that blood.
I had never realized something so obvious as you just said it, but that's one part of
the body where it's really easy. I mean, the limbs would be the same. Where directionally, it's so clear, you know which way your magnet is oriented,
you know which way is blood flow away from the heart, and you've got this beautiful iron
floating around in water. Right. That's one of the beauties of MRI. There's all these different
things that you can actually add to it. And so not only that, you can actually excite anything flowing in one direction,
but you can actually also pick off the frequency
that's different between oxygenated arterial blood
and deoxygenated venous blood.
And so that comes into a different sequence called SWI
or susceptibility weighted imaging,
where you can actually look at the deoxygenation status
of venous blood and you can get spectacular contrast
to the small blood vessels in the brain using that sequence.
I remember the first time you did an MRI of my head.
I don't know why I was more nervous
about seeing that than anything else
because we sort of remember the most extreme horrible stories,
but I mean, I know people who have died of aneurysms.
You and I were even speaking about a patient
a few hours ago about this.
I used to ride a bike with a guy who was maybe six years, seven years older than me,
and was at Disneyland one day with his kids and had a horrible headache and dropped
head.
And he had an aneurysm, which is congenital.
And so yeah, I was sort of like really nervous, even though I realized straight probability
basis, the odds were quite low.
They weren't zero, and I figured, well, it's better
to find this now, because you can treat these things
electively quite easily.
But once they rupture, the mortality is incredibly high.
The mortality of ruptured aneurysms is over 93 to 95%.
So most people don't make it.
Whereas when you do find them earlier,
there's all sorts of options, such as coiling where
you can actually treat it or clipping. And so that's actually one
of the real powers of being able to kind of see what's going on without any injection
or anything like that. You can see the exquisite detail of the arteries. And if there is a problem,
and we've found a fair number of people with them, you can actually save their lives.
What is the frequency? Admittedly, you could argue a somewhat biased population because they're
more health conscious, obviously, anyone who can afford to just pay for an MRI out of pocket is
going to have a social economic advantage. But if you argue that that's still a reasonable cross
section of the population from a genetic standpoint, which is what we're basically asking,
what is the prevalence you find of aneurysm in the brain?
So when we actually scan a thousand people we actually found eight
Intercranial brain aneurysms, so point eight percent. That's higher than I would have guessed
Does the literature support that? The literature is actually a little bit less and the question is is that because you don't find them
Because basically people have passed away and we don't know what happens to the elderly because if they pass away
It's natural causes.
Yeah, we're not doing the autopsy.
Now, there are other aneurysms that are not quite as lethal, but are really bad.
And the two that I remember from residency were splenic artery aneurysms and popliteal artery aneurysms.
Do you see those? And if so, at what frequency?
We found only thing two, splenic artery aneurysms, but they are particularly deadly.
And now the popliteal arteries haven't seen many of those.
No, haven't seen those. And then those should be actually easier to...
You can palpate those on a thin enough individual.
I was gonna say, those are actually easier to feel and to see and to look at,
but we actually haven't found any of those.
I'm kind of still shocked.
That's a frightening statistic, Raj, that to think that almost one percent of the population
has an aneurysm in their brain.
And one of the things that we actually find though, and this may be showing the genetic component to it,
is that when you find it in one person in the family, next thing you know all their extended families coming in,
right, they want to know what's going on.
We looked into this three years ago. I have a patient, a young woman, probably in her late 30s.
Her mother died very young. When she was very young, the patient was very young,, probably in her late 30s. Her mother died very young when she was very young.
The patient was very young, and the mother herself was quite young from an aneurysm.
It was not in the brain, but I'll, for the sake of trying to protect her confidentiality
out.
Refrained from saying what part of the body it was.
And then when we dug into her family history further, we found another person who had died
of an aneurysm, and yet a different part of the body.
So not aortic where you normally see that link to atherosclerosis, but a different
major vessel.
And our team did a bit of work on this and actually found evidence that there really
was potentially a genetic component here.
And so we petitioned her insurance company to pay for an MRA, a magnetic resonance angiography,
which is basically what we're talking about here.
And they declined it, which really irked me
and we fought with her insurance company for six months
to get this paid and they denied it
and they denied it and they denied it.
And finally the woman just paid out of pocket for it.
And I was blown away at how much it cost.
Do you want to take a guess at how much it cost
to get an MRA in the United States?
I've seen some interesting pricing.
There's $9,000.
Wow.
Wow, that's unbelievable.
Yeah.
And it was negative.
So we were happy and she was obviously fortunate enough to be able to afford that.
But it upset me that we couldn't make a case to the insurance company that two people,
one first degree, one second degree, related to this this woman have died from an aneurysm,
young.
And they were like, yeah, that's cool.
Wow, that's a tragedy, that's.
So let's come back to now what you do here, Raj, because I've been around a lot of MRI,
and if we bring this story back full circle four years ago or whenever we were introduced,
the question that was asked of me was, hey, is this thing kind of cool or what? And I came up here and I spent the full day with you and I thought, yeah,
boy, this is really cool. But so many things that you were doing just seemed counter to
what we were seeing in the big shot hospitals. And for starters, you were using a puny magnet,
right? So one of the things hospitals love to brag about is the size of their magnet,
right? I'm going to just try not to name any hospitals and offend everyone, but you know,
pick your favorite institution. We've got the newest four Tesla magnet. I probably was in the top
five questions I asked you, oh, so what size magnet are you using? And you said, we're using a 1.5
Tesla magnet. And I said oh that's interesting
that seems a little bit JV. So explain why you use a magnet that is not at the peak of what you're
capable of just from a technology standpoint. Well it really depends on like basically how you tune
a magnet. So actually kind of you have a magnet is very much like a smartphone. If you actually build
the right hardware you can actually really get it to sing and do an amazing job. And so with a 3-Tit
T-magnet, one of the things is you can get some pretty exquisite imaging as you see quite commonly.
And really there's a lot of bragging rights associated with it. We're not much of braggers up here.
We just actually want to do the best imaging we can and actually tune the machine as
optimally as possible. So with a 3-tasle magnet, one of the things that actually commonly happens
is that when you look at the wavelength of a three-tasle,
because remember, it's electromagnetic fields actually go hand in hand
and those are actually wavelengths.
And so the three-tasle wavelength is roughly 15 centimeters,
so it's the width of your head.
1.5 is roughly 30 centimeters,
so it's the width of most people's shoulders.
So as a result, you actually start to get a lot more penetration with a lower field magnet.
And so that way you actually be able to see things quite well when you're particularly having everything tuned to that particular wavelength.
And quite commonly, when people are purchasing machines, they just don't know the physics of how the static magnetic field, the gradient magnetic fields, the coils, and there's roughly about 150 parameters per T1,
T2, fat saturation sequence that you can actually just to make it work the way you need it.
And most of the time, what commonly happens almost everywhere is that you'll have the vendor
will actually come in and set the standard parameters and
from there on, it's kind of like let's make it as simple as possible, push a button, and
that's kind of not what I do.
We don't want to just push buttons.
We actually want to understand how it all works, how it can be optimized to the person that's
coming in, and how the entire system from front to back is optimized, so we're maximizing
our signal to noise.
And when you maximize your signal to noise,
that's when you actually really get a lot of speed and detail.
And that's where one of the real values
of being able to talk engineering or physics
with the MRI physicist, and also then put on your clinical hat
and kind of saying, well, this is what I want to see.
This is a level of detail I need,
and a level of resolution that you can really tune
the machine to where you want it to be.
To me, of course, that was the analogy. You came up with the first one that jumps to my mind
is looking at sort of the heyday of F1 in the late 80s and early 90s when the cars had become
monsters. So if you look at the McLaren MP44, which is regarded as either the greatest or second
greatest Formula One car in history, the only other car that could probably rival it would be the 1993 Williams.
It had a 1.5 liter engine, so for any gear head listening, that's a really tiny engine. Like your Prius probably has a bigger engine than a 1.5 liter engine, and yet it produced 1200 horsepower redlining at something like 15,000 RPM.
power, redlining it, something like 15,000 RPM. And I just remember being a boy being so obsessed with that, like how could that possibly happen? And I remember looking at my dad's station wagon,
which had like a five liter Chevy block in it and thinking, how is this thing so inferior? But
in the end, like you can engineer, I mean, I think the technical term is you can
engineer the shit out of anything, right? That would be exactly. And that's exactly what it is.
And it's very analogous to the formula one. And a lot of people kind of, they're more into the
bragging rights of like the bigger, the bigger, the bigger, it's not always bigger. It's kind of like
you really understand what you're doing and want to get underneath the hood. You can take that 1.5
liter engine. You can put the turbo chargers on it. You can put, you know, like the multiple
valves and everything to actually get the torque and horsepower you want out of it. But
most people don't think that way. They think bigger is better.
How did you do all this tinkering? Because you basically have here in Vancouver a piece
of hardware that doesn't exist anywhere
else in the world. And you've layered on top of that software that is now also in a league
of its own. And that's even more complicated. I'm just interested in this hardware. I mean,
one of the things that I send a number of patients here, and usually the first question I ask
is, why are you sending me to Vancouver? Like, I live in, fill in the blank, some city in the United States, we do everything the best. There's no way, Peter,
you're telling me there's an MRI in Vancouver. In fact, I told my parents the other day,
I was coming to Vancouver to get the MRI and they live, you could almost hear them
look at me through the phone, like, why are you coming to Canada? So, I mean, not the tutor horn too much, but you're doing something very different, Rod. So, how did you
go through this process of tinkering with the 150 variables at your disposal to come up with this
super custom pimped out hardware that doesn't resemble anything else on the planet?
So, part of it is it's like the biggest problem with me
is that I'm an engineer in medicine.
And so when I kind of go through,
it's like I say, well, what do I want to know,
what I want to see and how do I make it work?
And so I kind of start at the sort of the back end
and say, okay, what I want to know
is exactly what's going on everywhere in the body
and what are the different sequences
that are going to get me there.
And then I kind of work backwards.
And then this is where you put your engineering
or physics hat on, and you actually wind up starting
to talk to like the MRI physicists who are,
there's a plethora of them, they're almost everywhere.
And they love to talk to doctors,
but just most of the time,
doctors can't talk to them or vice versa.
And that's when you start to really kind of get
under the hood and really kind of understand how
to make this work.
And then you travel around to different academic centers or different places.
And you wind up spending time with the people who actually really understand the hardware.
And those are mainly the physicists very similar to a mechanic.
It's like if you want to figure out how to make your five liter, behave like a thousand
horsepower, you talk to
the mechanics, you know how to do it.
Don't try it yourself, right?
They've already been there, they've seen it, they've worked on things forever.
And that's actually how a lot of it happens.
And so we would actually be having some of the top MRI physicists sort of saying, hey, Raj,
can you test us?
We wrote this sequence.
And the sequence is basically like a filter, like a T1 or a T2 or a fat saturation. Can you try it out and kind of see how it works?
So we go and try it out, usually on me as a subject, because I also know what I'm looking for.
And then we'd have a feedback loop, one or two of my MRI technologists here,
who would actually sort of push the buttons and run the machine,
and we'd see what it would give me.
And I knew from all the other imaging training that I would have,
what I would be looking for.
So I put my nuclear medicineicine hat on and say,
okay, from a functional point of view,
this is what I wanna see.
Then I put my radiology hat and say,
this is what I wanna see from an imaging perspective.
And let's define that a little bit.
I mean, objective is important.
So when you went about this process,
what were you optimizing for?
Were you interested primarily in detection of cancer?
Or what was the problem you wanted to solve clinically?
The first thing I wanted to do is, so talk about the nuclear medicine, so when we're
injecting somebody with a radioactivity, we want to basically optimize that dose that we're
giving to somebody, so that means we want to cover everything from head to foot. We don't
want to just look at an individual body part and we want to see how it all works. Then we go to
radiology, typically we're just doing a snapshot of an individual part like a head or a neck or a torso.
And so I kind of thought, well, all these MRI machines that are out there, all they're doing is looking at individual body parts.
And I thought, if I customize this hardware with a few things that might allow me to move people around while they're on the table, while they're laying there,
will I maybe be able to connect the head with the neck, with the chest, with the abdomen.
And so I actually, when I bought the hardware myself, I kind of put together probably about
50 options that the vendor has kind of said, you're crazy, we've never seen any of this
stuff.
Just with the thought that, you know, I think this might work.
This is where I was kind of looking at all the different options and kind of knew what
they could possibly do.
And I thought, if I build this hardware this way, will it work?
And it was a complete guess, but an educated guess.
And then once I put that hardware together, then we started to test and test and did more
and more.
Then we would start talking to more physicists, the vendors themselves actually have a lot
of good resources with very technologically capable people and when I started to put this together,
then I kind of thought, okay, what would I want? If I'm a patient,
what would I want to know? Well, number one, I'd want to know that my brain's okay.
I'd want to know that the arteries in my brain are okay, they're not going to rupture.
And then I basically want to say, whenever I go into any test or anybody goes into the
doctor and gets any kind of imaging test of any kind, the first question of their mind is to
have cancer, yes or no.
And in nuclear medicine, most of the tests are binary.
We can actually answer that with a yes or no.
In radiology, it's not so clear.
It's kind of like maybe, and you're actually kind of playing more statistics, like probably
not.
And I thought, how do I marry these two together?
And this is where MRI becomes a beautiful machine.
And the fact that it actually allows you to take that,
yes or no binary answer of functional nucleomedicine
and combine it with the anatomic localization
and understanding of tissue types that radiology has.
And so I merged those two together on the one machine.
And what is the functional arm that you brought into it?
Yeah, so the functional arm is actually an area that's actually growing a lot in academia.
It's actually called DWI or DWI, which stands for diffusion weighted imaging with background
subtraction.
And so what we're doing with DWI is that we're actually looking at water at two points in
time.
And so we're actually looking at it within about 60 microseconds of water motion. And so by
doing that, what happens is that you first look at water at one point in time, and then you look
at it at the second point in time, and if it hasn't moved, it's because it's not allowed to move.
It's effectively trapped between walls. And so that could be because of the fact there's a tight
cell membrane, or it could be because components of a cell are preventing that water from moving.
What's the time gap between those two samples?
Six microseconds.
Wow. And so when you see that something isn't moving, when you see that water is being forced
to be stationary as opposed to moving according to the stochastic prediction you have,
what do you infer clinically about that tissue?
So as soon as you start to see that water is being prevented from moving, that means that there's basically
going to be a high density of cells there,
so a big cluster of cells.
And so it's very much like I actually call it the lump detector.
So it's basically like they tell women for breast cancer,
feel for a lump.
And basically when you're feeling for a lump,
that's hard spot.
And so the reason it's hard is because you have this
increased cellular density.
And so with that increased cellular density, that's where water. And so the reason it's hard is because you have this increased cellular density.
And so with that increased cellular density,
that's where water is restricted from moving.
And that's what DWI, your diffusion weighted imaging does.
And then what it's called DWIs
because the fixed lot of diffusion
basically means that the normal diffusion of water
allowing it to move a lot is being completely restricted.
And it just doesn't have the ability to move.
You know, I usually tell patients about this part of the MRI, telling them something that I
think many people outside of medicine would find surprising when you do what's called a
laparotomy, when you open up a person's abdomen and let's say they have colon cancer.
So the colonoscopy has confirmed that, of course, you have a biopsy.
So now you're going in to do an operation to remove their colon, but you still have another
step along the way, which is you have to complete what's called staging.
You have to ask the question, has this cancer spread?
So usually the first thing you're doing is you're running your hand along parts of the
abdomen.
You can't even visualize the entire surface of the liver, even behind the liver, something
you won't see.
It's actually unmistakable what cancer feels like because it is so in contrast to what
normal tissue feels like.
And even the colon, before you cut it out, if you just reach in and pick up a piece of
the ascending colon, it's not remotely subtle where the cancer is.
It's entirely obvious just based on the firmness of the tissue.
And even when I talk to surgeons who operate on parts of the body that I didn't operate on,
such as the prostate or things like that,
it's the same thing.
And the example you give with breast is perfect.
And so it really is this amazing ability
to pair exquisite anatomic detail at resolutions
that we'll discuss, but basically now approaching one
by one by one millimeter resolution anatomically
with now this functional property of firmness.
Is that an accurate statement?
It definitely is.
So we're actually combining the anatomic and functional.
And that's where just like the on the PET CT where that famous one plus one equals three
is exactly what we're doing.
And the beauty of it is there's absolutely no radiation.
So there's no risk.
So the risk it seems, because one of the things I do explain to patients is who should
consider doing this?
And my view with cancer screening is, it's just a very personalized decision.
I don't think it is for everybody to do the kind of stuff that I do or that's a number
of my patients who you've now scanned have done over the past three or four years.
And when people say, is there a harm of doing this outside of the probably rare, rare event
of getting a migraine headache triggered by the magnet, I say there is a harm, the harm
of a false positive.
The harm is that we see something that turns out in the long run to not be cancer, but
in the process of going down the advanced diagnostic pathway to get there,
you are either physically harmed by something we do subsequently, for example,
another biopsy or a biopsy or a subsequent biopsy.
And of course, the emotional toll it takes on you to see a shadow in this part of your body
and have to sit there and have a discussion about what it could be, what it's probably a cyst, but it might be a tumor we probably need to do follow. I mean,
to me, this gets back to where we were a while ago on the discussion of sensitivity and specificity.
Right? So if somebody came along and said, I have a test that is a 100% sensitive, but only 50%
specific, I'd throw it in the waste basket.
I mean, it would serve virtually no purpose
for reasons I could walk the listener through
in terms of positive and pretty good value,
negative, pretty good value.
So when you think about the sensitivity and specificity
of the technology that you've developed here,
which again, we haven't even really done just as to get into,
we've talked a little bit about the hardware,
we haven't even got to the software. I'd love to talk about that
a little bit.
Do you think about sensitivity and specificity by tissue type, by cancer type? How do you
in your mind wrap your head around that?
So, the tip of the way I look at it is really almost organ by organ. When we're actually
going through, for example, in the liver, basically the simple thing we want to know, is there
a problem, yes or no?
Like really, that's the simplicity that the average person, and I put myself in that category
wants to know, do I have a problem to worry about?
And that's where I kind of say, by combining this functional as well as an anatomic imaging
together, we're actually really able to nail that down.
So in our thousand people that we did, the fascinating thing about this is all these people
we actually followed them up and actually talked to them and kind of found out what happened.
And so we actually had two false positives. So these were two people where we kind of thought,
okay, there's a problem here that you need to get addressed further by their further imaging
and see what's going on. And of those two false positives, one was a male with asymmetric
breast tissue. So we actually just had one
sided breast tissue. We didn't know what it was. It's like, so meaning you, he came out
of the MRI and you believed he had breast cancer, which most listeners might think is odd,
but it turns out men can get breast cancer. It's just virtually and exceedingly rare.
Exactly. But that's basically the DWI showed a difference in density between one breast
and the other. Yeah. And so we're like, why is that?
Most of the time when man actually have kind of a comasture, they have breast tissue,
it's usually bilateral because it's hormonal.
But to have unilateral is somewhat hot.
And so as a result, we sent this person to an ultrasound, which is a commonly done,
and they too had no idea.
And so they actually also made the call to biopsy, It came back as normal breast glandular tissue in a mail.
So let's talk just about the harm there. So emotionally, that man probably spent the
series of, well, if it was in Canada a year, if it was in the United States a week being
stressed out about this, sorry, I just can't help but take digs at your healthcare system
as you take digs at ours. No, I'm totally teasing. So there's a legitimate emotional strain
here, which I don't think anybody who's known someone who's gone through that or who's gone through that themselves,
you just can't deny this. And I've not lived it personally, but I've seen it and it's very difficult.
And then secondly, he had to get a procedure. He had to get a needle stuck into his breast tissue
and look, that's on the scale of procedures that's still pretty minor, but it's not trivial.
So what was the second case?
And so the second case was actually a woman who basically had
a seat belt injury to her breast and actually wound up having
an unusual scar that had actually trapped fluid in it.
And so this person actually should have, but never did actually
have any mammograms because that would have led to the same
conclusion that we don't know what this is.
So that was the second case where it's kind of like,
there's something unusual going on this breast. We don't know what it is. So that was the second case where it's kind of like, there's something unusual going on this brassed.
We don't know what it is,
but we didn't actually have any proper history from her.
And so we-
How old was she?
She would have been late 50s.
A woman in her late 50s had never had a mammogram?
Surprise, it's out there.
Even in Canada?
Even in Canada, yeah.
That in and of itself is very hard to believe in a country
where- It's free, yeah.
Yeah.
And then what would bring that patient in to get a whole body MRI?
The person actually kind of felt that I just want to know where I'm at.
And you know, it's like I don't believe in the radiation from a mammography.
And I keep trying to tell him, look, it's so minimal that the benefit outweighs the risks.
But they're like, I want the MRI instead because number one,
patients kind of know that it's the most detailed exam you can get.
And as well, there's no radiation.
So we actually had the patient, and it's kind of like,
yes, I don't really know what this is going on here.
So we sent them off to a facility that does nothing,
but women's imaging, and they too didn't know what it was.
And so they stuck and eliminated it,
and it actually came back as a...
Trapped...
Something fibrous.
Exactly, it was actually actually trap scar tissue.
And at that point when we'd spoken to a woman afterwards, we're like, did you ever have
trauma?
Like, why would you have scar to that area?
And it's like, oh, yeah, I was in a bad car accident.
And that was it.
It was a seat belt scar.
Those are two pretty interesting false negatives, right?
Both breast, men, women, I would have always maybe guessed or been most concerned about the
false positives
that occur deeper in the body.
I always tell patients that the call I'm always most afraid of getting is the little shadow
in the pancreas, where you just don't know is this in adenocarcinoma the pancreas, which
of course is something that if you're lucky, you can resect it, and if you're even luckier
you can survive it.
And I guess that's the only shot you're going to have at surviving pancreatic cancer
is an incidental finding.
You really don't think anybody that presents with pancreatic cancer is going to survive
it, at least not as an adenocarcinoma.
But then you worry about, well, what if it's something that turns out not to be cancer,
and you hear these horror stories?
There's a very famous one I believe it's Stanford several years ago where a woman went
to a sort of drive by CT clinic, got a CT scan, showed something in the same room, I remember when I was in the same room, I was
in the same room, I was in the same room, I was in the same room, I was in the same room,
I was in the same room, I was in the same room, I was in the same room, I was in the same room,
I was in the same room, I was in the same room, I was in the same room, I was in know that firsthand, so that might be a bit of a wives' tail stretch, but certainly that's a very popular story in the Bay Area.
But it's the cautionary tale, right?
Definitely it is, and that's kind of where the real value of actually having MRIs
opposed to CT comes in, and the fact that when we're looking at organs, particularly
like the pancreas or any of the visceral solid organs, we're looking at about seven different
filters looking at different ways, top to bottom, front to back, to really be able to see what's going on.
And that's where what we call contrast density
becomes really important in the fact that
when we're actually looking at the pancreas in particular,
we can actually pick out the pancreatic duct
as well as a bowel duct and be able to see that
just standing out against the rest of the organ.
And one of the first most common things
that pancreatic cancer likes to do
is to actually start to block that duct.
And so that's why when ERCPs are done, they're actually looking for cells of pancreatic cancer.
And an ERCP is basically when they go down into the mouth and the esophagus, and they actually go and
take a trace of fluid from the pancreatic bile duct.
So one of the other things that kind of amazes me when we go through these images here is,
when we've talked a little bit about the hardware, though, actually I kind of amazes me when we go through these images here is,
when we've talked a little bit about the hardware, though, I actually kind of want to come
back and ask more hardware questions.
But it's almost like you've created your own software now as well.
I had never seen this.
Is it commercially available to have that rotating diffusion weighted image map?
Is that a commercially available piece of software?
Or did you guys make that?
We actually built that as a display tool, and that's actually effectively taking a page out of the
nuclear medicine positron emission tomography or PET CT handbook. And the reason why we actually put
it together is because it actually allows you when effectively a pretty efficient viewing to be
able to see what's going on through the entire body. It's almost like making a transparent person.
And where basically any of the black spots that stand out would be the hard spots
or the firm areas. And the one that we just looked at earlier, I remember you saying that
if I understood you correctly, one of the advantages of using a quote-unquote low power magnet,
like you're using, is you don't have any of the gaps in the spine. You've got this everything
that you showed on that rotating diffusion weighted image. You had the dark brain, obviously full of
firm fluid, and then you have this dark beautiful tail coming out of it, which is the spinal fluid,
but it was perfectly smooth. Right. And that's actually one of the important things because
magnets actually have a lot of homogeneity problems we call them. And the fact that you want it to be perfect, so that the field in between the top
and the bottom and the left and the right are identical. And as soon as you put a person in there,
that comes in various sizes and shapes, they actually distort that magnetic field. And the sweet spot
for the magnetic field is perfectly in the center. And so when we put all these protocols and
built all these things, we actually built it for different body shapes and we can actually go and tune it for all these
body shapes so that the goal is that no matter what we're doing these rotating images,
that it looks like a normal person, not a segmented piece of a person.
Yeah, it's funny you say that. You took a playbook out of the PET CT. That's exactly what it looks
like. It looks just like you're looking at the FDG pet juxtaposed with the CT.
Right.
And that's the entire purpose.
And so that's where I talk about the MRI being this tool that can actually combine functional
imaging of, in this case, dwebs or DWI diffusion weighted imaging.
And the MRI being the equivalent to the CT, which is far more tissue weightings in detail,
it's where the one plus one equals three.
Now, if the radiation didn't bother you
of a whole body pet CT,
and of course it should bother you
because a whole body pet CT would be more than 50% of your,
it'd be probably close to 80% of your annual
allotment of radiation, right?
If not, home more.
It'd be quite high, yeah.
Depending on if you live at altitude or where you live,
right, so if you're at sea level, you'd probably allowed one a year maximum, if not one every
two years. Yeah. So putting aside that issue, which is not trivial, what advantage do
you think that the MRI with DWI has over the PET CT? And where does the PET CT have an
advantage? So if you go either by histology, by tissue, by tumor type, with the PET CT. And where does the PET CT have an advantage? So if you go either by
histology, by tissue, by tumor type. With the PET CT with radioactive glucose,
one of the areas that actually doesn't work very well at all is the brain. And the MRI is always
known as like the best image of the brain. The PET CT, you can actually miss things in the brain
because what you're looking for with the radioactive glucose is areas of increased glucose utilization. And the brain in particular is a glucose, that's all I can
use, unless you're in ketosis. And then the other problem is that the glucose is then
expreated by the kidneys. And so the kidneys now become difficult to see because they're
actually full of glucose. And as is a bladder, you can't see a thing in the bladder because
it's full of the accumulated glucose.
As well in the prostate, prostate is very, very poorly perfused, and as a result, it doesn't
get a lot of glucose coming to it.
And so, PET is actually almost entirely useless with FDG at looking at the prostate.
The fusion weighted image of the prostate, coupled with the more advanced molecular tests, the 4K as an
example of a blood test. In my mind, have totally revolutionized the way we
think about prostate cancer. So we now have a blood test that produces much better
resolution than just a PSA, but more importantly, we have this MRI and even in a practice as small as mine, I have had two patients for whom PSA is high.
4K comes back high.
So these are patients who now have a 20% chance,
maybe 16, 18, 20% chance of having cancer in their prostate
or having metastatic cancer over the next decade.
That's basically what the high 4K tells you.
In the old days, we would just biopsy them,
and now we run them through the MRI,
and the answer is nope, that's totally fine.
Right, and that's actually where MRI becomes very, very powerful,
particularly with the DWI,
and I think in many countries,
it's now coming to US and becoming more popular,
but in Australia,
in Europe, particularly UK, Scandinavia, it's actually the de facto standard, basically almost
all men are actually getting screened with MRI.
Wait, wait, wait, did you say in Europe and Australia?
Yeah.
They're actually doing it with a DWI.
And so how is that even possible that countries with single payer, socialized medicine could
use an MRI for the screening tool.
I mean, that would be unheard of in Canada, wouldn't it?
Well, we just don't have the access to the number of machines here,
but I think one of the things that people are actually finding with screening for the prostate
is that all men are either going to die with or from prostate cancer
and so you really want to be able to separate those out.
And up until MRI with DWI came into effect, there was no real way to do that.
So you'd be doing PSA or 4K and all that would do is say, yeah, there's an increased risk
of something going on, but is it going on?
So PSA in particular, it can actually be elevated for three reasons, one prostate cancer,
the other one inflammation or prostititis, and then the third being in large prostate.
And so if it was up for any of those causes, then you would actually go and take a biopsy,
which actually comes with risks.
But the whole idea is that all the staging
was based on that tissue sample.
Whereas what's happening very similar to the breast
is kind of like a lot of people are saying,
well, treating this as like a big deal,
I don't want the biopsy and people get a choice
of what they want to do.
And a lot of men are saying, look,
I want to see what's going on.
I want to see if there's going to be a change.
And if it actually starts to grow or something's growing in the process and accelerated rate,
that's when I want to deal with it.
Whereas if it's actually just there and holding still and not changing much,
I'm not going to worry about it because something else may take me first.
Is DWI going to have the same effect on breast cancer?
In other words, if you could put resources aside for a moment, if a woman could have a mammogram and a DWI MRI, and it's important to point out
that you can't eliminate mammography because we're going to come to this, but MRI has its own
blind spots and small calcifications would be a blind spot. But would those two tests mammogram
would be a blind spot. But with those two tests, mammogram and DWI MRI done the way you guys are doing it, not just off the shelf. Are you going to miss breast cancer in those situations?
Pretty unlikely. And actually, there's been a couple of really nice big studies that have
finally started to come out from groups at UCSF and as well at Sloan Kettering,
Memorial Sloan Kettering in New York. They've actually shown that.
You did your fellowship at Memorial Didn't you?
I was actually there for quite a while actually doing PET CT.
Okay.
Yeah, yeah.
Amazing institution, absolutely amazing.
But what's actually come out of the MRI group is that basically if you actually use
DWI with MRI, you actually are as sensitive as giving a contrast injection breast MRI.
Wow.
But that's diffusion done right and the problem is out of the box,
it's not always done right.
Yeah, that's the challenge, I think, for the patient, right?
Is the patients, look, you kind of need a PhD in physics.
Let's be honest to really understand the nuances of MRI.
I consider myself pretty technically smart
when it comes to the physics of this stuff.
And I would not feel competent to try to differentiate
or even parse out the differences between scanners.
In fact, anytime I'm sending my patients to a scanner,
I sort of have to rely on other people to help me.
I have to reach out to experts and say,
hey, my patient has to get this scanned
on in New York or in San Francisco or LA
is the best we got if they're not going to get on a plane
and go to someplace where I know exactly what they're going to get.
So that's a significant challenge, right? Because there's people are going to listen to this and think, okay, well, as long as it's diffusion-weighted imaging MRI, it's perfect.
And that's actually the biggest problem with MRI. Like earlier on, we talked about CT having units of Houndsfield, like Houndsfield units, to actually sort of calibrate and standardize them. Unfortunately, MRI has no standardization whatsoever.
And there's actually a movement called Kiba,
or quantitative imaging, biomarkers alliance.
It's a component of the radiology society of North America
that's actually really trying to push to standardize the amount
of signal to noise coming off of MRI machines
with the goal that if you actually get a scan at one site
or another site, the image quality is the same.
Right now it's really not that at all and really is sort of caveat mdore look out.
So right now if somebody goes to Shreveport and gets a 256 slice CT scanner on a Siemens
pick your favorite model and they do the same thing in Seattle.
You can share those data across radiologists, and it can be made to look identical.
Your acquisition is the same.
Relatively, so what I mean by that is that the actual amount of signal on your film or
on your screen, water is going to be zero, and so the Hound Field Unit is always going
to be exactly calibrated.
So what's the opposition?
I mean, that seems like a no-brainer.
What is the opposition to doing this with MR?
It actually relies on the vendor is coming together and a few years ago we actually spoke
with a bunch of the vendors and saying, look, why don't you guys do this particularly for
a diffusion where it's actually so important because this is such a new and powerful sequence.
And they all kind of came back and said, well, you guys write a white paper and then we'll implement what you said.
And this is fortunately starting to move forward with this organization, Keybot of RSNA.
And they're doing it organ by organ, so there is a bit of a standardization for prostate, for liver, and as well, breast is now coming out.
And that was actually, the breast was led by a group out of University of Washington.
And the overall leader for this is a person named Michael Boss out of now he's American
College of Radiology.
And this needs to move forward because otherwise people have no idea what they're
getting.
And it's really sad because even if you walked down the streets, for example, in a
place like New York, I used to live literally 20 feet from a MRI shop.
And they had all these sort of images and what I consider just sort of bogus
propaganda all over their window like why go down a memorial and get your MRI there when you can
come here and do a standing MRI it's comfortable it's fast and blah blah blah I'm thinking to myself
and it sucks so and again I don't know that exists in Canada but it's certainly in the United States
there's a bit of a cottage industry around one-stop shop scanners that I think patients
just don't know what they're getting into, right?
Right.
And I don't know how well it works in the United States, but it really is.
It's like because of this lack of standardization in the field of MRI, and it's really unfortunate
because this is of all the imaging tools.
It's the most powerful, but it really does need this ability for standardization. And it may also sort of be the
fact that in order to make it standardized, you need to get
the physicists together with the radiologists who are basically
the high of the final image. And quite often that doesn't
happen because of the language barrier.
Right, and of course it's not, it's the language of physics,
is the language, you know. Going back to the hardware for a
second, where do you see things evolving?
In other words, if you had to project where you think
you with the right technology would like to see this
in five or 10 years, what could make this better?
What I'd actually like to do, and when you see sort
of what we're doing, the speed with which we do
and that the detail and resolution that we're able
to acquire in about 55 minutes is really unprecedented anywhere.
But I know from a physics point of view that I could speed this up further.
Right now everything we're doing is perfectly within FDA specifications.
There's nothing outside of the box,
but I really would like to push this and go outside of the box.
And what that really requires is a lot more computational horsepower.
It's really difficult to do all that computation within a single
CPU machine on site, whereas
I expect it in the future, as wars, long computers get faster or faster, you can actually
do a lot of this stuff computationally and make it much faster.
And the goal would really be to actually have these scans that we're doing, you know,
under half an hour even faster.
And it can be done from a physics point of view.
It's not a technological barrier.
Even with the magnet that you have, even at 1.5.
Yeah.
Now, I had my scan today, a friend had a scan today, and one of the things that people
always talk about when they're doing these scans is, my God, it gets hot in there.
What is it about a whole body MRI, even one that's done in a short period of time is 55
minutes, that makes it so uncomfortable by the end in terms of body temperature?
It really has to do with the amount of energy that's being absorbed.
So what we're doing with the electromagnetic field is you're actually putting in radio
frequency, right?
And that radio frequency is always also coming out.
And that radio frequency is the same thing as a cell phone would get.
That's called SAR or a specific absorption ratio.
And the hydrogen ions are basically moving around and that's basically
effectively heating you up. So it's not quite like a micro-hafe, but you can
actually think about it as a microwave. The wavelength is exactly very similar to an AM radio.
And so your cell phone is typically far more powerful. So as an example, I went and did the
calculation a while ago on how much SAR we're actually putting into a whole body Prenubile scan, and it's equivalent to talking on a cell phone for about four hours.
Interesting, but it concentrates it across your whole body.
Right.
Yeah, it's funny.
Every time I get an MRI or a whole body, the first 30 minutes, I'm like, yeah, it's not
so bad.
And then the last 10 minutes, I'm like, get me out of here.
Right.
And we've actually done it that way on purpose because we kind of know that the way we
kind of run our sequences or filters together is that we actually kind of want to get as
much information in such a way.
Yeah, you do the head first and that's not nearly as much as doing the abdomen and thighs
or probably where a ton of that heat gets generated right and is sort of needs to abdomen.
Right.
And so when you look at basically the overall blood flow, which is what cools your body,
well, the brain takes 20% of your cardiac output.
So it's basically like this big, cool,
it's this big heat sink.
Right, it's just cools everything away.
Whereas when you get down and lowered to the legs,
which you're all muscle, it's going to heat that up.
And so that's why we figure out how to orient these
in what organization to make,
what plan of sequence is to make it not as uncomfortable?
Commerciality, what's the best off the shelf scanner that could come close to producing the resolution you're producing?
Is it fully isotropic?
It's isotropic in the brain, but in the rest of the body we're actually doing more conventional clinical images.
Tell us what isotropic is, I'm sorry, I should have clarified that.
Sure, so what isotropic basically means is that it's more basic slicing you in cubes.
So a 1 by 1 by 1 millimeter cube, for example, and the power of actually doing that 1 by 1
by 1 is that you can now look at things again in three dimensions in any direction you want.
The detail and resolution is perfect.
And so that's what isotropic means.
Whereas MRI typically can't be done isotropically just because of time.
You want to cover as much as possible, but you want what we call in-plane resolution,
which is how you orient the first gradient to have the highest amount of detail,
and then you typically will take a perpendicular view.
And that's why when you do these rotations off your sagittal plane,
the resolution deteriorates wildly in conventional scans, right?
Right. Exactly.
And so the diffusions that we're doing are done isotropic, but unconventional, not often.
So that's why when you rotate, and hopefully in the show notes, we'll be able to get some videos,
like we'll literally just show what it looks like, because I know this is a kind of a difficult
discussion to have without being able to kind of picture for us.
It's easy, but I think we want to make sure that the listener can see this.
That's why you don't see any distortion when you rotate the DWI.
So is there a commercially available scanner that can do that?
Not yet.
Someday, not yet.
And so basically your goal was just to be, I don't know how to put a time stamp on it.
How far are you ahead of what's happening conventionally?
I mean, four years ago, you were doing things that I still don't see any scanner doing in the country.
And I see the best scanners.
Thank you.
But, uh, well, for example, like when I have a patient that went to one of the most famous
hospitals in the country and had a dedicated prostate CT scan, it took 40 minutes just
to do the prostate.
Dedicated prostate MRI.
MRI, not CT.
Yes. So he had the prostate MRI, took 40 minutes.
It was on a three or four Tesla magnet.
And so he spent two thirds of the time
to get a slightly inferior image by resolution,
especially on the DWI, was far inferior
to what you were doing on the whole body.
It all comes down to basic engineering of signal to noise.
If you can make all the hardware that you have,
really sing, your signal to noise is so much better.
And then you can basically dial it to effectively where you want.
So if you need more and more signal,
depending on your machine's, I guess, horse power
and coil configuration, just takes time.
It's always a balance between time and signal to noise.
So where is machine learning going to come into the fold here?
You actually mentioned something to me recently that I had never thought of, which is it's
really hard to throw a whole body image at a machine and have it solve even the simplest
problem that we take for granted as a human, which is which one's the liver, which one's
the kidney. And whereas if you weren't doing a whole body, if you were just doing a liver image,
that's an easier problem to hand the machine because it already knows it's looking at liver.
So, I mean, how far are we away from a machine being able to help you do this?
I think that there's actually a lot of tools that actually still need to be written.
So, for example, part of that is to really kind of look at organs and isolate organs.
Conventionally, most imaging is done by body part.
So head, neck, chest, abdomen, pelvis, and not connected together.
And so when you actually give a machine, okay, here's your brain, it's actually able to
kind of go through that relatively efficiently.
But part of it really comes down to building the tools to actually
analyze whole body, like even the software to view the whole body is exquisitely complex.
But the difference is that when you actually start to build these tools, it can actually start
to help us narrow down what's going on. And the goal is to really sort of have machines make
radial just more efficient. And also more importantly, we never want to miss anything, right? And so,
you know, we can't have a second reader all the time,
but if you have a machine being a second reader,
you wind up actually training that machine as you go along.
And I think most people would be comfortable with that.
And that's what's actually done in momography right now.
And so, for, I mean, momography, obviously,
is like the tip of the iceberg, but you got to start somewhere, right?
It's very, I don't want to minimize,
because I couldn't read a mammogram to save my life,
but it's relative to what we're talking about. It's much simpler. It seems that where the
machine might first be able to make a dent in what you're doing is not the patient who gets their
first skin, but the one who gets the repeat skin. That seems to be paired T-test, seems to be an
easier problem to solve. And an important problem to solve, because a lot of times for us as
radiologists, like those studies, we still do things the same way when we review
them, whereas when you actually go and you take like a pair of T tests, like you
said, and you actually do a subtraction where you're looking for the
difference or that delta, it can actually stand out and become very, very simple
and very obvious. And once that subtraction is done, and I think that's where
machine learning will actually really help make us more efficient. And at the end of the day, we just don't want to miss anything.
Well, Raj, I've monopolized more of your time today. And that means that there've been probably
three or four fewer patients that have been scanned today. So I really appreciate you taking the time.
And I appreciate just all the time you've spent over the last three or four years educating me.
You're incredibly generous with your insights. And I constantly lob questions at you and you've always got all the time in the world for me and
by extension my patience and all the people that I hope to sort of try to educate
with this. So thank you for the amazing work you're doing here and then also just for your generosity.
Oh thanks, that's a pleasure. Love it. You need to visit more often.
Yeah, next time you come down to California. Sure. We have Uber.
Yeah, next time you come down to California. Sure.
We have Uber.
Thank you.
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