How AI is making it easier to diagnose disease
-
0:01 - 0:05Computer algorithms today
are performing incredible tasks -
0:05 - 0:10with high accuracies, at a massive scale,
using human-like intelligence. -
0:10 - 0:14And this intelligence of computers
is often referred to as AI -
0:14 - 0:16or artificial intelligence.
-
0:16 - 0:20AI is poised to make an incredible impact
on our lives in the future. -
0:21 - 0:25Today, however,
we still face massive challenges -
0:25 - 0:28in detecting and diagnosing
several life-threatening illnesses, -
0:28 - 0:31such as infectious diseases and cancer.
-
0:32 - 0:34Thousands of patients every year
-
0:34 - 0:37lose their lives
due to liver and oral cancer. -
0:38 - 0:41Our best way to help these patients
-
0:41 - 0:45is to perform early detection
and diagnoses of these diseases. -
0:46 - 0:50So how do we detect these diseases today,
and can artificial intelligence help? -
0:52 - 0:56In patients who, unfortunately,
are suspected of these diseases, -
0:56 - 0:58an expert physician first orders
-
0:58 - 1:01very expensive
medical imaging technologies -
1:01 - 1:05such as fluorescent imaging,
CTs, MRIs, to be performed. -
1:05 - 1:07Once those images are collected,
-
1:07 - 1:12another expert physician then diagnoses
those images and talks to the patient. -
1:13 - 1:16As you can see, this is
a very resource-intensive process, -
1:16 - 1:20requiring both expert physicians,
expensive medical imaging technologies, -
1:20 - 1:24and is not considered practical
for the developing world. -
1:24 - 1:27And in fact, in many
industrialized nations, as well. -
1:28 - 1:31So, can we solve this problem
using artificial intelligence? -
1:32 - 1:36Today, if I were to use traditional
artificial intelligence architectures -
1:36 - 1:37to solve this problem,
-
1:37 - 1:39I would require 10,000 --
-
1:39 - 1:43I repeat, on an order of 10,000
of these very expensive medical images -
1:43 - 1:44first to be generated.
-
1:44 - 1:47After that, I would then go
to an expert physician, -
1:47 - 1:49who would then analyze
those images for me. -
1:50 - 1:52And using those two pieces of information,
-
1:52 - 1:55I can train a standard deep neural network
or a deep learning network -
1:55 - 1:57to provide patient's diagnosis.
-
1:57 - 1:59Similar to the first approach,
-
1:59 - 2:01traditional artificial
intelligence approaches -
2:01 - 2:03suffer from the same problem.
-
2:03 - 2:07Large amounts of data, expert physicians
and expert medical imaging technologies. -
2:08 - 2:13So, can we invent more scalable, effective
-
2:13 - 2:16and more valuable artificial
intelligence architectures -
2:16 - 2:19to solve these very important
problems facing us today? -
2:19 - 2:22And this is exactly
what my group at MIT Media Lab does. -
2:22 - 2:26We have invented a variety
of unorthodox AI architectures -
2:26 - 2:29to solve some of the most important
challenges facing us today -
2:29 - 2:32in medical imaging and clinical trials.
-
2:32 - 2:36In the example I shared
with you today, we had two goals. -
2:36 - 2:39Our first goal was to reduce
the number of images -
2:39 - 2:42required to train
artificial intelligence algorithms. -
2:42 - 2:44Our second goal -- we were more ambitious,
-
2:44 - 2:48we wanted to reduce the use
of expensive medical imaging technologies -
2:48 - 2:49to screen patients.
-
2:49 - 2:50So how did we do it?
-
2:51 - 2:52For our first goal,
-
2:52 - 2:54instead of starting
with tens and thousands -
2:54 - 2:57of these very expensive medical images,
like traditional AI, -
2:57 - 2:59we started with a single medical image.
-
2:59 - 3:03From this image, my team and I
figured out a very clever way -
3:03 - 3:06to extract billions
of information packets. -
3:06 - 3:10These information packets
included colors, pixels, geometry -
3:10 - 3:12and rendering of the disease
on the medical image. -
3:12 - 3:17In a sense, we converted one image
into billions of training data points, -
3:17 - 3:20massively reducing the amount of data
needed for training. -
3:20 - 3:21For our second goal,
-
3:21 - 3:25to reduce the use of expensive medical
imaging technologies to screen patients, -
3:25 - 3:28we started with a standard,
white light photograph, -
3:28 - 3:32acquired either from a DSLR camera
or a mobile phone, for the patient. -
3:32 - 3:35Then remember those
billions of information packets? -
3:35 - 3:38We overlaid those from
the medical image onto this image, -
3:39 - 3:41creating something
that we call a composite image. -
3:41 - 3:45Much to our surprise,
we only required 50 -- -
3:45 - 3:46I repeat, only 50 --
-
3:46 - 3:50of these composite images to train
our algorithms to high efficiencies. -
3:51 - 3:52To summarize our approach,
-
3:52 - 3:55instead of using 10,000
very expensive medical images, -
3:55 - 3:58we can now train the AI algorithms
in an unorthodox way, -
3:58 - 4:03using only 50 of these high-resolution,
but standard photographs, -
4:03 - 4:05acquired from DSLR cameras
and mobile phones, -
4:05 - 4:07and provide diagnosis.
-
4:07 - 4:08More importantly,
-
4:08 - 4:11our algorithms can accept,
in the future and even right now, -
4:11 - 4:14some very simple, white light
photographs from the patient, -
4:14 - 4:16instead of expensive
medical imaging technologies. -
4:17 - 4:20I believe that we are poised
to enter an era -
4:20 - 4:22where artificial intelligence
-
4:22 - 4:25is going to make an incredible
impact on our future. -
4:25 - 4:27And I think that thinking
about traditional AI, -
4:27 - 4:30which is data-rich but application-poor,
-
4:30 - 4:32we should also continue thinking
-
4:32 - 4:35about unorthodox artificial
intelligence architectures, -
4:35 - 4:37which can accept small amounts of data
-
4:37 - 4:40and solve some of the most important
problems facing us today, -
4:40 - 4:41especially in health care.
-
4:41 - 4:42Thank you very much.
-
4:42 - 4:46(Applause)
- Title:
- How AI is making it easier to diagnose disease
- Speaker:
- Pratik Shah
- Description:
-
Today’s AI algorithms require tens of thousands of expensive medical images to detect a patient’s disease. What if we could drastically reduce the amount of data needed to train an AI, making diagnoses low-cost and more effective? TED Fellow Pratik Shah is working on a clever system to do just that. Using an unorthodox AI approach, Shah has developed a technology that requires as few as 50 images to develop a working algorithm -- and can even use photos taken on doctors' cell phones to provide a diagnosis. Learn more about how this new way to analyze medical information could lead to earlier detection of life-threatening illnesses and bring AI-assisted diagnosis to more health care settings worldwide.
- Video Language:
- English
- Team:
- closed TED
- Project:
- TEDTalks
- Duration:
- 04:59
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