TED Talks Daily - Why your blood should flow like ketchup | Sean Farrington
Episode Date: November 7, 2025Your blood should have more in common with ketchup than just color, says chemical engineer Sean Farrington. Demonstrating the flow of everyday products like shampoo, peanut butter and ketchup, he make...s the case for expanding the use of blood viscosity as a medical diagnostic, much like blood pressure. Learn more about the little-known field of rheology and how it could save lives — if taken seriously.Interested in learning more about upcoming TED events? Follow these links:TEDNext: ted.com/futureyou Hosted on Acast. See acast.com/privacy for more information.
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You're listening to TED Talks Daily, where we bring you new ideas to spark your curiosity every day.
I'm your host, Elise Hugh.
Reality is the branch of physics that studies the deformation and flow of materials, both solids and liquids.
And while this may be one of the lesser-known scientific fields of study, according to chemical engineer Sean Farrington, it has the potential to
completely transform how we understand and diagnose cardiovascular disease.
In his talk, Sean Shet's light on why this field is so powerful
and why it's time for engineers and medical professionals to work together
to integrate this emerging science into routine care.
When I was a kid, my uncle would tell me these great stories about his aeroseph.
space engineering career. He used to tell me all about the machinery and the designs that he
built throughout his life and always said he picked the perfect career for himself because of all
the cool stuff he was able to build. Once he told me about working in the nose cone of an Apollo
rocket fixing some sensitive piece of equipment just a few days before its launch. I was
enamored by this. Listening to his stories had me daydreaming about all the innovative technology
that I could build. And it's what inspired me to become an engineer too. Since going down this
path, I've learned there's more to engineering than just the amazing stuff we build. There's also
a vital responsibility in the work, sometimes with the ability to save human life. Put simply,
when engineers mess up, people die.
And this is what my PhD advisor warned me about
when I started working with him four years ago.
When I decided to follow the path of chemical engineering,
I could have never imagined I'd be doing my PhD
in a field of study called reology.
But reology was interesting to me,
enough so I spend a few years of my life understanding it.
Reology is the study of flow and deformation of materials.
It's mainly a method to measure the viscosity or thickness of a material
so that it works for its intended function.
Reology is best used for materials that are neither liquid nor solid but some combination of both.
and the concepts of reality are easiest to understand when we compare across different products
because it is essential to almost every consumer product on the market,
whether that's a lotion that evenly coats your hands or a motor oil that lubricates at all operating
temperatures or cement that won't harden before making it to the job site.
And there's so many other examples across many industries.
So why don't I take you over to the Riology Lab where I can demonstrate this for you?
Okay, first off, everybody has their favorite peanut butter, unless you're allergic.
And maybe you prefer the one that will stick to the bread, or you prefer the one that can't support itself and just slides right off.
But how about shampoo?
So the purpose of shampoo is to squeeze from the bottle and sit on your hand so that you can
sufficiently measure out a drop that cleans your hair.
But how about when that shampoo gets a little low, right?
And now you fill it up with water so that you can save that last little drop and now it no longer
stays in the palm of your hand, completely ruining one of its core functions.
Okay, now for my favorite example, it'll be the last one, that's ketchup.
Because ketchup, there's such a huge difference in the texture between those popular brands.
And for this one, we'll do a little bit of an experiment.
We have one ketchup in each beaker, and when I flip them, we're going to watch closely to see which one
drains faster.
Okay, we can see there's clearly one ketchup that's much thicker than the other.
And that happens to be the one that's my preference.
So all of these materials are a part of a class of materials called non-Newtonian fluids.
and reology is used to measure the different flow properties of each of these materials
so that they can be made reproducibly and with the most desired texture for their application.
Maybe by now you see the value of reallogy for product manufacturing.
But why should your blood flow like ketchup?
Well, one application of reality that I'm most interested in is in medical diagnostics.
You see our blood, it doesn't flow like water, how you might imagine.
Rather, it flows a bit close to ketchup.
And that's because blood is a non-Newtonian fluid, just like all the materials in my demonstration.
Specifically, it's a sheer thinning fluid.
And it does this because it's necessary for healthy blood flow.
If your blood's viscosity is too high, there's a higher chance of developing something like a clot or potentially an aneurysm.
So measuring this information would allow physicians another method to detect for cardiovascular disease.
Yet it's not being used because reality,
is this niche technical engineering field,
largely unknown to the public.
But I bet everyone here can think of at least one person in their lives
who has or had a heart condition.
Some studies show that up to 46% of people
over the age of 40 have some form of coronary atherosclerosis,
which is a chronic condition where plaque builds up,
and your arteries and narrows them, reducing the flow.
One quarter of deaths in the United States are caused by heart disease.
And one major challenge within these diseases is to detect them early
so that medication and treatment have enough time to take effect.
Blood pressure is a metric commonly used by physicians to,
inform their decisions for medications and treatment of cardiovascular disease.
And blood pressure monitoring has been going on for over 300 years.
Now imagine the past 300 years if physicians didn't know about blood pressure monitor.
There would be countless unnecessary suffering.
This is the stage that blood break.
is that. Though blood's viscosity has been studied for over a hundred years, and blood
rheologists have shown significant evidence correlating it to cardiovascular disease,
it's still not widely used as a diagnostic tool. Spreading awareness about reology is necessary
so that it becomes known as commonly as blood pressure monitoring. Blood reology is one of those
areas where physicians can work together with the engineers so that we can proactively create
solutions that put this knowledge into practice. Some of my work as a PhD student is to help
simplify the rheological measurement. While I'm studying the reallogy of blood and its use
for cardiovascular disease diagnosis, I'm also building a small microfluidic chart.
ship. My goal in this work is to measure the same
radiological information in a small, cheap, portable device
that we're currently able to do in a bulky, stationary, half a million
dollar machine. This could simplify
the radiological measurement, making it more accessible for
many doctors. And some physicians have begun to use
blood reallogy to augment their patient care, and they've seen
positive results so far, but just like the blood pressure monitor will all be better off when
the public has a greater awareness of this technology so that we can help improve cardiovascular
disease. And so that's why I'm asking you to just have a conversation with someone in your life
about this science. And if you're in the medical community, I want you to take a close
her look at blood reallogy, dive into this science, and see how you might be able to use it
in your field. There's so much valuable information in blood reallogy that tells us about our
health. If we can just get over its obscurity, we might be able to help solve some of our
most pressing modern medical issues. If we just spread a little awareness, we could save lives.
That was Sean Farrington at TEDx Wilmington in Delaware, USA in 2025.
If you're curious about Ted's curation, find out more at TED.com slash curation guidelines.
And that's it for today.
TED Talks Daily is part of the TED Audio Collective.
This talk was fact-checked by the TED Research Team and produced and edited by our team,
Martha Estefanos, Oliver Friedman, Brian Green, Lucy Little,
and Tonzica Songmar Nivong. This episode was mixed by Christopher Faisi Bogan.
Additional support from Emma Tobner and Daniela Balareso. I'm Elise Hugh. I'll be back
tomorrow with a fresh idea for your feed. Thanks for listening.