Huberman Lab - The Science of Vision, Eye Health & Seeing Better
Episode Date: June 14, 2021This episode I describe how we see, meaning how our eyes focus, convert light information into electricity the rest of the brain can understand and how our brain creates the incredible thing we experi...ence as “sight”. I also describe how we can train and support our visual system to improve at any age. I describe more than a dozen protocols to support depth perception, offset near-sightedness, improve mood, sleep, and our ability to focus (both visual focus and our mental focus generally). I also explain how to use eyesight to improve our levels of alertness and why visual hallucinations, lazy eyes and colorblindness occur. I also describe various compounds that may assist in supporting visual health and possibly improve our vision. Many simple, zero-cost protocols and a lot of scientific mechanisms are covered in this episode in clear language anyone can understand-- it is for anyone that values their brain and whether eyesight, young, adult-age or advanced age. For the full show notes, visit hubermanlab.com. Thank you to our sponsors: AG1 (Athletic Greens): https://athleticgreens.com/huberman LMNT: https://drinklmnt.com/huberman Supplements from Momentous https://www.livemomentous.com/huberman Timestamps (00:00:00) Introduction (00:00:31) Sponsors: AG1, LMNT (00:04:51) Protocol: Concurrent Training For Endurance, Strength, Hypertrophy (00:07:24) The Senses, Vision, Seeing & What We Should All Do To See Better (00:10:35) Our Eyes: What They Really Do, & How They Work (00:14:30) Converting Light Into Electricity Language: Photoreceptors, Retinal Ganglion Cells (00:17:00) We Don’t See Anything Directly: It Is All A Comparison Of Reflected Light (00:19:35) Dogs, Cats, Snakes, Squirrels, Shrimps, Diving Birds, & You(r View Of The World) (00:24:05) Everything You See Is A Best Guess, Blind Spots (00:25:50) Depth Perception (00:28:00) Subconscious Vision: Light, Mood, Metabolism, Dopamine; Frog’s Skin In Your Eyes (00:32:00) Blue-Yellow Light, Sunlight; & Protocol 1 For Better Biology & Psychology; (00:35:00) Protocol 2: Prevent & Offset Near-Sightedness (Myopia): Outdoors 2 Hours Per Day (00:42:00) Improving Focus: Visual & Mental; Accommodation, Your Pupils & Your Bendy Lens (00:48:50) Protocol 3: Distance Viewing For 20min For Every 90 Minutes of “Close Viewing” (00:52:20) Protocol 4: Self-Generated Optic Flow; Move Yourself Through Space Daily (00:54:26) Protocol 5: Be More Alert; Eyelids, Eye Size, Chin Position, Looking Up Versus Down (00:59:21) Protocol 6: Sleep In A Very Dark Room To Prevent Myopia (Nearsightedness) (01:02:55) Color Vision, Colorblindness, Use Magentas Not Reds, (01:04:32) Protocol 7: Keeping Your Vision Sharp With Distance Viewing Every Day (01:06:05) Protocol 8: Smooth Pursuit (01:08:48) Protocol 9: Near-Far Visual Training 2-3 Minutes 3-4 Times a Week (01:13:33) Protocol 10: Red Light, Emerging Protocol To Improve Photoreceptors & Vision (01:16:20) Dry Eyes; Blinking, Protocol 11 (01:18:40) Lazy Eye, Binocular Vision, Amblyopia; Triggering Rapid Brain Plasticity; Protocol 12 (01:24:48) Protocol 12: Determine Your Dominant Eye; Near-Far Training (01:27:57) Visual Hallucinations: The Consequence of An Under-Active Visual Brain (01:29:47) Protocol 13: Snellen Chart: A Simple, Cost-Free Way To Test & Maintain Vision (01:33:00) Vitamin A, Lutein, Idebenone, Zeaxanthine, Astaxanthin, Blood Flow (01:44:20) Summary of Protocols, Vital Point About Blood & Oxygen For Vision (01:46:00) Episode Length, Captions, Zero-Cost Support, Instagram, Searching Topics Title Card Photo Credit: Mike Blabac Disclaimer
Transcript
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Welcome to the Huberman Lab podcast where we discuss science and science-based tools for everyday life.
I'm Andrew Huberman and I'm a professor of neurobiology and ophthalmology at Stanford School of Medicine.
This podcast is separate from my teaching and research roles at Stanford.
It is, however, part of my desire and effort to bring zero cost to consumer information about science and science-related tools to the general public.
In keeping with that theme, I'd like to thank the sponsors of today's podcast.
Our first sponsor is Athletic Greens.
Athletic Greens is an all-in-one vitamin mineral probiotic drink.
I've been taking Athletic Greens since 2012, so I'm delighted that they're sponsoring
the podcast.
The reason I started taking Athletic Greens and the reason I still take athletic greens once or twice a day
is that it helps me cover all of my basic nutritional needs.
It makes up for any deficiencies that I might have.
In addition, it has probiotics,
which are vital for microbiome health.
I've done a couple of episodes now on the so-called gut microbiome
and the ways in which the microbiome interacts
with your immune system, with your
brain to regulate mood, and essentially with every biological system relevant to health
throughout your brain and body.
With athletic greens, I get the vitamins I need, the minerals I need, and the probiotics
to support my microbiome.
If you'd like to try athletic greens, you can go to athleticgreens.com slash Huberman
and claim a special offer.
They'll give you five free travel packs plus a year supply of vitamin D3 K2.
There are a ton of data now showing that
vitamin D3 is essential for various aspects
of our brain and body health,
even if we're getting a lot of sunshine.
Many of us are still deficient in vitamin D3.
And K2 is also important because it regulates things
like cardiovascular function, calcium in the body,
and so on.
Again, go to at letitgreens.com slash uberman to claim the special offer of the 5 free travel
packs and the year supply of vitamin D3 K2.
Today's episode is also brought to us by Element.
Element is an electrolyte drink that has everything you need and nothing you don't.
That means the exact ratios of electrolytes are an element and those are sodium, magnesium,
and potassium, but it has no sugar.
I've talked many times before on this podcast about the key role of hydration and electrolytes
for nerve cell function, neuron function, as well as the function of all the cells and
all the tissues and organ systems of the body.
If we have sodium, magnesium, and potassium present in the proper ratios, all of those
cells function properly and all our bodily systems can be optimized.
If the electrolytes are not present and if hydration is low, we simply can't think as well
as we would otherwise.
Our mood is off, hormone systems go off, our ability to get into physical action, to
engage in endurance and strength, and all sorts of other things is diminished.
So with element, you can make sure that you're staying on top of your hydration
and that you're getting the proper ratios of electrolytes.
If you'd like to try element, you can go to drink element
that's element.com slash huberman,
and you'll get a free element sample pack with your purchase.
They're all delicious.
So again, if you wanna try element,
you can go to element element.com slash huberman.
We are now beginning a new topic
for the next four to five episodes of the Huberman Lab
podcast.
Before we move into that, I want to just briefly touch on a couple questions that I got
from the last episode, which was related to the science of endurance training.
I described the four kinds of endurance training.
We posted protocols of the specific four kinds of endurance training at HubermanLab.com.
Just go to that episode.
You can see the download.
It's a zero-cost PDF.
I got a lot of questions about what's called concurrent training, which is how to program
endurance training if you are also interested in strength and hypertrophy training or how
to incorporate strength and hypertrophy training, which was in the previous episode, with endurance
training.
This can all be made very simple.
Ask yourself, what are you trying to emphasize, and then emphasize that for a 10 to 12 week
cycle.
So if you're mostly interested in endurance, I would say use a 3 to 2 ratio, maybe get
3 endurance training workouts per week, maybe four, and two strength and hypertrophy
workouts. If you're mainly focusing on strength and hypertrophy, get three or four workouts for
strength and hypertrophy, and do two endurance workouts. Start with the minimum number of sets
that's required to get the result that you want. So if you're not accustomed to doing endurance
work, you would start with the minimum number
that's listed on that protocol.
So if it says three to five sets,
you would start with three, maybe even just two.
And then work your way up by adding sets each week.
I do suggest that people get at least one complete rest day
per week.
Although I know a lot of people don't like that.
I benefit from that.
I actually benefit from having two complete rest days
each week.
I just
continue to make progress that way, whether or not it's first strength and hypertrophy or for endurance.
I am a big believer in rest days. Other people are not. And those could be active rest days,
hiking, relaxing, etc. After a 10 to 12 week cycle, then I also suggest taking anywhere from five to
seven days completely off. You can still enjoy life and do things.
I know for you, addicted exercises that you're going to load to do that, but that's one
way to stay injury free, keep your joints and tissues healthy over time and continue to
make progress.
If you don't want to do that week off, don't do it.
None of this is holy.
None of it is a strict prescriptive.
Just ask yourself, what are you going to emphasize and emphasize that in terms of the total volume
of workouts that you do and work up incrementally and then move into another cycle.
That's what I suggest.
So go to hewroommanlab.com, you can get the protocol there.
We are now going to move into a new topic unrelated to physical performance starting with
this episode and for the next four to five episodes, we are going to talk all about the
senses.
That's sight, eyesight, hearing, touch, taste, smell,
and we are also going to talk about this critical sense that we call interoception or our sense
of our internal real estate.
Now, the reason that we are talking about the senses
is because if you understand how the
senses are perceived, what they're about, what the underlying cells and connections are about,
you will be in a terrific position to understand the month's topic that follows, which is all about
mental health. Now, I want to emphasize that if you're somebody who doesn't have any trouble seeing, hearing,
tasting, smelling, and has an excellent sense of inter-reception, I do believe that these
episodes will still be very relevant to you because they have everything to do with how
you move through the world, how you make sense of information, and how you organize your
thoughts and your emotions.
I also want to emphasize that we're going to cover a lot of practical tools.
So today's episode is going to be all about vision and eyesight,
a topic that's very near and dear to my heart because it's the one that I've been focusing on
for well over 25 years of my career.
But we're not just going to get into the mechanistic details about how light is converted into electrical potentials and things like that.
We are going to talk about practical tools that you can and should use to help maintain
the health of your visual system and your eyesight.
Very often, young people will say, what should I do?
You're always talking about neuroplasticity and how it tapers off over time, but I'm a
young person. What should I do?
You should absolutely train and support your eyesight. In fact, if you're a young person and you see perfectly, or you feel as if you see the world perfectly,
you are in the best position to
bolster to reinforce that visual system so that you don't lose your vision as you age.
In addition, you can leverage your visual system for better mental and physical performance,
and we're going to talk about that. If you're somebody who suffers from a clinical disorder of vision,
you have trouble seeing, or if you need corrective lenses in order to see,
this episode is definitely for you. And while, of course, I can't make clinical diagnoses,
I can't have a one-on- one conversation with any of you in this format nor am I a clinician,
I'm a scientist, not a physician.
I did consult with our chair of ophthalmology,
Dr. Jeffrey Goldberg at Stanford University School of Medicine,
as well as several other people to really vet the information
and make sure that the protocols that I'm describing
are consistent with the clinical literature.
If you have a severe eye problem, you should be working with a really good ophthalmologist
and or optometrist, but certainly an ophthalmologist who's a medical doctor.
But I do believe that the information that we're going to discuss today is going to be relevant
to everybody and we'll set the stage for the month on mental health and mental performance. So let's get started. When we hear the word vision, we most often
think about eyesight or our ability to perceive shapes and objects and faces and
colors. And indeed, vision involves eyesight, our ability to see shapes and
objects and faces and colors and so forth. However, our eyes are responsible for much more than that, including our mood, our level
of alertness, and all of that is included in what we call vision.
So I just want to take about three, maybe four minutes and talk about how the visual system
works, how it's built, and how you are able to so-called see things around you.
I also want to describe the ways in which your eyes
and your visual system impact your mood and your level of alertness.
And then we are going to get right into some protocols, some specific things
that each and all of you should do if you want to enhance your vision and
maintain your vision as you get older.
And again, if you're a 15-year-old or a 12-year-old, this episode is especially for you because
your nervous system is far more plastic than mine is.
It's much more amenable to change, so you can really build a very strong visual system
and in doing that. And if you adopt specific behaviors at any age of light viewing at particular times and
particular ways, then you can build an emotional system that's also reinforced by your visual system.
So let's talk about vision. What is vision? Well, vision starts with the eyes.
We have no what's called extra extraocular light perception. While it
feels good to have light on our skin, while it feels good to be outside in the sunlight
for most people, the only way that light information can get to the cells of your body is through
these two little goodies on the front of your face. And for those of you listening,
I'm just pointing to my eyes. As many of you have heard me say before on this and other podcast, your eyes,
in particular, your neural retinas,
are part of your central nervous system.
They are part of your brain.
They're the only part of your brain
that sits outside the cranial vault.
In other words, you have two pieces of your brain
that deliberately got squeezed out of the skull
during development and placed in these things
we call eye sockets.
There's a genetic program for the specific purpose of making sure that three little layers
of neurons, nerve cells, got squeezed out and form what are called your neural retinas.
Now the eyes have a lot of other goodies in them that are very important and those are
the goodies that we're going to focus on a lot today.
There's a lens to focus light precisely to the retina. If you're
somebody who requires eyeglasses or contacts, chances are you don't do that correctly. And
that's why you use other lenses like eyeglasses or contacts. There are also other pieces of
the eye that are designed to keep the eye lubricated. You also have these things that we call
eyelashes. Most people don't know this,
but eyelashes are there to trigger the blink reflex if a piece of dust or something gets in front
of your eye. It's a beautiful adaptation of nature. They aren't just aesthetically nice.
Costello happens to have very long eyelashes. He gets compliments about this all the time.
Maybe you have long eyelashes. I don't have particularly long eyelashes, but the eyelashes are there so that if a piece
of dust or something starts to head towards the cornea, the eye blinks very, very fast.
It's the fastest reflex you own is your eye-blink reflex.
We also have these things called eye lids.
Now eye lids might seem like the most boring topic of all, but they are incredibly fascinating.
Today we're going to talk about how you can actually use your visual system to increase
your levels of alertness based on the neural circuits that link your brainstem with your
eyelids.
No, we are not going to have a blinking contest because I would win and you would lose.
That wouldn't be fun for you.
Let's talk about what the eyes do for vision.
Basically, the entire job of the eyes
is to collect light information and send it off
to the rest of the brain in a form that the brain can understand.
Remember, no light actually gets in past those neural retinas.
It gets to the neural retina, and we have specific cells
in the eye called photoreceptors.
They come in two different types, rods and cones.
Cones are mainly responsible for daytime vision.
And the rods are mainly responsible for vision at night
or under low light conditions, generally speaking.
So basically what happens is if your eyelids are open,
light comes into the eye. the lens focuses that light.
Light is also just called photons, light energy onto the retina.
These photoreceptors, the rods and cones, have chemical reactions inside them that involve
things like vitamin A, and that chemical reaction converts the light into electricity.
Now, that might seem incredibly abstract, but the way to think about this is very similar
to, for instance, you have touch receptors on your skin, and when you press on those touch
receptors, they convert physical pressure into electrical information and those neurons
send it up to your spinal cord and brain, and you can register that somebody or you are
touching the top of your hand as I'm doing now. and those neurons send it up to your spinal cord and brain, you can register that somebody or you are touching
at the top of your hand as I'm doing now.
With the eyes and the retina,
it's just that light gets converted into electrical information.
Within the eye, within the retina,
there are then a series of stages of processing
and that information eventually gets sent into the brain
by a very specific class of neurons.
I would like you
to know the names of these neurons. They're called retinal ganglion cells. So the only
thing you need to know about the neuroscience of the eye at this point are that they're
rods and cones. The cones are involved in bright daytime vision and rods are involved
in more dusk or nighttime vision. And you've got these cells called retinal ganglion cells
that send the information off to the rest of the brain.
Now, here's what's incredible. I just want you to ponder this for a second. This still blows my mind.
Everything you see around you, you're not actually seeing those objects directly. What you're doing is you're making a best guess about what's there based on the pattern of electricity that arrives in your brain
Now that might just seem totally wild and hard to wrap your head around
But think about it this way because this is the way it actually works
Let's take an example of a color like green or blue
you have cones in your eye that respond best to the wavelength of light that is reflected
off, say, a green apple.
So, you don't actually see the green apple.
What you see is the light bouncing off that green apple and goes into your eye and you
see it and perceive it as round and green.
But not because you see anything green.
No green light arrives in your brain.
What happens is your brain actually compares the amount of green reflection coming off
that apple to the amount of red and blue around it.
Well, you might say, well, the green apple is sitting on a brown table or a white surface.
Well, then it will appear very green because the amount of wavelength of light for green
is very high and the amount for red is very low.
And so it looks very green.
So we don't actually see anything directly.
What the brain is receiving is a series of signals, electrical signals,
and it's comparing electrical signals in order to come up with what we call these perceptions,
like I see something green, a green apple, or I see red. Let me give you a slightly different
example. If you were to play a key on the piano, let's say you play, I'm not a musician,
but I'm going to, so hopefully I won't get this too, too incorrectly. But let's say you have like E sharp.
And maybe it's on, ding, ding, ding, ding, ding.
If the brain gets that signal, it doesn't actually know E.
That's what, it doesn't recognize it until you were to play it
another key next to it, dun, dun, dun, dun, dun.
And what it does is does the math, it does the subtraction.
And it compares those two.
So when we see something green or we see red, or we see something blue, we're
not actually seeing it directly.
The brain is making a guess about how green or red or blue that thing is by comparing
what's around it.
And if that seems hard to wrap your head around, don't worry, because we will explain it
in more depth going forward. But I really want people to understand this that vision, eyesight, is not looking at things
directly and that information getting directly into your brain.
It is translated.
Light information is transformed into electrical signals that your visual system exquisitely
understands.
Now, what does this mean?
Why should you care about this?
Well, if you have a
dog like I do or a cat, they are not color blind, but they lack the, the cones that respond to red,
meaning long wavelength light. So what does that mean? That means that when they see green,
it's different than the green you see, not because that apple isn't visible to them,
but because they aren't able to compare it to red and you are.
As a consequence, when they look at a green lawn,
it looks more brownish or orange to them.
When you wear a red shirt in front of your dog or cat,
if you see a stop sign and they see a stop sign,
they see orange orangeish brown and
you see red, presuming that you are a tri-cumat meaning you have three color vision.
So this is all to say that every animal sees the world differently depending on whether
or not they have one or two or three of these different cones, the red, blue or green
cones. If you are a mantish shrimp of all things,
you see hundreds of colors that human beings can't see.
Okay?
Many animals see into visual ranges that you and I can't see in.
So for instance, a pit viper senses heat emissions.
It literally sees the heat coming off of you
or of an animal that they want to eat.
If you are a ground squirrel, you can see ultraviolet light. This is going to sound kind of weird,
but ground squirrels actually signal one another by standing up outside and shining sunlight off
each other's stomachs to each other, signaling at a distance, just like you know, you could signal
somebody with a mirror in sunlight at distance. There are species of primates, this isn't very pleasant to think about, that urinate on their hands
and then wipe it all over their stomach and then use that sunlight to reflect different signals to
each other. I don't know what they're saying, we always assume it's something cute and nice, but
maybe they're insulting each other. So this actually gets right down to the heart of these bigger
questions like consciousness, what do we see, what's out there? How much of life is really accessible to us? And I could go on and on.
This used to be an obsession of mine when I was coming up in the field of visual neuroscience
to understand how different animals see the world compared to us. I'll give one more
example, a diving bird, a bird that flies over the ocean, it has an incredible task.
It has to both view the horizon and it has to view schools of fish and then it has to
make a trajectory down into the water and grab one of those fish to eat.
And the water has what's called a refractory index.
It actually shifts like a prism, the impression or the perception of where that fish is, right?
If the bird sees the fish right below it,
it has to know, it has to adjust its diving trajectory just right because it knows that that fish
actually isn't where it sees it. It's probably a few inches ahead or to the side of that because of
the way that water diverts the image. If you've ever dropped a coin to the bottom of a pool,
if you go straight down looking at that location
if you were looking from the top of the pool and you dive straight down with your eyes closed, you will miss
because the water refracts, it shifts the visual image. Well diving birds have an arrangement of these retinal cells
that communicate to the brain that's both a streak to view the horizon because they need to know where they are relative to the horizon and they have a pupil like we do on the bottom
of their eye so that they can make very accurate dive and attacks on these schools of fish
and catch fish and eat those fish.
We just have pupils in the middle of our eyes.
So there's a ton about the optics of the eye and the way that it communicates with the
brain that allows us to see.
We could spend hours talking about this but what I'd like to embed in your mind
is that what you experience in the outside world
is bottlenecked.
It's limited by which wavelengths,
which colors, if you will, of light that you can see,
that your brain is coming up with a best guess
about what's there.
It doesn't actually know what's there
and that your vision is distinctly different
from, say, the vision of a dog or from the vision of somebody who's a dichromat, meaning they don't
have a red cone. A lot of people in particular, about one in 80 males, lacks a red cone and therefore
sees the world much the same way that Costello does, although he sees it from just much lower
toward the ground.
So that's what I'd like you to understand about the way the eye communicates with the
brain.
I would also like you to understand that the brain itself is making these guesses and that
those guesses are largely right.
How do I know that?
Well, they're right because when you reach out to grab a glass, most of the time you grab the glass
and you don't miss, right?
Most of the time when you make judgments
about the world around you based on your visual impression
of them, it allows you to move functionally
through the world.
But let me give you some examples
of where this guessing is happening right now.
And it's so incredible that to this day this
still blows my mind.
Cover one eye with one hand, if you're driving, maybe don't do this.
If you're viewing the world around you, presumably you can see everything that's out there.
I could do this with one eye or the other eye.
You probably see better out of one or the other and we'll talk about that.
You have a giant blind spot in the middle of your visual field.
It's called your blind spot.
It is the spot in which the connections,
the wires from all those retinal ganglion cells
exit the back of the eye and head off toward the brain.
In other words, you are blind for a huge spot
of your central vision, the part of your vision
that's highest acuity, highest detail.
And yet you don't see that ever.
You cover one eye and you see perfectly fine.
And it's not just because your eye is moving around really quickly.
Your brain is guessing what's in that spot, which is absolutely incredible.
And so you don't see that blind spot.
This is happening all the time.
Now, when you have two eyes open, the way that your eyes are positioned in your head
and the way they view the world is such that they fill in each other's blind spot. So it's pretty
convenient. But if you cover one eye, that's impossible. And yet you still see the world as complete.
So the brain is doing these incredible things. It's also creating depth, the sense of depth,
even though what arrives from the retina is essentially a readout of a two-dimensional flat image, so it can sense depth.
How do you know depth? Well, this is very simple. Things that are closer to you
tend to be larger than things that are far away. Things that are closer to you
tend to look like they're moving faster if you've ever been in a train and you
look to your side, the rungs on offense or the train tracks going by you,
look like they're going very fast.
If you look off in the distance, they look like they're moving very slowly.
And there are differences between what's close to you and what's further away.
So a little house on the horizon, you don't look at and say, oh, that must be a tiny little
house.
You have some prior knowledge that things further away are smaller.
So that's the main way that you do that. And you compare the location at which information about light
lands on the two eyes.
So your eyes are slightly offset from one another.
So that, for instance, if I look at you,
if you're standing right in front of me right now,
and I were to look at you, the image of your face,
the light bouncing off your face, to be more precise,
lands on one eye in a slightly different location
than it does in the other eye,
and then the brain does math.
It basically does the equivalent of geometry and trigonometry
and essentially figures out how far away you are from me,
which is just incredible.
So the brain does all this very, very fast,
and the brain uses about 40 to 50% of its total real estate
for vision.
That's how important vision is.
Now, for those of you that are blind
or low vision or no vision,
that real estate in the brain will be taken over
by neurons that control a sense of touch
and a sense of hearing.
And you're indeed hearing and touch are much better,
higher acuity and faster in blind people.
But for most of you who I presume are sighted,
this is how it works.
So that's kind of vision from eye to brain in a nutshell.
There are a bunch of different stations in the brain
that do different things.
That's eyesight.
Now I want to talk about the other aspect of vision, which is the stuff that you don't
perceive, the subconscious stuff.
And then we'll transition directly into how you can use light and eyesight to control
this other stuff because it's very important and that other stuff is mood, sleep, and
appetite.
And there are ways in which you can use
the same protocols that I will describe
in order to preserve and even enhance your vision,
your ability to see things and consciously perceive them.
So the protocols we will describe
have a lot of carryover to both conscious eyesight
and to these subconscious aspects of vision. And I
just want you to understand a little bit more about the science of seeing of eyesight and
vision. And then all the protocols will make perfect sense. So as amazing as eyesight
is, it actually did not evolve for us to see shapes and colors and motion and form. The most ancient cells in our eyes, and the reason we have eyes, is to communicate information
about time of day to the rest of the brain and body.
Remember, there's no extracurricular photoreception.
There's no way for light information to get to all the cells of your body, but every cell
in your body needs to know if it's night or day. I talked a little bit about this in the episodes on sleep, and this episode is not about sleep,
but I want to emphasize that there is a particular category of retinal ganglion cell, remember
the neurons that connect the retina to the brain, that is involved in a special kind of
vision that has nothing to do with conscious perception
of what's around you.
And it's happening right now.
It's happening all the time.
These are so-called melanopsin retinal ganglion cells
named after the opsin that they contain within them.
They are essentially photoreceptors.
Remember before I said there are photoreceptors
and then these ganglion cells?
Well, these melanopsin cells, as the name suggests, melanopsin, have their own photoreceptor built inside them. The opsin that they contain
is actually very similar to the melanopsin that is present in the skin of some amphibians
and that causes those amphibians to change their skin color in different light conditions.
So you have, believe it or not, a little bit of frog skin in your eye, so to speak.
Not exactly, but you essentially have the equivalent of what frogs have in their skin in your
eye. If you are low vision or no vision, as long as you
have retinas, it's very likely you still have these cells, even though you can't see or
you don't see well. These cells, retinal ganglion cells, communicate to areas of the brain when
particular qualities of light are present in your environment
and signal to the brain, therefore,
that it's early day or late in the day.
These melanops and ganglins, cells are sometimes also called intrinsically photosensitive cells
because they behave like photoreceptors.
What do these cells respond to and why should you care about them?
Well, you should care about them because they regulate when you'll get sleepy, when you'll feel awake, how fast your
metabolism is, excuse me, your blood sugar levels, your dopamine levels, and your pain threshold.
There are other factors that impact those things, but they are one of the, if not the most
powerful, determinant of those other things like mood and pain threshold,
sleepiness, wakefulness, etc.
These melanopsin gangling cells have been shown by the night's group and E.I.T.Z. up
at the University of Washington and by Samarhattar's lab and David Burson's lab and a number
of other people's labs such in Panda, the E. Prevencio, etc. A number of excellent labs in neuroscience
to set the circadian clock and to respond best to the contrast between blue and yellow light of the
sort that lands on these cells when you view the sun when it's so-called low solar angle when it's low in the sky
either in the morning or in the evening. What does all this mean? It means and here's the first
protocol and you've probably heard me say this before but it is appropriate to this episode to say it
again. If you are not viewing the sun sunlight even through cover, for two to ten minutes in the early
part of the day when the sun is still low in the sky and doing the same thing again in
the evening, you are severely disrupting your sleep rhythms, your mood, your hormones,
your metabolism, your pain threshold, and many other factors including your ability to
learn and remember information.
The most central and important aspect of our biology
and perhaps our psychology as well,
is to anchor ourselves in time,
to know when we exist, okay?
It sounds a little bit abstract and philosophical,
but it's not.
And we don't know time as a real thing because of watches and clocks.
We know time at a biological level based on where the sun is and where, which of course
is where we are relative to the sun because the earth is spinning around.
Now, what does this mean for a protocol?
It means see, get that light in your eyes early in the day and anytime you want
to be awake. So try and get as much sunlight in your eyes during the day as you safely
can. We'll talk about eye safety this episode in depth. And the blue light and the contrast
of that blue yellow. Remember, we don't see blue. This is all subconscious. This is blue
reflections coming off of sunlight. Blue light we've been told is so terrible for us. It
is absolutely essential and wonderful for waking up the brain,
for triggering all sorts of positive biological reactions,
but it needs to be viewed early in the day.
If you can't see sunlight because it's the thick cloud cover of, say,
in a, you know, you're in the UK and it's winter,
then artificial lights, especially blue lights,
would be very beneficial to you.
You need a lot of this light and its contrast with yellow in order to trigger these melanops
and cells which would then trigger your circadian clock, which sits above the roof of your
mouth, which will signal every cell in your body, including temperature rhythms, etc.
So first things first, your visual system was not for seeing faces, motion, etc. The most ancient cells in your eye, which
are there right now, as we speak, are there to inform your body and brain about time of
day. So you want to get that bright light early in the day. Absolutely essential. Two to
10 minutes. You can download the light meter app if you want to measure looks when I explain
to do that in earlier episodes, I got a little convoluted.
Get that two to ten minutes, ideally without sunglasses.
Now here's another reason to do this, and I've never spoken about this before on any podcast,
which is that there have been several studies now in thousands of subjects exploring what
can be done to prevent myopia, near-sightedness, and other visual
defects.
And it turns out in a series of large clinical trials, the conclusion is emerged that getting
two hours a day of outdoor time without sunglasses, blue light, this blue light that everyone is
demonized, getting that sunlight during
the day for two hours, even if you're reading other things and doing other things outside
has a significant effect on reducing the probability that you will get myopia near-sightedness. Now,
whether or not that's also due to the fact that myopia can be caused by viewing things
up close to too much.
So if you're indoors, we tend to be looking at things more closely, right, unless you
have a very large house with walls that are very far away from you.
But the effect does seem to be directly related to getting sunlight and not just to the
distance that you're viewing.
I'm going to describe this study just briefly, but this is a second protocol.
So we have one protocol about getting sunlight to set your circadian clocks, meaning wake you up,
establish your sleep will occur about 12 to 16 hours later.
That's all in the sleep episode,
but also to enhance your mood, to enhance your metabolism,
to optimize your hormone levels,
and to optimize learning and dopamine levels,
this feel good neuromodulator that's essential
to not getting depressed for etc.
But now is a second protocol which is ideally and this includes children as long as they're
not very small infants, ideally we're all getting two hours of outdoor time even if there's
cloud cover.
Remember we evolved mostly under outdoor conditions, not indoor conditions, and no artificial blue light
will not replace this aspect of your visual system
and offsetting myopia.
So I just wanna briefly describe this study
because it's a very important one
and I don't think it's discussed often enough.
There are many studies exploring this,
but one of the ones I like the most,
looked at 693 students students and a subset of them were encouraged to spend
11 hours a week outdoors.
Okay, so most kids are in school five days a week or so, so they're spending 11 hours a
week outdoors.
They are sometimes reading outdoors and I don't always just playing outdoors, they might
be reading books, etc. They used eight different
schools. And the reason they did this study, I probably should have mentioned, is that
myopia, near-signness, is a global epidemic, at least that's how it was referred to in
the study. I don't know who decides what's an epidemic or not. I think there are thresholds
for that. This paper, published in the journal Ophthalmology in 2018,
described the fact that being outdoors for two hours a day
could significantly reduce the probability
that these children would develop near-sightedness.
And it turns out, based on other studies,
that adults who spend two hours a day outside,
so that would be reading outside, talking outside,
know it does not include light coming
through the windshield of your car. I'll explain why in a few moments. Offset the formation
of myopia. Now, myopia or near-sightedness has to do with the way that the lens focuses light
onto the retina. I don't want to get into a long description of this now But basically the lens has to bring light to the retina not in front of it not behind it
If it brings light to a position in front of the retina
Then you won't see clearly you will need corrective lenses
If it brings light directly to the retina then you will see clearly that should be intuitive why that makes what makes sense
So you might say why would being outside getting this blue light or this blue yellow contrast
from sunlight actually offset myopia? Well, it probably, and I want to emphasize probably,
has to do with the fact that these melanopsin ganglion cells, these intrinsically
photosensitive ganglion cells are not just responsible for sleep and talking to your circadian clock and that sort of thing.
They also make connections within the retina.
They connect to things like, this is for the aficionados, the ciliary body, the iris, the
muscles, and the structures within the eye that actually move the lens and allow you to
adjust your vision to things up close or far away.
And in doing so, they increase or improve the health of the little tiny muscles within the eye that move the lens.
And they probably, again, this needs a little bit more work in order to really tamp down the mechanism,
they're probably also involved in bringing growth factors and blood supply to the muscles
and to the neurons that are responsible for this focusing mechanism within the eye.
So remember your eye is an optical device.
You were born with lenses.
You don't have to use glasses or maybe you do because you have lenses in your eyes.
And those lenses need to move.
It's not a rigid lens, like a glass lens.
It's a dynamic lens.
It has little muscles that pull on it and squeeze it
and make it thicker or thinner.
As you look at things close and far away
and I'll describe how that works in a moment,
these melanops and cells and their activation
by sunlight, completely subconsciously,
unaware, you're unaware of this. Promote the health of this
system within the eye and allow you to offset the myopia near-sightedness. In other words,
getting outside for two hours a day each day on average, even if there's cloud cover without
sunglasses on will allow you to offset the formation of myopia. Now you might
still form myopia if you have certain structural features or a genetic basis for that we will talk
about things that you can do as well. But for everybody we should be doing this and that might
seem like a lot, but this is the way that your visual system works. Staying indoors, just getting
artificial light and looking at things up close leads to
visual defects. It's a form of visual obesity. The posture of your visual system, if you
will, is going to be unhealthy if you're just indoors and you're not getting sunlight early
in the day and for at least two hours per day. I want to talk a little bit more about
how our eyes adjust to things
that are close to us or far away. This is an absolutely brilliant consequence of our
nature and our design. And whenever I say nature and design, people always ask me, you know,
what are you really trying to say or you're trying to talk about creators or you're talking
about intelligence design. Look, I want to be very frank with you. I wasn't consulted the design phase and neither were you.
And so that is all very interesting, but it's not the topic of this discussion.
What is clear and what is the topic of this discussion is that the eye can dynamically
adjust where light lands by moving the lens and changing the shape of the lens in your
eye through a process called accommodation. And if you understand this process of
accommodation, you not only can enhance the health of your eyes in the immediate
and long term, but you also can work better. You'll be able to focus better on
physical and mental work. You will be able to concentrate for longer. And I want to emphasize that so much of our mental focus, whether or not it's for cognitive
endeavors or physical endeavors, is grounded in where we place our visual focus.
What we look at and our ability to hold our concentration there is critically determining
how we think. So in other words, if you can hold visual focus,
you can hold mental focus, cognitive focus.
But holding visual focus is challenging.
It's tiring because it requires movement of the lens.
And that movement of the lens requires activation of muscles.
And the activation of muscles, as you know,
from the physical performance episodes,
if you saw them, and even if you don't, is dictated by neurons. So what is accommodation?
Well, it's actually very simple and very elegant. And again, this is another case where whenever
I look at this stuff, even though I've been looking at it for years, learning about it for years,
it still boggles my mind that we have these Apparad eye built into our eyes
So we have lenses in our eyes and we have these things called the irises
You know you're all familiar with the iris because you'll see people's pupils get bigger or smaller and we
Intuitively think of eyes as having the pupils if you actually draw two circles on a on a sheet of paper and
You just they look like two circles.
But if you put little dots in the middle of them, they look like eyes.
Your brain recognizes those as eyes because one of the first things you see when you
come into this world are eyes.
And actually if you put the little dots close together, it'll look kind of wrong like
it's cross-eyed.
And if you put them at different locations within those two dots, opposing locations, it'll
look Google-eyed.
And so your brain is actually filling in all the face
and other information, even emotional information,
just based on this recognition of eyes.
And so there's clearly, we know this,
there's real estate, deep up, you know,
further up in the brain that's responsible for
analyzing and recognizing faces and the eyes
and the position of these little things we call
irises and pupils, etc.
is really important for how we interpret the status of others.
And that's why it's such a powerful thing just to put two circles and move the pupils
around on paper.
In fact, I want to get into a combination, but if you think about it, if one of my pupils
was up there and the other one was down there, one was really big and one was really small,
that would actually be a sign of pretty severe damage
If someone gets hit hard on the side of the head you'll notice that they shine a light in one eye
You know what they're doing that they're actually looking at the other eye
When you shine light of the eye that pupil constricts to limit the amount of light that comes in so it doesn't damage the eye
It also happens when you walk outside and it's bright it constricts
But we have what's called the consensual pupil reflex.
There's a connection deep in the brainstem, deep back here in the brain near my neck.
The connects the pupil mechanism for the two eyes and they're looking at the other eye
and if you shine light in one eye and that pupil constricts, but the other one doesn't,
there's a good chance there's brainstem damage.
This is what they do on the side of a, you know, football field or a boxing match
or if someone unfortunately hits their head.
So two pupils and don't freak out
if one pupil is a little bit smaller than the others,
that doesn't necessarily mean brain damage.
But if you suddenly have one pupil bigger than the other,
you absolutely wanna go see a neurologist right away.
So the eyes and the pupils are indicative of things
that are happening deep in the brain. Now accommodation is our ability to accommodate to things that are up close
here or further away. And the way this works is that the iris and the musculature and
structure called the ciliary body move the lens. So when you look far away, okay, when
you see things far away, your lens actually relaxes. It can flatten out. So when you look far away, okay, when you see things far away, your lens actually relaxes.
It can flatten out.
So when you think about this, when you look far away, when it may be anywhere from like
20 feet away from you out to a horizon that's miles or kilometers away from you, the lens
can just relax, it can flatten out.
And you'll notice that it actually is relaxing to look at a horizon.
It's relaxing to look far away.
Whereas if I look at something up close to me,
like this pen or my phone or a computer screen
or this microphone, it takes effort.
You'll sense the effort.
Now, some of that effort is actually eye movements
because you have muscles that can move your eyes
within their sockets.
But a lot of the work, quote unquote, is neural work
of the muscles having to move and contract
such that the lens actually gets thicker
in order to bring the light to the retina
and not to a location in front of it or behind it,
so-called accommodation.
There's also changes in the size of the pupil
as things are closer and further away from you. In fact, there's a simple way to think about this. Healthy pupils
are going to dilate when you look at something far away from you. Now, when you see something
that excites you or stresses you out, your pupils also get big. Your eyes get wide.
But if you look at something far away, your pupils are going to dilate. And when
you look at things that are closer to you, when you move them up close, the pupils are
going to shrink. That's all part of this accommodation mechanism. Now, you might say,
why are you telling me about accommodation? This is crazy. Why are you telling me about this?
Well, these days, we're spending a lot of time looking at things mainly our phones up
close and computers up close and we are indoors. If you time looking at things, mainly our phones up close and
computers up close and we are indoors.
If you are a young person and even if you are 25 or older and you are spending a lot of
time looking at things up close and you are not allowing your vision to relax, in other
words, you are not giving your lens the opportunity to flatten out and for these muscles to relieve
themselves of this work, you may or may not have migraine headaches. not giving your lens the opportunity to flatten out and for these muscles to relieve themselves
of this work, you may or may not have migraine headaches. You may or may not have headaches.
You might and that could be the cause of those. But you are also training your eyes to be
good at looking at things up close and not far away. And as a consequence, you are reshaping the neural circuitry in your brain, and it is not
good.
It is not healthy to only look at things up close.
Now there are a lot of recommendations out there right now, especially with all the lockdowns
of the last, you know, 12 to 18 months, that people should look up from Zoom every once
a while, or maybe now I'm hearing that people should take calls instead of doing Zoom or you should look up from your computer
screen.
It's actually not going to solve the problem just to look up from your computer screen.
You need to go to a window, you need to look out at a distance.
Ideally, you would even open the window because those windows actually filter out a lot of
the blue light that you want during the daytime, a lot of the sunlight.
It's actually 50 times less gets through.
You want to get out onto a balcony.
You want to relax your eyes and look out at the horizon.
You want to go into what's called panoramic vision and let your vision expand.
You want this lens mechanism to be very elastic.
You don't want it to get stuck in that configuration of looking at things up close.
A combination is a wonderful feature of your visual system, but you don't want to push that too hard,
too often or for too long. You want to view the horizon, you want to get outside,
not just to lighten the load on your mind or to think about other things, but to maintain the health of your visual system.
In other words, you want to exercise these muscles, and that involves both the lens moving
and getting kind of thicker and relaxing that lens.
The relaxation of the lens is actually one of the best things you can do for the musculature
of the inner eye.
So what's the protocol?
How often should you do this?
You might be surprised, but for every 30 minutes
of focused work, you probably want to look up every once
a while and just try and relax your face and eye muscles,
including your jaw muscles, because all these things
are closely linked in the brainstem,
and allow your eyes to go into a so-called panoramic vision
where you're just not really focusing on anything,
and then refocus on your work.
At least every 90 minutes of looking at things up close, or even if you're looking at a
screen, a television screen, or you're watching a movie, or you're indoors, for every 90
minutes of that, you ideally would have at least 20, probably more like 30 minutes of being outside
ideally, but if you can't be outside of non-up close vision. Now you might say,
that's impossible. How am I supposed to do that? I'm in an office or I'm in a building.
Get to a window, get outside if you can do it safely, get onto a balcony, and just let your eyes relax.
Many people are experiencing severe vision problems
because they're not getting enough sunlight during the day.
They have sleep problems
because they're not viewing sunlight early in the day.
And as I've mentioned previous episodes,
they're getting a lot of artificial stimulation,
artificial light stimulation of the eye
in the middle of the night.
All of this is in the middle of the night,
all of this is through the visual system.
So migraines, fatigue, challenges with your eyesight getting worse as you age, or even in
young people, there's, you know, at least according to the articles they described as this
epidemic of myopia, can largely be dealt with by getting outside, going into panoramic vision,
experiencing some distance division.
Look at things off in the horizon.
If you're walking or hiking or biking,
not looking at your phone the whole time
that you're doing that.
If you're at the bus stop or you're commuting,
certainly not looking at your phone
the entire time you're doing that.
So this is vital.
And I wanna emphasize another protocol,
though I don't want to get
into it in too much depth because I want to make sure that I also talk about a number
of other important aspects of the visual system that are more related to sight. But getting
into optic flow is very important for de-stressing your system. When you move through space,
whether or not it's through walking, biking, even swimming, if it's self-generated optic flow.
So probably not driving or motorcycling, but yes, bicycling or, I don't know, unicycling,
I don't know, I thought about unicycling.
There used to be a graduate student at Stanford who was really impressive unicycler.
Those are pretty rare.
As long as it's self-generated optic flow, meaning you're generating motion of your body and
the visual images around you are passing by on your eyes, that is very good for the visual
system.
And it's very good for the mood systems and the neuromodulator systems of the brain and
body that regulate mood.
This is well established.
So I'm not telling people to get away from their phone and their computers.
I spend a lot of time staring at a page, drawing, writing, texting, et cetera, just like you
do.
But we're really talking about some very simple protocols that aren't just designed to improve
your sleep, but are really designed to bolster and enhance your vision.
And of course, because it's this podcast, we will also talk about things that you can
take to improve your vision.
But if your visual behavior isn't right,
and I do believe we should always start with behaviors
and then think about nutrition supplementation, et cetera.
If your behavior is around vision aren't right,
you cannot expect to have good, healthy eyesight
for a long time, meaning throughout your lifespan.
And if your vision is already poor,
many of these things that I'm talking about today,
perhaps all of them will improve your vision to already poor. Many of these things that I'm talking about today, perhaps all of them will improve your vision
to some degree.
And if your vision is starting to go,
then doing these behaviors is likely to really enhance
the quality of the vision that you will build
and maintain over time.
And all of these are essentially zero cost.
Okay, if you live in a very dark environment,
like a cave, or outer space, it's going to be hard
to do some of this stuff.
But if you're on planet earth, even if there's cloud cover, chances are you can do some or
most or even all of these some most or all days.
What I'm about to describe next is going to seem so silly on the face of it, but has
deep mechanism to support it. Put simply, when you get tired, your eyelids close.
And when you're alert, your eyelids are open.
That is because you have neurons in your brain that, depending on your level of alertness,
will make it easy or hard to keep your eyes open.
Now, that's a complete duh,
except that we don't often think about the relationship
between alertness and where we are looking and our eyelids.
Now, I learned this from a colleague of mine in psychiatry
who happens to work on hypnosis.
I'm not gonna hypnotize you right now.
That's actually for a future episode.
But what happens when we get tired? Our eyelids close and our chin moves down.
We tend to nod out this way. If you have ever been in a classroom, certainly not one of mine,
but if you've been in a classroom and the lecture is kind of drawing on or it's the afternoon,
well, you'll notice is that a number of students, their heads are, chill, kind of, their eyelids are closing and their chin is dropping.
And then they, you'll see a bunch of heads balancing back up.
All right. I was definitely one of those people in class.
If it was post lunch, when the afternoon, it's warm, the hum of the air
condition or whatever it is. And I just out, okay?
When we're wide awake, the opposite happens.
Our eyelids are open all the way
and our chin happens to be up.
And no, this is not me telling you
to have a good posture.
However, what I learned from my colleague at Stanford
is that these circuits actually act in loops
when we look up.
Maybe it's because these melanops and cells
are in the bottom of our retina, they are. And maybe it's because these melanopsin cells are in the bottom of our retina, they
are, and maybe it's because they're there in order to view sunlight, which is overhead,
which it is.
But that system of alertness is linked to the position of our eyes.
So when we look up and our eyelids are up, it actually has a purpose.
It actually creates a wakefulness signal for the brain.
And so while this might seem like the silliest
and simple tool that I might ever describe
on this podcast, if you are feeling tired,
it actually can be beneficial to the wakefulness systems
of the brain, including the locus serulius
in these areas that release Neuroepinephrine
to actually look up, to actually look up toward the ceiling.
You don't want your chin all the way back, but to look up and to raise your eyes toward
the ceiling and to look up and try and hold that for 10 to 15 seconds.
So this isn't looking up and closing your eyes like I don't know, and I sunny day.
That's relaxing.
This is looking up and actually looking up at the ceiling.
It actually triggers some of the areas of the brain that are involved in wakefulness. So if you're somebody who's falling asleep at your work,
this can be very beneficial. Likewise, many people are looking at their phone all day and
their chin is down and then they're sitting at a computer that's positioned below them
and they're having trouble staying awake or focusing.
It can be very, I tell Costello this all the time because he's always falling asleep while
he's trying to do his work positioning your computer screen up at eye level or sometimes
having it actually above eye level can actually create wakefulness and alertness for the work
that you're going to do.
This is simply because of this connection between the brainstem circuits and the other neural circuits that control
wakefulness and
eyelids opening and looking up.
Okay, so it's again, it's remarkably simple, almost laughably simple, but it's grounded in some of the most hard-wired, meaning present from birth
aspects of our neural circuitry and
present from birth aspects of our neural circuitry. And nor epinephrine released from locus arulias isn't just a mouthful.
It's a really interesting and powerful mechanism for how the
rest of the brain wakes up.
Locus relays hoses the rest of your brain with nor epinephrine in
order to wake up those circuits for work and attention. And so
eyes up is actually a way a route into increased alertness. Eyes down
is a route into sleepiness, into reduced alertness. And I only have one friend that texts up here,
like on the street, holds his phone up here. It looks ridiculous. And yet, you know, if we were
trying to create more sense of alertness, if that's your goal,
positioning computer screens up high, chin up, looking up if you need to kind of create an alertness
signal, not always being chin down and texting or working into typewriters or reading below us,
is actually going to send a recurring wakefulness signal. If when things are up, we tend to be alert
when everything's focused down, including your eyes, It tends to have a more suppressive or sedative type signaling to the deeper centers of the brain.
Now before we move on to the science and tools and protocols related to pattern vision,
I want to mention another study that was done by the University of Pennsylvania.
They have a terrific group that were there that works on sleep that made an important discovery that I think everybody should know about,
which is that children that sleep in rooms
that have a night light or dim lights
are much more likely to develop myopia near-sightedness.
Conversely, children that sleep in very dark rooms,
so either very dim nightlights or
complete black, they have a much lower, statistically speaking, a significantly lower probability
of developing myopia, near-sightedness.
Now, why is that?
It's because the wavelengths of light that matter for these melanopsin cells, oftentimes can get through
the eyelids.
And that's particularly true for children and people that have thin eyelids.
Some people like me have very thin eyelids.
I've been told this before.
Not many people touch my eyelids, but among those that have that very thin eyelids.
I notice I have very thin eyelids compared to say Costello.
Now Costello's eyes droopy,
he can't even close his eyes all the way,
they're so droopy, but many people have thin eyelids
and those people are going to be even more prone
to light coming in through the eyelid.
So for parents, for kids, and for adults,
you really want to try to get to a place
where you can sleep in a completely black or dark environment.
One little exposure to light, no big deal,
but this ties back to the other protocol
that I've described before in the mood and sleep episodes,
which is that viewing light, even a very low intensity,
between the hours of 10 pm and 4 am,
is extremely detrimental to the
dopamine and other mood producing systems of the brain.
It can negatively impact learning and immunity and even blood sugar and make people type
to diabetes prone by way of communication from these melanops and cells to a structure
in the brain called the habanula.
Why am I throwing out all this verbiage?
Well, because people have asked for more mechanisms.
So if you really want to know when you look look at blue light, or if blue light is getting
in through your eyelids in the middle of the night, it is likely distorting these lens accommodation
mechanism in the eye and leading to myopia in some cases. So that's one reason to avoid
blue light exposure and bright light exposure, even night light exposure in the middle of
the night, viewing any light of bright intensity between the hours of 10 pm and 4 am on a consistent
basis is going to suppress dopamine because of the way that that light activates these
milenops and cells and the hebenula and the dopamine system. So it's all very simple. Get as much
bright light as you can safely, right? You never want to look at any light so bright that it's painful look at during the daytime.
Try and go without sunglasses unless you need them.
Now, I wear sunglasses for sake of sport
and say when it's really bright out,
but I try to get two hours a day of working outside
or being outside, even if there's cloud cover,
that's going to offset myopia.
It's going to help you get better sleep.
It's going to support mood and metabolism, et cetera.
And at night, if you're sleeping with a lot of lights
in the room, and especially if there are kids
that need a night light, you should try
and wean them off that night light
because it's going to be beneficial for their vision
to wean them off that night light
and put them into a darker environment.
Obviously, you want to get them emotionally comfortable
with that first.
Now, let's talk about pattern vision, actual seeing things like faces and colors, et cetera.
I'm presuming that some of you out there are colorblind.
We can all help the red-green colorblind folks out there by not using red in slides and
diagrams and on menus and things of that sort.
Trying to use magenta instead, they can see the contrast between
magenta and green better than if there's red and green.
So be kind to the colorblind folks out there.
It's actually a fair percentage.
And there are a lot of different kinds of colorblind.
As you just mentioned, some people are true monochromats.
They see the world in black and white.
That's exceedingly rare.
Most colorblind people, colorblind in quotes,
are red, green, colorblind, meaning they lack red cone photopigment, meaning they can't
see long wavelengths of light, so they see the world much as a canine or a cat does, where
they don't get the green red contrast, that's where we call it, red, green, colorblind.
They have the green cones, but they can't do the contrast comparison that I described at the beginning of the episode. So use magenta and they will be able to see things.
You wonder why stop signs and stop lights and things aren't in magenta well because the world
is unkind to the red, green colorblind individuals and they have to learn the position of those lights
in the in the street lights and they have to learn the shapes of signs, which they can do readily and it usually says stop on it as well.
But if you care about colorblind folks, which I do, then we can all do them a service by,
I think by law actually in the US menus are required to be colorblind accessible.
How can you improve your vision?
How can you get better at seeing things?
Well, one way is to make sure that you spend
at least 10 minutes a day total, at least,
viewing things off in the distance.
So that would be well over half a mile or more.
Try and see a horizon, try and get your vision out
to a location that's beyond the four walls
of your house or apartment, or the doors of your car and the windshield of your car.
I know that can be hard to do but it's very valuable. If you live in a city like
New York and its skyscrapers everywhere, you've probably experienced the incredible
sense of relaxation
and it's aesthetically beautiful when you are walking down one of these long
avenues and you turn
and I think they have a name for this in New York, where the sunset is suddenly visible along a long avenue between some skyscrapers.
And it's just very relaxing to be able suddenly to see at a distance.
And that's actually because this eye mechanism, relaxing the lens and relaxing some of the
musculature around the eyes, sends signals deep into the brainstem that release some of the musculature around the eyes. Send signals deep into the brainstem
that release some of the centers that are involved
in alertness, aka stress,
and it's very pleasant for a reason.
It's not a placebo effect, if you will.
There are a bunch of neurochemicals
and things that are associated with that.
So try and see at a distance
because it's good for your eyesight.
It'll keep this lens nice and elastic and the muscles nice and strong that move the
lens.
And it has this relaxing component to it.
Now our visual system is exquisitely tuned to motion, not just our self-generated motion
but the motion of things around us.
And one of the things that it does is something called smooth pursuit. Smooth pursuit is our ability to track individual objects moving, as the name suggests, smoothly
through space in various trajectories.
You can actually train or improve your vision by looking at smooth pursuit, stimuli, and that
sounds really boring.
What you can do is, and I'll provide a link to some
that I think are pretty good,
that are used in various clinics,
ophthalmology and optometry clinics.
You can actually take a few minutes each day,
or maybe if you don't do it each day,
you could every third day or so.
And actually just visually trackable.
Sometimes it's moving in kind of an infinity symbol.
Sometimes it's more of a sawto tooth. Sometimes it's changing speed.
Sometimes the the cue that you're following, the little target is dilating and contracting.
This is going to keep the muscles, I want to be clear, this is going to keep the extraocular muscles
conditioned and strong and allow you to have a healthy, smooth pursuit system.
Remember, the brain follows the eye.
It follows the movements of the eye.
It has to deal with that.
The neural circuits within the brain have to cope with changes in smooth pursuit.
If you're doing a lot of reading up close, you're not viewing horizons, you're not getting
a lot of smooth pursuit type stimulation from your life, or you're just getting it within
the confines of a little box on your phone, like your smooth pursuit is over, you know, millimeters
or what we always talk in terms of visual angle, but the amount of degrees of visual angle,
but if you're just looking at smooth pursuit in this little tiny box on your phone or on
your computer screen and you're not looking at objects in your environment like swooping
birds and things like that, which I'm guessing many of you are not spending your time doing.
Well these mechanisms for smooth pursuit will get worse over time.
Your vision will get worse.
And so while I prefer that people get out into the real world and experience smooth pursuit
tracking of visual objects, I don't know, maybe it's a good reason to go to a hockey game
or to, you know, and try and keep your eye on the puck, which I can never seem to do.
Move so fast. Or I guess this is a good reason
to watch live sports, if that's your thing,
or watch a tennis match, like a cat,
like a kitten, watch in the ball, go back and forth.
Whatever watching kids play, it doesn't really matter.
The idea is that you want to use the visual system regularly
for what it was designed for, and smooth pursuit
is a great way to keep
the visual and motion tracking systems of the brain and the eye and the extracurricular
muscles working in a really nice coordinate fashion.
I would say 5 to 10 minutes, 3 times a week will be great if you care about your vision,
you can train your vision in this way.
The other one is to train accommodation.
There are a lot of videos out there. I want to
be clear on the internet, some of which are from clinicians, some of which are not, some of
which are from scientists, some of which are from other sources, talking about things you
can do to make your vision better, to improve your vision. Most of those are geared toward
improving the extracurricular eye muscles, but
I did consult with our chair of ophthalmology at Stanford School of Medicine, Jeff Goldberg,
who's an MD, NAPHD, a phenomenal scientist and a phenomenal clinician and incidentally,
a phenomenal chairman as well, about what sorts of things tools are actually beneficial
for pattern vision and sight,
because there's just so much out there on the internet,
not all of which is accurate or good, frankly.
And he agreed that a smooth pursuit stimulus,
that kind of training, as well as, or exercise,
as well as near-far.
So spending a few minutes,
you might even just do this for two minutes
of looking at something up close. That's going to activate these accommodation
mechanisms and then moving it at arm's length and focusing on it for five, ten
seconds, maybe more, maybe fifteen or twenty seconds, then slowly moving it into
a location and then out. This is actually a lot like the visual training that's
done post-concussion to try and repair, actually repair some of
the balance and motor and visual and cognitive aspects of the brain.
And we are going to have a guest on in a future time that to deal with concussion and some
post-concussion training, a lot of post-concussion recovery and training centers around the
visual system, not just because people are trying to recover their vision
and their sense of balance, but because, as I mentioned earlier, the brain's ability to
make sense of its environment and the brain's ability to parse time, not just on the day
night schedule, but also shorter time intervals, follows the visual system, something we'll
turn to a little bit more at the end.
So what does this mean?
The tool is
Spend two to three minutes doing smooth pursuit. There's some programs on YouTube
You can just look up smooth pursuit stimulus and I'll provide a link to do a couple I like as well
You could do this with a pen if you wanted you could do this
Someone else could hold a wand and you could do that if you got someone that can do that for you
Practice accommodation for a few minutes, maybe every other day. Just bring in something in close,
you'll feel the strain of your eyes doing that.
I can feel it right now.
Move it out.
You'll feel a relaxation point.
Move it past that relaxation point
where you will have to do what's called a virgin side movement
to maintain focus on that location as it moves out.
Bring it back in.
At the point where you actually have to go cross side,
this will differ for different people depending on how far apart your eyes are, so-called inter-pupillary distance.
So for me, I have been teased before. I have a very short inter-pupillary distance. I'm
not a cyclops, but I'm hidden there. Some people are more wall-eyed, like a flounder.
Well depending on your inter-pupillary distance, the point at which things get blurry and cross-eyed will vary. But for
me, you know, as I get about, oh gosh, I guess it's about six inches from my nose, it's
really hard. I can't accommodate any longer. I move it out another inch and everything's
in nice focus. Try and see whether or not you can get things closer. Now you don't want
to get cross-eyed. Remember what your parents told you or my parents told me that if you
cross your eyes when you're young, that they can stay that way. Actually, they won't necessarily stay that way, but your brain can start losing information.
And the ability to see binocular depth, something we'll talk about in a moment.
But for now, the protocol would be two to three, maybe five minutes, just practice that,
practice accommodation, and then be sure to give your eyes some rest.
Get outside, look at a horizon, or do nothing. Just kind of give your eyes some rest. Get outside, look at a horizon
or do nothing, just kind of let your eyes go soft. I guess what the yogis would call soft
gaze, just kind of relax your eyelids, not this, not eyes closed, just relax, panoramic
vision, try and see the walls around you without moving your head. Exercise your eye muscles,
exercise the accommodation mechanisms of your eyes, practice a little bit of smooth pursuit.
You don't have to be neurotic about this, but if you do this often enough, meaning every
other day, every third day or so, you can be the strange person on the plane or in the
classroom doing this.
People might chuckle or look at you funny or tease you, but that's okay because you'll
be able to see when they are losing their vision.
So you'll get the last laugh.
Please don't laugh at them, but maybe you can help them
at that point, you can hold the pen for them.
It's worth doing.
It's really worth preserving your vision.
And again, if you're a young person, this is great,
because then you can actually build an extra strong visual
system using all the tools that we're describing.
I do want to talk about a new set of findings
that are related to red light and offsetting
age-related macular degeneration.
There are a lot of ways in which our visual system gets worse over time, but one is so-called
age-related macular degeneration.
Glenn Jeffery at the University of College London, somebody I've known for decades, because
he's a scientist, has done beautiful work on development and function of the visual system. He's published a number of papers recently,
one that got a particularly high amount of attention
in the press was one that showed that flashing red light
into the eyes early in the day, not late in the day.
Early in the day can help offset some age-related
macular degeneration, presumably by enhancing
the mitochondrial function in the photo
receptors.
There does seem to be some evidence for that, although it's still early days.
I want to emphasize you don't want to shine really bright lights into your eyes.
You never want to look at any light that's so bright that it's painful, and you never
want to force your eyelids to stay open.
If you need to close your eyes in order to be comfortable, well then chances are that
light is too bright.
But doing just a couple minutes a day,
like two minutes a day of flashing this red light
into one eye and then the other,
as long as it was early in the day before noon time,
and as long as it was in individuals
that were 40 years or older,
did seem to have a significant effect
in offsetting some of the age-related
macular degeneration that would otherwise occur. Again, these are early findings. If you want to do
this, please be careful. Please talk to your optometrist and or ophthalmologist. Your eyesight is
precious. You don't want to damage it, but it is interesting and it does seem like red light can
improve the function of the mitochondria. These photoreceptors have a lot of mitochondria, the energy
producing organelles within the cells
because they are some of the most metabolically active cells in your entire body.
Your photoreceptors are active all the time as you're looking around and even when your
eyes are closed they're active.
In fact, through a weird twist of the biology, and please look this up if you're really
interested in this, your photoreceptors are actually most active in the dark.
This is so weird.
It's a twist of biology, the way the system's arranged,
that when light comes on, they shut off their activity.
So actually, whether or not you see something in front of you like this pen or my face
is because the way your photoreceptors are turning off, not turning on.
It's a really cool twist. And I don't want to go too far down that rabbit hole.
But check it out, if you're interested in how photoreceptors work, it's an absolutely incredible
literature. Just Google, excuse me, look up on the web. We are not partial just to Google.
I happen to use Google, but use your web browser to look up a photoreceptors hyper polarization
site. And you can learn a lot about that if you're a real nerd for the stuff like I am
Okay, so red light
To the eye can perhaps it seems help maintain vision
Doing smooth pursuit exercises and accommodation near far exercises
Some people suffer from poor eyesight simply because their eyes get dry There are incredible believe it not, lubricating mechanisms for the eye, not just
tears, but thin sheet of oil.
I mean, it's just amazing unless you have some sort of corneal abrasion, the corneas, the
clear stuff on the outside of your eye, corneal abrasion.
When you blink, it's smooth.
You don't feel it.
It's just really, really smooth.
And yet, if you've ever had a corneal scratch, I've had this, it's really rough.
It is so painful.
You have a ton of pain receptors in the cornea.
The lubrication of the cornea is supported by blinking.
And while it seems a little silly, some people actually benefit from doing, you know, some
you know, five or 10 or 15 seconds of blinking and then doing their focused work.
Some people their eyes are drying out
because as we focus, if we're trying to do something,
our eyelids stay open, the eyes can dry out,
but it also can make it such that when we blink the next time,
there's a kind of a need to focus
because there's some distortions in these oils
and liquids across the corneal surface.
If you're somebody who suffers from dry eye,
I do hope they'll find a treatment or a cure
for dry eye soon.
There isn't one that is present.
Someone stands to make a lot of money out there.
If you can find a cure for dry eye, let the company know or start a company.
Right now it's still a mystery as to how to do that.
But blinking for five to fifteen seconds, probably slowly, not as quickly as I'm doing here
on video, but just maybe a blink every second or two, 15 seconds, can lubricate the eyes.
And that's not directly really anything neural.
It's just going to allow the optics of your eye to be clear, just like when the screen
of your phone gets dirty, like when costal is texting on my phone and I pick it up and
it's like covered with smudge, to clean it off in order to see things clearly.
The same thing is happening for these optical devices on the front of your brain.
Remember, these are brain.
Okay, so a lot of protocols today, almost all of them, behavioral protocols, I do want
to talk a little bit more about vision and how it works internally.
And then I also want to talk about some of the foods and supplements that have been
shown to support vision and offset visual loss and maybe even reverse some visual loss.
Let's talk about binocular vision and lazy eye.
I'm very familiar with lazy eye because when I was a kid, I went swimming one day, one
day, and I didn't have my goggles.
And so something must have been happening as I I recall, with the eye moving down through
the water, I've always had this problem that I can only do the freestyle stroke off to
one side.
The people I swim with are always laughing.
Somehow I kind of moved toward drowning when I try and breathe on the right side.
I think there's some asymmetry in the way I'm organized.
Anyway, I was off to my left and my eye kept going in and out of the water and there was
chlorine in the water and it was making my uncomfortable so I just closed my eye. I just decided, you know, I knew more
less out of swim straight, ish. Might have bounced off the lane lines a few times, but I just
used the other eye to kind of steer for that mark on the wall. Got out of the pool, took a shower,
tried off, and then completely lost binocular vision for three days. Completely.
and then completely lost by an ocular vision for three days. Completely.
The young brain up until about age seven,
but maybe even extending out until about age 12
is extremely vulnerable to differences
in ocular input between the two eyes.
My scientific great grandparents won the Nobel Prize
for discovering so-called critical periods,
periods of time in which the brain is more plastic, more able to change.
Those two guys, David Hewlett and Torrance and Weasel, thank you, David and Torrance
and forever change the face of visual neuroscience and forever change the way we think about treatment
of the young brain.
It used to be thought that you wouldn't want to do a surgery on a young kid because of
risk of anesthesia and young individuals.
But we now know that you need to repair these imbalances that even a few hours, okay, I don't
want to scare anybody.
I'll talk about reversal, but a few hours of occluding one eye early in life can lead to
permanent, unless something's done.
Permanent changes in the way that the brain perceives the outside world such that when that
eye is opened up again, the brain actually can't make sense, such that when that eye is opened up again,
the brain actually can't make sense of anything that's coming through it.
It shuts down that visual pathway somehow.
So what happened to me was, actually, my eye was fine.
I got out of the pool.
I opened my eye, but I couldn't see through that eye.
Everything was blurry, double vision, unless I covered this eye, and then I could see perfectly
fine.
Fortunately, I went to an ophthalmologist who understood the literature.
Thank you, Dr. Mark Loury, who understood the literature
and made it clear that what I needed to do was to
occlude the other eye, the eye that was working very well.
Clearly, he understood the work of you when weasel.
Now again, you don't wanna start playing games
with this kind of stuff when you're a kid.
If you wear, let's say you have a Halloween costume
and you wear an eye patch, you're a pirate
or something for Halloween and you cover it up on one side.
Probably for the night of Halloween, it's okay.
I do not recommend doing that recreationally.
If you don't need that, if you're a young child
or for your child to do that, because indeed,
you create imbalances in the brain machinery
that compares information coming in through the two eyes
and it can shut down the neural information for the occluded, the closed eye. Now, I was able to
reverse this issue, but my binocular vision has never been terrific. I'm much better at the
dart board and still not very good. If I close one eye, I'm much better at the pool table. If I
close one eye and I still am terrible, I was the kid in the outfield,
the ball's coming towards me,
the ball's coming towards me,
I'm gonna catch the ball
and then like I hit me square in the lip.
My binocular vision isn't great
as a consequence of this early event
and I have a hard time with those binocular stereograms,
those images that are kind of,
you're supposed to look at them
and then the binocular depth image pops out, all the other kids are going, there's the whatever,
the statual liberty, there's the immigrant, I see dots.
Okay, so I have binocular vision, but I use other cues, I use the near far cues that
I talked about before, motion parallax, the fact that things are closer to me are moving
faster than things further away in order to judge depth.
And years later, when I got involved in, and I don't suggest this for most people, I got
involved in boxing and martial arts when I was younger.
Sometimes we'll see fighters.
This is a slip to avoid getting punched.
It's also generating motion parallax.
Many animals judge depth by moving their head, not by using other mechanisms of accommodation.
Okay, so a lot of birds and monkeys and animals will judged depth by moving their head like
this or they'll move from side to side.
Animals that will undulate sometimes are actually doing a depth measurement because as you move
from side to side, the brain is able to do the math of depth.
So what does this all mean in terms of protocols?
If you're a young person, do your best to get really good binocular vision, not just at
level of your phone or your tablet, but also at distance.
You will build strong binocular visual machinery in the brain and at the level of the eyes
and the eye musculature.
Now, if you're somebody who did have an occlusion, what's needed is to cover up the other eye,
to create an imbalance so that the weak eye, the so-called lazy eye, this sometimes referred
to as amblyopia, that eye has to work harder.
So for me, they patched this other eye and made this eye, eventually I got visioned through
that eye back, then they opened them both up.
Now, you might ask, what happens if you cover both eyes early in life?
And this is where it gets interesting.
You might think, well, if covering one eye leads to poor vision for that eye after that
eye is open, covering both eyes will probably make you blind, right?
Actually that's not what happens.
What Hubeon Viesel discovered in what's been affirmed many, many more times over in subsequent
studies is that it's competitive, that the two eyes are competing
for real estate up in the brain. So if you actually cover both eyes, you actually extend the
period of the critical of critical plasticity. This is a really interesting aspect that other people
are starting to leverage now in terms of how to reopen plasticity later in life. But please don't,
you know, go around with your eyes covered for too long. There are some retreats and stuff where people go into caves with absolutely no vision,
creates hallucinations.
We'll talk about why that is in just a moment, but here's my suggestion.
Try and get balanced visual input through the two eyes.
Almost everybody has a dominant eye.
It usually doesn't relate to your dominant hand, although it can.
So for me, if I cover up my right eye,
I see much less well, much more poorly. It's a little bit fuzzy and I have to work harder in order
to see the camera, for instance. Then if I cover up my left eye, it's actually really easy for me
to relax. I have a dominant eye. You can balance that out by covering up the dominant eye a little
bit each day. But I would warn any young people, meaning,
you know, 12 or younger, against creating these imbalances if there isn't a clinical need
to do that.
And if you do have strong imbalances between the two eyes, which can be caused by cataract
and lens issues, can be caused by neuromuscular issues, et cetera, to try and get those dealt
with as early as possible by contacting a really good
ophthalmologist and ideally a neuroophthalmologist.
It is very normal, I should say it's very common
for young children, babies, to have an eye that
was strabismus, that either deviates out
or that deviates in.
It is important to correct that.
If you would like to have balanced vision
between the two eyes and for the brain
to respond equally to the two eyes and to have, I would say, high fidelity quality vision.
Although some people who have an eye that Drifts can function normally in life, you have
an opportunity early in life to rescue that.
I won't do it.
Well, maybe I will do this, but I can actually relax this eye.
It's so weak in some cases that it actually can start to deviate.
Here, I'll just do this here.
It's not crossing my eye, so I actually can move, I can misalign my eyes because I have
to fight very hard to have the musculature for this eye, keep that eye aligned with the
other eye.
And that's because I've been doing eye exercises since I was in my 20s because I noticed
when I would study a lot, this eye would start to drift in and I'd start to see double and I
would then next thing you know I was just covering the eye up, it was getting weaker and
weaker just like the atrophy of a muscle.
So I went to the doctor, what did they do?
They did the exact wrong thing.
The optometrist I went to gave me a prism which adjusted it so that I could see things
normally, it was just made the eye weaker and weaker.
It's like putting a weak arm into a sling.
So I had to spend at least three years of 10 minutes a day.
It's what I recommend.
Doing near-far, covering up my good eye,
doing near-far with my bad eye,
and now it's been about 10, 12 years
that I have pretty decent binocular vision.
Now, many of you aren't dealing with this
or have these early childhood issues.
Some of you might be experiencing challenges
with fatigued eyes or with differences
in focus with the two eyes.
These eye exercises of near-far, smooth pursuit
and checking for dominant and non-dominant eye
can be very beneficial.
Again, I'm not a clinician,
so I don't wanna give you protocols or enforce protocols
on anybody.
You need to figure out what's right and safe for you, giving your vision history.
I do recommend talking to a really good ophthalmologist if you have severe vision problems of any
kind or if you want to offset vision problems of any kind, an optometrist as well, but ideally
it would be a neuroophthalmologist.
Okay. I did mention hallucinations and they're fun to talk about and think about.
For years, people have asked, why do people get visual hallucinations?
Costello isn't sleep right now. He can probably hear him snoring. He's snoring so
loud. He's probably having hallucinations about rabbits, pizza, and those are
mainly his favorite and sleep. He's dreaming about sleep in sleep.
Hallucinations are a property of the visual system
and it was always thought that hallucinations arise
because of over activation or activation
of certain aspects of the visual system.
I just briefly wanna mention a paper that was published
by my good friend and phenomenal scientist
and physicist for that matter.
Chris Neal, who's up at the University of Oregon in Eugene,
they studied LSD-like compounds and discovered
that hallucinations actually occur because portions
of your brain become underactive.
The visual portions of your brain are understimulated.
This is probably why when people go into these cave retreats,
something I've never done, I don't think I ever will do, where it's completely black.
Pretty soon, they start hallucinating, they start seeing things, even though there's nothing there.
The visual system is desperate to make guesses about what's out in the world.
It's like the eager beaver of your brain. It's like, what's out there? What's out there? What's out there?
Even in low to no vision people, blind people,
their brain is going to be making guesses about what's out there in the in low to no vision people, blind people, their brain is going to be making
guesses about what's out there in the auditory world, what sounds are there, what touch
sensations are there. Forcited folks, it's going to be what's out there in terms of light.
Light is the dominant way, vision is the dominant way that we evaluate the world around us.
So it turns out that hallucinations are an under activation of the visual system and
then a compensatory, a compensation by which the visual system creates activity and hallucinations.
So if you're in the dark long enough, you start to hallucinate and see things.
So that's a little note about hallucinations.
One of the things that you can do to improve your vision and it's also kind of fun is to
put a SNELL and chart in your
home. A snow and chart is that list of letters. If you go to the dreaded department of motor
vehicles, actually, I'm up for renewal soon. So I love the department of motor vehicles.
The department of motor vehicles, I'll have you cover up an eye, read the letters on
the chart. The letters of course get smaller and smaller. They're trying to figure out roughly
what your vision is. Cover up the other eye, you'll do that.
Some people, including nerdy vision scientists like me,
have had SNELIN charts in their office
or in their home for many years now,
and you can just practice and you can see
how you're doing sitting at a particular distance.
Your, this is something that's not often mentioned,
but your performance on the SNELIN chart will vary depending on time of day because your level of fatigue and your ability to control
that accommodation and other mechanisms of the eye muscles will vary.
So you can take it as an average.
It's also a good thing if you're going to get your vision tested for corrective lenses
or maybe you're going to do laser surgery or something of that sort.
If you're thinking about any of that, to really get it measured by a professional, the ones
that you get in those supermarkets or in many eyeglass stores, apologies to the eyeglass
stores, are often wrong by an order of magnitude.
And then when you start putting corrective lenses on that are overcorrecting or undercorrecting,
but more often are overcorrecting, then you're
essentially weakening the system. It's like putting a prosthetic on a limb that you didn't necessarily
need or a robot arm when you didn't need the use of the robot arm, although I now there's so much
excitement about robots. I think people are going to be doing that. Anyway, nonetheless, get your
vision tested by somebody who really understands vision like an ophthalmologist or a really good optometrist
If you put a snelling chart in your home, you know
You can do that as part of your visual training now this might seem excessively nerdy, but what is more important than your eyesight
Right eyesight is so vital. It's right up there with movement and our ability to move to generate to get up out of chairs and to walk and to run and to
To take care of ourselves.
Eye sight and movement are the main ways that we are able to take care of ourselves and
take care of others.
When you start having compromised eyesight or compromised movement, people need to take
care of us and we become much more challenged in moving through our daily life.
So while it might seem nerdy to have a snelling chart in your home or to do a smooth pursuit exercise a couple
times a week or to get outside for a few hours a day and do your reading or your
laptop work there, preserving your eyesight and preserving your vision is one of
the most life enhancing or quality of life enhancing things that you can do.
And if you're a young person and you can build some of this into your framework
of exercise or brain training.
If you want to call it that, that can be immensely beneficial.
We'll really set you up to have really good vision over a long period of time.
Now of course, there are genetic factors and there are injury-related factors that can
compromise eyesight and our ability to see.
And of course, this is the things I'm talking about today aren't going to solve all those
issues, but they can have a tremendous positive impact
if you're willing to do just a little bit of work.
And none of this is involving any cost, right?
It's just time cost.
So I do wanna talk about a few other things
that can perhaps improve vision.
I wanna dispel a few myths about stuff to take,
to improve vision.
And then I want to dispel a few myths about stuff to take to improve vision. And then I want to just
close by talking about how we perceive time using our vision because that will nicely set the
stage for what we're going to talk about next episode. So now you understand a lot about the biology
of vision. You understand that light has to arrive at the retina and get converted into electrical signals. That process requires things like vitamin A,
a fat soluble vitamin. It requires things like the keratinnoids. That metabolic cascade, that biochemical
cascade, is essential for vision. And this is why you've been told that carrots help you see better
because they're high in vitamin A. There are a few
simple things you can do to support your vision. First of all, it is true that eating vegetables,
the dark leafy vegetables, and things like carrots that have vitamin A in abundance, and
eating them in close to their raw form. So naturally occurring foods that contain a lot of vitamin A in their raw form
can help support vision. Now does that mean that if you ingest super physiological amounts of that
stuff that it's going to make your vision that much better? No, but you do need a threshold level
of vitamin A in order to see, and in order to see well.
Now, there's a lot of excitement nowadays about supplementation to help support the health
of the visual system.
And I'm somebody who's pretty open to novel forms of supplementation.
You've probably gathered that.
If you've been listening to this podcast for a while, you have to determine what's safe
and economical and right for you, what your risk tolerance is, et cetera.
But I wanna talk about a molecule
that's in a lot of supplements to support vision.
And there are some really good data on, and that's lutein.
Now the study I wanna describe is actually published
in 2016, it's from the Journal of Ophthalmology.
It's a good journal.
And the title of this paper is,
might catch your attention,
it's increased macular pigment optical density,
that just means that the macula is an area of the eye
for central vision, for high acuity vision.
Pigment density there is good, you want pigment there.
Increased macular pigment optical density and
Visual acuity visual acuity is your ability to see things in fine detail
Following consumption of a buttermilk drink containing lutean enriched egg yolks remember raw foods
Lutean enriched egg yolks sounds like a rocky movie where he would drink the raw egg yolks a
Randomized double-blind placebo controlled trial now. I'm not suggesting you he would drink the raw egg yolks. A randomized double-blind placebo-controlled trial.
Now I'm not suggesting you go out and eat raw egg yolks.
There's the risk of salmonella.
Although I did hear this, someone correct me if I'm wrong,
that the salmonella is actually on the outside of the egg,
not actually in the egg itself.
It's on the shell for reasons that relate
to how that egg got into the world.
That's where the salmonella lives, but I could be wrong about that.
But raw egg yolks are not something that most people want to consume.
What is this luteen stuff?
Well luteen is in the pathway that relates to vitamin A and the formation of the ops in
the photopigment that captures light in the back of your eye, literally absorbs
light pigment in your eye and converts that into electrical signals and allows you to see.
And there is some evidence, I spoke to our chair of ophthalmology, there is some evidence
through quality peer reviewed studies that supplementing with lutein can help offset some of the detrimental effects of age-related
macular degeneration, but I want to emphasize, but, or emphasize, however, only for
individuals with moderate to severe macular degeneration. For people that have
normal vision or with just a low degree of macular degeneration,
these studies did not see a significant improvement of vision from supplementing with
lutein.
So I'm not going to tell you to supplement with lutein or not.
I don't think any study is holy, but it does seem that if you have moderate to severe
macular degeneration, talk to your physician, of course,
talk to your ophthalmologist, I'll always say that,
and I'll say it three times.
Supplementing with lutein could perhaps support vision
and offset some vision loss in that case.
Probably also talk to your ophthalmologist
or consider the red light therapy
that I talked about earlier.
Whereas if you have normal vision
or a low amount of macular degeneration,
it does not seem, at least from these studies, that lutein, how much of an effect.
Now I know, and I confess, I'm sort of of the mind that if I personally had age-related
macular degeneration or propensity for it in my family, which fortunately I don't. But in that case, I would think that supplementing with lutein provided it's safe, could perhaps
be of benefit.
You might want to consider a low dose of that.
So again, I'm not pushing any of this on anybody by any means, but you should know that under
certain conditions of severe macular degeneration or moderate macular degeneration, it does seem
like lutein can be beneficial. It does not have to be consumed through raw egg yolks,
although that is the highest density source.
Cooking your eggs, if you like your scrambled eggs dry
or you like your eggs not easy over or whatever,
not runny, then you aren't going to get the benefits
of the leucine.
There are other sources of leucine,
non-animal sources of leucine as well. You can look those up on the internet. Now, there are other compounds
that have been shown to perhaps be important for offsetting or helping different forms of vision
loss. One is, I'm going to spell this out, IDE, B-E-N-O-N-E in de bone, in-de ben-none, in de ben-none.
No, I can never pronounce these compounds, forgive me,
unless I've worked with them.
There is evidence that it can be beneficial
for leabers congenital eye disease.
I would definitely go onto examine.com,
put in IDE, B-E-N-O-N-E,
and for things like leab's optical neuropathies,
which is a degenerative condition of the eye.
Whether or not people should just be taking this stuff anyway is still an open question.
There aren't a lot of studies about it.
A lot of people that are interested in taking things to support their vision are taking
luteen as a preventative measure.
I don't pass any judgment one way or the other.
Typically those supplements also include
the z-axophins and the asthacens.
Okay, the pronunciation of this is terrible, I'm sure,
but that's not too far off,
but basically ZEAX, ANTHIN.
You can see what I'm talking about. ZEAXX-A-N-T-H-I-N. Let me see what I'm talking about.
Z-A-X-A-N-T-H-I-N.
And the other one is A-S-T-A-X-A-N-T-H-I-N.
Both of these have been shown, excuse me,
both of these have been shown to offset
some of the disruption in vision
that occurs with aging.
What is Aztec Saksin?
It's a really interesting compound.
It's the red pigment found in various seafoods.
So shrimp, I'm not a big seafood fan,
but like certain fish, like the,
you'll see at the fish market,
we'll have that red pigment.
And it's also in the feathers of flamingos.
Please don't eat the feathers of flamingos.
And please also don't eat flamingos.
It's structurally similar to beta-carotene.
So it's very pro-vitamin A.
But it has some chemical differences,
which may make it safer than vitamin A.
Remember, vitamin A is a lipid-solid vitamin,
so it can be stored in our body for long periods of time.
What is the deal with this AstonX, then, you know,
what are its drawbacks? Well, we can go to our ever favorite examin.com.
What does it do? Well, it has a number of different effects, a huge number, in fact.
But it does seem to notably increase. It's now been shown in three studies,
the antioxidant enzyme profile.
It has a number of different effects,
but the most notable for sake of this episode
is the one on ocular blood flow.
It does seem to increase the amount of ocular blood flow,
so the blood supply to the eyes.
So that makes it an interesting compound.
There's a number of other effects for whatever reason.
It also has a notable effect,
several studies have shown this,
on fertility in males.
So it seems to at least double the pregnancy rate when men take astaxanthin and works
as in particular it seems here in men that were previously infertile.
So I don't know if that has something to do with the blood flow to the eyes, probably
not, it probably has something to do with something unrelated to the eyes.
Nonetheless, that's an effect of this molecule.
It's also been shown to have positive effects on things like skin elasticity, skin moisture,
skin quality, etc.
Probably due to its effects on blood flow.
So lutein, astataxin, ASTAX X-A-N, T-H-I-N, and for people who have concerns about
levers, optic neuropathies, which is going to be a small percentage of people out there,
but that is a pretty severe condition.
There are supplements that are available out there.
I do encourage you, as always, to talk to your ophthalmologists and physician about them.
And I will say that there are a number of people that take lutein and some of these other things
as a precautionary measure in order to bolster their health.
And the same way that some people take vitamins and minerals
to bolster their health and some people are very health,
excuse me, and some people are very averse
to taking vitamins and minerals
because they feel like they can get all that
from healthy whole foods.
And of course, you can get these from from whole foods. The question is
whether or not you can get them in concentrations that are sufficient. I do think that in the years
to come we are going to see more about lutein. I think we are going to see more about some of these
other compounds like Azteczatz and and hopefully by then I'll be able to pronounce it. But at present
these things are more or less
than the kind of experimental or self-experimental phase.
There are some good double blind placebo controlled studies
like the egg yolk buttermilk study of all things
published in really good journals.
Journal of Ophthalmology, Journal, Investigative Optimology
and Vision Sciences, these are good journals.
These are journals that are peer-reviewed by experts.
The study that I mentioned earlier about keeping rooms dark,
that was also published in an excellent journal.
I think it was JAMA.
I'll go back and look.
It's not on my screen any longer,
but very easy to find.
And there have been some follow-up studies as well
from the University of Pennsylvania
and other universities.
So everything I've talked about today
relates to studies that were done and published in
quality peer reviewed journals. That doesn't necessarily mean you want to run out and start taking
the stuff that I've described or even doing the protocols I've described. I've given you an array,
a palette, a buffet, if you will, of things that you could do to try and enhance or support your
vision depending on how good your vision is. Your family history of vision and vision loss. Your occupational hazards, people that work with metal filings that are flying out of machines
are going to have a higher degree of risk to their visual system, then will people who just
do office work, although if you're doing a lot of office work, chances are you're not getting
a lot of long-view vision, your accommodation mechanisms are going to start to suffer over time.
I think we can reliably predict that.
So I tried to give you an array of behavioral tools, and we did touch upon some supplementation tools.
I'd be remiss if I didn't say that because blood flow is so critical for the neurons of the eye,
remember these are the most metabolically active cells in your entire body, the cells within your retina,
because blood flow is required to get them
the energy and nutrients they need,
having a healthy cardiovascular system, right?
Doing endurance work, doing strength, training work,
regularly is going to support your eyes
and your brain and your vision.
It's indirect, but it's essential, right?
It's necessary, but it's not gonna be sufficient.
You're gonna have to do other things
to support your eyesight as well.
But having a healthy cardiovascular system because it's going to deliver blood and oxygen
and nutrients to this incredible aparaty on the front of your face, it's two pieces of
brain, is going to support your overall brain health and vision over time.
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And last but not least, I want to thank you for your time and attention today, your willingness
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support the health and functioning of your visual system.
And of course, I want to thank you for your interesting silence.
you