“A Real Eye Opener – The Eye, Part 4”

Welcome all students to today’s Anatomy Lesson #32, The eye – Part 4! Remarkable sensory organ that it is, this will be our fourth lesson of the eye series. Although I thought this would be the last eye lesson, a 5th and last lesson on eye anatomy is required. But, you’ll see why this fascinating and wonderful organ requires yet another lesson!

We know that the eye is designed to provide us with vision. Understand that the air around us is filled with a sea of electromagnetic energy from the shortest gamma waves to the longest radio waves. Humans are blind to almost all of this energy because our eyes detect only that part of the electromagnetic spectrum known as the visible spectrum or, in more common terms, visible light.

Let’s begin the lesson with a quick review. In Anatomy Lesson #31, we learned parts of the eyeball. Photo A is a horizontal section through a left eyeball (as viewed from above). The sclera is the white outer coat. The choroid is a coat of blood vessels internal to the sclera. The retina with its specialized sites is inside the choroid. The transparent cornea projects from the front surface. Iris and pupil (Anatomy Lesson #31) are behind the cornea. The biconvex lens is behind the iris. The ciliary body with its ciliary muscle forms a ring around the lens. The anterior chamber is a space between cornea and iris that is filled with the watery aqueous humor. A space between iris and lens is the poorly named posterior chamber which is also filled with aqueous humor. Behind the lens is the largest space of the eyeball, the vitreous chamber containing vitreous humor or vitreous body.

Figure0083-a-KLS-editede

Photo A

NOTE: this lesson shows images of the eyeball in horizontal section oriented with the cornea directed upward (Photo A) or rotated 90° so the cornea faces left or right (Photo C). Don’t be distressed when you see this flip flop; it just reflects preference by the creator of the image.

This lesson will cover sclera, cornea and lens. The sclera is the tough, white outer fibrous coat of the eyeball (Photo B – red arrow); it provides shape and resistance as well as attachment for extraocular muscles (Anatomy Lesson #30) and some intraocular muscles (Anatomy Lesson #31). The tiny red blood vessels seen in Photo B are actually located in the bulbar conjunctiva (Anatomy Lesson #30) which adheres to the anterior sclera.

Hazel-Eye-Morguefile2-KLS-edited

Photo B

The cornea (Latin meaning horn) is a transparent dome covering the anterior 1/6 of the globe. It bulges because its radius is smaller than that of the remaining eyeball. This creates a small sulcus (groove) at the corneoscleral junction known as the limbus (Latin meaning edge or border; Photo C).

Try this: Ask a partner to sit while you look at one of their eyes from a side view. Identify the white sclera. Find the transparent cornea bulging from the front of the eyeball. Find the limbus, the groove where cornea and sclera meet.

862

Photo C

The cornea is a truly fascinating part of the eye being composed of cells and extracellular molecules arranged in five microscopic layers (Photo D). With the exception of the stroma or middle layer, the names of the other layers don’t concern us today. A normal cornea is transparent because the stroma is made of regularly arranged layers of collagen molecules and because it lacks blood vessels.

Question: if it has no blood supply, how does it get oxygen and nutrients?

Answer: these are delivered to the superficial cornea by the tear film and to the deep cornea by aqueous humor (or humour). The cornea is well-equipped with pain fibers as anyone knows who has injured it. And, as you realize, if the cornea is touched an automatic reflex is evoked that closes the eyelid for protection.

shutterstock_127500686

Photo D

The cornea is not of the same thickness throughout: it is thinnest at its middle (~0.5 mm) and thickest near its rim (~0.8 mm). This change in thickness is clearly evident in this magnificent image from Lesson #31 (Photo E – yellow arrow at middle of lens; red arrow at rim).

Picture3-KLS-edited

Photo E

The normal cornea is smooth and clear like glass, but it is also strong and durable so it helps the eye in three ways:

  • Refracts (bends) light rays to help focus them on the retina (Photo F – black arrow).
  • Shields the eyeball from germs, dust, and other harmful matter.
  • Filters out some of the damaging ultraviolet (UV) wavelengths in sunlight.

Light rays entering the eyeball must be bent to focus them on the retina. The cornea is powerful providing roughly 2/3 of the overall refractive power of the globe. But, understand that its curvature is fixed and normally does not change.

normal%20vision%20diagram

Photo F

Corneas are subject to a variety of diseases and conditions including allergies, conjunctivitis (pink eye), infection, dryness and dystrophies (cloudiness) to name a few. A seriously damaged cornea may be injured such that light cannot penetrate the eyeball to reach the light-sensitive retina. Sometimes a corneal transplant is required wherein a surgeon removes the central portion of the cloudy cornea and replaces it with a clear cornea, usually donated through an eye bank.

Here are two pairs of clear corneas going at it eye-to-eye (Starz episode 109, The Reckoning). Look me in the corneas lass, when I’m talking to ye! I am your 18th century hubby and ye will obey me! This  Sassynach looks Jamie in the eye and while she’s at it, she’ll spit in it too! She doesn’t have to do what Jamie says. Aye ye do; If ye dinna do what I say then there’s a price ye’ll have to pay! Ouch!

ep-109-Jamie-and-Claire-cornea-KLS-edited

And, just when we think that we have seen it all, well, we haven’t! Have you ever heard of corneal jewelry? Yep, small crystals and other gewgaws hang via a thread from a contact-type lens! Not sure that swinging counterweight would feel very good dropping from the cornea but can’t say as I’ve never tried one.

fashion-eyeful-contact-lens-jewelry-KLS-edited

Photo G

Moving along, the lens (Latin meaning lentil) is next. The lens is a transparent, bi-convex structure suspended between iris and vitreous humor that continues to grow throughout life. The lens is shaped like a flying saucer although its front surface is flatter than its back surface (Photo H). Near the pupillary rim, the iris is in contact with the front surface of the lens but the two diverge at the sides. The back surface of the lens sits in a divot of the vitreous humor. Like the cornea, its purpose is to refract light rays to focus on the retina and is responsible for about 1/3 of the overall refractive power of the eyeball.

eye KLS edited

Photo H

Lens structure is amazing and complex but simplified for this lesson. Like the cornea, the lens is avascular to assist with transparency. It is made of very long (12 mm) and very thin cells known as lens fibers (Photo I). These cells are arranged in layers around a central core much like the rings of an onion. The lens has also a capsule, some cube-shaped cells in front and a few other features but these do not concern us for this lesson.

The_Anatomy_and_Structure_of_the_Adult_Human_Lens-copy-KLS-edited

Photo I

Photo J is an image of lens fibers taken with a scanning electron microscope (Anatomy Lesson #6), an instrument that takes 3-D images of microscopic structures. Very cool! With this type of microscopy, lens fibers look like tightly-packed lasagna noodles. Nuclei and other cell structures (organelles) are absent from mature lens fibers to boost transparency. Lastly, the fibers are filled with crystalin protein and their water content is very low.

fig_1_1_big-KLS-edited

Photo J

The lens is suspended from the ciliary body by a ring of fibrous strands known as zonular fibers. Although difficult to appreciate in a two dimensional image, zonular fibers attach all the way around the equator of the lens (Photo K – red arrow) much like a round trampoline pad that is suspended from a frame by its coils.

Figure0085B-KLS-edited

Photo K

A closer look at the suspensory mechanism reveals that several layers of zonular fibers attach to the lens at various points at or near its equator (Photo L – red arrow). Collectively zonular fibers form the suspensory ligament of the lens. Another important feature, the ciliary body contains bundles of (involuntary) smooth muscle cells (Photo L – black arrows).

Figure0084-KLS-edited

Photo L

Like the cornea, the lens refracts (bends) light rays to help focus them on the retina. Unlike the cornea with its fixed curvature, the lens is flexible and its curvature can be adjusted to fine tune focus, an ability which decreases with age. Based on the distance from a viewed object, the lens flattens or fattens.

Simply put #1: light rays from far objects enter the eyeball roughly parallel (Photo M – top image) and not much lens refraction is required to focus them on the retina. With this scenario, the ciliary muscle is relaxed and the lens is flat because it is under tension by zonular fibers of the suspensory ligament.

Simply put #2: light rays from near objects (Photo M – bottom image) diverge before reaching the eye so the lens thickens to refract these rays and bring them into focus at the retina (if the lens doesn’t thicken, near light rays would come to focus behind the retina and the image would be blurry). With this scenario, ciliary muscles contract releasing tension on zonular fibers (i.e. the suspensory ligament) so the lens fattens, an action known as accommodation of the lens. Accommodation is accomplished by, yes, the parasympathetic division (PSNS) of the autonomic nervous system causing ciliary muscles to contract!

eye-anatomy-15-728

Photo M

A clarification is important here – accommodation for near vision actually involves three important changes, all of which occur automatically:

  • Eyeballs converge because both medial rectus muscles contract (Anatomy Lesson #30)
  • Pupils shrink in size because the sphincter pupillae muscles contract (Anatomy Lesson #31)
  • Lens thickens because ciliary muscles contract, releasing tension on zonular fibers and the lens assumes its natural fat state (This description may sound counterintuitive but it is correct)

Although scientists know that lens curvature increases with near vision to ensure that the light entering the eye focuses on the retina, the way this happens is still unresolved. Photo N, left panel shows the flattened shape of the lens with far vision. The middle and right panels show two theories about the shape change of the lens during near vision/accommodation. The Helmholtz theory (1855) proposes that the ciliary muscle contracts, all zonular fibers relax and the lens thickens. The Scharchar theory (1992) suggests that the ciliary muscle contracts, selective zonular fibers relax and only the central part of the lens thickens. There is yet a third theory but too technical for today’s lesson. It has been claimed that most modern eye specialists hold with the Helmholtz theory.

Try This: Have a pal sit at one end of a room and focus on something at the far end. Now, step in front of the pal, bend down and ask him/her to look at your nose. If you do this carefully, you can see the eyeballs draw together and the pupils shrink with accommodation. You will not see the lens change shape because it lies too deeply. Try it a couple of more times with the pal looking at something over your shoulder and then at your nose to be sure you got it. This is accommodation.

Theories-of-eye-accommodation

Photo N

Claire presents us with a wonderful example of accommodation as she looks into the bonny orbs of her handsome Highland Hero (Starz episode 110, By the Pricking of My Thumbs)! Her pupils are constricted and her eyes converge to focus on the object of her desire. Thickening of her lens is not visible. Come back to her, James Fraser!

ep-110-Claire-eyes-KLS-edited

Not to be outdone, Jamie’s eyes can accommodate too (Starz episode 111, The Devil’s Mark). Ahhhh, where did ye say ye were from, Sassylass??? Pupils constricted and eyes convergent…great job, laddie!

ep-111-Jamie-eyes-KLS-edited

With age, the lens and ciliary muscle undergo changes. Known as presbyopia (Greek meaning old eye), the lens gradually loses its flexibility and the ciliary muscle weakens so focusing on near objects is impaired (Photo O – top image) and the image comes to focus behind the retina. Thankfully, distance vision usually remains unaffected. This condition is easily treated with eyeglasses or contact lenses (Photo O – bottom image) which refract the light rays to bring them to focus at the retina. Please note that at present, presbyopia cannot be treated effectively with surgery. Presbyopia usually becomes apparent in our early- to mid-40s, but this is actually a gradual process that often begins earlier.

presbyopia-treatment-copy-KLS-edited

Photo O

Next, let’s consider cataracts: not a torrent of water but opacities of the lens that can result in impaired vision or blindness (Photo P). Cataracts have been around for a very long time with the earliest documented case being depicted in a small wooden Egyptian statue from about 2400 B.C.E.

A cataract can occur in either or both eyes but does not spread from one eye to the other. Eye cataracts are common in older people as the aging lens and its fibers become more and more opaque, but cataracts can also form congenitally, after injury, following treatment with some medications, or from disorders such as glaucoma. A startling statistic: half of the US population 80 years old and older have cataracts or have had cataract surgery. Now days, there are several different surgical approaches to cataract treatment but they typically involve removal of the natural lens followed by implanting an artificial intraocular lens.

cataracts%203

Photo P

Let’s take a look at some interesting history about the cataract. It may be difficult to believe, but the earliest recorded surgical treatment of cataracts was 800 B.C.E., in India. Using a procedure known as couching, a curved needle was inserted through the coats of the eyeball. The lens was pushed downwards and backwards into the vitreous humor and out of the field of vision. Later, couching spread from India to China, Babylonia and Egypt. Centuries later, couching was practiced in Europe (Photo Q) by traveling barber-surgeons with little or no training and the procedure often left patients blind or at best with only partially restored vision. Other strange and startling treatments were also popular. Nicholas Culpeper records a cataract treatment in his School of Physick (1659):

“The head of a cat that is all black burned in a new pot or crucible, and made into fine ashes, and a little of it blown with a quill into an eye that hath a web or pearl growing in it, three times a day is a sovereign remedy”

couching cataracts copy KLS edited

Photo Q

During Outlander’s time, John Taylor (1703-1772) was the first in a long line of British oculists. Dubbing himself “Chevalier” and “Ophthalmiater Royal,” Taylor became the personal eye surgeon to King George II (Yep; same sovereign that Claire mentions to Colum in Starz episode 102, Castle Leoch), the pope, and a number of European royal families (Photo R). A colorful character who many consider a charlatan, he traveled throughout Europe in a coach painted with images of eyes to advertise his expertise. Taylor removed cataracts either by couching or breaking them up and extracting the bits and pieces. Prior to performing each surgery, he delivered to the audience (yes, groups of people often observed such surgeries) a long, grandiose self-promoting speech.

Purportedly, Taylor once confessed that he had blinded hundreds of patients. Two of Taylor’s botched cataract surgeries included famous composers George Frederic Handel (1685–1759) and Johann Sebastian Bach (1685-1750). Taylor performed couching on Handel but it was unsuccessful and the composer suffered blindness throughout his remaining years. Taylor also used couching to treat Bach’s bilateral cataracts. A week later, Bach was re-operated on but he remained blind and, weakened by the surgeries, he died four months later.

Joannes_Taylor_Medicus KLS edited

Photo R

Many of us are indeed fortunate to be able to choose good eye surgeons with superior training and expertise than those of Jamie’s time. But, I would be amiss not to note that today couching is still practiced in remote areas of third world countries. Let’s give a shout out (and a donation if possible) to those surgeons who travel to dangerous regions of the globe and often at their own expense to bring current therapies to those who are less fortunate.

Let’s close the lesson with a parting keek at Jamie as he keeks at Claire (Starz episode 102, Castle Leoch)! Herself reveals in her 8th book, Written in My Own Heart’s Blood, that Jamie often surreptitiously appraised Claire with his bonny orbs before they wed. He declares that anyone would have thought them well-suited for each other had they noticed his thorough perusal of her:

“If they’d seen the way I looked at ye, Sassenach, when ye didna see me lookin’—then, aye, they would.”

OR, to quote Rick’s famous line from Casablanca:

“Here’s looking at you kid!”

looking 5

Yum! Yum! Gah!

Next lesson will be the last one on the eye: we’ll cover the retina and its parts, nearsightedness, farsightedness and some grand experiments with our own vision. For now, let’s end with a fun poem about eyes by Mr. R! The last Anatomy Lesson to feature one of his delightful science poems was in Anatomy Lesson #24.

Eyes Poem: sense of sight

I need my eyes,
So I can see,
I don’t have 5,

poem 1

Or 1,

poem 2

Or 3…

poem 3

Just 2 eyes,
On my face,

poem 4

It seems to be,
A common place,
For eyes to sit,
On animals,
From frogs, to fish,
From bears, to gulls…

poem 5

2 eyes,
1 face,
That’s a match,
But really here’s,
A little catch…
Spiders see,
With 8 bug-eyes,
And here’s another,
Eye surprise,
Scallops have,
Most of all,

poem 6

More than 50,
Must see all!
I’ll stick with 2,
They let me see,
My 2 eyes,
Are good for me…

 

A deeply grateful

Outlander Anatomist

photo creds: Starz, Netter’s Atlas of Human Anatomy, 4th ed. (Photos A, K, L), Wheater’s Functional Histology, 4th edition (images of structure of eye and of retina), Outlander Anatomy collection (Photo E), www.archopht.jamanetwork.com (Photo Q – couching lenses), www.discovery.lifemapsc.com (Photo I – lens anatomy), www.en.wikipedia.org (Photos R – John Taylor), www.lasik-center.com (Photo H – lens), www.medicine.academic.ru (Photo C – limbus), www.optics.rochester.edu (Photo J – SEM of lens fibers), www.rosineyecare.com (Photo O – presbyopia), www.sciencelearn.comm.nz (Photo N – theories of accommodation), www.sciencepoems.net (-Eyes poem, Sense of Sight; Mr. R’s World of Math and Science), www.slideshare.net (Photo M – accommodation), www.timelessnaturalhealth.com (Photo B – sclera), www.toovia.com (Photo G – corneal jewelry), www.visioncarespecialists.com (Photo D – corneal structure), www.webmd.com (Photo P – cataracts), www.wynneeeyeassociates.com (Photo F – refraction of light rays by cornea)

Fun Fact – orbicularis oris

kiss

Noun, Latin: orbicularis oris musculus  or.bik.je’lear.is -ˈōr-əs muːs.ku.lus.

Anatomy def: muscle around the mouth that closes and compresses the lips

Outlander def: kissing muscle that puckers those amazing smackers!

Learn about orbicularis oris muscle in Anatomy Lesson #14! It truly is known as the kissing muscle because it is used to pucker the lips.

See Claire’s and Jamie’s orbicularis oris muscles meet-and-greet in the grassy glen, Starz, episode 108 Both Sides Now.

Read about the kissing muscle in Outlander book:

While my mind might object to being taken on a bare rock next to several sleeping soldiers, my body plainly considered itself the spoils of war and was eager to complete the formalities of surrender. He kissed me, long and deep, his tongue sweet and restless in my mouth. “Jamie,” I panted.

A deeply (hee hee) grateful,

Outlander Anatomist

 

“An Aye for an Eye – The Eye, Part 3”

jamie eating bread 3 jamie eating bread 4

We’ll get to these images and eye secks later, but isn’t this is a grand place to begin today’s Anatomy Lesson #31? An old English Proverb posits that “The eyes are the window of the soul.” Well, for today’s lesson, we will peer into these wonderful windows to learn about their structure and function.

Back in Anatomy Lesson #29, it was proposed that the eye is the most elegant and complex of our sense organs. After we consider a brief overview of eye structure, this entire lesson is devoted to the iris, a part so detailed that it requires its own lesson!

Let’s look at a “dissection” of the human eye using a horizontal section through the right eyeball (Photo A – bird’s eye view). The cornea projects from the front surface. The iris with its central opening, the pupil, lies behind the cornea. The biconvex lens is located immediately behind the iris. The red tissue near the lens is the ciliary body (labelled ciliary muscle in Photo A). The sclera is the outer fibrous coat that we see as the white of the eye. The choroid, a layer rich in blood vessels, lies internal to the sclera. The neural coat or retina lies inside the choroid. At the back of the globe are fovea, optic disc and optic nerve. The fovea, site of greatest visual acuity, lies in our visual axis (Photo A – dashed green line). The optic disc, or blind spot, is in front of the optic nerve. The optic nerve (cranial nerve II) at the back of the eyeball carries electronic impulses from the retina to vision centers in the brain. In each eye, the optic nerve angles towards the nose.

The eyeball has three chambers. The anterior chamber (Photo A, light gray crescent) is a space between cornea and iris that is filled with the watery aqueous humor. A space between iris and lens (Photo A, small dark gray area) is the posterior chamber, also filled with aqueous humor. Deep to the lens is the largest space of the eyeball, the vitreous chamber (Photo A, large dark gray area); it is filled with vitreous humor, a gel-like material.

EyeAnatomy-by-aclens.com-KLS-edited

Photo A

With the overview completed, we will consider the iris: first its structure, then its color, and finally its ability to change size.

The iris is a thin circular structure deep to the cornea that has a central hole, the pupil (Photo B); think of the pupil as the absence of iris. Shaped a bit like an old-time 45-rpm record, the iris controls the diameter of the pupil and therefore the amount of light reaching the retina.

pupil-KLS-edited

Photo B

Learning the parts of the iris helps us understand its purpose. Photo C shows one-half of an iris with pie-shaped segments to illustrate different features. The iris has the following layers from front to back:

  1. Stroma and sphincter muscle
  2. Dilator muscle
  3. Posterior pigment cells

Stroma is the part of the iris that we can see: an amazing meshwork of collagen fibers, structural cells, melanocytes (Photo C – 1st and 2nd pie segments) and small blood vessels (Photo C – 3rd pie segment). The sphincter muscle is a ring of smooth muscle cells (Photo C – 4th pie segment, black arrow) surrounding the pupil.

Behind the stroma is the dilator muscle formed of specialized myoepithelial cells which contain both contractile filaments and melanin. Myoepithelial cells radiate away from the pupil much like the spokes of a wheel (Photo C – 4th pie segment, green arrow).

Posterior pigment cells contain lots of melanin and form the deepest layer (Photo C – 5th pie segment, red arrow – layer is flipped to show the back). Melanin inside the posterior pigment cells and the myoepithelial cells absorbs light rays except those admitted through the pupil. This design controls the amount of light rays reaching the retina.

iris-structure-KLS-edited-2

Photo C

Now that we have an idea of iridial (adj.) structure, let’s consider the many colors of the iris. People refer to the color of the eyes but they really mean the color of the iris. The word iris is derived from the Greek goddess, Iris, meaning rainbow. Although the iris doesn’t come in all the colors of the rainbow, its hues are quite varied.

Herself often uses iridial color to describe her beloved Outlander characters. In the Outlander book alone, we read about eyes of amber, black, blue, brilliant blue, dark blue, light blue, blueberry, brown, liquid brown, cornflower, gold, golden, green, grey (English spelling), dove grey, hazel, saffron, sherry, soft blue, soft grey and yellow… What an imagination!

In the past, iridial color has sometimes presented a problem as a legitimate child was expected to have irises the same color as one or both parents. Recall how Geillis (Starz, episode 111, The Devil’s Mark) was treated at the witch trial for dabbling in the murky arts? Well, some women have faced accusations and indignities for bearing children whose irises differed in color from those of either parent. Later, science declared that iris color was a simple dominant-recessive inherited trait, e.g. brown irises dominant over blue. An old myth in human genetics is that two blue-eyed parents cannot have a brown-eyed child. Unfortunately this erroneous concept is still being taught in some genetic courses. Not so! New data has caused science to revise understanding of eye color. Iris color is now known to be a polygenetic trait with perhaps as many as 15 genes operating to determine final iris color. The genetics of eye color are so complex that almost any parent-child combination of iris colors can and does occur. Go, science!

ep-111-Geillis-02-KLS-edited

Human iris color ranges from very light blue to very dark brown. Scientists generally agree that there are at least five or six major colors plus many mixtures: hazel, brown, black (actually very dark brown), grey, green and blue (Photo D). Indeed, iris color is so diverse that charts and scales have been developed in an effort to categorize and standardize the wide spectrum of iris colors.

eye_color KLS edited

Photo D

In Anatomy Lesson #5 we learned that skin contains melanin, a pigment produced by melanocytes. Well, the iris contains melanocytes too, but the melanin is not blue, grey, hazel or green. Rather, iris melanin ranges from light brown to dark brown (eumelanin) with a wee bit of yellow to red (pheomelanin) sometimes present.

So, if irises do not contain blue, gray, green or hazel melanin, what accounts for these colors? Well, the causes are a bit complicated but four factors play a role:

  1. Melanin content in pigment epithelium and myoepithelial cells at the back of the iris: although there are slight differences, both cell types are typically heavily pigmented in all eyes (an exception is noted below). These layers absorb all the light that reaches them.
  2. Melanin content within stromal melanocytes: stromal melanin varies greatly with different iris colors (compare 1st and 2nd pie segments of Photo C). Brown or “black” irises have heavily pigmented stromal melanocytes. Blue or grey irises have little or no stromal melanin. Green irises have light brown stromal melanin or amber (see below) pigments. Hazel irises contain moderate amounts of light brown melanin.
  3. Light scattering properties of stromal collagen: these molecules scatter light rays depending on their size and density, much like water droplets in the air makes the sky appear grey.  Grey irises contain larger collagen deposits that scatter light in this manner.
  4. Light scatter properties of stromal turbidity: This is a fancy way of saying pigments and other stromal molecules also scatter light but in a different way: long wave light is absorbed and short wave light is reflected back towards the viewer. This effect is similar to a type of light scattering that causes the sky to appear blue (it isn’t) and occurs is blue, hazel and green eyes.

An exception to the above occurs in a true albino who lacks all iridial pigment so the iris appears red from its blood supply (Photo C, 3rd pie section).

Now, let’s consider some iris colors from Outlander characters. Here is wee winsome Willie with his big beautiful brown irises. He informs Claire that Jamie has always helped him so he will help rescue Jamie from Wentworth Prison (Starz episode 114, The Search). But, mayhap he carries a soft spot in his heart for Claire? Show him the way lassie! Willie has oodles and oodles of dark melanin in the stromata (pl.) of his irises so they appear very dark brown.

ep-114-Willie-eyes-KLS-edited

DNA studies on ancient remains show that all humans once had brown eyes. They also show that blue eyes are probably the result of a genetic mutation that occurred some 6,000 to 10,000 years ago and may be the source of all blue-eyed humans alive on the planet today.

Dougal’s light blue irises inform us that there is little or no melanin in his iridial stroma (Starz episode 109, The Reckoning). Notice, however, that in some light his irises appear gray or blue-grey. Dougal is a likely candidate for the scattering effect of external light on stromal collagen explaining why his eyes sometimes appear bluer or grayer depending on lighting conditions, how much money is involved or if kissing Claire is on his mind. Either way, gie him back that bag o’ gold, Colum!

ep-109-Dougal-eyes-KLS-edited

In the Outlander books, Herself informs us that Claire has golden/amber/whisky-/sherry-colored eyes. Whew, lucky lady! Jamie remarks on Claire’s unusual eyes – shortly after their wedding:

The finger moved to my face, drawing from temple to cheek, smoothing the hair back behind my ear. I remained immobile under his scrutiny, trying not to move as his hand passed behind my neck, thumb gently stroking my earlobe. “Golden eyes; I’ve seen a pair like that once before—on a leopard.”

Amber eyes in humans are unusual (Photo E). Such irises are typically a solid color with strong yellow/gold or russet/copper tints. The basis for amber coloration is poorly understood but some scientists believe it is due to deposits of lipochrome. Lipochrome is not a type of melanin; rather it is an aggregation of various molecules of golden hues. Lipochrome may also account for the yellowish specks or patches in green eyes or gold tones in hazel and blue irises.

amber-eyes-RLS-edited

Photo E

Also, stromal pigmentation may not be uniform between a pair of eyes or even within one eye. There are wedges, flecks, rings and patches of varying stromal pigmentation. Consider Captain Rat-Man’s right iris as “witch-that-she-is” Claire gives him the hour of his death (Starz episode 115, Wentworth Prison). Oooh, BJR, did ye get a bit o’ bad news? Aye, he is going to pay the price for messing with her Jamie! He’s a bad man, but in this light, his lovely hazel eyes contain scattered dark brown flecks. Such flecks are sites of heavier stromal pigmentation. Out damn spot (“the Scottish play”, Act 5, Scene 1)!

ep-115-BJR-eyes-KLS-edited

Claire’s beautiful blue eyes are on full display as she presents a delightful example of a dark blue limbal ring, a site of increased light scattering at the outer rim of the iris (Starz episode 116, To Ransom A Man’s Soul). Her pupils are contracted as she inspects her beloved red-heided Highlander: whew, he hasn’t started to puke yet! Eye-love if I ever kent it! (love, love, love her hair and elegant neck!)

ep-116-Claire-eyes-02-KLS-edited-2

Can the irises change color? Well, yes, they can. For example, many babies are born with blue eyes that change color with age. Lightening or darkening of iris color has been reported during early puberty, pregnancy, and sometimes after serious trauma suggesting that chemical reactions and hormonal changes can influence iris color. A particular drug used to treat glaucoma can also increase pigmentation of the iris and a few other diseases can change iris color. Recently, a patient suffering from the Ebola virus reported that the infection turned one of his blue irises to green.

Many people consider blue irises to be a most desirable color. Pertinent to us Outlanderphiles – Scotland has the second highest rate of blue irises in the world: 50% of Scotland’s population has blue eyes and that number jumps to 86% if green eyes are included! Finally, for thrill seekers, a laser treatment is now available that changes brown irises to blue by eliminating the brown melanin of the iridial stroma (Photo F). Hopefully, readers will get thoroughly informed about side effects before opting for such a treatment.

eye-colors KLS edited

Photo F

Another interesting fact about iris color: likely, you have seen individuals with one iris a different color than its counterpart. This is heterochromia and it may be complete wherein each iris is a different color (Photo G) or partial where part of one iris is a different color. This uncommon condition can be inherited or acquired through disease or injury. Actually, quite a few actors have heterochromia. One actor, well known for roles in early spaghetti westerns, had complete heterochromia and was made to wear a contact lens on the light colored iris because producers feared negative reactions from the viewing audience! I doubt this would be a problem for today’s movie goers.

heterochromia-KLS-edited

Photo G

Ok, done with iris color. Let’s talk about pupil size…. Question: what do an orgasm, a multiplication problem and a photo of a dead body have in common? Each induces a slight, irrepressible expansion of the pupils. Hee, hee!

How do our pupils change size? Well, this occurs because the iris is equipped with a pair of intraocular (inside the eyeball) muscles that were mentioned earlier. We do not have voluntary control over these muscles.

Sphincter pupillae is the smooth muscle cells that encircle the pupil. Like a sphincter, this muscle contracts to close the pupil and reduce the amount of light reaching the retina (Photo H – left image). This muscle is under control of the parasympathetic division of the autonomic nervous system; known by the acryonym PSNS, it activates in response to intense light and during rest, repose and rejuvenation.

Dilator pupillae muscle is composed of the myoepithelial cells that contain melanin pigment and muscle filaments. These are arranged radially like the spokes of a wheel (Photo H – right image). As these cells contract, the pupil enlarges to increase the amount of light reaching the retina. Dilator pupillae is under control of the sympathetic division of the autonomic nervous system; known for short as SNS, it activates in response to dim light and during fright, fight and flight responses.

NOTE: The middle panel of Photo H represents the iris and pupil with muscles at rest.

15-09_Pupil-KLS-edited

Photo H

You should know that light intensity alone is sufficient to exert major effects on pupillary diameter. Studies have shown that in very bright light, a normal pupil can shrink to a tiny 1.0 mm diameter.

“One misty, moisty morning when cloudy was the weather,” they meet Hugh Munroe amid the rain and heather. This day looks very misty and cold! Nevertheless, the light intensity is sufficient to shrink Claire’s lovely pupils as she shares bread and cheese with her new hubby and arrow deflector (Starz, episode 108, Both Sides Now)!

ep-108-Claire-pupils-KLS-edited

Such studies also show that with very dim light, the pupil can enlarge to 8.0 mm – roughly the size of a chickpea (Photo I – garbanzo bean)!

chickpea-seeds-KLS-edited

Photo I

Light rays aren’t the only stimuli that affect pupillary size: some years ago, a Princeton psychologist showed that pupil size increases in proportion to the difficulty of an assigned task (i.e. stress or challenge): multiply nine times 13 and the pupils dilated slightly. Calculate 29 times 13 and they widened further and remained dilated until subjects found the answer or stopped trying. In a related experiment, subjects were required to recite a series of seven digits from recall; their pupils enlarged steadily as the numbers were presented one by one and shrunk steadily as they unloaded the digits from memory. Ergo, our pupils reflect exposure to stress and mental effort.

In summary, pupils constrict in response PSNS stimulus and excessive light but also prior to REM sleep and by conditioning stimuli. Pupils dilate in response to SNS stimulation and low light and also with sexual stimulation, mental challenge, some CNS psychoactive drugs and conditioning to a particular stimulus.

Eye_dilate

We’ve known from the get-go that Jamie’s pupils can dilate verra well. Anatomy Lesson #2 described his pupillary response when “Not-A-Wet-Nurse” Claire reduces his dislocated shoulder (Starz episode 101, Sassenach). That lesson explains how his dilated pupils were consistent with the SNS-induced fright, flight and fight response. Och, lassie, that hurt!

ep-101-Jamie-eyes-KLS-edited

But then, along comes Starz episode 116 (To Ransom a Man’s Soul) and whoa! This episode generated lots of on-line chatter as some fans posited that there was no way Jamie’s iris could dilate to the degree shown without the aid of CGI, dilating medications or contact lenses.

ep-115-Jamie-eyes-KLS-edited

Well, remember, given low light alone, they can dilate to the size of a chickpea. Add to that the stressing and depressing back-licking antics by BJR and the pupil dilates even more! Talk about fight, fright and flight! I argued for natural dilation but despite my efforts, the explanation was met with skepticism so I asked “Jamie.” To my delight he responded from a span of 202 years, that indeed his dilated pupils were unaided by anything (except the creepy crawly circumstances and very low dungeon lighting – my words)! Kudos to his fantastic acting skills!

Screen Shot 2015-05-25 at 4.44.19 PM

Back to pupil dilation: just how large can the pupil dilate? More than 8 mm if dilating drops are applied! You can see in Photo J, that with such medications, the iris is reduced to a very thin rim completely dominated by the pupillary opening.

 

artificially-dilated-pupils-KLS-edited

Photo J

Would you like to see another view of the pupil after drug-induced dilation? Take a wee keek at this next amazing image (Photo K)! The narrow vertical slice of light running down the surface of eyelids and eye is from a slit lamp. The beautiful arc of cornea (Photo K – white arrow) bulges from the anterior surface of the eyeball. Deep to the cornea is the dark anterior chamber (Photo K: green star). Yellow arrows mark the rim of the iris; its tissues actually fold back during pupil dilation. The red star marks the convex anterior surface of the lens. Generally speaking, dilating medications paralyze the sphincter pupillae allowing the dilator pupillae muscle to contract unopposed.

cornea-KLS-edited

Photo K

Like other body parts, the iris has diseases and disabilities, but there are too many to cover in this lesson. One point worth mentioning: in general, both pupils should be very nearly the same size. Slight variations in pupil size can be normal, but if you notice a sudden and significant difference between the size of both irises, known as anisocoria, then you should see a specialist to rule out significant medical issues (Photo L).

Anisocoria-KLS-edited

Photo L

The iris is endlessly entertaining because it is a body part we can readily see and appreciate. But, it is time to close this session. What better way than to praise the best blue eyes ever with a little more eye secks and an Ode to Sawny Blue Eyes!

jamie eating bread jamie eating bread 2

Ode to Sawny Blue Eyes

I may be a dutter,

Or even a nutter,

Embroiled in a true-stew.

It makes us all mutter

And then start to stutter,

As brilliant orbs come into view.

Bread swiped with butter

Sets hearts all aflutter,

Wit’ big eyes of bonny blue!

Thoughts in a clutter

Spitter and sputter,

What in the world shall we do?

With our minds in the gutter

Together we utter

“Gie that fab-lad his just due!”

A deeply grateful,

Outlander Anatomist.

photo creds: Starz, Grey’s Anatomy, 39th edition (Photo C), Orgasm joke from 2012 Scientific American, Outlander Anatomy collection (Photo K), www.aclens.com (Photo A), www.apsubiology.org (Photo K), www.cancer.gov (Photo B), www.enwikipedia.org (Photo M), www.imgbuddy.com (Photo E), www.memrise.com (Photo H), www.nataliacoretraining.com (Photo I), www.9gag.com (Photo L), www.pinterest.com (Photo G), www.pitchengine.com (Photo H), www.sites.psu.edu (Photo F), www.talks.fredite.com (Photo D), www.en.wikipedia.org (Photo J; gif of pupillary reflex), Jamie eating bread http://henricavyll.tumblr.com