Math Is Fun Forum

Femur

Gist

The femur, or thigh bone, is the longest, strongest, and heaviest bone in the human body, extending from the hip to the knee. It is critical for weight-bearing, walking, and running. Key structures include the ball-shaped head (hip joint), a strong shaft, and the condyles (knee joint).

The femur, or thigh bone, is the body's longest, strongest, and heaviest bone, running from the hip to the knee, supporting body weight, and enabling leg movement for activities like walking, running, and jumping. It connects to the pelvis at the hip (forming the hip joint) and the tibia (shin bone) at the knee, acting as a crucial pillar and anchor point for powerful muscles. 

Summary:

What Is the Femur?

The femur is the longest, strongest, and heaviest bone in the human body, making it a difficult one to break. It’s also protected by various muscles and helps you maintain your posture and balance.

Femur bone function

Your femur connects many important muscles, tendons, and ligaments in your hips and knees to the other parts of your body, including parts of the circulatory system. More than that, it helps you carry your body weight when you stand and move. Your femur is critical in helping you maintain stability so you don’t fall over easily.

The femur also contains bone marrow, which is a soft, fatty tissue made up of stem cells. Stem cells have two unique abilities that make them essential to survival — they can make more stem cells, and they can “morph” or develop into other types of cells (this process is called “differentiation”).

These stem cells form two types of bone marrow: red and yellow. Each has an important job. Red bone marrow cells produce all the components of your blood (red and white blood cells and blood platelets). Yellow bone marrow cells store fat, which is needed for energy and to produce bone, cartilage, and muscles. From birth to around age 7, your bones contain only red marrow. From then on, yellow bone marrow gradually replaces red.

Details

The femur or thigh bone is the only bone in the thigh — the region of the lower limb between the hip and the knee. In many four-legged animals, the femur is the upper bone of the hindleg.

The top of the femur fits into a socket in the pelvis called the hip joint, and the bottom of the femur connects to the shinbone (tibia) and kneecap (patella) to form the knee. In humans the femur is the largest and thickest bone in the body.

Structure

The femur is the only bone in the upper leg and the longest bone in the human body. The two femurs converge medially toward the knees, where they articulate with the proximal ends of the tibiae. The angle at which the femora converge is an important factor in determining the femoral-tibial angle. In females, thicker pelvic bones cause the femora to converge more than in males.

In the condition genu valgum (knock knee), the femurs converge so much that the knees touch. The opposite condition, genu varum (bow-leggedness), occurs when the femurs diverge. In the general population without these conditions, the femoral-tibial angle is about 175 degrees.

The femur is the thickest bone in the human body. It is considered the strongest bone by some measures, though other studies suggest the temporal bone may be stronger. On average, the femur length accounts for 26.74% of a person's height, a ratio found in both men and women across most ethnic groups with minimal variation. This ratio is useful in anthropology, as it provides a reliable estimate of a person's height from an incomplete skeleton.

The femur is classified as a long bone, consisting of diaphysis (shaft or body) and two epiphyses (extremities) that articulate with the hip and knee bones.

Upper part

The upper or proximal extremity (close to the torso) contains the head, neck, the two trochanters and adjacent structures. The upper extremity is the thinnest femoral extremity, the lower extremity is the thickest femoral extremity.

The head of the femur, which articulates with the acetabulum of the pelvic bone, comprises two-thirds of a sphere. It has a small groove, or fovea, connected through the round ligament to the sides of the acetabular notch. The head of the femur is connected to the shaft through the neck or collum. The neck is 4–5 cm. long and the diameter is smallest front to back and compressed at its middle. The collum forms an angle with the shaft in about 130 degrees. This angle is highly variant. In the infant, it is about 150 degrees and in old age reduced to 120 degrees on average. An abnormal increase in the angle is known as coxa valga and an abnormal reduction is called coxa vara. Both the head and neck of the femur is vastly embedded in the hip musculature and can not be directly palpated. In skinny people with the thigh laterally rotated, the head of the femur can be felt deep as a resistance profound (deep) for the femoral artery.

The transition area between the head and neck is quite rough due to attachment of muscles and the hip joint capsule. Here the two trochanters, greater and lesser trochanter, are found. The greater trochanter is almost box-shaped and is the most lateral prominent of the femur. The highest point of the greater trochanter is located higher than the collum and reaches the midpoint of the hip joint. The greater trochanter can easily be felt. The trochanteric fossa is a deep depression bounded posteriorly by the intertrochanteric crest on the medial surface of the greater trochanter. The lesser trochanter is a cone-shaped extension of the lowest part of the femur neck. The two trochanters are joined by the intertrochanteric crest on the back side and by the intertrochanteric line on the front.

A slight ridge is sometimes seen commencing about the middle of the intertrochanteric crest, and reaching vertically downward for about 5 cm. along the back part of the body: it is called the linea quadrata (or quadrate line).

About the junction of the upper one-third and lower two-thirds on the intertrochanteric crest is the quadrate tubercle located. The size of the tubercle varies and it is not always located on the intertrochanteric crest and that also adjacent areas can be part of the quadrate tubercle, such as the posterior surface of the greater trochanter or the neck of the femur. In a small anatomical study it was shown that the epiphyseal line passes directly through the quadrate tubercle.

Body

The body of the femur (or shaft) is large, thick and almost cylindrical in form. It is a little broader above than in the center, broadest and somewhat flattened from before backward below. It is slightly arched, so as to be convex in front, and concave behind, where it is strengthened by a prominent longitudinal ridge, the linea aspera which diverges proximally and distal as the medial and lateral ridge. Proximally the lateral ridge of the linea aspera becomes the gluteal tuberosity while the medial ridge continues as the pectineal line. Besides the linea aspera the shaft has two other bordes; a lateral and medial border. These three bordes separate the shaft into three surfaces: One anterior, one medial and one lateral. Due to the vast musculature of the thigh the shaft can not be palpated.

The third trochanter is a bony projection occasionally present on the proximal femur near the superior border of the gluteal tuberosity. When present, it is oblong, rounded, or conical in shape and sometimes continuous with the gluteal ridge. A structure of minor importance in humans, the incidence of the third trochanter varies from 17–72% between ethnic groups and it is frequently reported as more common in females than in males.

Lower part

The lower extremity of the femur (or distal extremity) is the thickest femoral extremity, the upper extremity is the shortest femoral extremity. It is somewhat cuboid in form, but its transverse diameter is greater than its antero-posterior (front to back). It consists of two oblong eminences known as the condyles.

Anteriorly, the condyles are slightly prominent and are separated by a smooth shallow articular depression called the patellar surface. Posteriorly, they project considerably and a deep notch, the Intercondylar fossa of femur, is present between them. The lateral condyle is the more prominent and is the broader both in its antero-posterior and transverse diameters. The medial condyle is the longer and, when the femur is held with its body perpendicular, projects to a lower level. When, however, the femur is in its natural oblique position the lower surfaces of the two condyles lie practically in the same horizontal plane. The condyles are not quite parallel with one another; the long axis of the lateral is almost directly antero-posterior, but that of the medial runs backward and medialward. Their opposed surfaces are small, rough, and concave, and form the walls of the intercondyloid fossa. This fossa is limited above by a ridge, the intercondyloid line, and below by the central part of the posterior margin of the patellar surface. The posterior cruciate ligament of the knee joint is attached to the lower and front part of the medial wall of the fossa and the anterior cruciate ligament to an impression on the upper and back part of its lateral wall.

The articular surface of the lower end of the femur occupies the anterior, inferior, and posterior surfaces of the condyles. Its front part is named the patellar surface and articulates with the patella; it presents a median groove which extends downward to the intercondyloid fossa and two convexities, the lateral of which is broader, more prominent, and extends farther upward than the medial.

Each condyle is surmounted by an elevation, the epicondyle. The medial epicondyle is a large convex eminence to which the tibial collateral ligament of the knee-joint is attached. At its upper part is the adductor tubercle and behind it is a rough impression which gives origin to the medial head of the gastrocnemius. The lateral epicondyle which is smaller and less prominent than the medial, gives attachment to the fibular collateral ligament of the knee-joint.

Development

The femur develops from the limb buds as a result of interactions between the ectoderm and the underlying mesoderm; formation occurs roughly around the fourth week of development.

By the sixth week of development, the first hyaline cartilage model of the femur is formed by chondrocytes. Endochondral ossification begins by the end of the embryonic period and primary ossification centers are present in all long bones of the limbs, including the femur, by the 12th week of development. The hindlimb development lags behind forelimb development by 1–2 days.

Function

As the femur is the only bone in the thigh, it serves as an attachment point for all the muscles that exert their force over the hip and knee joints. Some biarticular muscles – which cross two joints, like the gastrocnemius and plantaris muscles – also originate from the femur. In all, 23 individual muscles either originate from or insert onto the femur.

In cross-section, the thigh is divided up into three separate fascial compartments divided by fascia, each containing muscles. These compartments use the femur as an axis, and are separated by tough connective tissue membranes (or septa). Each of these compartments has its own blood and nerve supply, and contains a different group of muscles. These compartments are named the anterior, medial and posterior fascial compartments.

Clinical significance:

Fractures

A femoral fracture that involves the femoral head, femoral neck or the shaft of the femur immediately below the lesser trochanter may be classified as a hip fracture, especially when associated with osteoporosis. Femur fractures can be managed in a pre-hospital setting with the use of a traction splint.

Cortical desmoid

Cortical desmoid (also known as a tug lesion or periosteal desmoid) is an irregularity of the distal femoral cortex commonly observed is adolescents.

Additional Information

The femur is the longest, strongest bone in your body. It plays an important role in how you stand, move and keep your balance. Femurs usually only break from serious traumas like car accidents. But if your bones are weakened by osteoporosis, you have an increased risk for fractures you might not even know about.

Overview:

What is the femur?

The femur is your thigh bone. It’s the longest, strongest bone in your body. It’s a critical part of your ability to stand and move. Your femur also supports lots of important muscles, tendons, ligaments and parts of your circulatory system.

Because it’s so strong, it usually takes a severe trauma like a fall or car accident to break your femur. If you do experience a fracture, you’ll likely need surgery to repair your bone and physical therapy to help you regain your strength and ability to move.

Your femur, like all bones, can be affected by osteoporosis.

Function:

What does the femur do?

Your femur has several important jobs, including:

* Holding the weight of your body when you stand and move
* Stabilizing you as you move
* Connecting muscles, tendons and ligaments in your hips and knees to the rest of your body

Anatomy:

Where is the femur located?

The femur is the only bone in your thigh. It runs from your hip to your knee.

What does the femur look like?

The femur has two rounded ends and a long shaft in the middle. It’s the classic shape used for bones in cartoons: A cylinder with two round bumps at each end.

Even though it’s one long bone, your femur is made up of several parts. These include:

Femur proximal aspect

The upper (proximal) end of your femur connects to your hip joint. The proximal end (aspect) contains the:

* Head
* Neck
* Greater trochanter
* Lesser trochanter
* Intertrochanteric line and crest

Femur shaft

The shaft is the long portion of the femur that supports your weight and forms the structure of your thigh. It angles slightly toward the center of your body. The shaft of your femur includes the:

* Linea aspera
* Gluteal tuberosity
* Pectineal line
* Popliteal fossa

Femur distal aspect

The lower (distal) end of your femur forms the top of your knee joint. It meets your tibia (shin) and patella (kneecap). It includes the:

* Medial and lateral condyles
* Medial and lateral epicondyles
* Intercondylar fossa

All of these parts and labels are usually more for your healthcare provider to use as they describe where you’re having pain or issues. If you ever break your femur — a femoral fracture — your provider might use some of these terms to describe where your bone was damaged.

How big is the femur?

Your femur is the largest bone in your body. Most adult femurs are around 18 inches long.

The femur is also the strongest bone in your body. It can support as much as 30 times the weight of your body.

Conditions and Disorders:

What are the common conditions and disorders that affect the femur?

The most common issues that affect femurs are fractures, osteoporosis and patellofemoral pain syndrome.

Femur fractures

A bone fracture is the medical term for breaking a bone. Because femurs are so strong, they’re usually only broken by serious injuries like car accidents, falls or other traumas. Symptoms of a fracture include:

* Pain
* Swelling
* Tenderness
* Inability to move your leg like you usually can
* Bruising or discoloration
* A deformity or bump that’s not usually on your body

Go to the emergency room right away if you’ve experienced a trauma or think you have a fracture.

Osteoporosis

Osteoporosis weakens bones, making them more susceptible to sudden and unexpected fractures. Many people don’t know they have osteoporosis until after it causes them to break a bone. There usually aren’t obvious symptoms.

Females and adults older than 50 have an increased risk of developing osteoporosis. Talk to your provider about a bone density screening that can catch osteoporosis before it causes a fracture.

Patellofemoral pain syndrome

Patellofemoral pain syndrome (PFPS) is pain around and under your kneecap (patella). It’s sometimes called runner’s or jumper’s knee. PFPS can be caused by everything from overusing your knees to getting new shoes. Symptoms of PFPS include:

* Pain while bending your knee, including squatting or climbing stairs
* Pain after sitting with your knees bent
* Crackling or popping sounds in your knee when standing up or climbing stairs
* Pain that increases with changes to your usual playing surface, sports equipment or activity intensity

Talk to your provider if you’re experiencing new pain in your knee.

What tests are done on femurs?

The most common test done to check the health of your femur is a bone density test. It’s sometimes called a DEXA or DXA scan. A bone density test measures how strong your bones are with low levels of X-rays. It’s a way to measure bone loss as you age.

If you’ve experienced a femoral fracture your provider or surgeon might need imaging tests, including:

* X-rays
* Magnetic resonance imaging (MRI)
* CT scan

What are common treatments for femurs?

Usually, your femur won’t need treatment unless you’ve experienced a fracture or have been diagnosed with osteoporosis.

Femur fracture treatment

How your fracture is treated depends on which type it is and what caused it. You’ll need some form of immobilization, like a splint or cast, and will probably need surgery to realign (set) your bone to its correct position and secure it in place so it can heal.

Osteoporosis treatment

Treatments for osteoporosis can include exercise, vitamin and mineral supplements and medications.

Exercise and taking supplements are usually all you’ll need to prevent osteoporosis. Your provider will help you develop a treatment plan that’s customized for you and your bone health.

Come Quotes - XXII

1. Nothing else in the world... not all the armies... is so powerful as an idea whose time has come. - Victor Hugo

2. Non-violence, which is the quality of the heart, cannot come by an appeal to the brain. - Mahatma Gandhi

3. When we are born we cry that we are come to this great stage of fools. - William Shakespeare

4. Walk while ye have the light, lest darkness come upon you. - John Ruskin

5. The goal towards which the pleasure principle impels us - of becoming happy - is not attainable: yet we may not - nay, cannot - give up the efforts to come nearer to realization of it by some means or other. - Sigmund Freud

6. When we understand string theory, we will know how the universe began. It won't have much effect on how we live, but it is important to understand where we come from and what we can expect to find as we explore. - Stephen Hawking

7. Let us more and more insist on raising funds of love, of kindness, of understanding, of peace. Money will come if we seek first the Kingdom of God - the rest will be given. - Mother Teresa

8. I balanced all, brought all to mind, the years to come seemed waste of breath, a waste of breath the years behind, in balance with this life, this death. - William Butler Yeats.

Cataract

Gist

A cataract is the gradual clouding of the eye's natural lens, usually caused by aging, which results in hazy vision, light sensitivity, and faded colors. Primarily affecting adults over 60, risks include smoking, diabetes, and UV exposure. Treatment requires a safe, 15-30 minute outpatient surgery to replace the cloudy lens with an artificial one, typically allowing quick recovery.

The main cause of cataracts is aging, as proteins in the eye's lens break down and clump together, causing clouding, but other major factors include long-term UV light exposure, smoking, diabetes, eye injuries, and steroid medication use. These risk factors accelerate the natural aging process, leading to vision becoming hazy or cloudy over time. 

Summary

A cataract is a clouding of the lens of the eye, which is typically clear. For people who have cataracts, seeing through cloudy lenses is like looking through a frosty or fogged-up window. Clouded vision caused by cataracts can make it more difficult to read, drive a car at night or see the expression on a friend's face.

Most cataracts develop slowly and don't disturb eyesight early on. But with time, cataracts will eventually affect vision.

At first, stronger lighting and eyeglasses can help deal with cataracts. But if impaired vision affects usual activities, cataract surgery might be needed. Fortunately, cataract surgery is generally a safe, effective procedure.

Symptoms

Symptoms of cataracts include:

* Clouded, blurred or dim vision.
* Trouble seeing at night.
* Sensitivity to light and glare.
* Need for brighter light for reading and other activities.
* Seeing "halos" around lights.
* Frequent changes in eyeglass or contact lens prescription.
* Fading or yellowing of colors.
* Double vision in one eye.

At first, the cloudiness in your vision caused by a cataract may affect only a small part of the eye's lens. You may not notice any vision loss. As the cataract grows larger, it clouds more of your lens. More clouding changes the light passing through the lens. This may lead to symptoms you notice more.

When to see a doctor

Make an appointment for an eye exam if you notice any changes in your vision. If you develop sudden vision changes, such as double vision or flashes of light, sudden eye pain, or a sudden headache, see a member of your health care team right away.

Details

A cataract is a cloudy area in the lens of the eye that impairs vision. Cataracts often develop slowly and can affect one or both eyes. Symptoms may include faded colours, blurry or double vision, halos around light, trouble with bright lights, and difficulty seeing at night. This may result in difficulty driving, reading and recognizing faces. Poor vision caused by cataracts may also result in an increased risk of falling and depression. In 2020 Cataracts caused 39.6% of all cases of blindness and 28.3% of visual impairment worldwide. Cataracts remain the single most common cause of global blindness.

Cataracts are most commonly due to aging but may also be due to trauma or radiation exposure, be present from birth or occur following eye surgery for other problems. Risk factors include diabetes, longstanding use of corticosteroid medication, smoking tobacco, prolonged exposure to sunlight and alcohol. In addition, poor nutrition, obesity, chronic kidney disease and autoimmune diseases have been recognized in various studies as contributing to the development of cataracts. Cataract formation is primarily driven by oxidative stress, which damages lens proteins, leading to their aggregation and the accumulation of clumps of protein or yellow-brown pigment in the lens. This reduces the transmission of light to the retina at the back of the eye, impairing vision. Additionally, alterations in the lens's metabolic processes, including imbalances in calcium and other ions, contribute to cataract development. Diagnosis is typically through an eye examination, with ophthalmoscopy and slit-lamp examination being the most effective methods. During ophthalmoscopy the pupil is dilated and the red reflex is examined for any opacities in the lens. Slit-lamp examination provides further details on the characteristics, location and extent of the cataract.

Wearing sunglasses with UV protection and a wide brimmed hat, eating leafy vegetables and fruits and avoiding smoking may reduce the risk of developing cataracts or slow the process. Early on, the symptoms may be improved with glasses. If this does not help, surgery to remove the cloudy lens and replace it with an artificial lens is the only effective treatment. Cataract surgery is not readily available in many countries, and surgery is needed only if the cataracts are causing problems and generally results in an improved quality of life.

About 20 million people worldwide are blind owing to cataracts. They are the cause of approximately 5% of blindness in the United States and nearly 60% of blindness in parts of Africa and South America. Blindness from cataracts occurs in 10 to 40 per 100,000 children in the developing world and 1 to 4 per 100,000 children in the developed world. Cataracts become more common with age. In the United States, cataracts occur in 68% of those over the age of 80 years. They are more common in women and less common in Hispanic and Black people.

Additional Information

A cataract is a cloudy or opaque area in the normally clear lens of the eye. Depending upon its size and location, it can interfere with normal vision.

Most cataracts develop in people over age 55, but they occasionally occur in infants and young children or as a result of trauma or medications. Usually, cataracts develop in both eyes, but one may be worse than the other.

The lens is located inside the eye behind the iris, the colored part of the eye. Normally, the lens focuses light on the retina, which sends the image through the optic nerve to the brain. However, if the lens is clouded by a cataract, light is scattered so the lens can no longer focus it properly, causing vision problems. The lens is made of mostly proteins and water. The clouding of the lens occurs due to changes in the proteins and lens fibers.

Types of cataracts

The lens is composed of layers, like an onion. The outermost is the capsule. The layer inside the capsule is the cortex, and the innermost layer is the nucleus. A cataract may develop in any of these areas. Cataracts are named for their location in the lens:

* A nuclear cataract is located in the center of the lens. The nucleus tends to darken with age, changing from clear to yellow and sometimes brown.
* A cortical cataract affects the layer of the lens surrounding the nucleus. The cataract looks like a wedge or a spoke.
* A posterior capsular cataract is found in the back outer layer of the lens. This type often develops more rapidly.

Causes & risk factors

Most cataracts are due to age-related changes in the lens of the eye that cause it to become cloudy or opaque. However, other factors can contribute to cataract development, including:

* Diabetes mellitus. People with diabetes are at higher risk for cataracts.
* Drugs. Certain medications are associated with cataract development. These include:
** Corticosteroids.
** Chlorpromazine and other phenothiazine related medications.
* Ultraviolet radiation. Studies show an increased chance of cataract formation with unprotected exposure to ultraviolet (UV) radiation.
* Smoking. There is possibly an association between smoking and increased lens cloudiness.
* Alcohol. Several studies show increased cataract formation in patients with higher alcohol consumption compared with people who have lower or no alcohol consumption.
* Nutritional deficiency. Although the results are inconclusive, studies suggest an association between cataract formation and low levels of antioxidants (for example, vitamin C, vitamin E, and carotenoids). Further studies may show that antioxidants can help decrease cataract development.
* Family History. If a close relative has had cataracts, there is a higher chance of developing a cataract.

Rarely, cataracts are present at birth or develop shortly after. They may be inherited or develop due to an infection (such as rubella) in the mother during pregnancy. A cataract may also develop following an eye injury or surgery for another eye problem, such as glaucoma.

Symptoms

Cataracts generally form very slowly. Signs and symptoms of a cataract may include:

* Blurred or hazy vision.
* Reduced-intensity of colors.
* Increased sensitivity to glare from lights, particularly when driving at night.
* Increased difficulty seeing at night.
* Change in the eye's refractive error, or eyeglass prescription.

Diagnosis

Cataracts are diagnosed through a comprehensive eye examination. This examination may include:

* Patient history to determine if vision difficulties are limiting daily activities and other general health concerns affecting vision.
* Visual acuity measurement to determine to what extent a cataract may be limiting clear distance and near vision.
* Refraction to determine the need for changes in an eyeglass or contact lens prescription.
* Evaluation of the lens under high magnification and illumination to determine the extent and location of any cataracts.
* Evaluation of the retina of the eye through a dilated pupil.
* Measurement of pressure within the eye.
* Supplemental testing for color vision and glare sensitivity.

Further testing may be needed to determine how much the cataract is affecting vision and to evaluate whether other eye diseases may limit vision following cataract surgery.

Using the information from these tests, your doctor of optometry can determine if you have cataracts and advise you on your treatment options.

Treatment

Cataract treatment is based on the level of visual impairment they cause. If a cataract minimally affects vision, or not at all, no treatment may be needed. Patients may be advised to monitor for increased visual symptoms and follow a regular check-up schedule.

In some cases, changing the eyeglass prescription may provide temporary vision improvement. In addition, anti-glare coatings on eyeglass lenses can help reduce glare for night driving. Increasing the amount of light used when reading may be beneficial.

When a cataract progresses to the point that it affects a person's ability to do normal everyday tasks, surgery may be needed. Cataract surgery involves removing the lens of the eye and replacing it with an artificial lens. The artificial lens requires no care and can significantly improve vision. Some artificial lenses have the natural focusing ability of a young healthy lens. Once a cataract is removed, it cannot grow back.

Two approaches to cataract surgery are generally used:

* Small-incision cataract surgery involves making an incision in the side of the cornea (the clear outer covering of the eye) and inserting a tiny probe into the eye. The probe emits ultrasound waves that soften and break up the lens so it can be suctioned out. This process is called phacoemulsification.
* Extracapsular surgery requires a somewhat larger incision in the cornea so that the lens core can be removed in one piece. The natural lens is replaced by a clear plastic lens called an intraocular lens (IOL). When implanting an IOL is not possible because of other eye problems, contact lenses and, in some cases, eyeglasses may be an option for vision correction.

As with any surgery, cataract surgery has risks from infection and bleeding. Cataract surgery also slightly increases the risk of retinal detachment. It is important to discuss the benefits and risks of cataract surgery with your eye care providers. Other eye conditions may increase the need for cataract surgery or prevent a person from being a cataract surgery candidate.

Cataract surgery is one of the safest and most effective types of surgery performed in the United States today. Approximately 90% of cataract surgery patients report better vision following the surgery.

Prevention

There is no treatment to prevent or slow cataract progression. In age-related cataracts, changes in vision can be very gradual. Some people may not initially recognize the visual changes. However, as cataracts worsen, vision symptoms increase.

While there are no clinically proven approaches to preventing cataracts, simple preventive strategies include:

* Reducing exposure to sunlight through UV-blocking lenses.
* Decreasing or stopping smoking.
* Increasing antioxidant vitamin consumption by eating more leafy green vegetables and taking nutritional supplements.

Researchers have linked eye-friendly nutrients such as lutein and zeaxanthin, vitamin C, vitamin E and zinc to reducing the risk of certain eye diseases, including cataracts. For more information on the importance of good nutrition and eye health, please see the diet and nutrition section.

Come Quotes - XXI

1. When we look back on all the perils through which we have passed and at the mighty foes that we have laid low and all the dark and deadly designs that we have frustrated, why should we fear for our future? We have come safely through the worst. - Winston Churchill

2. Whether you come from a council estate or a country estate, your success will be determined by your own confidence and fortitude. - Michelle Obama

3. The smaller the planets are, they are, other things being equal, of so much the greater density; for so the powers of gravity on their several surfaces come nearer to equality. They are likewise, other things being equal, of the greater density, as they are nearer to the sun. - Isaac Newton

4. If you want to cut your own throat, don't come to me for a bandage. - Margaret Thatcher

5. I've been here before and will come again, but I'm not going this trip through. - Bob Marley

6. I perhaps ought to say that individually I never was much interested in the Texas question. I never could see much good to come of annexation, inasmuch as they were already a free republican people on our own model. - Abraham Lincoln

7. This is the moment when we must come together to save this planet. Let us resolve that we will not leave our children a world where the oceans rise and famine spreads and terrible storms devastate our lands. - Barack Obama

8. We will burn that bridge when we come to it. - Johann Wolfgang von Goethe.