Medicine and Surgery - Anatomy (2026)

15/11/2023

Treasure your Health to secure the future you dream about... A compromised health is a failed dream (Dream Big and Treasure Your Health).

14/02/2023

Keep spreading Love wherever you find yourself. To love is what you must do. Know this, it is not Love when it's centered on self and lust. Genuine Love is Unconditional ❤❤❤

As you are celebrating today, Please don't forget to prioritize your health. Remember, Health is Wealth.

Wishing you a happy Valentine's Day 💝

18/01/2023

This is a group I can vouch for, I followed their old page for a while and I bet they are good at what they do...
Many of you have contacted me concerning your difficulties in choosing a career. Trust me, you will learn a lot from these great minds... I contacted them and they allow me to introduce them to you. They are 'Amazing Crew Tv'.

They will be having a timely Educational Program on Sunday 22nd January 2023, with the topic "Career Choice in Education".
Follow their new page, I promise you won't regret it. The link is below 👇

https://www.facebook.com/Amazingcrewtv/

I would be glad if you give them a trial 🤔

19/12/2022

CANCER AND AGE

Cancer is to a great degree a disease of the elderly, and age is thus a very important factor in cancer development. However, individuals of any age, including very young children, can be stricken with the disease. In many developed countries cancer deaths in children are second only to accidental deaths.

In the United States the most-striking increase in cancer mortality is seen in persons between the ages of 55 and 75. A decline in cancer mortality in persons older than 75 simply reflects the lower number of persons in that population.

DEATH RATES

Age-adjusted death rates (deaths per 100,000 population) for specific types of tumours have changed significantly over the years. In 1996, for the first time since data began being compiled, cancer deaths in the United States decreased (almost 3 percent), and the declines continued through the first decade of the 21st century. Worldwide, however, death rates from cancer were on the rise. The World Health Organization (WHO) projected that 13.1 million people globally would die from cancer in 2030.

In the United States and certain other developed countries, decreases in death rates from cancer can be attributed to successes of therapy or prevention. For example, a reduction in the number of deaths due to lung cancer has been attributed to warnings that have altered cigarette-smoking habits. Therapy has greatly lessened mortality from Hodgkin disease and testicular cancer, and it also has improved the chances of surviving breast cancer. Preventive measures have played a major role in the decrease of cancer mortality as well. For example, colonoscopy, which is used to detect early asymptomatic cancers or premalignant growths (polyps) in the colon, has contributed to declines in death rates from colon cancer. Routine Pap smear, an examination used to screen for carcinoma of the uterine cervix, has resulted in a downward trend in mortality observed for that disease. The identification of certain types of HPV as the causal agents of cervical cancer has improved cervical-cancer-screening programs by enabling samples obtained from asymptomatic women to be tested for the presence of harmful viral types that could later give rise to cancer. The effectiveness of preventative measures for cervical cancer is thought to have been greatly increased by the availability of HPV vaccines such as Gardasil, which was approved for the immunization of young girls and boys prior to their becoming sexually active.

26/07/2022

CANCER (Continued)

SYMPTOMS

Signs and symptoms caused by cancer will vary depending on what part of the body is affected.
Some general signs and symptoms associated with, but not specific to, cancer, include:

* Fatigue

* Lump or area of thickening that can be felt under the skin

* Weight changes, including unintended loss or gain

* Skin changes, such as yellowing, darkening or redness of the skin, sores that won't heal, or changes to existing moles

* Changes in bowel or bladder habits

* Persistent cough or trouble breathing

* Difficulty swallowing

* Hoarseness

* Persistent indigestion or discomfort after eating

* Persistent, unexplained muscle or joint pain

* Persistent, unexplained fevers or night sweats

* Unexplained bleeding or bruising

WHEN TO SEE A DOCTOR

Make an appointment with your doctor if you have any persistent signs or symptoms that concern you.
If you don't have any signs or symptoms, but are worried about your risk of cancer, discuss your concerns with your doctor. Ask about which cancer screening tests and procedures are appropriate for you.

TO BE CONTINUED...

29/05/2022

CANCER

Cancer, group of more than 100 distinct diseases characterized by the uncontrolled growth of abnormal cells in the body.

Though cancer has been known since antiquity, some of the most significant advances in scientists’ understanding of it have been made since the middle of the 20th century. Those advances led to major improvements in cancer treatment, mainly through the development of methods for timely and accurate diagnosis, selective surgery, radiation therapy, chemotherapeutic drugs, and targeted therapies (agents designed against specific molecules involved in cancer).

Advances in treatment have succeeded in bringing about a decrease in cancer deaths, though mainly in developed countries. Indeed, cancer remains a major cause of sickness and death throughout the world. By 2018 the number of new cases diagnosed annually had risen to more than 18 million, more than half of them in less-developed countries, and the number of deaths from cancer in 2018 was 9.6 million worldwide. About 70 percent of cancer deaths were in low- and middle-income countries.

The World Health Organization (WHO) has estimated that the global cancer burden could be reduced by as much as 30 to 50 percent through prevention strategies, particularly through the avoidance of known risk factors. In addition, laboratory investigations aimed at understanding the causes and mechanisms of cancer have maintained optimism that the disease can be controlled. Through breakthroughs in cell biology, genetics, and biotechnology, researchers have gained a fundamental understanding of what occurs within cells to cause them to become cancerous.
Those conceptual gains are steadily being converted into actual gains in the practice of cancer diagnosis and treatment, with notable progress toward personalized cancer medicine, in which therapy is tailored to individuals according to biological anomalies unique to their disease.

TO BE CONTINUED!!!
(Stay Connected: As we educate you about Cancer)

03/12/2021

PLATELETS (THROMBOCYTES)

The blood platelets are the smallest cells of the blood, averaging about 2 to 4 μm in diameter. Although much more numerous (150,000 to 400,000 per cubic millimetre) than the white cells, they occupy a much smaller fraction of the volume of the blood because of their relatively minute size. Like the red cells, they lack a nucleus and are incapable of cell division (mitosis), but they have a more complex metabolism and internal structure than the red cells. When seen in fresh blood they appear spheroid, but they have a tendency to extrude hairlike filaments from their membranes. They adhere to each other but not to red cells and white cells. Tiny granules within platelets contain substances important for the clot-promoting activity of platelets.

The function of the platelets is related to hemostasis, the prevention and control of bleeding. When the endothelial surface (lining) of a blood vessel is injured, platelets in large numbers immediately attach to the injured surface and to each other, forming a tenaciously adherent mass of platelets. The effect of the platelet response is to stop the bleeding and to form the site of the developing blood clot, or thrombus. If platelets are absent, this important defense reaction cannot occur, and protracted bleeding from small wounds (prolonged bleeding time) results. The normal resistance of capillary membranes to leakage of red cells is dependent upon platelets. Severe deficiency of platelets reduces the resistance of the capillary walls, and abnormal bleeding from the capillaries occurs, either spontaneously or as the result of minor injury. Platelets also contribute substances essential for the normal coagulation of the blood, and they cause the shrinking, or retraction, of a clot after it has been formed.

Platelets are formed in the bone marrow by segmentation of the cytoplasm (the cell substance other than the nucleus) of cells known as megakaryocytes, the largest cells of the marrow. Within the marrow the abundant granular cytoplasm of the megakaryocyte divides into many small segments that break off and are released as platelets into the circulating blood. After about 10 days in the circulation, platelets are removed and destroyed. There are no reserve stores of platelets except in the spleen, in which platelets occur in higher concentration than in the peripheral blood. Some platelets are consumed in exerting their hemostatic effects, and others, reaching the end of their life span, are removed by reticuloendothelial cells (any of the tissue phagocytes). The rate of platelet production is controlled but not so precisely as the control of red cell production. A hormonelike substance called thrombopoietin is believed to be the chemical mediator that regulates the number of platelets in the blood by stimulating an increase in the number and growth of megakaryocytes, thus controlling the rate of platelet production.

03/09/2021

WHITE BLOOD CELLS
*Types and functions*

03/09/2021

WHITE BLOOD CELLS (LEUKOCYTES)

White blood cells (leukocytes), unlike red cells, are nucleated and independently motile. Highly differentiated for their specialized functions, they do not undergo cell division (mitosis) in the bloodstream, but some retain the capability of mitosis. As a group they are involved in the body’s defense mechanisms and reparative activity.

The number of white cells in normal blood ranges between 4,500 and 11,000 per cubic millimetre. Fluctuations occur during the day; lower values are obtained during rest and higher values during exercise. Intense physical exertion may cause the count to exceed 20,000 per cubic millimetre. Most of the white cells are outside the circulation, and the few in the bloodstream are in transit from one site to another. As living cells, their survival depends on their continuous production of energy. The chemical pathways utilized are more complex than those of the red cells and are similar to those of other tissue cells. White cells, containing a nucleus and able to produce ribonucleic acid (RNA), can synthesize protein. They comprise three classes of cells, each unique as to structure and function, that are designated granulocytes, monocytes, and lymphocytes.

GRANULOCYTES
Granulocytes, the most numerous of the white cells, are larger than red cells (approximately 12–15 μm in diameter). They have a multilobed nucleus and contain large numbers of cytoplasmic granules (i.e., granules in the cell substance outside the nucleus). Granulocytes are important mediators of the inflammatory response. There are three types of granulocytes: neutrophils, eosinophils, and basophils. Each type of granulocyte is identified by the colour of the granules when the cells are stained with a compound dye. The granules of the neutrophil are pink, those of the eosinophil are red, and those of the basophil are blue-black. About 50 to 80 percent of the white cells are neutrophils, while the eosinophils and basophils together constitute no more than 3 percent.

NEUTROPHILS
The neutrophils are fairly uniform in size with a diameter between 12 and 15 μm. The nucleus consists of two to five lobes joined together by hairlike filaments. Neutrophils move with amoeboid motion. They extend long projections called pseudopodium into which their granules flow; this action is followed by contraction of filaments based in the cytoplasm, which draws the nucleus and rear of the cell forward. In this way neutrophils rapidly advance along a surface. The bone marrow of a normal adult produces about 100 billion neutrophils daily. It takes about one week to form a mature neutrophil from a precursor cell in the marrow; yet, once in the blood, the mature cells live only a few hours or perhaps a little longer after migrating to the tissues. To guard against rapid depletion of the short-lived neutrophils (for example, during infection), the bone marrow holds a large number of them in reserve to be mobilized in response to inflammation or infection. Within the body, the neutrophils migrate to areas of infection or tissue injury. The force of attraction that determines the direction in which neutrophils will move is known as chemotaxis and is attributed to substances liberated at sites of tissue damage. Of the 100 billion neutrophils circulating outside the bone marrow, half are in the tissues and half are in the blood vessels. Of those in the blood vessels, half are within the mainstream of rapidly circulating blood, and the other half move slowly along the inner walls of the blood vessels (marginal pool), ready to enter tissues on receiving a chemotactic signal from them.

Neutrophils are actively phagocytic; they engulf bacteria and other microorganisms and microscopic particles. The granules of the neutrophil are microscopic packets of potent enzymes capable of digesting many types of cellular materials. When a bacterium is engulfed by a neutrophil, it is encased in a vacuole lined by the invaginated membrane. The granules discharge their contents into the vacuole containing the organism. As this occurs, the granules of the neutrophil are depleted (degranulation). A metabolic process within the granules produces hydrogen peroxide and a highly active form of oxygen (superoxide), which destroy the ingested bacteria. Final digestion of the invading organism is accomplished by enzymes.

EOSINOPHILS
Eosinophils, like other granulocytes, are produced in the bone marrow until they are released into the circulation. Although about the same size as neutrophils, the eosinophil contains larger granules, and the chromatin is generally concentrated in only two nonsegmented lobes. Eosinophils leave the circulation within hours of release from the marrow and migrate into the tissues (usually those of the skin, lung, and respiratory tract) through the lymphatic channels. Like neutrophils, eosinophils respond to chemotactic signals released at the site of cell destruction. They are actively motile and phagocytic. Eosinophils are involved in defense against parasites, and they participate in hypersensitivity and inflammatory reactions, primarily by dampening their destructive effects.

BASOPHILS
Basophils are the least numerous of the granulocytes, and their large granules almost completely obscure the underlying double-lobed nucleus. Within hours of their release from the bone marrow, basophils migrate from the circulation to the barrier tissues (e.g., the skin and mucosa), where they synthesize and store histamine, a natural modulator of the inflammatory response. When aggravated, basophils release, along with histamine and other substances, leukotrienes, which cause bronchoconstriction during anaphylaxis (a hypersensitivity reaction). Basophils incite immediate hypersensitivity reactions in association with platelets, macrophages, and neutrophils.

MONOCYTES
Monocytes are the largest cells of the blood (averaging 15–18 μm in diameter), and they make up about 7 percent of the leukocytes. The nucleus is relatively big and tends to be indented or folded rather than multilobed. The cytoplasm contains large numbers of fine granules, which often appear to be more numerous near the cell membrane. Monocytes are actively motile and phagocytic. They are capable of ingesting infectious agents as well as red cells and other large particles, but they cannot replace the function of the neutrophils in the removal and destruction of bacteria. Monocytes usually enter areas of inflamed tissue later than the granulocytes. Often they are found at sites of chronic infections.

In the bone marrow, granulocytes and monocytes arise from a common precursor under the influence of the granulocyte-macrophage colony-stimulating factor. Monocytes leave the bone marrow and circulate in the blood. After a period of hours, the monocytes enter the tissues, where they develop into macrophages, the tissue phagocytes that constitute the reticuloendothelial system (or macrophage system). Macrophages occur in almost all tissues of the body. Those in the liver are called Kupffer cells, those in the skin Langerhans cells. Apart from their role as scavengers, macrophages play a key role in immunity by ingesting antigens and processing them so that they can be recognized as foreign substances by lymphocytes.

LYMPHOCYTES
Lymphocytes constitute about 28–42 percent of the white cells of the blood, and they are part of the immune response to foreign substances in the body. Most lymphocytes are small, only slightly larger than erythrocytes, with a nucleus that occupies most of the cell. Some are larger and have more abundant cytoplasm that contains a few granules. Lymphocytes are sluggishly motile, and their paths of migration outside of the bloodstream are different from those of granulocytes and monocytes. Lymphocytes are found in large numbers in the lymph nodes, spleen, thymus, tonsils, and lymphoid tissue of the gastrointestinal tract. They enter the circulation through lymphatic channels that drain principally into the thoracic lymph duct, which has a connection with the venous system. Unlike other blood cells, some lymphocytes may leave and reenter the circulation, surviving for about one year or more. The principal paths of recirculating lymphocytes are through the spleen or lymph nodes. Lymphocytes freely leave the blood to enter lymphoid tissue, passing barriers that prevent the passage of other blood cells. When stimulated by antigen and certain other agents, some lymphocytes are activated and become capable of cell division (mitosis).

The lymphocytes regulate or participate in the acquired immunity to foreign cells and antigens. They are responsible for immunologic reactions to invading organisms, foreign cells such as those of a transplanted organ, and foreign proteins and other antigens not necessarily derived from living cells. The two classes of lymphocytes are not distinguished by the usual microscopic examination but rather by the type of immune response they elicit. The B lymphocytes (or B cells) are involved in what is called humoral immunity. Upon encountering a foreign substance (or antigen), the B lymphocyte differentiates into a plasma cell, which secretes immunoglobulin (antibodies). The second class of lymphocytes, the T lymphocytes (or T cells), are involved in regulating the antibody-forming function of B lymphocytes as well as in directly attacking foreign antigens. T lymphocytes participate in what is called the cell-mediated immune response. T lymphocytes also participate in the rejection of transplanted tissues and in certain types of allergic reactions.

All lymphocytes begin their development in the bone marrow. The B lymphocytes mature partly in the bone marrow until they are released into the circulation. Further differentiation of B lymphocytes occurs in lymphoid tissues (spleen or lymph nodes), most notably on stimulation by a foreign antigen. The precursors of the T lymphocytes migrate from the marrow to the thymus, where they differentiate under the influence of a hormonelike substance. (The thymus is a small organ lying just behind the breastbone in the upper portion of the chest. It is relatively large at birth, begins to regress after puberty, and may be represented only by a fibrous cord in the elderly. The thymus begins to exert its effects on the differentiation of lymphocytes before birth. The removal of the thymus from certain animals at birth prevents the normal development of immunologic responses.) Once they have matured, the T lymphocytes leave the thymus and circulate through the blood to the lymph nodes and the spleen. The two classes of lymphocytes originally derived their names from investigations in birds, in which it was found that differentiation of one class of lymphocyte was influenced by the bursa of Fabricius (an outpouching of the gastrointestinal tract) and thus was called the B lymphocytes, and the other was influenced by the thymus and was called the T lymphocytes.

A primary function of lymphocytes is to protect the body from foreign microbes. This essential task is carried out by both T lymphocytes and B lymphocytes, which often act in concert. The T lymphocytes can recognize and respond only to antigens that appear on cell membranes in association with other molecules called major histocompatibility complex (MHC) antigens. The latter are glycoproteins that present the antigen in a form that can be recognized by T lymphocytes. In effect, T lymphocytes are responsible for continuous surveillance of cell surfaces for the presence of foreign antigens. By contrast, the antibodies produced by B lymphocytes are not confined to recognizing antigens on cell membranes; they can bind to soluble antigens in the blood or in extravascular fluids. T lymphocytes typically recognize antigens of infectious organisms that must pe*****te cells in order to multiply, such as viruses. During their intracellular life cycle, viruses produce antigens that appear on the cell membrane. Two classes of T lymphocytes can be involved in the response to those cell-associated viral antigens: cytotoxic T lymphocytes, which destroy the cells by a lytic mechanism, and helper T lymphocytes, which assist B cells to produce antibodies against the microbial antigens. Helper T lymphocytes exert their influence on B lymphocytes through several hormonelike peptides termed interleukins (IL). Five different T lymphocyte interleukins (IL-2, IL-3, IL-4, IL-5, and IL-6) have been discovered, each with different (and sometimes overlapping) effects on B lymphocytes and other blood cells. Interleukin-1, produced by macrophages, is a peptide that stimulates T lymphocytes and that also acts on the hypothalamus in the brain to produce fever. The ability to develop an immune response (i.e., the T cell-mediated and humoral immune responses) to foreign substances is called immunologic competence (immunocompetence). Immunologic competence, which begins to develop during embryonic life, is incomplete at the time of birth but is fully established soon after birth. If an antigen is introduced into a person’s body before immunologic competence has been established, an immune response will not result upon reinfection, and that person is said to be tolerant to that antigen.

Study of immunologic competence and immune tolerance has been accelerated by interest in organ transplantation. The success rates of organ transplantations have been improved by better knowledge about donor selection and improved techniques for suppressing the immune responses of the recipient. An important element in donor selection is tissue typing: the matching of the donor’s histocompatibility antigens (human leukocyte antigens) with those of the prospective recipient. The closer the match, the greater the probability that the graft will be accepted.

02/08/2021

RED BLOOD CELLS (Erythrocytes)

The red blood cells are highly specialized, well adapted for their primary function of transporting oxygen from the lungs to all of the body tissues. Red cells are approximately 7.8 μm (1 μm = 0.000039 inch) in diameter and have the form of biconcave disks, a shape that provides a large surface-to-volume ratio. When fresh blood is examined with the microscope, red cells appear to be yellow-green disks with pale centres containing no visible internal structures. When blood is centrifuged to cause the cells to settle, the volume of packed red cells (hematocrit value) ranges between 42 and 54 percent of total volume in men and between 37 and 47 percent in women; values are somewhat lower in children. Normal red blood cells are fairly uniform in volume, so that the hematocrit value is determined largely by the number of red cells per unit of blood. The normal red cell count ranges between four million and six million per cubic millimetre.

The red blood cell is enclosed in a thin membrane that is composed of chemically complex lipids, proteins, and carbohydrates in a highly organized structure. Extraordinary distortion of the red cell occurs in its passage through minute blood vessels, many of which have a diameter less than that of the red cell. When the deforming stress is removed, the cell springs back to its original shape. The red cell readily tolerates bending and folding, but, if appreciable stretching of the membrane occurs, the cell is damaged or destroyed. The membrane is freely permeable to water, oxygen, carbon dioxide, glucose, urea, and certain other substances, but it is impermeable to hemoglobin. Within the cell the major cation is potassium; in contrast, in plasma and extracellular fluids the major cation is sodium. A pumping mechanism, driven by enzymes within the red cell, maintains its sodium and potassium concentrations. Red cells are subject to osmotic effects. When they are suspended in very dilute (hypotonic) solutions of sodium chloride, red cells take in water, which causes them to increase in volume and to become more spheroid; in concentrated salt solutions they lose water and shrink.

When red cell membranes are damaged, hemoglobin and other dissolved contents may escape from the cells, leaving the membranous structures as “ghosts.” This process, called Hemolysis, is produced not only by the osmotic effects of water but also by numerous other mechanisms. These include physical damage to red cells, as when blood is heated, is forced under great pressure through a small needle, or is subjected to freezing and thawing; chemical damage to red cells by agents such as bile salts, detergents, and certain snake venoms; and damage caused by immunologic reactions that may occur when antibodies attach to red cells in the presence of complement. When such destruction proceeds at a greater than normal rate, hemolytic anemia results.

The membrane of the red cell has on its surface a group of molecules that confer blood group specificity (i.e., that differentiate blood cells into groups). Most blood group substances are composed of carbohydrate linked to protein, and it is usually the chemical structure of the carbohydrate portion that determines the specific blood type. Blood group substances are antigens capable of inducing the production of antibodies when injected into persons lacking the antigen. Detection and recognition of the blood group antigens are accomplished by the use of blood serum containing these antibodies. The large number of different red cell antigens makes it extremely unlikely that persons other than identical twins will have the same array of blood group substances.

11/07/2021

Your sight is one of your most valuable assets. Because maintaining the health of your eyes is so important.
Here are few most common issues people experience with their eyes. If any of these apply to you, please see an ophthalmologist as soon as possible before the condition threatens your eyesight.

1. Cataracts
Characterized by a cloudy, milky white lens in the eye, most cataracts are age-related and more common in people over 50 (but can develop at any age). Cataracts can be the result of injury, UV exposure, or protein deterioration over time; this is what causes the eye’s lens to cloud. If left untreated, cataracts can ultimately cause severe vision loss.

** Treatment: Fortunately, cataracts are common eye problem that can be treated through surgery. Whether surgery is needed depends on the degree of vision loss and whether it affects your quality of life and ability to function.

2. Keratoconus
Normally, the cornea (the clear outer lens of the eye) has a dome shape, like a ball. Sometimes, however, the collagen which holds the cornea in place becomes weak, causing the cornea to become cone shaped. This condition is called keratoconus. This can cause serious loss of vision if not treated early and quickly. Left untreated, many people will need a cornea transplant.

** Treatment: Treatment usually starts with eyeglasses. Contact lenses, usually rigid gas permeable ones, may be recommended to strengthen the cornea and improve vision. In addition, cornea collagen crosslinking is often effective to help prevent progression, as well as intacs (implants placed under the surface of the cornea to reduce the cone shape and improve vision). A last resort is a cornea transplant.

3. Diabetic Retinopathy
Diabetic retinopathy occurs as a result of prolonged high blood sugar associated with types 1 and 2 diabetes and can cause blindness if left untreated. Too much blood sugar can alter the blood vessels in the back of the eye, preventing the retina from receiving the proper amount of nutrients it needs to maintain vision. Anyone with diabetes type 1 or type 2 is at risk of developing diabetic retinopathy. However, the type of diabetes a person has, how often their blood glucose fluctuates, how well they control their sugars, and how long they have had diabetes all affects his/her risk.

** Treatment: In most cases, laser surgery can prevent significant vision loss associated with diabetic retinopathy. A procedure called laser photocoagulation can seal or destroy growing or leaking blood vessels in the retina.

4. Macular Degeneration
This leading cause of blindness is characterized by damage to the macula, the area of the retina that perceives light. Risk factors include: age, smoking, female gender and family history. Unfortunately, there is no known cure for macular degeneration. However, current treatments can slow the progression of the disease.

** Treatment: Age-related macular degeneration treatments may prevent severe vision loss or slow the progression of the disease considerably. Several treatment options are available, including:

Anti-angiogenic drugs. Injected into the eye, these medications block the development of new blood vessels and leakage from the abnormal vessels within the eye.
Laser therapy. High-energy laser light can sometimes be used to destroy actively growing abnormal blood vessels.
Photodynamic laser therapy. A two-step treatment in which a light-sensitive drug is used to damage the abnormal blood vessels. A medication is injected into the bloodstream to be absorbed by the abnormal blood vessels in the eye. A cold laser is then shone into the eye to activate the drug, damaging the abnormal blood vessels.
Vitamins C, E, beta-carotene, zinc and copper can decrease the risk of vision loss in certain patients with intermediate to advanced dry age-related macular degeneration.

5. Refractive Errors
According to the National Eye Institute, refractive errors are the most common cause of vision problems. Refraction in the eye occurs when light passes through the cornea and the lens. Errors can occur as a result of the length of the eyeball, changes in the shape of the cornea or natural aging of the lens. Nearsightedness, farsightedness and astigmatism are categorized by refractive errors.

** Treatment: The most common forms of treatment are eyeglasses, contact lenses and surgery.

6. Glaucoma
Glaucoma is a condition that causes damage to the eye’s optic nerve and worsens over time. Associated with a buildup of pressure inside the eye, glaucoma tends to be inherited and may not show up until later in life. The increased pressure, called intraocular pressure, can damage the optic nerve, which transmits images to the brain. If damage to the optic nerve from high eye pressure continues, glaucoma will cause permanent loss of vision. Because most people with glaucoma have no early symptoms or pain from this increased pressure, it is important to see your eye doctor regularly so that glaucoma can be diagnosed and treated before long-term visual loss occurs.

** Treatment: Once detected, glaucoma can be treated with either surgery, lasers or eye drops.

7. Presbyopia
Presbyopia is the loss of the ability to clearly see close objects or small print. Part of the natural aging process of the eye, presbyopia is often confused with farsightedness but the two are not the same. Presbyopia occurs when the natural lens in the eye loses flexibility, while farsightedness occurs as a result of the natural shape of the eyeball, which causes light rays to bend incorrectly once they have entered the eye.

** Treatment: Treatment options include wearing corrective lenses, undergoing refractive surgery or getting lens implants.

8. Floaters
Common among people over 50, floaters are tiny spots or specks that float across the field of vision. Formed by a deposit of protein drifting about in the vitreous (the clear, jelly-like substance that fills the middle of the eye), floaters seem to drift in front of the eye but do not block vision. Usually benign, floaters sometimes can indicate a more serious eye problem such as retinal detachment, especially if they are accompanied by light flashes. If you notice a sudden change in the type or number of spots or flashes you see, visit your eye doctor as soon as possible.

9. Dry eyes
The condition known as “dry eyes” happens when tear glands cannot make enough tears or produce poor quality tears. Dry eyes can be uncomfortable, causing itching, burning and in rare cases, some loss of vision.

** Treatment: Your eye doctor may suggest using a humidifier in your home, special eye drops that simulate real tears, or plugs placed in tear ducts to decrease tear drainage.

10. Tearing
If your eyes produce too many tears, this may indicate that your eyes are particularly sensitive to light, wind or temperature changes. Protecting your eyes by shielding them or wearing sunglasses can sometimes solve the problem. Tearing may also mean that you have a more serious problem, such as an eye infection or a blocked tear duct. Your eye doctor can treat or correct both of these conditions.

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Medicine and Surgery - Anatomy

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