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856) Frederick Sanger

Frederick Sanger, (born August 13, 1918, Rendcombe, Gloucestershire, England—died November 19, 2013, Cambridge), English biochemist who was twice the recipient of the Nobel Prize for Chemistry. He was awarded the prize in 1958 for his determination of the structure of the insulin molecule. He shared the prize (with Paul Berg and Walter Gilbert) in 1980 for his determination of base sequences in nucleic acids. Sanger was the fourth two-time recipient of the Nobel Prize.

Education

Sanger was the middle child of Frederick Sanger, a medical practitioner, and Cicely Crewsdon Sanger, the daughter of a wealthy cotton manufacturer. The family expected him to follow in his father’s footsteps and become a medical doctor. After much thought, he decided to become a scientist. In 1936 Sanger entered St. John’s College, Cambridge. He initially concentrated on chemistry and physics, but he was later attracted to the new field of biochemistry. He received a bachelor’s degree in 1939 and stayed at Cambridge an additional year to take an advanced course in biochemistry. He and Joan Howe married in 1940 and subsequently had three children.

Because of his Quaker upbringing, Sanger was a conscientious objector and was assigned as an orderly to a hospital near Bristol when World War II began. He soon decided to visit Cambridge to see if he could enter the doctoral program in biochemistry. Several researchers there were interested in having a student, especially one who did not need money. He studied lysine metabolism with biochemist Albert Neuberger. They also had a project in support of the war effort, analyzing nitrogen from potatoes. Sanger received a doctorate in 1943.

Insulin Research

Biochemist Albert C. Chibnall and his protein research group moved from Imperial College in London to the safer wartime environment of the biochemistry department at Cambridge. Two schools of thought existed among protein researchers at the time. One group thought proteins were complex mixtures that would not readily lend themselves to chemical analysis. Chibnall was in the other group, which considered a given protein to be a distinct chemical compound.

Chibnall was studying insulin when Sanger joined the group. At Chibnall’s suggestion, Sanger set out to identify and quantify the free-amino groups of insulin. Sanger developed a method using dinitrofluorobenzene to produce yellow-coloured derivatives of amino groups.  Information about a new separation technique, partition chromatography, had recently been published. In a pattern that typified Sanger’s career, he immediately recognized the utility of the new technique in separating the hydrolysis products of the treated protein. He identified two terminal amino groups for insulin, phenylalanine and glycine, suggesting that insulin is composed of two types of chains. Working with his first graduate student, Rodney Porter, Sanger used the method to study the amino terminal groups of several other proteins. (Porter later shared the 1972 Nobel Prize for Physiology or Medicine for his work in determining the chemical structure of antibodies.)

On the assumption that insulin chains are held together by disulphide linkages, Sanger oxidized the chains and separated two fractions. One fraction had phenylalanine at its amino terminus; the other had glycine. Whereas complete acid hydrolysis degraded insulin to its constituent amino acids, partial acid hydrolysis generated insulin peptides composed of several amino acids. Using another recently introduced technique, paper chromatography, Sanger was able to sequence the amino-terminal peptides of each chain, demonstrating for the first time that a protein has a specific sequence at a specific site. A combination of partial acid hydrolysis and enzymatic hydrolysis allowed Sanger and the Austrian biochemist Hans Tuppy to determine the complete sequence of amino acids in the phenylalanine chain of insulin. Similarly, Sanger and the Australian biochemist E.O.P. Thompson determined the sequence of the glycine chain.

Two problems remained: the distribution of the amide groups and the location of the disulphide linkages. With the completion of those two puzzles in 1954, Sanger had deduced the structure of insulin. For being the first person to sequence a protein, Sanger was awarded the 1958 Nobel Prize for Chemistry.

Sanger and his coworkers continued their studies of insulin, sequencing insulin from several other species and comparing the results. Utilizing newly introduced radiolabeling techniques, Sanger mapped the amino acid sequences of the active centres from several enzymes. One of these studies was conducted with another graduate student, Argentine-born immunologist César Milstein. (Milstein later shared the 1984 Nobel Prize for Physiology or Medicine for discovering the principle for the production of monoclonal antibodies.)

RNA Research

In 1962 the Medical Research Council opened its new laboratory of molecular biology in Cambridge. The Austrian-born British biochemist Max Perutz, British biochemist John Kendrew, and British biophysicist Francis Crick moved to the new laboratory. Sanger joined them as head of the protein division. It was a banner year for the group, as Perutz and Kendrew shared the 1962 Nobel Prize for Chemistry and Crick shared the 1962 Nobel Prize for Physiology or Medicine with the American geneticist James D. Watson and the New Zealand-born British biophysicist Maurice Wilkins for the discovery of DNA (deoxyribonucleic acid).

Sanger’s interaction with nucleic acid groups at the new laboratory led to his pursuing studies on ribonucleic acid (RNA). RNA molecules are much larger than proteins, so obtaining molecules small enough for technique development was difficult. The American biochemist Robert W. Holley and his coworkers were the first to sequence RNA when they sequenced alanine-transfer RNA. They used partial hydrolysis methods somewhat like those Sanger had used for insulin. Unlike other RNA types, transfer RNAs have many unusual nucleotides. This partial hydrolysis method would not work well with other RNA molecules, which contain only four types of nucleotides, so a new strategy was needed.

The goal of Sanger’s lab was to sequence a messenger RNA and determine the genetic code, thereby solving the puzzle of how groups of nucleotides code for amino acids. Working with British biochemists George G. Brownlee and Bart G. Barrell, Sanger developed a two-dimensional electrophoresis method for sequencing RNA. By the time the sequence methods were worked out, the code had been broken by other researchers, mainly the American biochemist Marshall Nirenberg and the Indian-born American biochemist Har Gobind Khorana, using in vitro protein synthesis techniques. The RNA sequence work of Sanger’s group did confirm the genetic code.

DNA Research

By the early 1970s Sanger was interested in deoxyribonucleic acid (DNA). DNA sequence studies had not developed because of the immense size of DNA molecules and the lack of suitable enzymes to cleave DNA into smaller pieces. Building on the enzyme copying approach used by the Swiss chemist Charles Weissmann in his studies on bacteriophage RNA, Sanger began using the enzyme DNA polymerase to make new strands of DNA from single-strand templates, introducing radioactive nucleotides into the new DNA. DNA polymerase requires a primer that can bind to a known region of the template strand. Early success was limited by the lack of suitable primers. Sanger and British colleague Alan R. Coulson developed the “plus and minus” method for rapid DNA sequencing. It represented a radical departure from earlier methods in that it did not utilize partial hydrolysis. Instead, it generated a series of DNA molecules of varying lengths that could be separated by using polyacrylamide gel electrophoresis. For both plus and minus systems, DNA was synthesized from templates to generate random sets of DNA molecules from very short to very long. When both plus and minus sets were separated on the same gel, the sequence could be read from either system, one confirming the other. In 1977 Sanger’s group used this system to deduce most of the DNA sequence of bacteriophage ΦX174, the first complete genome to be sequenced.

A few problems remained with the plus and minus system. Sanger, Coulson, and British colleague Steve Nicklen developed a similar procedure using dideoxynucleotide chain-terminating inhibitors. DNA was synthesized until an inhibitor molecule was incorporated into the growing DNA chain. Using four reactions, each with a different inhibitor, sets of DNA fragments were generated ending in every nucleotide. For example, in the A reaction, a series of DNA fragments ending in A (adenine) was generated. In the C reaction, a series of DNA fragments ending in C (cytosine) was generated, and so on for G (guanine) and T (thymine). When the four reactions were separated side by side on a gel and an autoradiograph developed, the sequence was read from the film. Sanger and his coworkers used the dideoxy method to sequence human mitochondrial DNA. For his contributions to DNA sequencing methods, Sanger shared the 1980 Nobel Prize for Chemistry. He retired in 1983.

Additional Honours

Sanger’s additional honours included election as a fellow of the Royal Society (1954), being named a Commander of the Order of the British Empire (CBE; 1963), receiving the Royal Society’s Royal Medal (1969) and Copley Medal (1977), and election to the Order of the Companions of Honour (CH; 1981) and the Order of Merit (OM; 1986). In 1993 the Wellcome Trust and the British Medical Research Council established a genome research centre, honouring Sanger by naming it the Wellcome Trust Sanger Institute.

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966) Tetanus

Tetanus, also called lockjaw, acute infectious disease of humans and other animals, caused by toxins produced by the bacillus Clostridium tetani and characterized by rigidity and spasms of the voluntary muscles. The almost constant involvement of the jaw muscles accounts for the popular name of the disease.

Spores of Clostridium are distributed widely in nature, especially in soil, and may enter the body through any wound, even a superficial abrasion; puncture wounds and deep lacerations are particularly dangerous because they provide the oxygen-free environment needed for growth of the microorganism.

Both the occurrence and severity of tetanus are determined by the amount of toxin produced and the resistance of the host. The neurotoxic component, tetanospasmin, is one of the deadliest poisons known. It is believed to act on the synthesis and liberation of acetylcholine, a substance having a key role in the synaptic transmission of nerve impulses throughout the body. Once it has entered the body, the toxin rapidly spreads by way of the bloodstream or directly by a nerve to the central nervous system, where it attacks motor nerve cells and excites them to overactivity. Excessive impulses rush through the nerves to the muscles, which are thrown into severe convulsive spasm. The most common spasms occur in the muscle of the jaw, and the first sign of the illness often is stiffness of the jaw, or trismus. The muscles of the mouth are often affected, pulling the lips out and up over the teeth into a grimace, the mixture of smile and snarl that heralds the onset of the generalized convulsive stage of tetanus. Spasm of the muscles of the throat can make swallowing impossible, whereas the muscles of the larynx or of the chest wall can be thrown into such violent spasm that breathing is impossible and life is threatened. This is a common cause of death if the tetanus is untreated, but there are other effects on the heart, blood pressure, and vital brain centres that may cause death later in the disease.

The incubation period is quite variable in length—from two days to two weeks in most cases but sometimes up to three months. In general, the longer the incubation period, the milder will be the disease. Treatment of tetanus is primarily supportive. Tetanus antitoxin, which contains antibodies derived from the blood of persons who have been immunized against the disease, is given to help neutralize the toxin in the bloodstream, but it has little effect once the toxin has affected the nerve endings. Intravenous penicillin kills the organisms that remain within the wound site. Patients are usually intentionally paralyzed with drugs (such as curare) to prevent muscle spasms caused by the disease; artificial or mechanical respiration is necessary because the respiratory muscles are paralyzed. After a few weeks, when the disease is curtailed, the curare treatment is stopped and the patient begins to breathe on his own again.

Passive protection with tetanus antitoxin should be administered in all cases of injuries that may be contaminated by clostridial spores. Active immunization with tetanus toxoid (prepared by chemical modification of toxin) is a relatively slow process, requiring weeks or months to become effective, and must be renewed every few years (booster doses). A first dose should be given to every accident victim, followed by two more doses several months later. This applies also to persons who have recovered from tetanus, for an attack of the disease does not confer immunity.

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964) Dermatology

Summary : What is dermatology?

Dermatology is a branch of medicine that deals with the skin and diseases of the skin. It concerns the study, research and diagnosis of normal skin and disorders of the skin. Cancers, cosmetic and aging conditions of the skin, fat, hair, nails and oral and genital membranes are all aspects of dermatology.

Subspecialties of the dermatology field include dermatopathology, which is involved with the pathology of the skin; immunodermatology, which specializes in the treatment of immune-mediated skin disorders, including lupus, bullous pemphigoid and pemphigus vulgaris; Mohs’ surgery, which involves removing tumors from the skin without harming healthy cells; and pediatric dermatology, in which dermatologists may treat infants, hereditary skin disorders and children.

An expert in the field of dermatology is a dermatologist. A dermatologist may be involved with medical or surgical treatments. Dermatologists may perform a range of procedures, many of which are cosmetic. These include cosmetic filler injections, hair removal or transplantation, intralesional treatment, laser therapy, photodynamic therapy, phototherapy, tattoo removal, tumescent liposuction, radiation therapy and vitiligo surgery.

Other treatments in the dermatology field include cryosurgery, which is the treatment of warts, skin cancers or other dermatoses; allergy testing; systemic therapies such as antibiotics, immunomodulators or injectable products; or topical therapies.

The skin is the largest organ in the body. Moreover, because the entire surface area of the skin is visible, dermatologists have the advantage of direct visual examination.
Details : A dermatologist is a doctor that specializes in treating skin, hair, nail, and mucous membrane disorders and diseases.

They can also address cosmetic issues, helping to revitalize the appearance of the skin, hair, and nails.

The Centers for Disease Control and Prevention (CDC) estimate that, in the United States, there were 39 million visits to office-based dermatologists, who were not federally employed, in 2010.

Below, we explore common issues that dermatologists encounter, the treatments they offer, and the qualifications involved.

What is dermatology?

Dermatology is an area of medicine that focuses on health issues affecting the skin, hair, nails, and mucous membranes.

The skin is the largest organ of the body. It is also the first line of defense against pathogens and injury, and it can be a good indicator of overall health.

Qualifications

It is important to know that a dermatologist has a full license or certification before visiting them. Some practitioners in spas and beauty clinics call themselves dermatologists but do not have the necessary accreditation.

In the U.S., a qualified dermatologist will be certified by the American Board of Dermatology, the American Osteopathic Board of Dermatology, or the Royal College of Physicians and Surgeons of Canada.

The American Academy of Dermatology (AAD) is the largest membership dermatology group in the United States, with more than 20,000 members.

To qualify for registration with the AAD, a dermatologist has to finish both college and medical school as either a medical doctor (MD) or a doctor of osteopathic medicine (DO). They will also have completed a residency involving 1 year of hands-on work.

Some dermatologists have the initials FAAD after their names. This abbreviation stands for: Fellow of the American Academy of Dermatology. It indicates that the dermatologist:
•    has a license to practice medicine
•    has passed exams given by either the American Board of Dermatology or the Royal College of Physicians and Surgeons of Canada
•    is a member of the AAD

The AAD provide a search tool to help people with skin, hair, or nail conditions find a nearby dermatologist.

Common conditions

Being a dermatologist requires a great depth of clinical knowledge, including, for example, the various internal health problems that can cause skin symptoms.

Dermatologists can treat more than 3,000 conditions. Below are some examples of those that they see most commonly:

Acne: Among the most prevalent skin issues, acne has a range of causes that can lead to different types of pimples. Some people experience scarring, low self-esteem, and other complications.

Dermatitis and eczema: Dermatitis is inflammation of the skin, and it typically leads to swelling with an itchy rash. There are various forms, including atopic dermatitis, which is the most common type of eczema.

Fungal infections: These are common and sometimes involve the skin, nails, and hair. A group of yeasts called Candida can cause a wide range of fungal infections, including oral thrush, ringworm, athlete’s foot, and balanitis.

Hair loss: About 80 million people in the U.S. have hereditary hair loss. A range of health issues can also cause hair loss, including head lice, which affects around 6–12 million children aged 3–11 years in the U.S. annually.

Warts: These are contagious, benign skin growths that appear when a virus has infected the top layer of skin. A dermatologist can use a variety of treatments to remove persistent warts.

Nail problems: Dermatologists also treat health issues that damage the skin around and under the nails. Ingrown nails, fungal infections, and various other conditions can cause this damage.

Vitiligo: This involves the skin losing melanin, a pigment. As a result, some patches of skin are lighter in color than others.

Psoriasis: This chronic autoimmune disorder speeds up the growth of skin cells, resulting in patches of skin that may be thick, red, purple, or silvery and scaly. There are several types of psoriasis.

Rosacea: This causes redness in the face, sometimes with pus-filled bumps, visible blood vessels, and swelling of the eyelids. Symptoms can spread from the nose and cheeks to the forehead, chin, ears, chest, and back.

Shingles, or herpes zoster: This viral infection causes a rash that may be painful. It may clear in a few weeks without treatment, but medical intervention can help speed recovery and prevent complications, which can be severe.

Skin cancer: About 1 in 5 people in the U.S. develop a type of skin cancer by age 70. The most common forms are basal cell carcinoma, melanoma, and squamous cell carcinoma.

Procedures

Dermatologists use a range of medical and cosmetic procedures to manage issues affecting the skin, nails, and hair.

Medications and noninvasive therapies can treat many skin conditions, while others require more invasive approaches. These procedures can take place in an outpatient setting, such as the doctor’s office, or in a hospital.

Chemical peels

This involves applying a chemical solution that causes a layer of skin to peel off, revealing regenerated skin beneath that is typically smoother.

Dermatologists use this procedure to treat sun-damaged skin and some types of acne. It can also address cosmetic complaints, such as age spots and lines under the eyes.

Cosmetic injections

Wrinkles, scarring, and reduced facial fullness can be temporarily addressed with injections. A dermatologist can inject Botox or fillers such as collagen and fat during an office visit.

Results tend to last for a few months, and maintaining the effects requires regular injections. However, some people develop antibodies to Botox that make the injections ineffective.

Cryotherapy

Cryotherapy can be a quick treatment for many benign skin issues, such as warts.

The procedure involves freezing skin lesions — often with liquid nitrogen — to destroy the affected cells.

Dermabrasion

Dermabrasion can help reduce scar tissue, the appearance of fine wrinkles and tattoos, and potentially precancerous areas of skin.

Using a high-speed rotating brush, a dermatologist removes the top layer of skin.

Excision of lesions

Dermatologists excise skin lesions for several reasons. They may cut away these lesions:
•    to prevent a disease from spreading
•    for cosmetic reasons
•    to prevent reoccurring infection
•    to alleviate symptoms
•    to diagnose an underlying issue

Depending on the size of the lesion, the person may receive a local or general anesthetic before the removal.

Hair removal or restoration

A dermatologist can use various methods to address hair loss, including transplantation.

Alternately, they can remove unwanted body hair using lasers.

Laser surgery

Dermatologists can also use laser surgery to treat a variety of skin issues or cosmetic complaints, including:
•    tumors
•    warts
•    moles
•    unwanted tattoos
•    birthmarks
•    scars
•    wrinkles

Vein procedures

Superficial leg veins are small, dilated surface veins. People sometimes call them spider veins and may request their removal.

Sclerotherapy tends to be the spider vein treatment of choice. It involves injecting either foam or a special solution into the vein, which irritates the lining, causing the vein to shut, then become less distinct or disappear.

Tumescent liposuction

Dermatologists use tumescent liposuction to remove fat. It involves injecting large volumes of local anesthetic into fatty tissue, then sucking it from the body.

Tumescent liposuction is not a treatment for obesity — it is a cosmetic procedure for body contouring.

Dermatologists can also use lasers to selectively burst fat cells.

Skin grafts and flaps

Dermatologists can restore missing skin using skin from elsewhere on the body.

Or, they may repair skin loss by creating a flap of skin from a nearby area and using it to cover the damaged patch.

Biopsies

A dermatologist usually performs a skin biopsy to diagnose or rule out certain conditions.

They typically use one of the following three approaches:

•    Shave biopsies remove small sections of the top layer of skin.
•    Punch biopsies remove small, circular sections of skin, including deeper layers.
•    Excision biopsies remove entire areas of skin that seem to be unhealthy.

PUVA

PUVA stands for: psoralen combined with ultraviolet A radiation. Psoralen is a drug that makes the skin more sensitive to the radiation treatment.

Dermatologists use PUVA to treat skin diseases, such as psoriasis, dermatitis, and vitiligo.

Mohs surgery

Mohs surgery is a treatment for skin cancer.

First, the dermatologist removes layers of skin to get rid of cancerous cells, then examines them under a microscope.

They then remove successive layers until there are no more cancerous cells. Performing this surgery requires specialized training.

When to see a dermatologist

If skin, hair, or nail symptoms are not responding to home treatment, it may be time to seek professional attention.

If concerns are cosmetic, a person can seek out a specialized cosmetic dermatologist.

It is important for people to discuss any upcoming dermatological treatments with their insurance providers, who often do not fund cosmetic procedures.

Be sure to obtain copies of any medical reports, consultation notes, and diagnostic test results to assure the insurer of the medical necessity of the treatment.

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#1626. What does the medical term 'Amniotic sac' mean?