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#9217.

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#2562. What does the medical term Granuloma mean?

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2262.

2132) Chemistry

Gist

Chemistry is a branch of natural science that deals principally with the properties of substances, the changes they undergo, and the natural laws that describe these changes.

Summary

Chemistry, the science that deals with the properties, composition, and structure of substances (defined as elements and compounds), the transformations they undergo, and the energy that is released or absorbed during these processes. Every substance, whether naturally occurring or artificially produced, consists of one or more of the hundred-odd species of atoms that have been identified as elements. Although these atoms, in turn, are composed of more elementary particles, they are the basic building blocks of chemical substances; there is no quantity of oxygen, mercury, or gold, for example, smaller than an atom of that substance. Chemistry, therefore, is concerned not with the subatomic domain but with the properties of atoms and the laws governing their combinations and how the knowledge of these properties can be used to achieve specific purposes.

The great challenge in chemistry is the development of a coherent explanation of the complex behaviour of materials, why they appear as they do, what gives them their enduring properties, and how interactions among different substances can bring about the formation of new substances and the destruction of old ones. From the earliest attempts to understand the material world in rational terms, chemists have struggled to develop theories of matter that satisfactorily explain both permanence and change. The ordered assembly of indestructible atoms into small and large molecules, or extended networks of intermingled atoms, is generally accepted as the basis of permanence, while the reorganization of atoms or molecules into different arrangements lies behind theories of change. Thus chemistry involves the study of the atomic composition and structural architecture of substances, as well as the varied interactions among substances that can lead to sudden, often violent reactions.

Chemistry also is concerned with the utilization of natural substances and the creation of artificial ones. Cooking, fermentation, glass making, and metallurgy are all chemical processes that date from the beginnings of civilization. Today, vinyl, Teflon, liquid crystals, semiconductors, and superconductors represent the fruits of chemical technology. The 20th century saw dramatic advances in the comprehension of the marvelous and complex chemistry of living organisms, and a molecular interpretation of health and disease holds great promise. Modern chemistry, aided by increasingly sophisticated instruments, studies materials as small as single atoms and as large and complex as DNA (deoxyribonucleic acid), which contains millions of atoms. New substances can even be designed to bear desired characteristics and then synthesized. The rate at which chemical knowledge continues to accumulate is remarkable. Over time more than 8,000,000 different chemical substances, both natural and artificial, have been characterized and produced. The number was less than 500,000 as recently as 1965.

Intimately interconnected with the intellectual challenges of chemistry are those associated with industry. In the mid-19th century the German chemist Justus von Liebig commented that the wealth of a nation could be gauged by the amount of sulfuric acid it produced. This acid, essential to many manufacturing processes, remains today the leading chemical product of industrialized countries. As Liebig recognized, a country that produces large amounts of sulfuric acid is one with a strong chemical industry and a strong economy as a whole. The production, distribution, and utilization of a wide range of chemical products is common to all highly developed nations. In fact, one can say that the “iron age” of civilization is being replaced by a “polymer age,” for in some countries the total volume of polymers now produced exceeds that of iron.

Details

Chemistry is the scientific study of the properties and behavior of matter. It is a physical science within the natural sciences that studies the chemical elements that make up matter and compounds made of atoms, molecules and ions: their composition, structure, properties, behavior and the changes they undergo during reactions with other substances. Chemistry also addresses the nature of chemical bonds in chemical compounds.

In the scope of its subject, chemistry occupies an intermediate position between physics and biology. It is sometimes called the central science because it provides a foundation for understanding both basic and applied scientific disciplines at a fundamental level. For example, chemistry explains aspects of plant growth (botany), the formation of igneous rocks (geology), how atmospheric ozone is formed and how environmental pollutants are degraded (ecology), the properties of the soil on the Moon (cosmochemistry), how medications work (pharmacology), and how to collect DNA evidence at a crime scene (forensics).

Chemistry has existed under various names since ancient times. It has evolved, and now chemistry encompasses various areas of specialisation, or subdisciplines, that continue to increase in number and interrelate to create further interdisciplinary fields of study. The applications of various fields of chemistry are used frequently for economic purposes in the chemical industry.

Etymology

The word chemistry comes from a modification during the Renaissance of the word alchemy, which referred to an earlier set of practices that encompassed elements of chemistry, metallurgy, philosophy, astrology, astronomy, mysticism, and medicine. Alchemy is often associated with the quest to turn lead or other base metals into gold, though alchemists were also interested in many of the questions of modern chemistry.

The modern word alchemy in turn is derived from the Arabic word al-kīmīā. This may have Egyptian origins since al-kīmīā is derived from the Ancient Greek, which is in turn derived from the word Kemet, which is the ancient name of Egypt in the Egyptian language. Alternately, al-kīmīā may derive from 'cast together'.

Modern principles

The current model of atomic structure is the quantum mechanical model. Traditional chemistry starts with the study of elementary particles, atoms, molecules, substances, metals, crystals and other aggregates of matter. Matter can be studied in solid, liquid, gas and plasma states, in isolation or in combination. The interactions, reactions and transformations that are studied in chemistry are usually the result of interactions between atoms, leading to rearrangements of the chemical bonds which hold atoms together. Such behaviors are studied in a chemistry laboratory.

The chemistry laboratory stereotypically uses various forms of laboratory glassware. However glassware is not central to chemistry, and a great deal of experimental (as well as applied/industrial) chemistry is done without it.

A chemical reaction is a transformation of some substances into one or more different substances. The basis of such a chemical transformation is the rearrangement of electrons in the chemical bonds between atoms. It can be symbolically depicted through a chemical equation, which usually involves atoms as subjects. The number of atoms on the left and the right in the equation for a chemical transformation is equal. (When the number of atoms on either side is unequal, the transformation is referred to as a nuclear reaction or radioactive decay.) The type of chemical reactions a substance may undergo and the energy changes that may accompany it are constrained by certain basic rules, known as chemical laws.

Energy and entropy considerations are invariably important in almost all chemical studies. Chemical substances are classified in terms of their structure, phase, as well as their chemical compositions. They can be analyzed using the tools of chemical analysis, e.g. spectroscopy and chromatography. Scientists engaged in chemical research are known as chemists. Most chemists specialize in one or more sub-disciplines. Several concepts are essential for the study of chemistry; some of them are:

Matter

In chemistry, matter is defined as anything that has rest mass and volume (it takes up space) and is made up of particles. The particles that make up matter have rest mass as well – not all particles have rest mass, such as the photon. Matter can be a pure chemical substance or a mixture of substances.

Atom

The atom is the basic unit of chemistry. It consists of a dense core called the atomic nucleus surrounded by a space occupied by an electron cloud. The nucleus is made up of positively charged protons and uncharged neutrons (together called nucleons), while the electron cloud consists of negatively charged electrons which orbit the nucleus. In a neutral atom, the negatively charged electrons balance out the positive charge of the protons. The nucleus is dense; the mass of a nucleon is approximately 1,836 times that of an electron, yet the radius of an atom is about 10,000 times that of its nucleus.

The atom is also the smallest entity that can be envisaged to retain the chemical properties of the element, such as electronegativity, ionization potential, preferred oxidation state(s), coordination number, and preferred types of bonds to form (e.g., metallic, ionic, covalent).

Element

A chemical element is a pure substance which is composed of a single type of atom, characterized by its particular number of protons in the nuclei of its atoms, known as the atomic number and represented by the symbol Z. The mass number is the sum of the number of protons and neutrons in a nucleus. Although all the nuclei of all atoms belonging to one element will have the same atomic number, they may not necessarily have the same mass number; atoms of an element which have different mass numbers are known as isotopes. For example, all atoms with 6 protons in their nuclei are atoms of the chemical element carbon, but atoms of carbon may have mass numbers of 12 or 13.

The standard presentation of the chemical elements is in the periodic table, which orders elements by atomic number. The periodic table is arranged in groups, or columns, and periods, or rows. The periodic table is useful in identifying periodic trends.

Compound

A compound is a pure chemical substance composed of more than one element. The properties of a compound bear little similarity to those of its elements. The standard nomenclature of compounds is set by the International Union of Pure and Applied Chemistry (IUPAC). Organic compounds are named according to the organic nomenclature system. The names for inorganic compounds are created according to the inorganic nomenclature system. When a compound has more than one component, then they are divided into two classes, the electropositive and the electronegative components. In addition the Chemical Abstracts Service has devised a method to index chemical substances. In this scheme each chemical substance is identifiable by a number known as its CAS registry number.

Molecule

A molecule is the smallest indivisible portion of a pure chemical substance that has its unique set of chemical properties, that is, its potential to undergo a certain set of chemical reactions with other substances. However, this definition only works well for substances that are composed of molecules, which is not true of many substances (see below). Molecules are typically a set of atoms bound together by covalent bonds, such that the structure is electrically neutral and all valence electrons are paired with other electrons either in bonds or in lone pairs.

Thus, molecules exist as electrically neutral units, unlike ions. When this rule is broken, giving the "molecule" a charge, the result is sometimes named a molecular ion or a polyatomic ion. However, the discrete and separate nature of the molecular concept usually requires that molecular ions be present only in well-separated form, such as a directed beam in a vacuum in a mass spectrometer. Charged polyatomic collections residing in solids (for example, common sulfate or nitrate ions) are generally not considered "molecules" in chemistry. Some molecules contain one or more unpaired electrons, creating radicals. Most radicals are comparatively reactive, but some, such as nitric oxide (NO) can be stable.

The "inert" or noble gas elements (helium, neon, argon, krypton, xenon and radon) are composed of lone atoms as their smallest discrete unit, but the other isolated chemical elements consist of either molecules or networks of atoms bonded to each other in some way. Identifiable molecules compose familiar substances such as water, air, and many organic compounds like alcohol, sugar, gasoline, and the various pharmaceuticals.

However, not all substances or chemical compounds consist of discrete molecules, and indeed most of the solid substances that make up the solid crust, mantle, and core of the Earth are chemical compounds without molecules. These other types of substances, such as ionic compounds and network solids, are organized in such a way as to lack the existence of identifiable molecules per se. Instead, these substances are discussed in terms of formula units or unit cells as the smallest repeating structure within the substance. Examples of such substances are mineral salts (such as table salt), solids like carbon and diamond, metals, and familiar silica and silicate minerals such as quartz and granite.

One of the main characteristics of a molecule is its geometry often called its structure. While the structure of diatomic, triatomic or tetra-atomic molecules may be trivial, (linear, angular pyramidal etc.) the structure of polyatomic molecules, that are constituted of more than six atoms (of several elements) can be crucial for its chemical nature.

Substance and mixture

A chemical substance is a kind of matter with a definite composition and set of properties. A collection of substances is called a mixture. Examples of mixtures are air and alloys.

Mole and amount of substance

The mole is a unit of measurement that denotes an amount of substance (also called chemical amount). One mole is defined to contain exactly 6.02214076×{10}^{23} particles (atoms, molecules, ions, or electrons), where the number of particles per mole is known as the Avogadro constant. Molar concentration is the amount of a particular substance per volume of solution, and is commonly reported in mol/{dm}^3.

Additional Information

Chemistry is the scientific study of matter, its properties, composition, and interactions. It is often referred to as the central science because it connects and bridges the physical sciences, such as physics and biology. Understanding chemistry is crucial for comprehending the world around us, from the air we breathe to the food we eat and the materials we use in everyday life.

Chemistry has many sub-disciplines such as analytical chemistry, physical chemistry, biochemistry, and more. Chemistry plays a crucial role in various industries, including pharmaceuticals, materials science, environmental science, and energy production, making it a cornerstone of modern science and technology

The area of science devoted to studying nature and also composition, properties, elements, and compounds that form matter as well as looking into their reactions forming new substances is chemistry. Chemistry has also been categorized further based on the particular areas of study.

1441) John Vane

Summary

Sir John Robert Vane (born March 29, 1927, Tardebigg, Worcestershire, England—died November 19, 2004, Farnborough, Hampshire) was an English biochemist who, with Sune K. Bergström and Bengt Ingemar Samuelsson, won the Nobel Prize for Physiology or Medicine in 1982 for the isolation, identification, and analysis of prostaglandins. These are biochemical compounds that influence blood pressure, body temperature, allergic reactions, and other physiological phenomena in mammals.

Vane graduated from the University of Birmingham in 1946 and earned a doctorate at the University of Oxford in 1953. He spent several years on the faculty of Yale University (1953–55) in the United States before returning to England to join the Institute of Basic Medical Sciences of the University of London. In 1973 he became research director of the Wellcome Research Laboratories in Beckenham, Kent, a post he held until 1985. In 1986 Vane founded the William Harvey Research Institute, attached to St. Bartholomew’s Hospital in London, which funded cardiovascular research. He remained with the institute, in various positions, until his death.

As part of his Nobel Prize-winning work, Vane demonstrated that aspirin inhibits the formation of prostaglandins associated with pain, fever, and inflammation, thus providing a physiological rationale for the effectiveness of the world’s most widely used drug. He also discovered prostacyclin, an important prostaglandin that plays a vital role in the process of blood coagulation.

Vane, the recipient of numerous honours, was elected a fellow of the Royal Society in 1974 and was made an honorary member of the American Academy of Arts and Sciences in 1982. He was knighted in 1984.

Details

Sir John Robert Vane (29 March 1927 – 19 November 2004) was a British pharmacologist who was instrumental in the understanding of how aspirin produces pain-relief and anti-inflammatory effects and his work led to new treatments for heart and blood vessel disease and introduction of ACE inhibitors. He was awarded the Nobel Prize in Physiology or Medicine in 1982 along with Sune Bergström and Bengt Samuelsson for "their discoveries concerning prostaglandins and related biologically active substances".

Education and early life

Born in Tardebigge, Worcestershire, John Vane was one of three children and grew up in suburban Birmingham. His father, Maurice Vane, was the son of Jewish Russian immigrants and his mother, Frances Vane, came from a Worcestershire farming family. He attended a local state school from age 5, before moving on to King Edward's School in Edgbaston, Birmingham. An early interest in chemistry was to prove the inspiration for studying the subject at the University of Birmingham in 1944.

During his undergraduate studies, Vane became disenchanted with chemistry but still enjoyed experimentation. When Maurice Stacey, the Professor of Chemistry at Birmingham, was asked by Harold Burn to recommend a student to go to Oxford and study pharmacology, Vane jumped at the chance and moved to Burn's department in 1946. Under Burn's guidance, Vane found motivation and enthusiasm for pharmacology, writing: "[the] laboratory gradually became the most active and important centre for pharmacological research in the U.K. and the main school for training of young pharmacologists." Vane completed a Bachelor of Science degree in pharmacology and briefly went to work at the University of Sheffield, before coming back to Oxford to complete his Doctor of Philosophy degree in 1953[4] supervised by Geoffrey Dawes.

Career and research

After completing his DPhil, Vane worked as an assistant professor the Department of Pharmacology at Yale University before moving back to the United Kingdom to take up a post as a senior lecturer in the Institute of Basic Medical Sciences at the University of London in 1955.

University of London

Vane held a post at the University of London for 18 years, progressing from senior lecturer to Professor of Experimental Pharmacology in 1966 (at the Royal College of Surgeons). During that time he developed certain bioassay techniques and focussed his research on both angiotensin-converting enzyme and the actions of aspirin, eventually leading to the publication with Priscilla Piper of the relationship between aspirin and the prostaglandins that earned him the Nobel Prize in Physiology or Medicine in 1982.

Wellcome Foundation

In 1973, Vane left his academic post at the Royal College of Surgeons and took up the position as Director of Research at the Wellcome Foundation, taking a number of his colleagues with him who went on to form the Prostaglandin Research department. Under the leadership of Salvador Moncada, this group continued important research that eventually led to the discovery of prostacyclin.

Return to academia

In 1985, Vane returned to academic life and founded the William Harvey Research Institute at the Medical College of St Bartholomew's Hospital (now Barts and The London School of Medicine and Dentistry. At the William Harvey Research Institute, Vane's work focused on selective inhibitors of COX-2, and the interplay between nitric oxide and endothelin in the regulation of vascular function.

Awards and honours

Vane was elected a Fellow of the Royal Society (FRS) in 1974. He was also awarded honorary doctorate degrees from Jagiellonian University Medical College (formerly Copernicus Academy of Medicine) in 1977, Paris Descartes University in 1978, Mount Sinai School of Medicine in 1980 and the University of Aberdeen in 1983. He was awarded the Lasker Award in 1977 for the discovery of prostacyclin and was knighted in 1984 for his contributions to science. In 2000, Vane received the Golden Plate Award of the American Academy of Achievement.

Personal life

John Vane married, in 1948, (Elizabeth) Daphne Page and had 2 daughters. He died on 19 November 2004 in Princess Royal University Hospital, Kent, from long-term complications arising from leg and hip fractures he sustained in May of that year. Lady Vane died in 2021.

Additional Information

Prostaglandins are hormone-like substances that govern several important processes in the body. They also come into play when the body is under attack. In 1971 John Vane showed that acetylsalicylic acid, a substance found in pain-relieving and fever-reducing medications like aspirin, works by inhibiting the formation of prostglandins. In 1976 Vane discovered the prostacyclin prostglandin, which expands the smallest blood vessels and, unlike certain other prostglandins, inhibits the formation of blood particles called platelets that cause blood to coagulate.

Introduction

Through space exploration humans have learned a great deal about the planets, stars, and other objects in space. More than 5,000 spacecraft have been launched into space to gather information since 1957. They include spacecraft with humans on board, space probes, and satellites. The Soviet Union (now Russia) and the United States were originally the main countries exploring space. Many other countries are now involved.

Astronauts

Astronauts (called cosmonauts in Russia and taikonauts in China) go through a thorough training program. They study math and science in classrooms. They learn to operate their spacecraft by using computer-controlled simulators. These devices present astronauts with conditions that they will later experience during actual flight. Astronauts also must improve their physical fitness. They make special trips in airplanes to get used to the feeling of weightlessness.

Humans cannot survive in outer space on their own. The environment is not the same as it is on Earth. Astronauts therefore travel in space in tightly sealed compartments. They bring their own supply of oxygen with them. Once in space, astronauts may conduct scientific experiments. They also may make repairs to their spacecraft or other equipment in space. They wear heavy space suits for work outside the spacecraft.

The Race into Space

In the 1900s scientists developed rockets that could travel fast enough to escape the pull of the force called gravity. Gravity is a force on Earth that pulls objects toward the center of the planet. The development of powerful rockets allowed the Soviet Union to launch the first artificial satellite on October 4, 1957. It was called Sputnik 1, and it orbited around Earth. On November 3, 1957, the Soviet Union sent a dog into orbit. On April 12, 1961, the Russian cosmonaut Yury Gagarin became the first human to circle Earth in space. In 1963 Valentina Tereshkova became the first woman in space.

The National Aeronautics and Space Administration (NASA) took charge of the U.S. effort. The first U.S. satellite was launched on January 31, 1958. On May 5, 1961, astronaut Alan B. Shepard, Jr., became the first American to enter space. Shepard flew for only 15 minutes and did not complete an orbit around Earth. On February 20, 1962, John H. Glenn, Jr., completed three orbits around Earth. On July 20, 1969, astronaut Neil Armstrong became the first human to walk on the Moon.

Space Stations

Space stations are spacecraft that stay in orbit for a long period of time. Scientists can spend days or even months at a station doing experiments. The Soviet Union began launching space stations in 1971, and the United States followed in 1973. But these stations did not stay in space long. The Soviet station Mir stayed in orbit much longer, from 1986 to 2001.

In the 1990s the United States and 15 other countries agreed to build and operate a large space station together. The new project was called the International Space Station (ISS). Assembly of the ISS began in 1998. The first crew began to live in the station in November 2000.

Space Shuttles

In 1981 the United States launched the first reusable spacecraft, called a space shuttle. The main section had wings and was called the orbiter. Attached to the orbiter were rockets, fuel tanks, and oxygen tanks. These boosted the craft through the thickest part of Earth’s atmosphere. When their fuel was used up, the boosters fell into the ocean, where they could be recovered. At the end of a mission, the orbiter returned to Earth and landed like an airplane.

The first shuttle missions were successful. Astronaut Sally Ride became the first U.S. woman in space on June 18, 1983. But in January 1986 the shuttle Challenger exploded 73 seconds after liftoff. All seven crew members were killed. NASA stopped the shuttle program to study the cause of the explosion.

The United States returned to space in September 1988 with the launching of the shuttle Discovery. In 1990 Discovery put the Hubble Space Telescope into orbit around Earth. This telescope sends clear images of space back to Earth. But then in February 2003 the shuttle Columbia broke apart as it was returning to Earth. The seven crew members on board were killed. The shuttle program did not resume until 2005.

NASA ended the shuttle program in 2011. Later missions to space were expected to use Russian spacecraft or new spacecraft built by U.S. companies.

Space Probes

Space probes are vehicles that carry scientific equipment but no passengers. Some make one-way voyages into deep space. Probes are controlled from Earth by radio. They send back their findings the same way.

In the late 1950s the Soviet Union and the United States launched their first deep-space probes. Probes eventually landed on the planets Mars and Venus and flew past the planets Jupiter, Saturn, Uranus, and Neptune. They collected information on the planets’ atmospheres, moons, and ring systems. In the early 2000s scientists sent several new probes to explore Mars and other planets and objects in space.

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#5736.

Hi,

#9783. Name the Canadian-American executive, non-profit leader, and prominent women's-issues supporter based in New York City (born 1959). In April 2014, she became president and CEO of Grameen America, a nonprofit microfinance organization founded by Nobel Peace Prize winner, Muhammad Yunus. From 1999 until 2012, she served as the first female CEO and chairman of Avon Products, Inc., a multi-level marketing company. She was also the first woman to serve as Chairman of the Cosmetic, Toiletry & Fragrance Association, and Chairman of the World Federation of Direct Selling Associations.

#9784. Name the American businesswoman and politician, known primarily for her tenure as chief executive officer (CEO) of Hewlett-Packard (HP) from 1999 to 2005 (born September 6, 1954). She was the first woman to lead a Fortune Top-20 company.

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2261.

2131) Amputation

Gist

Amputation is the loss or removal of a body part such as a finger, toe, hand, foot, arm or leg. It can be a life changing experience affecting your ability to move, work, interact with others and maintain your independence.

Summary

Amputation is the removal of a limb by trauma, medical illness, or surgery. As a surgical measure, it is used to control pain or a disease process in the affected limb, such as malignancy or gangrene. In some cases, it is carried out on individuals as a preventive surgery for such problems. A special case is that of congenital amputation, a congenital disorder, where fetal limbs have been cut off by constrictive bands. In some countries, judicial amputation is currently used to punish people who commit crimes. Amputation has also been used as a tactic in war and acts of terrorism; it may also occur as a war injury. In some cultures and religions, minor amputations or mutilations are considered a ritual accomplishment. When done by a person, the person executing the amputation is an amputator. The oldest evidence of this practice comes from a skeleton found buried in Liang Tebo cave, East Kalimantan, Indonesian Borneo dating back to at least 31,000 years ago, where it was done when the amputee was a young child.

Details

Amputation is the surgical removal of all or part of a limb or extremity such as an arm, leg, foot, hand, toe, or finger.

About 1.8 million Americans are living with amputations. Amputation of the leg -- either above or below the knee -- is the most common amputation surgery.

Reasons for Amputation

There are many reasons an amputation may be necessary. The most common is poor circulation because of damage or narrowing of the arteries, called peripheral arterial disease. Without adequate blood flow, the body's cells cannot get oxygen and nutrients they need from the bloodstream. As a result, the affected tissue begins to die and infection may set in.

Other causes for amputation may include:

* Severe injury (from a vehicle accident or serious burn, for example)
* Cancerous tumor in the bone or muscle of the limb
* Serious infection that does not get better with antibiotics or other treatment
* Thickening of nerve tissue, called a neuroma
* Frostbite

The Amputation Procedure

An amputation usually requires a hospital stay of five to 14 days or more, depending on the surgery and complications. The procedure itself may vary, depending on the limb or extremity being amputated and the patient's general health.

Amputation may be done under general anesthesia (meaning the patient is asleep) or with spinal anesthesia, which numbs the body from the waist down.

When performing an amputation, the surgeon removes all damaged tissue while leaving as much healthy tissue as possible.

A doctor may use several methods to determine where to cut and how much tissue to remove. These include:

* Checking for a pulse close to where the surgeon is planning to cut
* Comparing skin temperatures of the affected limb with those of a healthy limb
* Looking for areas of reddened skin
* Checking to see if the skin near the site where the surgeon is planning to cut is still sensitive to touch

During the procedure itself, the surgeon will:

* Remove the diseased tissue and any crushed bone
* Smooth uneven areas of bone
* Seal off blood vessels and nerves
* Cut and shape muscles so that the stump, or end of the limb, will be able to have an artificial limb (prosthesis) attached to it

RELATED:

How to Prevent Damaging Your Kidneys

The surgeon may choose to close the wound right away by sewing the skin flaps (called a closed amputation). Or the surgeon may leave the site open for several days in case there's a need to remove additional tissue.

The surgical team then places a sterile dressing on the wound and may place a stocking over the stump to hold drainage tubes or bandages. The doctor may place the limb in traction, in which a device holds it in position, or may use a splint.

Recovery From Amputation

Recovery from amputation depends on the type of procedure and anesthesia used.

In the hospital, the staff changes the dressings on the wound or teaches the patient to change them. The doctor monitors wound healing and any conditions that might interfere with healing, such as diabetes or hardening of the arteries. The doctor prescribes medications to ease pain and help prevent infection.

If the patient has problems with phantom pain (a sense of pain in the amputated limb) or grief over the lost limb, the doctor will prescribe medication and/or counseling, as necessary.

Physical therapy, beginning with gentle, stretching exercises, often begins soon after surgery. Practice with the artificial limb may begin as soon as 10 to 14 days after surgery.

Ideally, the wound should fully heal in about four to eight weeks. But the physical and emotional adjustment to losing a limb can be a long process. Long-term recovery and rehabilitation will include:

* Exercises to improve muscle strength and control
* Activities to help restore the ability to carry out daily activities and promote independence
* Use of artificial limbs and assistive devices
* Emotional support, including counseling, to help with grief over the loss of the limb and adjustment to the new body image

Additional Information:

Prevention

Methods in preventing amputation, limb-sparing techniques, depend on the problems that might cause amputations to be necessary. Chronic infections, often caused by diabetes or decubitus ulcers in bedridden patients, are common causes of infections that lead to gangrene, which, when widespread, necessitates amputation.

There are two key challenges: first, many patients have impaired circulation in their extremities, and second, they have difficulty curing infections in limbs with poor blood circulation.

Crush injuries where there is extensive tissue damage and poor circulation also benefit from hyperbaric oxygen therapy (HBOT). The high level of oxygenation and revascularization speed up recovery times and prevent infections.

A study found that the patented method called Circulator Boot achieved significant results in prevention of amputation in patients with diabetes and arteriosclerosis. Another study found it also effective for healing limb ulcers caused by peripheral vascular disease. The boot checks the heart rhythm and compresses the limb between heartbeats; the compression helps cure the wounds in the walls of veins and arteries, and helps to push the blood back to the heart.

For victims of trauma, advances in microsurgery in the 1970s have made replantations of severed body parts possible.

The establishment of laws, rules, and guidelines, and employment of modern equipment help protect people from traumatic amputations.

Prognosis

The individual may experience psychological trauma and emotional discomfort. The stump will remain an area of reduced mechanical stability. Limb loss can present significant or even drastic practical limitations.

A large proportion of amputees (50–80%) experience the phenomenon of phantom limbs; they feel body parts that are no longer there. These limbs can itch, ache, burn, feel tense, dry or wet, locked in or trapped or they can feel as if they are moving. Some scientists believe it has to do with a kind of neural map that the brain has of the body, which sends information to the rest of the brain about limbs regardless of their existence. Phantom sensations and phantom pain may also occur after the removal of body parts other than the limbs, e.g. after amputation of the breast, extraction of a tooth (phantom tooth pain) or removal of an eye (phantom eye syndrome).

A similar phenomenon is unexplained sensation in a body part unrelated to the amputated limb. It has been hypothesized that the portion of the brain responsible for processing stimulation from amputated limbs, being deprived of input, expands into the surrounding brain, such that an individual who has had an arm amputated will experience unexplained pressure or movement on his face or head.

In many cases, the phantom limb aids in adaptation to a prosthesis, as it permits the person to experience proprioception of the prosthetic limb. To support improved resistance or usability, comfort or healing, some type of stump socks may be worn instead of or as part of wearing a prosthesis.

Another side effect can be heterotopic ossification, especially when a bone injury is combined with a head injury. The brain signals the bone to grow instead of scar tissue to form, and nodules and other growth can interfere with prosthetics and sometimes require further operations. This type of injury has been especially common among soldiers wounded by improvised explosive devices in the Iraq War.

Due to technological advances in prosthetics, many amputees live active lives with little restriction. Organizations such as the Challenged Athletes Foundation have been developed to give amputees the opportunity to be involved in athletics and adaptive sports such as amputee soccer.

Nearly half of the individuals who have an amputation due to vascular disease will die within 5 years, usually secondary to the extensive co-morbidities rather than due to direct consequences of amputation. This is higher than the five year mortality rates for breast cancer, colon cancer, and prostate cancer. Of persons with diabetes who have a lower extremity amputation, up to 55% will require amputation of the second leg within two to three years.

Amputation is surgery to remove all or part of a limb or extremity (outer limbs). Common types of amputation involve:

* Above-knee amputation, removing part of the thigh, knee, shin, foot and toes.
* Below-knee amputation, removing the lower leg, foot and toes.
* Arm amputation.
* Hand amputation.
* Finger amputation.
* Foot amputation, removing part of the foot.
* Toe amputation.

Why are amputations done?

Amputation can be necessary to keep an infection from spreading through your limbs and to manage pain. The most common reason for an amputation is a wound that does not heal. Often this can be from not having enough blood flow to that limb.

After a severe injury, such as a crushing injury, amputation may be necessary if the surgeon cannot repair your limb.

You also may need an amputation if you have:

* Cancerous tumors in the limb.
* Frostbite.
* Gangrene (tissue death).
* Neuroma, or thickening of nerve tissue.
* Peripheral arterial disease (PAD), or blockage of the arteries.
* Severe injury, such as from a car accident.
* Diabetes that leads to nonhealing or infected wounds or tissue death.

Annulus

Annulus

An annulus is an inner region between two concentric circles i.e. two or more circles sharing the same center point. The annulus is shaped like a ring and has many applications in mathematics that we will be learning in this article. Some of the real-life examples are a doughnut, finger rings. etc. Let us learn more about the shape of the annulus and solve a few examples to understand the concept better.

Annulus Definition

An annulus is a two-dimensional flat figure shaped in a circular form which is constructed by two concentric circles. The region or the area formed in between these two concentric circles is called the annulus. Since it is a flat figure in a circular form, the edges are two circles with the same center. It is considered a circular disk having a circular hole in the middle.

Annulus Meaning

The word annulus is derived from a Latin word, 'annuli', meaning little rings. The shape of the annulus is flat and circular with a hole in between, much like a throw ring or a circular disc. Look at the image below showing two circles i.e. one small circle also called an inner circle and a big circle also called the outer circle. The point which is marked as red is the center of both circles. The shaded colored area, between the boundary of these two circles, is known as an annulus.

Area of the Annulus

The annulus area is the area of the ring-shaped space i.e. the enclosed region between the two concentric circles. To calculate the area of the annulus, we need the area of both the inner circle and the outer circle. The dimensions of an annulus are defined by the two radii R, and r, which are the radii of the outer ring and the inner ring respectively. Once the measurements of both the radii are known, we can calculate the area by subtracting the area of the small circle from the big circle. Hence, the formula used for finding the area of the annulus is:

Area \ of \ Outer \ Circle = \pi{R^2}

gives

Area \ of \ Inner \ Circle = \pi{r^2}

gives

Area of Annulus = Area of Outer Circle – Area of Inner Circle

Therefore, Area of Annulus =

\pi(R^2-r^2)

gives

\pi(R + r)(R - r)

gives

(R square units, where R is the radius of the outer circle, r is the radius of the inner circle, and

\pi

gives