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Nebulizer

Gist

A nebulizer is a medical device used to turn liquid medicine into a fine mist, allowing it to be easily inhaled deep into the lungs to treat respiratory conditions like asthma, COPD, cystic fibrosis, and bronchiectasis. It's especially helpful for people who have trouble using standard inhalers, delivering medication directly to the airways through a mouthpiece or mask over several minutes.

(COPD: Chronic Obstructive Pulmonary Disease)

According to the American College of Allergy, Asthma, and Immunology (ACAAI), nebulizers are often recommended for treating respiratory illnesses such as asthma, bronchitis, and chronic obstructive pulmonary disease (COPD), all of which may include chronic coughing as a symptom.

Summary:

What is a nebulizer?

A nebulizer changes liquid medicine into fine droplets (in aerosol or mist form) that are inhaled through a mouthpiece or mask. Nebulizers can be used to deliver many types of medicines. The medicines and moisture help control breathing problems like wheezing and help loosen lung secretions.

A nebulizer might be used instead of other inhalers. A nebulizer is powered by an air compressor that plugs into an electrical outlet.

What supplies do you need to use the nebulizer?

You will need the following supplies:

* Hand-held nebulizer.
* Air compressor.
* Mouthpiece or face mask.

Where should you use the nebulizer?

Use the nebulizer in a well-lighted area. Select a comfortable place in your home where you can take your treatment without being interrupted. Sit in a comfortable, straight-backed chair when taking your treatment.

Treatment procedure

* Place the compressor on a sturdy surface that will support its weight, such as a table or desk. Plug the compressor's cord into a properly grounded (three-pronged) outlet.
* Wash your hands with soap and water and dry completely with a clean towel.
* Become familiar with the nebulizer parts.
* Place your medication in the nebulizer cup.
* Attach the top portion of the nebulizer cup, and connect the mouthpiece or face mask to the cup.
* Connect the tubing to the nebulizer and compressor.
* Turn on the compressor with the on/off switch. Once you turn on the compressor, you should see a light mist.
* Sit up straight on a comfortable chair.
* Using a mouthpiece is preferred. When using a mouthpiece, place the mouthpiece between your teeth and seal your lips around it.
* If you are using a mask, position it comfortably and securely on your face.
* Breathe normally through your mouth. If possible, every fifth breath, take a slow deep breath and hold this breath for 2 to 3 seconds before breathing out. This allows the medication to settle into the airways.
* Continue the treatment until the medication is gone (about 5 to 15 minutes). Use all of the medicine unless you are directed otherwise by your doctor.
* If you become dizzy, slow your breathing or rest briefly. Some medicine may make you feel "jittery" or "shaky." This is not uncommon, but if these symptoms continue to bother you, inform your healthcare provider.
* Turn off the compressor.
* Wash your hands with warm water and soap. Dry them with a clean towel.

Care of nebulizer

Cleaning and disinfecting your equipment is simple, yet very important. After each treatment, rinse the nebulizer cup with warm water. Shake off excess water and let it air dry.

At the end of each day, the nebulizer cup, mask, or mouthpiece should be washed in warm, soapy water using a mild detergent. Rinse thoroughly, and allow to air dry. Note: There is no need to clean the tubing that connects the nebulizer to the air compressor.

Disinfect your nebulizer once per week or more frequently as directed. After washing your equipment, disinfect the nebulizer with one of the following methods.

Disposable nebulizers should use one of these cold disinfecting methods:

* Soak in 70% isopropyl alcohol for 5 minutes.
* Soak in 3% hydrogen peroxide for 30 minutes.
* Soak in a one-part white vinegar to 3-part water solution for 30 minutes.
* After any of these cold disinfecting techniques, rinse well and air dry.

Non-disposable nebulizers may be disinfected as described above. They may also be disinfected by any of the following heat disinfecting methods:

* Boil for 5 minutes.
* Microwave in a bowl of water for 5 minutes.
* Put in the dishwasher at 158 degrees Fahrenheit for 30 minutes.
* Use an electric steam sterilizer (baby bottle sterilizer).

Medicine storage

Store all of your medicines in a cool, dry place, and follow the manufacturer’s recommendations.

Check your medicines often. Make sure they have not changed color or formed crystals. If you notice any changes in the appearance of your medicines, throw them away.

Compressor care

* Make sure that your unit is unplugged before you clean it. Keep your air compressor clean by wiping it with a clean damp cloth as needed.
* Do not put the air compressor on the floor during your treatments or while storing.
* Check the air compressor’s filter as directed. Replace or clean or clean the filter according to the directions from your equipment supplier.
* Always have an extra nebulizer cup and mask or mouthpiece.
* You can obtain all of the equipment for your nebulizer therapy through your equipment supplier.

Details

In medicine, a nebulizer (American English) or nebuliser (English) is a drug delivery device used to administer medication in the form of a mist inhaled into the lungs. Nebulizers are commonly used for the treatment of asthma, cystic fibrosis, COPD and other respiratory diseases or disorders. They use oxygen, compressed air or ultrasonic power to break up solutions and suspensions into small aerosol droplets that are inhaled from the mouthpiece of the device. An aerosol is a mixture of gas and solid or liquid particles.

Medical uses:

Guidelines

Various asthma guidelines, such as the Global Initiative for Asthma Guidelines [GINA], the British Guidelines on the management of Asthma, The Canadian Pediatric Asthma Consensus Guidelines, and United States Guidelines for Diagnosis and Treatment of Asthma each recommend metered dose inhalers in place of nebulizer-delivered therapies. The European Respiratory Society acknowledge that although nebulizers are used in hospitals and at home they suggest much of this use may not be evidence-based.

Effectiveness

Recent evidence shows that nebulizers are no more effective than metered-dose inhalers (MDIs) with spacers. An MDI with a spacer may offer advantages to children who have acute asthma. Those findings refer specifically to the treatment of asthma and not to the efficacy of nebulisers generally, as for COPD for example. For COPD, especially when assessing exacerbations or lung attacks, there is no evidence to indicate that MDI (with a spacer) delivered medicine is more effective than administration of the same medicine with a nebulizer.

The European Respiratory Society highlighted a risk relating to droplet size reproducibility caused by selling nebulizer devices separately from nebulized solution. They found this practice could vary droplet size 10-fold or more by changing from an inefficient nebulizer system to a highly efficient one. Two advantages attributed to nebulizers, compared to MDIs with spacers (inhalers), are their ability to deliver larger dosages at a faster rate, especially in acute asthma; however, recent data suggests actual lung deposition rates are the same. In addition, another trial found that an MDI (with spacer) had a lower required dose for clinical result compared to a nebulizer.

Beyond use in chronic lung disease, nebulizers may also be used to treat acute issues like the inhalation of toxic substances. One such example is the treatment of inhalation of toxic hydrofluoric acid (HF) vapors. Calcium gluconate is a first-line treatment for HF exposure to the skin. By using a nebulizer, calcium gluconate is delivered to the lungs as an aerosol to counteract the toxicity of inhaled HF vapors.

Aerosol deposition

The lung deposition characteristics and efficacy of an aerosol depend largely on the particle or droplet size. Generally, the smaller the particle the greater its chance of peripheral penetration and retention. However, for very fine particles below 0.5 μm in diameter there is a chance of avoiding deposition altogether and being exhaled. In 1966 the Task Group on Lung Dynamics, concerned mainly with the hazards of inhalation of environmental toxins, proposed a model for deposition of particles in the lung. This suggested that particles of more than 10 μm in diameter are most likely to deposit in the mouth and throat, for those of 5–10 μm diameter a transition from mouth to airway deposition occurs, and particles smaller than 5 μm in diameter deposit more frequently in the lower airways and are appropriate for pharmaceutical aerosols. Nebulizing processes have been modeled using computational fluid dynamics.

Additional Information

There are different types of medicines and delivery devices to treat COPD. A nebulizer is a device that turns the liquid medicine into a mist which is then inhaled through a mouthpiece or a mask. Sometimes asthma medication is given through a nebulizer as well, so this information can benefit people living with asthma too. With COPD, or any chronic lung disease, taking your medicine correctly is a major part in successfully managing the disease.

Learning how to use your nebulizer and clean it properly is important so that your medications are most effective. These videos offer a step-by-step guide to cleaning and using medications correctly.

How to Use a Nebulizer

Many people with chronic lung diseases such as COPD or asthma use a nebulizer to take their medication in the form of a mist that is inhaled into the lungs.

Nebulizers are often recommended for patients who have a hard time using inhalers because of health issues, or patients who are unable to inhale deeply enough for other devices.

A nebulizer has five basic parts A medicine cup, a top piece or cap to attach to a mask or mouthpiece to the medicine cup.

With your healthcare provider, you can decide which type works best for you. thin plastic tubing connects the mouthpiece to the machine and an air machine called a compressor, which can be plugged into an electrical socket for indoor use, a car adapter for when you are on the go, or battery-operated for portable use while not at home.

With clean hands, take the medicine as prescribed by your healthcare provider, and pour it into the medicine cup. Attach the top piece to the medicine cup, and then the mouthpiece or mask. Connect the tubing from the compressor to the medicine cup.

Put the mask over your face, or put the mouthpiece in your mouth between your teeth, and close your lips tightly around it. Turn on your compressor. Hold the nebulizer in an upright position to prevent spilling and to ensure the medication is correctly distributed.

Take normal regular breaths in through your mouth so that the medicine can go deep into your lungs. Continue until all of the medicine is gone from the cup. For more demonstration videos and information on cleaning and caring for your nebulizer, visit the American Lung Association's website at Lung.org/nebulizer.

How to Clean a Nebulizer

Many people with chronic lung diseases such as COPD or asthma use a nebulizer to take their medication in the form of a mist that is inhaled into the lungs.

Cleaning your nebulizer is important to prevent the spread of germs and keep you from getting sick. It will also keep your device working properly. It is recommended to wash the parts of your nebulizer after each use, including the mouthpiece or mask, top piece, and medicine cup.

To start, take the nebulizer apart by removing the tubing and setting it aside.

The tubing should never be placed under water. Remove the mouthpiece or mask, and medicine cup from the top piece, and place them all into the top shelf of the dishwasher.

Or wash the medicine cup, top piece, and mouthpiece or mask, in warm soapy water, and rinse. Shake off the excess water and let the pieces air-dry in a cool, dry place until the next use.

Your nebulizer will also need a thorough cleaning once a week. Soak the mouthpiece or mask, top piece, and medicine cup in a white vinegar and water solution for 30 minutes, or as recommended by your device manufacturer.

After 30 minutes, rinse and air-dry in a cool, dry place.

Clean the surface of the compressor and the outside of the tubing with a soapy cloth or disinfectant wipe.

The compressor and the tubing should never be submerged in water.

And remember, most compressors have an air filter that will need to be replaced every six months, or as recommended by your manufacturer.

Chemotherapy

Gist

Chemotherapy (often called "chemo") is a type of cancer treatment that uses powerful anti-cancer drugs to destroy fast-growing cells in the body. The goal can be to cure the cancer, control its growth, or ease symptoms.

Chemotherapy itself isn't usually painful during administration (pills, IVs), but the process can cause discomfort from needle sticks, and the drugs often lead to painful side effects like mouth sores, nerve pain (neuropathy), headaches, and body aches, which are manageable with medications and support. Pain levels vary greatly, but reporting any discomfort to your medical team is key, as they can offer relief through anti-nausea meds, pain relievers, or other strategies like acupuncture and massage.

Summary

Chemotherapy is the treatment of diseases by chemical compounds. Chemotherapeutic drugs were originally those employed against infectious microbes, but the term has been broadened to include anticancer and other drugs.

Until the end of the 19th century, most drugs were derived either from minerals or from plants. The researches of Louis Pasteur in France and Robert Koch in Germany laid the foundations of bacteriology. It was Paul Ehrlich, however, who made the greatest contribution to the science (chemotherapy) he named. The problem facing medical scientists was to produce a disinfectant that would destroy parasites within a living animal without serious damage to the host.

William H. Perkin, in England, made the first aniline dye (1856) as a result of abortive attempts to synthesize quinine, the sole antimalarial drug available at that time. About 30 years later, Ehrlich found that a synthetic dye, methylene blue, has antimalarial properties. He had been led to this by a study of the specific staining of organs of an animal or of a parasite following the injection of a synthetic dye. From these studies there emerged (1901–04) Ehrlich’s well-known “side-chain” theory, in which he sought for the first time to correlate the chemical structure of a synthetic drug with its biological effects. In 1903 Ehrlich invented a dye, trypan red, which was the first drug to show activity against trypanosomal infections in mice. Ehrlich’s greatest triumph, however, was the discovery (1910) of the organic math drug Salvarsan, which proved to be effective in the treatment of syphilis. The discovery of other chemotherapeutic agents followed, including mepacrine, proguanil, and chloroquine.

The discovery of Prontosil in the early 1930s proved that antibacterial agents could be developed. Prontosil was the forerunner of the sulfonamide drugs, which came to be widely used for the treatment of bacterial infections in humans and domestic animals.

The discovery of penicillin by Sir Alexander Fleming in 1928, and its practical development by Sir Howard Florey and Ernst Chain, marked another important advance in bacterial chemotherapy. Penicillin, which did not become widely used until World War II, was the first of the so-called antibiotics, and it was followed by other important antibiotics such as streptomycin, the tetracyclines, and the macrolides.

Antibiotics, whether they are produced by living organisms (usually fungi or bacteria) or artificially synthesized, have transformed the modern management of diseases caused by bacteria and most other microorganisms. Paradoxically, the more widely they are used, the greater the likelihood that drug-resistant bacteria will emerge. Bacteria may develop resistance to drugs in several ways: mutation changes in genetic composition; transduction, whereby resistance is transferred from a resistant to a nonresistant strain; transformation, in which a bacterial cell takes from its environment the genes from a resistant form to acquire resistance; and conjugation, in which the organism acquires resistance by cell-to-cell contact.

Another comparative failure of chemotherapy is the lack of drugs to combat viruses (although viral infections can be controlled through prophylactic measures).

Drug modes of action vary. For example, some may act on the bacterial wall, others affect cell membranes, some modify the molecular mechanism for duplication, some change the nucleic acid metabolism, and others change the intermediary metabolism of two interacting organisms.

Cancer chemotherapy is an increasingly important aspect of drug treatment. Alkylating agents (that work by impairing cell division) and antimetabolites (that interfere with enzymes and thus block vital cell processes) are used cytotoxically to attack malignant cells. Steroid hormones are used in the treatment of breast and prostate cancers, and corticosteroids are used to treat leukemia and lymphatic cancers. The periwinkle plant derivatives vincristine and vinblastine have been used effectively in treating Hodgkin’s disease and leukemia.

The alkylating agents and antimetabolites have serious drawbacks. As they cannot distinguish between healthy and malignant cells, these drugs also interfere with actively multiplying noncancerous cells. They also reduce the body’s resistance to infection. Work is being done on tumour-specific agents that attack only cancer cells.

Another area where chemotherapy has had a major, albeit controversial, impact is mental illness. Severe depression, anxiety, and schizophrenia are now treated with various drugs.

Concomitant with the successes of drug therapy has come increasing concern about attendant dangers. Stringent controls are operated by such regulatory agencies as the Food and Drug Administration in the United States and the Committee on Safety of Medicines in the United Kingdom. These bodies ensure the safety of pharmaceuticals before they are placed on the market and monitor any side effects thereafter. Public demands for “watchdog” agencies were triggered in large part by the 1962 Thalidomide tragedy, when thousands of severely deformed children were born to users of that insufficiently tested drug.

Details

Chemotherapy (often abbreviated chemo, sometimes CTX and CTx) is the type of cancer treatment that uses one or more anti-cancer drugs (chemotherapeutic agents or alkylating agents) in a standard regimen. Chemotherapy may be given with a curative intent (which almost always involves combinations of drugs), or it may aim only to prolong life or to reduce symptoms (palliative chemotherapy). Chemotherapy is one of the major categories of the medical discipline specifically devoted to pharmacotherapy for cancer, which is called medical oncology.

The term chemotherapy now means the non-specific use of intracellular poisons to inhibit mitosis (cell division) or to induce DNA damage (so that DNA repair can augment chemotherapy). This meaning excludes the more-selective agents that block extracellular signals (signal transduction). Therapies with specific molecular or genetic targets, which inhibit growth-promoting signals from classic endocrine hormones (primarily estrogens for breast cancer and androgens for prostate cancer), are now called hormonal therapies. Other inhibitions of growth-signals, such as those associated with receptor tyrosine kinases, are targeted therapy.

The use of drugs (whether chemotherapy, hormonal therapy, or targeted therapy) is systemic therapy for cancer: they are introduced into the blood stream (the system) and therefore can treat cancer anywhere in the body. Systemic therapy is often used with other, local therapy (treatments that work only where they are applied), such as radiation, surgery, and hyperthermia.

Traditional chemotherapeutic agents are cytotoxic by means of interfering with cell division (mitosis) but cancer cells vary widely in their susceptibility to these agents. To a large extent, chemotherapy can be thought of as a way to damage or stress cells, which may then lead to cell death if apoptosis is initiated. Many of the side effects of chemotherapy can be traced to damage to normal cells that divide rapidly and are thus sensitive to anti-mitotic drugs: cells in the bone marrow, digestive tract and hair follicles. This results in the most common side-effects of chemotherapy: myelosuppression (decreased production of blood cells, hence that also immunosuppression), mucositis (inflammation of the lining of the digestive tract), and alopecia (hair loss). Because of the effect on immune cells (especially lymphocytes), chemotherapy drugs often find use in a host of diseases that result from harmful overactivity of the immune system against self (so-called autoimmunity). These include rheumatoid arthritis, systemic lupus erythematosus, multiple sclerosis, vasculitis and many others.

Additional Information

Chemotherapy (chemo) is one of the most common treatments for cancer. Learning about how it works and what to expect can help you prepare for treatment and make informed decisions about your care.

What is chemotherapy?

Chemotherapy is a treatment that uses medicines to destroy cancer cells. There are many different types of chemo. They don’t all work exactly the same way, so different types of chemo might be used for different types of cancer. Most are given as an infusion into a vein (IV), but some are given as an injection, taken as pills, or applied to the skin.

What is the goal of chemo?

If your doctor has recommended chemo, it’s important to understand the goal of treatment. This can depend on your type of cancer, its stage (size and location), and how far it has spread. Chemo can have 3 possible treatment goals:

* To cure the cancer (curative intent)
* To control the cancer
* To ease symptoms (palliative intent)

How is chemo different from other cancer treatments?

Chemo is a systemic treatment. It travels through the bloodstream to reach all parts of your body. It can kill cancer cells that have spread (metastasized) to parts of the body far away from the original (primary) tumor or cancer cells in blood cancers, such as leukemia, that have spread throughout the body. This makes chemo different from local treatments like surgery and radiation, which only affect one part of the body.

How does chemotherapy work?

Understanding how chemotherapy works can help you know what to expect during treatment.

Chemotherapy interrupts the cell cycle

Chemotherapy works by affecting cells when they are growing and dividing to make new cells. During this process (called the cell cycle), cells:

* Grow in size
* Make copies of their genetic material (DNA)
* Divide to form new cells

Some cells, such as skin cells, are fast growing, meaning they move through this process quickly. Other cells, such as muscle cells, complete it more slowly. Cancer cells tend to be faster growing, moving through the cell cycle very quickly.

Different types of chemo target cells at different phases of the cell cycle. This is why certain chemo drugs work better for different types of cancer cells, and sometimes different combinations of chemo work better together. Understanding how chemo works also helps doctors plan how often each chemo should be given, and how those doses should be timed.

Chemo affects normal cells, too

Chemo interrupts the cell cycles of normal cells, too – especially cells that grow faster, like hair or skin cells. This is why chemo often causes certain side effects, like hair loss.

The good news is that most normal cells will recover from chemo. Chemo is a useful cancer treatment because cancer cells are abnormal (mutated) and less able to recover from its effects.

To work best, chemo treatments must be at just the right dose to kill the cancer cells while sparing as many normal cells as possible.

Are all medicines used to treat cancer called chemo?

Not all cancer medicines are chemotherapy. Other medicines and biological treatments may be used alone or with chemo or other treatments. They work differently and often have different side effects.

* Targeted therapy: These  find and attack specific proteins or receptors that some cancer cells have, without affecting most normal cells.
* Hormone therapy: These block or lower hormones that help some cancers (like breast, prostate, and endometrial (uterine) cancers) grow. They either stop the body from making the hormone or block the cancer cells from using it.
* Immunotherapy: These help a person's immune system recognize and attack certain types of cancer cells.

Although these treatments can be very effective, they are more specialized than traditional chemo. They might only work on certain types of cancer, often based on specific traits of the cancer cells. And because many of them are newer, less is known about their long-term side effects. Sometimes they are used only when chemo isn’t working or is no longer effective.

What is it like to get chemo?

Most people get chemo as infusions at a clinic or hospital. But some types of chemo can be taken by mouth or applied to the skin at home. Each type has its own routine, side effects, and safety steps. Learn what it’s like to get each type of chemo and how to stay safe during treatment.

Q: What Welsh cheese must you always eat with caution?
A: Caerphilly.
* * *
Q: What do you call a cheese that is an alcoholic?
A: Livarot.
* * *
Q: What is a lions favourite cheese?
A: Roar-quefort.
* * *
Q: What did the piece of Cheddar say to the ghost?
A: I'm Lac-ghost intolerant.
* * *
Q: Why did the one legged clown leave the cheese circus?
A: Because he couldn't get his stilton.
* * *

Watch or Wrist watch

Gist

A wristwatch is worn around the wrist, attached by a watch strap or another type of bracelet, including metal bands or leather straps. A pocket watch is carried in a pocket, often attached to a chain.

The "best" watch depends on your needs: Quartz for accuracy & low cost, Automatic for craftsmanship & tradition, and Smartwatches for tech; choose styles like Field (rugged), Dress (formal), or Chronograph (multi-function) based on lifestyle, ensuring it fits your wrist and reflects your personality. There's no single best, but rather the best for you, balancing convenience, style, and purpose.

Summary

A watch is a timepiece carried or worn by a person. It is designed to maintain a consistent movement despite the motions caused by the person's activities. A wristwatch is worn around the wrist, attached by a watch strap or another type of bracelet, including metal bands or leather straps. A pocket watch is carried in a pocket, often attached to a chain. A stopwatch is a type of watch that measures intervals of time.

During most of their history, beginning in the 16th century, watches were mechanical devices, driven by clockwork, powered by winding a mainspring, and keeping time with an oscillating balance wheel. These are known as mechanical watches. In the 1960s the electronic quartz watch was invented, powered by a battery and keeping time with a vibrating quartz crystal. By the 1980s it had taken over most of the watch market, in what became known as the quartz revolution (or the quartz crisis in Switzerland, whose renowned watch industry it decimated). In the 2010s, smartwatches emerged, small wrist-worn computers with touchscreens and with functions that go far beyond timekeeping.

Modern watches often display the day, date, month, and year. Mechanical watches may have extra features ("complications") such as moon-phase displays and different types of tourbillon. Quartz watches often include timers, chronographs, and alarm functions. Smartwatches and more complicated electronic watches may even incorporate calculators, GPS and Bluetooth technology or have heart-rate monitoring capabilities, and some use radio clock technology to regularly correct the time.

Most watches used mainly for timekeeping have quartz movements. But expensive collectible watches, valued more for their elaborate craftsmanship, aesthetic appeal, and glamorous design than for timekeeping, often have traditional mechanical movements, despite being less accurate and more expensive than their electronic counterparts. As of 2019, the most expensive watch ever sold at auction was the Patek Philippe Grandmaster Chime for US$31.2 million.

Details

A watch is a portable timepiece that has a movement driven either by spring or by electricity and that is designed to be worn or carried in the pocket.

Mechanical watches

The first watches appeared shortly after 1500, early examples being made by Peter Henlein, a locksmith in Nürnberg, Ger. The escapement used in the early watches was the same as that used in the early clocks, the verge. Early watches were made notably in Germany and at Blois in France, among other countries, and were generally carried in the hand or worn on a chain around the neck. They usually had only one hand for the hours.

The mainspring, the element that drives the watch, consists of a flat spring-steel band stressed in bending or coiling; when the watch, or other spring-driven mechanism, is wound, the curvature of the spring is increased, and energy is thus stored. This energy is transmitted to the oscillating section of the watch (called the balance) by the wheeltrain and escapement, the motion of the balance itself controlling the release of the escapement and consequently the timing of the watch. A friction drive permits the hand to be set.

One of the main defects of the early watches was the variation in the torque exerted by the mainspring; that is, the force of the mainspring was greater when fully wound than when it was almost run down. Since the timekeeping of a watch fitted with a verge escapement was greatly influenced by the force driving it, this problem was quite serious. Solution of the problem was advanced almost as soon as the mainspring was invented (about 1450) by the application of the fusee, a cone-shaped, grooved pulley used together with a barrel containing the mainspring. With this arrangement, the mainspring was made to rotate a barrel in which it was housed; a length of catgut, later replaced by a chain, was wound on it, the other end being coiled around the fusee. When the mainspring was fully wound, the gut or chain pulled on the smallest radius of the cone-shaped fusee; as the mainspring ran down, the leverage was progressively increased as the gut or chain pulled on a larger radius. With correct proportioning of mainspring and fusee radii, an almost constant torque was maintained as the mainspring unwound.

The going barrel, in which the mainspring barrel drives the wheeltrain directly, is fitted to all modern mechanical watches and has superseded the fusee. With better quality mainsprings, torque variations have been reduced to a minimum, and with a properly adjusted balance and balance spring, good timekeeping is ensured.

Up to about 1580, the mechanisms of German watches were made almost wholly of iron; about this time, brass was introduced.

In the earliest watches a plain wheel, known as the balance, was used to control the rate of going of the mechanism. It was subjected to no consistent restoring force; consequently, its period of oscillation and, hence, the rate of the timekeeper were dependent on the driving force. This explains the great importance of the fusee.

Controlling the oscillations of a balance with a spring was an important step in the history of timekeeping. English physicist Robert Hooke designed a watch with a balance spring in the late 1650s; there appears to be no evidence, however, that the spring was in the form of a spiral, a crucial element that would become widely employed. Dutch scientist Christiaan Huygens was probably the first to design (1674–75) a watch with a spiral balance spring. The balance spring is a delicate ribbon of steel or other suitable spring material, generally wound into a spiral form. The inner end is pinned into a collet (a small collar), which fits friction-tight on the balance staff, while the outer end is held in a stud fixed to the movement. This spring acts on the balance as gravity does on the pendulum. If the balance is displaced to one side, the spring is wound and energy stored in it; this energy is then restored to the balance, causing it to swing nearly the same distance to the other side if the balance is released.

If there were no frictional losses (e.g., air friction, internal friction in the spring material, and friction at the pivots), the balance would swing precisely the same distance to the other side and continue to oscillate indefinitely; because of these losses, however, the oscillations in practice die away. It is the energy stored in the mainspring and fed to the balance through the wheel train and escapement that maintains the oscillations.

The performance of the modern watch depends on the uniformity of the period of oscillation of the balance—i.e., the regularity of its movement. The balance takes the form of a wheel with a heavy rim, while the spring coupled to it provides the restoring torque. The balance possesses inertia, dependent on its mass and configuration. The spring should ideally provide a restoring force directly proportional to the displacement from its unstressed or zero position.

The balance is mounted on a staff with pivots, and, in watches of good quality, these run in jewels. Two jewels are used at each end of the balance staff, one pierced to provide a bearing, the other a flat end stone providing axial location by bearing against the domed end of the pivot. Frictional effects at the pivots influence the performance of the watch in various positions—for example, lying and hanging.

The balance and spring can be brought to time, or “regulated,” by varying either the restoring couple provided by the spring or the moment of inertia of the balance. In the first case (by far the more common), this is generally effected by providing a pair of curb pins mounted on a movable regulator index that lengthen or shorten the balance spring as needed.

In the second instance, screws are provided at opposite points on the rim of the balance; these screws are friction-tight in their holes and thus can be moved in or out so as to adjust the inertia of the balance. In “free-sprung” watches no regulator index is provided, and the only adjusters are the screws on the balance rim.

Many modern mechanical watches use a lever escapement, invented in England about 1755 by Thomas Mudge, that leaves the balance free to oscillate, coupling to it only while delivering the impulse, taken from the mainspring via the wheel train and while being unlocked by the balance. It was developed into its modern form with the club-tooth escape wheel at the beginning of the 19th century but was not universally adopted until the early 20th century. In good-quality watches the club-tooth escape wheel is made of hardened steel, with the acting surfaces ground and polished. An improved form of the lever escapement is characterized by a double-roller safety action in which the intersection between the guard pin and roller, which takes place underneath the roller, is much deeper than in early single-roller watches; thus, any friction caused by jolts encountered in wear causes less constraint on the balance and less endangerment of the timekeeping properties of the watch. By far the most important watch escapement today is the lever escapement; it is used in its jeweled form in watches of moderate to excellent quality, and it is used with steel pallet pins and a simplified fork-and-roller action in cheaper watches (known as pin-pallet watches).

In the wheel train of a modern watch, it is necessary to achieve a step-up ratio of approximately 1 to 4,000 between barrel and escape wheel. This involves four pairs of gears, the ratio per pair commonly being between 6 to 1 and 10 to 1. Because of space considerations, the pinions must have a low number of leaves (teeth), commonly 6 to 12. This entails a number of special gearing problems, aggravated by the fineness of the pitch. Any error in centre distance, form, or concentricity is therefore proportionately more important than in larger gear trains.

The first patent covering the application of jewels in watches was taken out in London in 1704; diamonds and sapphires were used. Synthetic jewels made from fused powdered alumina (aluminum oxide) are now commonly used. Watch jewels are given a very high polish; a uniform outside diameter for the jewel bearings is highly important, because they are pressed into accurately sized holes smaller than the jewels themselves and held there by friction.

The first patent on the self-winding pocket watch was taken out in London in 1780. An English invention patented in 1924, the self-winding wristwatch by Louis Recordon, contains a swinging weight pivoted at the centre of the movement, coupled to the barrel arbor through reduction wheels and gears. A more modern self-winding watch is fitted with a weight or rotor swinging 360 degrees and winding in both directions.

Electric-powered and electronic watches

Electric-powered watches use one of three drive systems: (1) the galvanometer drive, consisting of the conventional balance-hairspring oscillator, kept in motion by the magnetic interaction of a coil and a permanent magnet, (2) the induction drive, in which an electromagnet attracts a balance containing soft magnetic material, or (3) the resonance drive, in which a tiny tuning fork (about 25 mm [1 inch] in length), driven electrically, provides the motive power. Both galvanometer and induction drive types use a mechanical contact, actuated by the balance motion, to provide properly timed electric-drive pulses. Each oscillation of the balance operates a time-indicating gear train by advancing a toothed wheel one tooth. First produced in 1953, the resonance drive type, properly called an electronic watch, is inherently more accurate since it operates at a frequency higher than that customarily used with balance-type watches, and the tuning fork is a fairly stable source of frequency. The higher frequency requires the replacement of a mechanical contact by a transistor. The minute and rapid motion of the tuning fork moves forward an extremely fine-toothed ratchet wheel. There is very little friction in the electronic watch; only tiny amounts of oil are needed. When the battery is too weak to operate the tuning fork, the watch simply stops, without deterioration. Miniature high-energy-density batteries are used as power sources in all three types.

The progressive miniaturization of electronic components in the late 20th century made possible the development of all-electronic watches, in which the necessary transistors, resistors, capacitors, and other elements were all on one or several miniature integrated circuits, or chips. The complex circuitry of such watches enabled them to perform a variety of timekeeping functions and also made possible digital readouts of the time in place of the traditional second, minute, and hour hands.

Additional Information

A wristwatch is a small, portable timepiece worn on the wrist, attached by a strap or bracelet, designed to keep consistent time despite a person's movements. Functioning as both a practical tool for telling time and a fashion accessory, wristwatches range from traditional mechanical or quartz models to modern smartwatches with advanced digital capabilities like fitness tracking and smartphone connectivity.

Wearing a watch offers benefits beyond just telling time, including improved time management, self-expression through style, a break from phone distractions, increased confidence, and the potential for sentimental value as a keepsake or heirloom, while also acting as a functional tool for fitness or notifications, especially with smartwatches. 

Collective Quotes - I

1. Really, the only thing that makes sense is to strive for greater collective enlightenment. - Elon Musk

2. The press should be not only a collective propagandist and a collective agitator, but also a collective organizer of the masses. - Vladimir Lenin

3. Duty is not collective; it is personal. - Calvin Coolidge

4. Collective fear stimulates herd instinct, and tends to produce ferocity toward those who are not regarded as members of the herd. - Bertrand Russell

5. You have many years ahead of you to create the dreams that we can't even imagine dreaming. You have done more for the collective unconscious of this planet than you will ever know. - Steven Spielberg

6. Money is our madness, our vast collective madness. - D. H. Lawrence

7. I don't believe in collective guilt, but I do believe in collective responsibility. - Audrey Hepburn

8. In America, it was decided to attempt the production of atomic bombs with an effort that would constitute a large part of the collective American war effort. In Germany, an effort one thousandth the scale of the American was applied to the problem of producing atomic energy that would drive engines. - Werner Heisenberg.

Q: What group of cheese has been known to fly?
A: Curds of prey!
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Q: What is the name of the country near Iraq that is made entirely of cheese?
A: Curd-istan.
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Q: What does a lady in a mall do with a cheesey credit card?
A: Go on a shopping brie.
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Q: What cheese surrounds a medieval castle?
A: Moatzeralla.
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Q: What cheese should you use to hide a horse?
A: Mascarpone.
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