Math Is Fun Forum

2447) Laughing Gas

Gist

Laughing gas is the common name for nitrous oxide (N2O), a colorless gas with a slightly sweet odor and taste that is used medically as an anesthetic and pain reliever, particularly in dentistry and surgery. It is also used as a propellant in whipped cream, as an oxidizer in rocket engines, and has recreational uses for its euphoric effects. In the environment, it is a powerful greenhouse gas and a major contributor to ozone depletion. 

Laughing gas is the common name for nitrous oxide (N2O), a colorless gas with a slightly sweet odor and taste that is used medically as an anesthetic and pain reliever, particularly in dentistry and surgery. It is also used as a propellant in whipped cream, as an oxidizer in rocket engines, and has recreational uses for its euphoric effects. In the environment, it is a powerful greenhouse gas and a major contributor to ozone depletion. 

N2O is called laughing gas because inhaling it produces euphoric, giggling effects due to its anesthetic properties. This colloquial name was given by Humphry Davy, and the gas's ability to cause a brief "high" is why it's used recreationally. 

Summary

Nitrous oxide (dinitrogen oxide or dinitrogen monoxide), commonly known as laughing gas, nitrous, or factitious air, among others, is a chemical compound, an oxide of nitrogen with the formula N2O. At room temperature, it is a colourless non-flammable gas, and has a slightly sweet scent and taste. At elevated temperatures, nitrous oxide is a powerful oxidiser similar to molecular oxygen.

Nitrous oxide has significant medical uses, especially in surgery and dentistry, for its anaesthetic and pain-reducing effects, and it is on the World Health Organization's List of Essential Medicines. Its colloquial name, "laughing gas", coined by Humphry Davy, describes the euphoric effects upon inhaling it, which cause it to be used as a recreational drug inducing a brief "high". When abused chronically, it may cause neurological damage through inactivation of vitamin B12. It is also used as an oxidiser in rocket propellants and motor racing fuels, and as a frothing gas for whipped cream.

Nitrous oxide is also an atmospheric pollutant, with a concentration of 333 parts per billion (ppb) in 2020, increasing at 1 ppb annually. It is a major scavenger of stratospheric ozone, with an impact comparable to that of CFCs. About 40% of human-caused emissions are from agriculture, as nitrogen fertilisers are digested into nitrous oxide by soil micro-organisms. As the third most important greenhouse gas, nitrous oxide substantially contributes to global warming. Reduction of emissions is an important goal in the politics of climate change.

(CFC: Chlorofluorocarbons).

Details:

Nitrous oxide (laughing gas) is a sedative healthcare providers use to keep you comfortable during procedures. It’s a colorless, faintly sweet-smelling gas that you breathe in through a nosepiece. Unlike other sedation options, you can drive shortly after receiving nitrous oxide.

What is nitrous oxide (laughing gas)?

Nitrous oxide (N20) — commonly known as laughing gas — is a type of short-acting sedative. It’s a colorless, slightly sweet-smelling gas that you breathe in through a mask or nosepiece.

Physicians and dentists have been using nitrous oxide since the mid-19th century — and it’s still one of the most common inhaled sedatives used today. It’s fast-acting and it wears off quickly, making it an ideal sedation option for short or minor procedures.

What does laughing gas do?

Nitrous oxide slows down your nervous system and induces a sense of calm and euphoria. It reduces anxiety and helps you stay comfortable during medical or dental procedures. It doesn’t fully put you to sleep, so you’ll still be able to respond to your provider’s questions or instructions.

Despite its name, laughing gas might not make you laugh. (But then again, it could.) Everyone responds a little differently.

Nitrous oxide takes effect quickly. Within three to five minutes, you might feel:

* Calm.
* Relaxed.
* Happy.
* Giggly.
* Mildly euphoric.
* Light-headed.
* Tingling in your arms and legs.
* Heaviness, like you’re sinking deeper into the exam chair or table.

Who shouldn’t use nitrous oxide sedation?

Laughing gas is a safe medical and dental sedation option for most people, from children to adults. But it might not be right for kids under the age of 2 and those with:

* Certain respiratory conditions, like chronic obstructive pulmonary disease (COPD).
* Stuffy nose (nasal congestion).
* Vitamin B12 deficiency.
* Severe psychiatric conditions.

Ask your healthcare provider whether you’re a candidate for nitrous oxide sedation.

Treatment Details:

What should I expect if I’m getting laughing gas?

Your healthcare provider will talk with you and answer any questions before your procedure. They’ll ask you to sign a consent form so you can receive nitrous oxide.

When it’s time for your procedure, your provider will:

* Place a mask over your nose and mouth. (If you’re getting laughing gas at your dentist’s office, they’ll give you a smaller mask that only covers your nose.)
* Open a tank valve to allow nitrous oxide and oxygen to flow into your mask. (They’ll start with a very low dose to see how you respond.)
* Adjust the dosage until you feel the desired effects.
* Do your procedure. (In many cases, your provider will also give you local anesthesia before beginning. This is because nitrous oxide reduces pain but won’t totally eliminate it. So, it’s common to combine it with other forms of anesthesia.)
* Stop the flow of laughing gas once your procedure is over.
* Ask you to breathe in pure oxygen through your mask until you feel alert again.
* Remove the mask from your face.
* Monitor you for a few minutes before releasing you to go home.

It’s normal to feel a little nervous if you’ve never had laughing gas before. The good news is that you’ll be able to tell your provider if you develop undesirable side effects. If you start to feel dizzy or nauseous, your provider can simply adjust the dosage until it feels comfortable to you.

How long does laughing gas last?

The effects of nitrous oxide last until your provider turns off the gas flow. Once this happens, it takes about 5 to 10 minutes for the sedative to leave your system and for your headspace to return to normal. Due to the short-acting nature of nitrous oxide, you can drive shortly after your procedure.

Additional Information

Nitrous oxide (N2O), one of several oxides of nitrogen, is a colourless gas with pleasant, sweetish odour and taste, which when inhaled produces insensibility to pain preceded by mild hysteria, sometimes laughter. (Because inhalation of small amounts provides a brief euphoric effect and nitrous oxide is not illegal to possess, the substance has been used as a recreational drug.) Nitrous oxide was discovered by the English chemist Joseph Priestley in 1772; another English chemist, Humphry Davy, later named it and showed its physiological effect. A principal use of nitrous oxide is as an anesthetic in surgical operations of short duration; prolonged inhalation causes death. The gas is also used as a propellant in food aerosols. In automobile racing, nitrous oxide is injected into an engine’s air intake; the extra oxygen allows the engine to burn more fuel per stroke. It is prepared by the action of zinc on dilute nitric acid, by the action of hydroxylamine hydrochloride (NH2OH·HCl) on sodium nitrite (NaNO2), and, most commonly, by the decomposition of ammonium nitrate (NH4NO3).

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#5465. What does the adjective certifiable mean?

#5466. What does the adjective ceremonious mean?

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#6301.

2394) Richard Feynman

Gist:

Work

Following the establishment of the theory of relativity and quantum mechanics, an initial relativistic theory was formulated for the interaction between charged particles and electromagnetic fields. This needed to be reformulated, however. In 1948 in particular, Richard Feynman contributed to creating a new quantum electrodynamics by introducing Feynman diagrams: graphic representations of various interactions between different particles. These diagrams facilitate the calculation of interaction probabilities.

Summary

Richard Phillips Feynman (May 11, 1918 – February 15, 1988) was an American theoretical physicist. He is best known for his work in the path integral formulation of quantum mechanics, the theory of quantum electrodynamics, the physics of the superfluidity of supercooled liquid helium, and in particle physics, for which he proposed the parton model. For his contributions to the development of quantum electrodynamics, Feynman received the Nobel Prize in Physics in 1965 jointly with Julian Schwinger and Shin'ichirō Tomonaga.

Feynman developed a pictorial representation scheme for the mathematical expressions describing the behavior of subatomic particles, which later became known as Feynman diagrams and is widely used. During his lifetime, Feynman became one of the best-known scientists in the world. In a 1999 poll of 130 leading physicists worldwide by the British journal Physics World, he was ranked the seventh-greatest physicist of all time.

He assisted in the development of the atomic bomb during World War II and became known to the wider public in the 1980s as a member of the Rogers Commission, the panel that investigated the Space Shuttle Challenger disaster. Along with his work in theoretical physics, Feynman has been credited with having pioneered the field of quantum computing and introducing the concept of nanotechnology. He held the Richard C. Tolman professorship in theoretical physics at the California Institute of Technology.

Feynman was a keen popularizer of physics through both books and lectures, including a talk on top-down nanotechnology, "There's Plenty of Room at the Bottom" (1959) and the three-volumes of his undergraduate lectures, The Feynman Lectures on Physics (1961–1964). He delivered lectures for lay audiences, recorded in The Character of Physical Law (1965) and QED: The Strange Theory of Light and Matter (1985). Feynman also became known through his autobiographical books Surely You're Joking, Mr. Feynman! (1985) and What Do You Care What Other People Think? (1988), and books written about him such as Tuva or Bust! by Ralph Leighton and the biography Genius: The Life and Science of Richard Feynman by James Gleick.

Details

Richard Feynman (born May 11, 1918, New York, New York, U.S.—died February 15, 1988, Los Angeles, California) was an American theoretical physicist who was widely regarded as the most brilliant, influential, and iconoclastic figure in his field in the post-World War II era.

Feynman remade quantum electrodynamics—the theory of the interaction between light and matter—and thus altered the way science understands the nature of waves and particles. He was co-awarded the Nobel Prize for Physics in 1965 for this work, which tied together in an experimentally perfect package all the varied phenomena at work in light, radio, electricity, and magnetism. The other cowinners of the Nobel Prize, Julian S. Schwinger of the United States and Tomonaga Shin’ichirō of Japan, had independently created equivalent theories, but it was Feynman’s that proved the most original and far-reaching. The problem-solving tools that he invented—including pictorial representations of particle interactions known as Feynman diagrams—permeated many areas of theoretical physics in the second half of the 20th century.

Born in the Far Rockaway section of New York City, Feynman was the descendant of Russian and Polish Jews who had immigrated to the United States late in the 19th century. He studied physics at the Massachusetts Institute of Technology, where his undergraduate thesis (1939) proposed an original and enduring approach to calculating forces in molecules. Feynman received his doctorate at Princeton University in 1942. At Princeton, with his adviser, John Archibald Wheeler, he developed an approach to quantum mechanics governed by the principle of least action. This approach replaced the wave-oriented electromagnetic picture developed by James Clerk Maxwell with one based entirely on particle interactions mapped in space and time. In effect, Feynman’s method calculated the probabilities of all the possible paths a particle could take in going from one point to another.

During World War II Feynman was recruited to serve as a staff member of the U.S. atomic bomb project at Princeton University (1941–42) and then at the new secret laboratory at Los Alamos, New Mexico (1943–45). At Los Alamos he became the youngest group leader in the theoretical division of the Manhattan Project. With the head of that division, Hans Bethe, he devised the formula for predicting the energy yield of a nuclear explosive. Feynman also took charge of the project’s primitive computing effort, using a hybrid of new calculating machines and human workers to try to process the vast amounts of numerical computation required by the project. He observed the first detonation of an atomic bomb on July 16, 1945, near Alamogordo, New Mexico, and, though his initial reaction was euphoric, he later felt anxiety about the force he and his colleagues had helped unleash on the world.

At war’s end Feynman became an associate professor at Cornell University (1945–50) and returned to studying the fundamental issues of quantum electrodynamics. In the years that followed, his vision of particle interaction kept returning to the forefront of physics as scientists explored esoteric new domains at the subatomic level. In 1950 he became professor of theoretical physics at the California Institute of Technology (Caltech), where he remained the rest of his career.

Five particular achievements of Feynman stand out as crucial to the development of modern physics. First, and most important, is his work in correcting the inaccuracies of earlier formulations of quantum electrodynamics, the theory that explains the interactions between electromagnetic radiation (photons) and charged subatomic particles such as electrons and positrons (antielectrons). By 1948 Feynman completed this reconstruction of a large part of quantum mechanics and electrodynamics and resolved the meaningless results that the old quantum electrodynamic theory sometimes produced. Second, he introduced simple diagrams, now called Feynman diagrams, that are easily visualized graphic analogues of the complicated mathematical expressions needed to describe the behaviour of systems of interacting particles. This work greatly simplified some of the calculations used to observe and predict such interactions.

In the early 1950s Feynman provided a quantum-mechanical explanation for the Soviet physicist Lev D. Landau’s theory of superfluidity—i.e., the strange, frictionless behaviour of liquid helium at temperatures near absolute zero. In 1958 he and the American physicist Murray Gell-Mann devised a theory that accounted for most of the phenomena associated with the weak force, which is the force at work in radioactive decay. Their theory, which turns on the asymmetrical “handedness” of particle spin, proved particularly fruitful in modern particle physics. And finally, in 1968, while working with experimenters at the Stanford Linear Accelerator on the scattering of high-energy electrons by protons, Feynman invented a theory of “partons,” or hypothetical hard particles inside the nucleus of the atom, that helped lead to the modern understanding of quarks.

Feynman’s stature among physicists transcended the sum of even his sizable contributions to the field. His bold and colourful personality, unencumbered by false dignity or notions of excessive self-importance, seemed to announce: “Here is an unconventional mind.” He was a master calculator who could create a dramatic impression in a group of scientists by slashing through a difficult numerical problem. His purely intellectual reputation became a part of the scenery of modern science. Feynman diagrams, Feynman integrals, and Feynman rules joined Feynman stories in the everyday conversation of physicists. They would say of a promising young colleague, “He’s no Feynman, but….” His fellow physicists envied his flashes of inspiration and admired him for other qualities as well: a faith in nature’s simple truths, a skepticism about official wisdom, and an impatience with mediocrity.

Feynman’s lectures at Caltech evolved into the books Quantum Electrodynamics (1961) and The Theory of Fundamental Processes (1961). In 1961 he began reorganizing and teaching the introductory physics course at Caltech; the result, published as The Feynman Lectures on Physics, 3 vol. (1963–65), became a classic textbook. Feynman’s views on quantum mechanics, scientific method, the relations between science and religion, and the role of beauty and uncertainty in scientific knowledge are expressed in two models of science writing, again distilled from lectures: The Character of Physical Law (1965) and QED: The Strange Theory of Light and Matter (1985).

When Feynman died in 1988 after a long struggle with cancer, his reputation was still mainly confined to the scientific community; his was not a household name. Many Americans had seen him for the first time when, already ill, he served on the presidential commission that investigated the 1986 explosion of the space shuttle Challenger. He conducted a dramatic demonstration at a televised hearing, confronting an evasive NASA witness by dunking a piece of rubber seal in a glass of ice water to show how predictable the failure of the booster rocket’s rubber seal might have been on the freezing morning of Challenger’s launch. He added his own appendix to the commission’s report on the disaster, emphasizing the space agency’s failures of risk management.

He achieved a growing popular fame after his death, in part because of two autobiographical collections of anecdotes published in the years around his passing, “Surely You’re Joking, Mr. Feynman!”: Adventures of a Curious Character (1985) and “What Do You Care What Other People Think?”: Further Adventures of a Curious Character (1988), which irritated some of his colleagues by emphasizing his bongo playing and his patronage of a topless bar more than his technical accomplishments. Other popular books appeared posthumously, including Six Easy Pieces: Essentials of Physics Explained by Its Most Brilliant Teacher (1994) and Six Not-So-Easy Pieces: Einstein’s Relativity, Symmetry, and Space-Time (1997), and his life was celebrated in an opera (Feynman [2005], by Jack Vees), a graphic novel (Feynman [2011], by Jim Ottaviani and Leland Myrick), and a play (QED [2001], by Peter Parnell), the latter of which was commissioned by and starred Alan Alda.

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#5463. What does the noun bottleful mean?

#5464. What does the adjective bouncy mean?

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#2526. What does the medical term Motor control mean?

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#9805.

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2651.

2445) Nitric Oxide

Gist

Nitric oxide (NO) is a colorless gas with the chemical formula NO, which acts as an important signaling molecule in the human body and is also an air pollutant. In the body, it relaxes blood vessels to improve blood flow, aids in neurotransmission, and plays a role in immune responses and other cellular processes. Industrially, it is a source of pollution and can be produced by high temperatures or chemical reactions.  

Nitric oxide is used for medical purposes, such as treating respiratory failure in newborns and helping with erectile dysfunction, and is also used in industrial applications. In the body, it's crucial for vasodilation (widening blood vessels), which helps regulate blood flow, blood pressure, and other physiological processes. 

Summary

Nitric oxide (nitrogen oxide, nitrogen monooxide, or nitrogen monoxide) is a colorless gas with the formula NO. It is one of the principal oxides of nitrogen. Nitric oxide is a free radical: it has an unpaired electron, which is sometimes denoted by a dot in its chemical formula (•N=O or •NO). Nitric oxide is also a heteronuclear diatomic molecule, a class of molecules whose study spawned early modern theories of chemical bonding.

An important intermediate in industrial chemistry, nitric oxide forms in combustion systems and can be generated by lightning in thunderstorms. In mammals, including humans, nitric oxide is a signaling molecule in many physiological and pathological processes. It was proclaimed the "Molecule of the Year" in 1992. The 1998 Nobel Prize in Physiology or Medicine was awarded for discovering nitric oxide's role as a cardiovascular signalling molecule. Its impact extends beyond biology, with applications in medicine, such as the development of sildenafil (Viagra), and in industry, including semiconductor manufacturing.

Nitric oxide should not be confused with nitrogen dioxide (NO2), a brown gas and major air pollutant, or with nitrous oxide (N2O), an anesthetic gas.

Details

Nitric oxide (NO) is a colorless, odorless gas molecule that plays a crucial role in various physiological processes within the human body. It was first discovered in the 18th century, but its significance in biological systems wasn’t fully understood until the late 20th century.

In the body, NO acts as a signaling molecule, participating in the regulation of numerous functions, including vasodilation (the widening of blood vessels), neurotransmission, immune response, and the regulation of inflammation. One of its most notable roles is in the regulation of blood pressure, where it helps to relax and widen blood vessels, thereby improving blood flow.

What is nitric oxide?

Nitric oxide (NO) is a molecule composed of one nitrogen atom and one oxygen atom. It is a colorless and odorless gas at room temperature. It is a crucial signaling molecule in the body involved in various physiological processes.

One of its primary roles is as a vasodilator, meaning it relaxes and widens blood vessels, leading to increased blood flow. This function is vital for regulating blood pressure and delivering oxygen and nutrients to tissues throughout the body.

Nitric oxide also acts as a neurotransmitter. Additionally, it plays a role in the immune system, helping to combat pathogens and regulate inflammation.

Synthesis

NO is synthesized in the body through a process involving the conversion of the amino acid arginine into nitric oxide and citrulline. This synthesis is catalyzed by a family of enzymes called nitric oxide synthases (NOS).

There are three isoforms of nitric oxide synthase:

* Endothelial NOS (eNOS): Found primarily in endothelial cells lining blood vessels, eNOS produces nitric oxide in response to various physiological stimuli, such as shear stress and certain hormones.
* Neuronal NOS (nNOS or NOS1): Present in neurons of the central and peripheral nervous systems, nNOS is involved in neurotransmission and neuromodulation, synthesizing nitric oxide in response to calcium influx during neuronal activation.
* Inducible NOS (iNOS or NOS2): Induced in response to inflammatory stimuli, such as cytokines and bacterial endotoxins, iNOS produces large amounts of NO for immune defense mechanisms and inflammation regulation.

The synthesis of nitric oxide by nitric oxide synthases involves several steps:

* L-arginine binding: The enzyme binds the substrate L-arginine, along with other cofactors such as tetrahydrobiopterin (BH4) and oxygen (O2).
* Conversion to L-citrulline and nitric oxide: Through a series of enzymatic reactions involving the cofactors and molecular oxygen, nitric oxide synthase catalyzes the conversion of L-arginine into nitric oxide and L-citrulline.
* Release of nitric oxide: Once synthesized, NO is released from the enzyme and diffuses freely across cell membranes to exert its physiological effects.

Functions

NO is a versatile molecule with numerous functions in the human body. Some of its key functions include:

* Vasodilation: NO acts as a potent vasodilator, meaning it relaxes and widens blood vessels. This helps to improve blood flow and regulate blood pressure.
* Neurotransmission: Serves as a signaling molecule in the nervous system, facilitating communication between nerve cells (neurons). It plays a role in neurotransmission, synaptic plasticity, and other neurological processes.
* Immune response: It is involved in the immune system’s defense against pathogens. It helps to regulate inflammation and can be produced by immune cells to kill invading bacteria, viruses, and parasites.
* Regulation of platelet function: Helps to regulate platelet aggregation, which is important for preventing excessive blood clotting and maintaining cardiovascular health.
* Smooth muscle relaxation: It relaxes smooth muscles found in various organs and tissues, including the gastrointestinal tract, airways, and urinary bladder. This relaxation helps to regulate processes such as digestion, breathing, and urination.
* Angiogenesis: It plays a role in angiogenesis, the formation of new blood vessels from existing ones. This process is important for tissue repair, wound healing, and the growth of tumors.
* Penile erection: It  is a key mediator of penile erection. It stimulates the relaxation of smooth muscle cells in the erectile tissue of the male reproductive organ, leading to increased blood flow and the attainment of an erection.
* Regulation of mitochondrial function: It can modulate mitochondrial respiration and energy production within cells, influencing cellular metabolism and overall energy balance.
* Regulation of gene expression: It can also act as a signaling molecule within cells to regulate gene expression and various cellular processes, including cell proliferation, differentiation, and apoptosis (programmed cell death).

NO rich foods

There are several foods that are naturally rich in nitrates, which can be converted into NO in the body. These foods include:

* Leafy greens: Spinach, kale, arugula, and other leafy greens are high in nitrates.
* Celery: Celery is another vegetable that contains nitrates and can contribute to nitric oxide production.
* Garlic: Garlic contains compounds that can stimulate nitric oxide production and promote cardiovascular health.
* Citrus fruits: Oranges, lemons, and other citrus fruits are rich in vitamin C, which can help support nitric oxide production.
* Pomegranate: Pomegranate juice and seeds contain antioxidants and nitrates that may support NO levels and cardiovascular health.
* Watermelon: Watermelon contains an amino acid called citrulline, which can be converted into arginine, a precursor to nitric oxide.
* Nitrates in Vegetables: Nitrates are compounds found in certain vegetables that can be converted into NO in the body. Examples of nitrate-rich vegetables include spinach, arugula, kale, beetroot, and lettuce.
* Beets and Beetroot Juice: Beets and beetroot juice are well-known for their high nitrate content, which can be converted into nitric oxide.
* Dark Chocolate: Dark chocolate contains flavonoids, which have been shown to support nitric oxide production and cardiovascular health.

Interaction with other drugs

NO can interact with various drugs due to its role as a signaling molecule in many physiological processes. Some interactions include:

* Blood pressure medications: NO donors or drugs that increase NO levels, such as nitroglycerin or other nitrate medications, can enhance the effects of blood pressure-lowering medications like antihypertensives. This interaction can lead to excessive hypotension (low blood pressure).
* Erectile dysfunction drugs: Drugs used to treat erectile dysfunction, such as sildenafil (Viagra), tadalafil (Cialis), and vardenafil (Levitra), work by enhancing the effects of NO, leading to vasodilation and improved blood flow. Combining these drugs with other NO donors or medications that increase NO levels can potentiate their effects and may cause a dangerous drop in blood pressure.
* Anticoagulants and antiplatelet drugs: NO inhibits platelet aggregation and can increase bleeding risk. Combining NO donors or medications that increase NO levels with anticoagulants (e.g., warfarin, heparin) or antiplatelet drugs (e.g., aspirin, clopidogrel) may further enhance the risk of bleeding.
* Drugs affecting nitric oxide synthesis: Medications that affect the synthesis of NO, such as inhibitors of NO synthase (NOS), may interact with drugs that rely on NO signaling for their effects. These interactions can affect cardiovascular function, neurotransmission, and immune response.
* Alpha-blockers: Alpha-blockers, used to treat conditions like benign prostatic hyperplasia (BPH) and hypertension, can interact with NO donors or drugs that increase NO levels, leading to additive effects on blood pressure lowering.
* Drugs affecting cytochrome P450 enzymes: Some drugs can affect the activity of cytochrome P450 enzymes, which are involved in the metabolism of NO donors and other drugs. Interactions with these drugs can alter the metabolism and effectiveness of medications that affect NO levels.

Side effects

While NO is essential for various physiological functions in the body, including vasodilation and neurotransmission, excessive intake or production of nitric oxide can lead to potential complications. Here are some of the possible complications associated with taking excessive amounts of nitric oxide:

* Hypotension: Excessive nitric oxide can cause a significant drop in blood pressure (hypotension). This can lead to symptoms such as dizziness, lightheadedness, fainting, and in severe cases, shock.
* Headaches: Increased levels of nitric oxide can cause headaches, which may range from mild to severe and can be debilitating for some individuals.
* Increased bleeding risk: NO can inhibit platelet aggregation and contribute to increased bleeding risk. Excessive nitric oxide production may lead to prolonged bleeding and difficulty in clot formation.
* Worsening of respiratory conditions: In individuals with certain respiratory conditions such as asthma, excessive nitric oxide production can exacerbate symptoms by causing airway dilation and inflammation.
* Nitric oxide toxicity: In rare cases, excessive exposure to NO gas, particularly in industrial or occupational settings, can lead to toxicity, causing respiratory distress, lung damage, and even death.
* Formation of reactive nitrogen species: Excessive nitric oxide can react with other molecules in the body to form reactive nitrogen species, such as peroxynitrite, which can contribute to oxidative stress, tissue damage, and inflammation.

Additional Information

Nitric oxide (NO) is a colourless toxic gas that is formed by the oxidation of nitrogen. Nitric oxide performs important chemical signaling functions in humans and other animals and has various applications in medicine. It has few industrial applications. It is a serious air pollutant generated by automotive engines and thermal power plants.

Nitric oxide is formed from nitrogen and oxygen by the action of electric sparks or high temperatures or, more conveniently, by the action of dilute nitric acid upon copper or mercury. It was first prepared about 1620 by the Belgian scientist Jan Baptista van Helmont, and it was first studied in 1772 by the English chemist Joseph Priestley, who called it “nitrous air.”

Nitric oxide liquefies at −151.8 °C (−241.2 °F) and solidifies at −163.6 °C (−262.5 °F); both the liquid and the solid are blue in colour. The gas is almost insoluble in water, but it dissolves rapidly in a slightly alkaline solution of sodium sulfite, forming the compound sodium dinitrososulfite, Na2(NO)2SO3. It reacts rapidly with oxygen to form nitrogen dioxide, NO2. Nitric oxide is a relatively unstable, diatomic molecule that possesses a free radical (i.e., an unpaired electron). The molecule can gain or lose one electron to form the ions NO− or NO+.

In the chemical industry, nitric oxide is an intermediate compound formed during the oxidation of ammonia to nitric acid. An industrial procedure for the manufacture of hydroxylamine is based on the reaction of nitric oxide with hydrogen in the presence of a catalyst. The formation of nitric oxide from nitric acid and mercury is applied in a volumetric method of analysis for nitric acid or its salts.

Though it is a toxic gas at high concentrations, nitric oxide functions as an important signaling molecule in animals. It acts as a messenger molecule, transmitting signals to cells in the cardiovascular, nervous, and immune systems. The nitric oxide molecule’s possession of a free radical makes it much more reactive than other signaling molecules, and its small size enables it to diffuse through cell membranes and walls to perform a range of signaling functions in various bodily systems. The body synthesizes nitric oxide from the amino acid L-arginine by means of the enzyme nitric oxide synthase.

The main site of the molecule’s synthesis is the inner layer of blood vessels, the endothelium, though the molecule is also produced by other types of cells. From the endothelium, nitric oxide diffuses to underlying smooth muscle cells and causes them to relax. This relaxation causes the walls of blood vessels to dilate, or widen, which in turn increases blood flow through the vessels and decreases blood pressure. Nitric oxide’s role in dilating blood vessels makes it an important controller of blood pressure. Nitric oxide is also produced by neurons (nerve cells) and is used by the nervous system as a neurotransmitter to regulate functions ranging from digestion to blood flow to memory and vision. In the immune system, nitric oxide is produced by macrophages, which are a type of leukocyte (white blood cell) that engulfs bacteria and other foreign particles that have invaded the body. The nitric oxide released by macrophages kills bacteria, other parasites, and tumour cells by disrupting their metabolism.

Nitric oxide’s role in regulating blood flow and pressure is used by modern medicine in several ways. The drug nitroglycerin has been used since the late 19th century to relieve the condition known as angina pectoris, which is caused by an insufficient supply of blood to the heart muscle. Nitroglycerin was long known to achieve its therapeutic effect by dilating the coronary arteries (thereby increasing the flow of blood to the heart), but why it did so remained unknown until the late 1980s, when researchers realized that the drug serves to replenish the body’s supply of nitric oxide, more of which is then available to relax, and thereby widen, the coronary blood vessels.

Nitric oxide is an important component of the air pollution generated by automotive engines and thermal power-generating plants. When a mixture of air and hydrocarbon fuel is burned in an internal-combustion engine or a power plant, the ordinarily inert nitrogen in the air combines with oxygen at very high temperatures to form nitric oxide. The nitric oxide and hydrocarbon vapours emitted by automotive exhausts and power-plant smokestacks undergo complex photochemical reactions in the lower atmosphere to form various secondary pollutants called photochemical oxidants, which make up photochemical smog. Nitric oxide combines with water vapour in the atmosphere to form nitric acid, which is one of the components of acid rain. Heightened levels of atmospheric nitric oxide resulting from industrial activity were also one of the causes of gradual depletion of the ozone layer in the upper atmosphere. Sunlight causes nitric oxide to react chemically with ozone (O3), thereby converting the ozone to molecular oxygen (O2).