Math Is Fun Forum

Bronchitis

Gist

Bronchitis is inflammation of the large airways in your lungs. The inflammation causes you to cough.

Bronchitis can be acute or chronic. Acute bronchitis is usually caused by a viral infection and goes away by itself. Chronic bronchitis is a type of chronic obstructive pulmonary disease (COPD), a long-term lung condition that is usually related to smoking.

What are the symptoms of acute bronchitis?

Someone with bronchitis will have a cough (either dry or bringing up phlegm). The cough may last for 2 to 3 weeks in people with acute bronchitis.

Other symptoms of bronchitis may include:

* wheezing or feeling short of breath
* chest discomfort or pain (due to frequent coughing)
* a blocked or runny nose
* headache
* fever
* aches and pains
* feeling tired

Summary

Bronchitis is inflammation of the bronchi (large and medium-sized airways) in the lungs that causes coughing. Bronchitis usually begins as an infection in the nose, ears, throat, or sinuses. The infection then makes its way down to the bronchi. Symptoms include coughing up sputum, wheezing, shortness of breath, and chest pain. Bronchitis can be acute or chronic.

Acute bronchitis usually has a cough that lasts around three weeks, and is also known as a chest cold. In more than 90% of cases, the cause is a viral infection. These viruses may be spread through the air when people cough or by direct contact. A small number of cases are caused by a bacterial infection such as Mycoplasma pneumoniae or Bordetella pertussis. Risk factors include exposure to tobacco smoke, dust, and other air pollution. Treatment of acute bronchitis typically involves rest, paracetamol (acetaminophen), and nonsteroidal anti-inflammatory drugs (NSAIDs) to help with the fever.

Chronic bronchitis is defined as a productive cough – one that produces sputum – that lasts for three months or more per year for at least two years. Many people with chronic bronchitis also have chronic obstructive pulmonary disease (COPD). Tobacco smoking is the most common cause, with a number of other factors such as air pollution and genetics playing a smaller role. Treatments include quitting smoking, vaccinations, rehabilitation, and often inhaled bronchodilators and steroids.[13] Some people may benefit from long-term oxygen therapy.

Acute bronchitis is one of the more common diseases. About 5% of adults and 6% of children have at least one episode a year. Acute bronchitis is the most common type of bronchitis. By contrast in the United States, in 2018, 9.3 million people were diagnosed with the less common chronic bronchitis.

Details

Bronchitis is an inflammation of the lining of your bronchial tubes. These tubes carry air to and from your lungs. People who have bronchitis often cough up thickened mucus, which can be discolored. Bronchitis may start suddenly and be short term (acute) or start gradually and become long term (chronic).

Acute bronchitis, which often develops from a cold or other respiratory infection, is very common. Also called a chest cold, acute bronchitis usually improves within a week to 10 days without lasting effects, although the cough may linger for weeks.

Chronic bronchitis, a more serious condition, is a constant irritation or inflammation of the lining of the bronchial tubes, often due to smoking. If you have repeated bouts of bronchitis, you may have chronic bronchitis, which requires medical attention. Chronic bronchitis is one of the conditions included in chronic obstructive pulmonary disease (COPD).

Symptoms

If you have acute bronchitis, you may have cold symptoms, such as:

* Cough
* Production of mucus (sputum), which can be clear, white, yellowish-gray or green in color — rarely, it may be streaked with blood
* Sore throat
* Mild headache and body aches
* Slight fever and chills
* Fatigue
* Chest discomfort
* Shortness of breath and wheezing

While these symptoms usually improve in about a week, you may have a nagging cough that lingers for several weeks.

For chronic bronchitis, signs and symptoms may include:

* Cough
* Production of mucus
* Fatigue
* Chest discomfort
* Shortness of breath

Chronic bronchitis is typically defined as a productive cough that lasts at least three months, with bouts that recur for at least two consecutive years. If you have chronic bronchitis, you're likely to have periods when your cough or other symptoms worsen. It's also possible to have an acute infection on top of chronic bronchitis.

When to see a doctor

Contact your doctor or clinic for advice if your cough:

* Is accompanied by a fever higher than 100.4 F (38 C).
* Produces blood.
* Is associated with serious or worsening shortness of breath or wheezing.
* Includes other serious signs and symptoms, for example, you appear pale and lethargic, have a bluish tinge to your lips and nail beds, or have trouble thinking clearly or concentrating.
* Lasts more than three weeks.

Causes

Acute bronchitis is usually caused by viruses, typically the same viruses that cause colds and flu (influenza). Many different viruses — all of which are very contagious — can cause acute bronchitis. Antibiotics don't kill viruses, so this type of medication isn't useful in most cases of bronchitis.

Viruses spread mainly from person to person by droplets produced when an ill person coughs, sneezes or talks and you inhale the droplets. Viruses may also spread through contact with an infected object. This happens when you touch something with the virus on it and then touch your mouth, eyes or nose.

The most common cause of chronic bronchitis is cigarette smoking. Air pollution and dust or toxic gases in the environment or workplace also can contribute to the condition.

Risk factors

Factors that increase your risk of bronchitis include:

* Cigarette smoke. People who smoke or who live with a smoker are at higher risk of both acute bronchitis and chronic bronchitis.
* Low resistance. This may result from another acute illness, such as a cold, or from a chronic condition that compromises your immune system. Older adults, infants and young children have greater vulnerability to infection.
* Exposure to irritants on the job. Your risk of developing bronchitis is greater if you work around certain lung irritants, such as grains or textiles, or are exposed to chemical fumes.
* Gastric reflux. Repeated bouts of severe heartburn can irritate your throat and make you more prone to developing bronchitis.

Complications

Although a single episode of bronchitis usually isn't cause for concern, it can lead to pneumonia in some people. Repeated bouts of bronchitis, however, may mean that you have chronic obstructive pulmonary disease (COPD).

Prevention

To reduce your risk of bronchitis, follow these tips:

* Get an annual flu shot. Many cases of acute bronchitis result from influenza, a virus. Getting a yearly flu vaccine can help protect you from getting the flu. Also ask your doctor or clinic if you need a vaccination that protects against certain types of pneumonia.
* Wash your hands. To reduce your risk of catching a viral infection, wash your hands frequently and get in the habit of using alcohol-based hand sanitizers. Also, avoid touching your eyes, nose and mouth.
* Avoid close contact with people who have a viral infection. Stay away from people who have the flu or another respiratory illness.
* Avoid cigarette smoke. Cigarette smoke increases your risk of chronic bronchitis.
* Wear appropriate face covering. If you have COPD, consider wearing a face mask at work if you're exposed to dust or fumes. Talk to your employer about the appropriate protection. Wearing a face mask when you're going to be among crowds helps reduce exposure to infections.

Additional Information

Bronchitis is when the airways leading to your lungs (trachea and bronchi) get inflamed and fill with mucus. You get a nagging cough as your body tries to get rid of the mucus. Your cough can last two or more weeks. Acute bronchitis is usually caused by a virus and goes away on its own. Chronic bronchitis never really goes away but can be managed.

Overview:

What is bronchitis?

Bronchitis is an inflammation of the airways leading into your lungs.

When your airways (trachea and bronchi) get irritated, they swell up and fill with mucus, causing you to cough. Your cough can last days to a couple of weeks. It’s the main symptom of bronchitis.

Viruses are the most common cause of acute bronchitis. Smoke and other irritants can cause acute and chronic bronchitis.

What are the types of bronchitis?

When people talk about bronchitis, they usually mean acute bronchitis, a temporary condition that makes you cough. Some people get bronchitis so often that it’s considered chronic bronchitis.

Acute bronchitis

Acute bronchitis is usually caused by a viral infection and goes away on its own in a few weeks. Most people don’t need treatment for acute bronchitis.

Chronic bronchitis

You have chronic bronchitis if you have a cough with mucus most days of the month for three months out of the year. This goes on for at least two years.

If you have chronic bronchitis, you may have chronic obstructive pulmonary disease (COPD). Ask your provider about whether you should get tested for COPD.

Who does bronchitis affect?

Anyone can get bronchitis, but you’re at higher risk if you:

* Smoke or are around someone who does.
* Have asthma, COPD or other breathing conditions.
* Have GERD (chronic acid reflux) (Gastroesophageal reflux disease.)
* Have an autoimmune disorder or other illness that causes inflammation.
* Are around smoke, chemicals or toxins in the air.

How does bronchitis affect my body?

When your airways are irritated, your immune system causes them to swell up and fill with mucus. You cough to try to clear the mucus out. As long as there’s mucus or inflammation in your airways, you’ll keep coughing.

Symptoms and Causes:

What are the symptoms of bronchitis?

A persistent cough that lasts one to three weeks is the main symptom of bronchitis. You usually bring up mucus when you cough with bronchitis, but you might get a dry cough instead. You might also hear a whistling or rattling sound when you breathe (wheezing).

You might have other symptoms, including:

* Shortness of breath (dyspnea).
* Fever.
* Runny nose.
* Tiredness (fatigue).

What causes bronchitis?

You almost always get bronchitis from a virus. However, nearly anything that irritates your airways can cause it. Infectious and noninfectious causes of bronchitis include:

* Viruses. Viruses that cause bronchitis include influenza (the flu), respiratory syncytial virus (RSV), adenovirus, rhinovirus (the common cold) and coronavirus.
* Bacteria. Bacteria that cause bronchitis include Bordetella pertussis, Mycoplasma pneumonia and Chlamydia pneumonia.
* Toxins in the air.
* Smoking cigarettes or marijuana (cannabis).

How do you get bronchitis?

You get bronchitis when your airways swell up and fill with mucus. You can get the viruses and bacteria that cause bronchitis from close contact (shaking hands, hugging, touching the same surfaces) with someone who has them. You don’t have to have bronchitis yourself to pass on a virus to someone else who ends up with bronchitis.

Other irritants are in the air you breathe.

Is bronchitis contagious?

Bronchitis itself — inflammation of your airways — isn’t contagious, but the viruses and bacteria that can cause it are. For instance, if you’re sick with the flu, you might get bronchitis too. But when your friend gets the flu from you, their airways don’t get inflamed like yours did.

Is bronchitis a side effect of COVID-19?

You can get bronchitis with almost any virus, including SARS-CoV2, the virus that causes COVID-19. The symptoms of bronchitis can be similar to COVID-19, so make sure you get tested to know which one you have. There haven’t been any studies that show that COVID-19 is any more likely to cause bronchitis than other viral illnesses.

Diagnosis and Tests:

How is bronchitis diagnosed?

Your healthcare provider can tell if you have bronchitis based on your health history and symptoms (clinical diagnosis). They’ll listen to your lungs for signs of congestion and to make sure you’re breathing well. They might test you for viral infections, like the flu or COVID-19.

What tests will be done to diagnose this condition?

There aren’t any specific tests to diagnose bronchitis, but you might be tested for other conditions. Possible tests include:

* Nasal swab. Your healthcare provider may use a soft-tipped stick (swab) in your nose to test for viruses, like COVID-19 or the flu.
* Chest X-ray. If your cough lasts for a long time, you may get a chest X-ray to rule out more serious conditions. Your healthcare provider will use a machine to get pictures of your heart and lungs. They’ll look for signs of other diseases that could cause your symptoms.
* Blood tests. Your provider may do blood tests, using a needle in your arm, to look for infections or check your overall health.
* Sputum test. Your provider may have you cough and then spit into a tube. Your sample will be tested for signs of a virus or bacteria.
* Pulmonary function tests. If your provider thinks you have chronic bronchitis, they may use a machine to test how well your lungs work.

Robotics

Gist

Robotics is the interdisciplinary field of engineering and computer science dedicated to the design, construction, and operation of automated machines (robots) that replicate or enhance human actions. Using sensors and AI, robots perform tasks ranging from repetitive industrial manufacturing to hazardous exploration.

Robotics is a branch of engineering and computer science that involves the conception, design, manufacture and operation of robots. The objective of the robotics field is to create intelligent machines that can assist humans in a variety of ways.

Summary

Robotics is the interdisciplinary study and practice of the design, construction, operation, and use of robots. A roboticist is someone who specializes in robotics. Robotics usually combines four aspects of design work: a power source (e.g. a battery), mechanical construction, a control system (electrical circuits), and software (run by remote control or artificial intelligence).

The goal of most robotics is to design machines that can assist humans in various fields, such as agriculture, construction, domestic work, food processing, inventory management, manufacturing, medicine, military, mining, space exploration, and transportation.

Robots impact humans by displacing workers. Some expect this to occur at an increasing rate, leading to proposed solutions such as basic income. Robotics is itself a lucrative business that creates careers, especially for postgraduates. Roboticists often aim to create machines that seem to interface naturally with humans. The field is under active research and development, with areas of interest including robot kinematics and quantum robotics.

Details

What is Robotics?
Robotics combines computer science, engineering, and technology to design, construct, and utilize machines that are programmed to replicate or substitute human actions and decision-making. These machines, known as robots, are deployed across a broad spectrum of industries to improve productivity, efficiency, and safety. Because robots can be used in so many ways, robotics is a broad, interdisciplinary field, meaning that there are many ways to study it and find a specialized career.

Robots aren't new. They've been around since ancient times, but the Industrial Revolution's rise in manufacturing highlighted the need for widespread automation. The first autonomous machines were built in the mid-20th century. In the 1990s, researchers developed the foundational elements for social robots that could understand and interpret human language and emotion. The advent of artificial intelligence (AI) and machine learning launched the field forward, expanding what is possible for robot automation and autonomy.

Each robot, regardless of its level of autonomy—meaning its ability to operate and make decisions without human supervision or intervention—consists of the same three components: mechanical construction, electrical power and control, and software or programming.

Robotics professionals can design and construct entire robots holistically, or they might focus on one component. They can specialize even further into sensors, control systems, human-robot interaction, and more. With a wide range of ever-growing industry applications, possibilities in the field of robotics are boundless.

What Are Robotics Applications?

Robotics got its start by providing an advantage in manufacturing and industrialization. But now, nearly every industry has found a need for robotic applications to make work more efficient and safe.

Manufacturing

From automobiles to smartphones, robotics have revolutionized the manufacturing industry. Industrial robots can assemble products, sort items, and even fix and maintain other machines in a factory or warehouse.

Healthcare

Medical robots transport medical supplies, perform surgery and diagnostics, manage hospital logistics, and dispense medications. As the robotics industry advances, more sophisticated machines are being developed to improve the efficiency of medical professionals and quality of patient care.

Agriculture

Robots help agricultural businesses meet growing global demand by performing routine tasks such as planting, pest and weed management, and harvesting.

Construction

Construction teams are safer, efficient, and more accurate thanks to robotic assistance. Autonomous technologies operate construction machinery and complete specialized tasks like welding, drilling, and brick-laying.

Shipping and Delivery

Robotics have streamlined the logistics of shipping and delivering goods. Autonomous mobile robots maneuver through warehouses and collect items for shipments, while companies deploy delivery bots to complete local deliveries in a timely manner.

More Real-World Robotics

Robots and autonomous technologies keep clean energy affordable through system installation and maintenance. Robots navigate mines for materials and analyze structural integrity. Search and rescue robots help disaster response teams by navigating floodwaters and putting out forest fires. In the home, robots keep surfaces clean and sanitized, mow lawns, engage with children, and assist people with disabilities.

Types of Robots

Robots come in all shapes and sizes, which is understandable given the variety of purposes they serve, from education and entertainment to integration as vital components in the manufacturing industry.

* Humanoid robots look like and mimic human behavior. Development of more advanced models is ongoing, as demand rises for robots to assist with research and professional services.
* Industrial robots are heavy-duty machines that automate manufacturing processes at scale.
* Mobile robots sort and deliver goods in warehouses, in the home, and on the street.
* Collaborative robots, or cobots, work in conjunction with people in the service industry and manufacturing.
* Social robots are AI-powered machines with a variety of applications in education, early childhood development, disability assistance, and companionship.
* Microrobots and nanorobots run diagnostics, monitor and treat diseases, and assess injuries.

What is Robotics?
Robotics combines computer science, engineering, and technology to design, construct, and utilize machines that are programmed to replicate or substitute human actions and decision-making. These machines, known as robots, are deployed across a broad spectrum of industries to improve productivity, efficiency, and safety. Because robots can be used in so many ways, robotics is a broad, interdisciplinary field, meaning that there are many ways to study it and find a specialized career.

Robots aren't new. They've been around since ancient times, but the Industrial Revolution's rise in manufacturing highlighted the need for widespread automation. The first autonomous machines were built in the mid-20th century. In the 1990s, researchers developed the foundational elements for social robots that could understand and interpret human language and emotion. The advent of artificial intelligence (AI) and machine learning launched the field forward, expanding what is possible for robot automation and autonomy.

Each robot, regardless of its level of autonomy—meaning its ability to operate and make decisions without human supervision or intervention—consists of the same three components: mechanical construction, electrical power and control, and software or programming.

Robotics professionals can design and construct entire robots holistically, or they might focus on one component. They can specialize even further into sensors, control systems, human-robot interaction, and more. With a wide range of ever-growing industry applications, possibilities in the field of robotics are boundless.

What Are Robotics Applications?
Robotics got its start by providing an advantage in manufacturing and industrialization. But now, nearly every industry has found a need for robotic applications to make work more efficient and safe.

Manufacturing
From automobiles to smartphones, robotics have revolutionized the manufacturing industry. Industrial robots can assemble products, sort items, and even fix and maintain other machines in a factory or warehouse.

Healthcare
Medical robots transport medical supplies, perform surgery and diagnostics, manage hospital logistics, and dispense medications. As the robotics industry advances, more sophisticated machines are being developed to improve the efficiency of medical professionals and quality of patient care.

Agriculture
Robots help agricultural businesses meet growing global demand by performing routine tasks such as planting, pest and weed management, and harvesting.

Construction
Construction teams are safer, efficient, and more accurate thanks to robotic assistance. Autonomous technologies operate construction machinery and complete specialized tasks like welding, drilling, and brick-laying.

Shipping and Delivery
Robotics have streamlined the logistics of shipping and delivering goods. Autonomous mobile robots maneuver through warehouses and collect items for shipments, while companies deploy delivery bots to complete local deliveries in a timely manner.

More Real-World Robotics
Robots and autonomous technologies keep clean energy affordable through system installation and maintenance. Robots navigate mines for materials and analyze structural integrity. Search and rescue robots help disaster response teams by navigating floodwaters and putting out forest fires. In the home, robots keep surfaces clean and sanitized, mow lawns, engage with children, and assist people with disabilities.

Types of Robots
Robots come in all shapes and sizes, which is understandable given the variety of purposes they serve, from education and entertainment to integration as vital components in the manufacturing industry.

Humanoid robots look like and mimic human behavior. Development of more advanced models is ongoing, as demand rises for robots to assist with research and professional services.
Industrial robots are heavy-duty machines that automate manufacturing processes at scale.
Mobile robots sort and deliver goods in warehouses, in the home, and on the street.
Collaborative robots, or cobots, work in conjunction with people in the service industry and manufacturing.
Social robots are AI-powered machines with a variety of applications in education, early childhood development, disability assistance, and companionship.
Microrobots and nanorobots run diagnostics, monitor and treat diseases, and assess injuries.
Advantages and Disadvantages of Using Robots
Robots have expanded what's possible across industries. But their onset has drawbacks as well as benefits.

Advantages of Robotics
Increased accuracy: Robots perform repetitive tasks with greater precision and accuracy than humans, allowing people to focus on more complex tasks.
Enhanced productivity: Robots can work at a faster pace than humans for longer durations, leading to more consistent and higher-volume productivity.
Improved safety: Robots can complete tasks and operations in unsafe environments, protecting workers from injuries.
Rapid innovation: Robots equipped with advanced sensors and cameras can collect and organize data quickly, leading to faster analysis and innovation.
Greater cost-efficiency: As robots accelerate productivity, they can be a more cost-effective option for companies over human labor.
Disadvantages of Robotics
Workforce displacement: Robotic process automation may put some human employees out of work and change the skills necessary for work in certain sectors.
Limited creativity: Robots aren't good with surprises. In unexpected situations, robots don't possess the same level of problem-solving skills as humans.
Security risks: Robots can be subject to cyber attacks, potentially exposing large amounts of data.
Maintenance costs: Robotic machines are expensive to repair and maintain. Faulty equipment can lead to production disruptions and revenue loss.
Environmental waste: Robot construction requires large amounts of raw materials. Discarded robots and parts can lead to pollution and waste disposal issues.
What Skills Do People In Robotics Fields Need?
Robotics professionals need to possess an interest and understanding of all three robotics components: mechanical construction, electrical power and control, and programming.

While the level of understanding across the three components may vary depending on career or role, all robotics professionals must have strong mathematical skills, expertise in physical sciences, computer programming proficiency, and ample problem-solving abilities. Robotics professionals must also possess strong communication skills in order to work well with others and present their developments to clients and stakeholders. Professionals can specialize based on skill, expertise, and interest.

What Careers Are There in Robotics?

The robotics field is broad and ever-expanding. Robotics jobs and careers vary widely depending on specialization, interest, and industry. Different robotics careers require different kinds of skills and education. Some standard robotics jobs include the following:

* Robotics engineer
* Mechatronics engineer
* Robotics programmer
* Automation engineer
* Robotics integration designer
* Industrial engineer
* Software engineer
* Mechanical engineer
* User interface/user experience (UI/UX) designer
* Robotics operator
* Controls engineer
* Manufacturing technician

The Future of Robotics

The future of robotics relies heavily on the advancements of artificial intelligence (AI). Advanced AI can affect robotic autonomy and problem-solving abilities as autonomous machines develop neural frameworks. Through generative AI tools, robots acquire the capability to adapt to unexpected situations and communicate with human operators more effectively.

As robots become increasingly prevalent in everyday life, the field of human-robot interaction is expanding to understand how people can operate and live harmoniously with robots in homes, in the workplace, and on the street. As interactions between humans and robotic systems grow, the look and behavior of robots has changed to be more visually appealing to humans, better understand human language and emotion, and respond more effectively.

With millions of robots being used around the world, societal and organizational developments will be needed as humans determine how to best work alongside robots and adapt the workforce to counteract the rise in displaced jobs from robotic labor. With the introduction of technologies such as AI and machine learning, humans will need to adapt to work alongside robots in a more efficient and productive society.

Additional Information

Robotics is design, construction, and use of machines (robots) to perform tasks done traditionally by human beings. Robots are widely used in such industries as automobile manufacture to perform simple repetitive tasks, and in industries where work must be performed in environments hazardous to humans. Many aspects of robotics involve artificial intelligence; robots may be equipped with the equivalent of human senses such as vision, touch, and the ability to sense temperature. Some are even capable of simple decision making, and current robotics research is geared toward devising robots with a degree of self-sufficiency that will permit mobility and decision-making in an unstructured environment. Today’s industrial robots do not resemble human beings; a robot in human form is called an android.

Japanese roboticist Masahiro Mori proposed that as human likeness increases in an object’s design, so does one’s affinity for the object, giving rise to the phenomenon called the "uncanny valley." According to this theory, when the artificial likeness nears total accuracy, affinity drops dramatically and is replaced by a feeling of eeriness or uncanniness. Affinity then rises again when true human likeness—resembling a living person—is reached. This sudden decrease and increase caused by the feeling of uncanniness creates a “valley” in the level of affinity.

Angiogram

Gist

An angiogram is a scan that shows blood flow through arteries or veins, or through the heart, using X-rays, computed tomography angiography (CTA) or magnetic resonance angiography (MRA). The blood vessels appear on the image after a contrast dye is injected into the blood, which lights up on the scan wherever it flows.

Angiography may be the first step of a procedure to find and fix a blood vessel blockage, aneurysm, structural heart or valve disease.

Summary

An angiogram is a type of X-ray used to examine blood vessels.

Blood vessels don’t show up clearly on ordinary X-rays, so a special dye is injected into the area being examined. The dye highlights the blood vessels as it moves through them. The medical name for this is a catheter angiogram.

Less commonly, angiograms can also be carried out using magnetic resonance imaging(MRI) and computerised tomography (CT) techniques.

Why angiograms are used

An angiogram can help diagnose conditions that affect blood vessels and the flow of blood through them. These include:

* coronary heart disease – the blood flow through the artery that supplies the heart muscle is disrupted because it has become narrowed
* aneurysm – a section of a blood vessel wall bulges outwards due to a weakness in the wall
* atherosclerosis – blood vessels become clogged up with fatty substances, such as cholesterol; an angiogram can be used to assess the level of atherosclerosis in specific blood vessels

Details

An angiogram is a diagnostic procedure that uses imaging to show your provider how your blood flows through your blood vessels or heart. An injected contrast material makes it easy to see where blood is moving and where blockages are. Your provider can use X-rays or other types of imaging for your angiogram.

Cerebral Arteriogram

An arteriogram is an X-ray of the blood vessels. It’s used to look for changes in the blood vessels, such as:

* Ballooning of a blood vessel (aneurysm)
* Narrowing of a blood vessel (stenosis)
* Blockages

This test is also called angiogram.

For arteriogram, your healthcare provider inserts a catheter into a large blood vessel and injects contrast dye. The contrast dye causes the blood vessels to appear on the X-ray image. This lets the healthcare provider better see the vessel(s) under exam.

Many arteries can be seen on an arteriogram, including those of the legs, kidneys, brain, and heart. A cerebral arteriogram is used to look at the blood vessels of the brain, head, or neck.

For a cerebral arteriogram, a catheter is usually inserted into an artery in the groin. Sometimes, an artery in the arm is used. Rarely, an artery in the neck may need to be used. The groin artery is most commonly used because it’s easier to get to. Once the catheter is inserted, the contrast dye is injected. Next, a series of X-rays are made. These images show the arteries, veins, and capillaries and blood flow in the brain.

What is computed tomography (CT) angiography?

CT angiography is a type of medical test that combines a CT scan with an injection of a special dye to produce pictures of blood vessels and tissues in a part of your body. The dye is injected through an intravenous (IV) line placed in your arm or hand.

A computerized tomography scan, or CT scan, is a type of X-ray that uses a computer to make cross-sectional images of your body. The dye injected to perform CT angiography is called a contrast material because it enhances blood vessels and tissues that are being studied.

Why might I need a computed tomography angiography?

* To find or measure the size of an aneurysm (a blood vessel that has become enlarged and may be in danger of rupturing)
* To find blood vessels that have become narrowed by atherosclerosis (fatty material that forms plaques in the walls of arteries)
* To follow vessels involved by dissections, which are tears that can form in the wall of vessels
* To find abnormal blood vessel formations inside your brain
* To identify blood vessels damaged by injury
* To find blood clots that may have formed in your leg veins and traveled into your lungs
* To evaluate a tumor that is fed by blood vessels

Information from CT angiography may help prevent a stroke or a heart attack. This type of test may also help your health care provider plan cancer treatment or prepare you for a kidney transplant. Your health care provider may have other reasons for ordering this test.

What is fluoroscopy?

Fluoroscopy is a study of moving body structures--similar to an X-ray "movie." A continuous X-ray beam is passed through the body part being examined. The beam is transmitted to a TV-like monitor so that the body part and its motion can be seen in detail. Fluoroscopy, as an imaging tool, enables physicians to look at many body systems, including the skeletal, digestive, urinary, respiratory, and reproductive systems.

Fluoroscopy may be performed to evaluate specific areas of the body, including the bones, muscles, and joints, as well as solid organs, such as the heart, lung, or kidneys.

Other related procedures that may be used to diagnose problems of the bones, muscles, or joints include X-rays, myelography ( myelogram ), computed tomography ( CT scan ), magnetic resonance imaging ( MRI ), and arthrography.

What is magnetic resonance angiography?

You’ve probably heard about the test called magnetic resonance imaging or MRI. In this test, radio waves, a magnetic field, and a computer create a scan of your body parts to look for health problems.

Magnetic resonance angiography–also called a magnetic resonance angiogram or MRA–is a type of MRI that looks specifically at the body’s blood vessels. Unlike a traditional angiogram, which requires inserting a catheter into the body, magnetic resonance angiography is a far less invasive and less painful test.

During magnetic resonance angiography, you lie flat inside the magnetic resonance imaging scanner. This is a large, tunnel-like tube. In some cases, a special dye, known as contrast, may be added to your bloodstream to make your blood vessels easier to see. When needed, the contrast is given with an intravenous (IV) needle.

What is a resting radionuclide angiogram?

Resting radionuclide angiogram (RNA) is a type of nuclear medicine test. Doctors use a tiny amount of a radioactive substance, called a tracer, during the scan to help show the heart’s chambers in motion. This test can tell the doctor how well the heart pumps and how much blood is pumped with each heartbeat. This is called the ejection fraction.

Your doctor injects a radioactive tracer (usually technetium) into an arm vein. The tracer “tags" blood cells so your doctor can track them with a scanner as they move through the heart. A special camera (called a gamma camera) then records the heart muscle at work, like a movie. Your doctor can match these recordings with the electrocardiogram (ECG). An ECG is a recording of the heart's electrical activity.

If the heart muscle doesn’t move normally, or not enough blood is pumped out by the heart, it may be a sign of one or more of the following:

* Injury to the heart muscle, possibly as a result of decreased blood flow to heart muscle due to clogged heart arteries

* An enlargement of one or more of the heart's chambers

* Aneurysm (a weak area in the heart muscle)

* Toxic effects of certain medicines

* Heart failure

Additional Information

An angiogram is a diagnostic procedure that uses imaging to show your provider how your blood flows through your blood vessels or heart. An injected contrast material makes it easy to see where blood is moving and where blockages are. Your provider can use X-rays or other types of imaging for your angiogram.

Overview:

An angiogram uses X-ray images and contrast dye to show blockages in blood vessels.

What is an angiogram?

An angiogram is a diagnostic procedure that uses X-ray images to look for blockages or narrow spots in your blood vessels (arteries or veins). An angiogram test can show how blood circulates in blood vessels at specific locations in your body. Healthcare providers use an angiogram of your heart, neck, kidneys, legs or other areas to locate the source of an artery or vein issue.

Your healthcare provider may want to do an angiogram procedure when you have signs of blocked, damaged or abnormal blood vessels. An angiogram test helps your provider determine the source of the problem and the extent of damage to your blood vessels.

With an angiogram procedure, your provider can diagnose and plan treatment for conditions like:

* Coronary artery disease (blockage or narrowing in the arteries that supply your heart)
* Peripheral artery disease (blockage or narrowing in your leg arteries)
* Blood clots (mass of blood cells)
* Aneurysm (weak artery wall)

Test Details:

How does an angiogram work?

An angiogram procedure involves injecting contrast material (dye) that your provider can see with an X-ray machine. Images on a screen show blood flow and blockages in your blood vessels.

Your provider will give you medicine to make sure you’re relaxed and comfortable. Most people receive sedation. Others get general anesthesia, which makes them sleep. Either way, someone will need to drive you home afterward.

How to prepare for an angiogram procedure

Before your angiogram test, your provider may want to check your blood to determine how well your blood clots. They also want to make sure your kidneys are working well.

Medications

Always consult with your provider before you stop taking any medication, especially antiplatelets and anticoagulants. With provider approval:

* Don’t take clopidogrel for five days before your procedure.
* Don’t take blood thinners like dipyridamole or warfarin within 72 hours before the test and 24 hours after the test.
* Take all other medications as usual.
* If you have diabetes, ask your provider for instructions about if and when to take your insulin and/or medicine.

Don’t eat anything after midnight the night before your angiogram. If you’re having general anesthesia during the procedure, don’t eat or drink anything after midnight.

The day of your angiogram

Be sure to:

* Drink only clear liquids for breakfast on the day of your procedure.
* Leave your jewelry and other valuables at home.
* Make sure you arrange for a responsible adult to drive you home.
* Bring a current list of your medications and allergies.
* Bring a book or magazine in case your healthcare provider has to handle an urgent case before yours.
* Let all of your providers know if you have diabetes.
* Change into a hospital gown and lie down on a special X-ray table.
* Meet with your provider to review instructions, questions and your medical history.

What to expect during angiography

During an angiogram procedure, your provider will:

1) Numb the area where the catheter will go.
2) Access your blood vessel with a needle.
3) Thread a wire through the needle.
4) Slide a long, slender tube called a catheter over the needle and into a large artery (usually in your groin or wrist area).
5) Slowly and carefully thread the catheter through your artery until the catheter’s tip reaches the part of the blood vessel they want to examine.
6) Inject a small amount of contrast material (dye) through the catheter and into your blood vessel segment. For a few seconds, this can make you feel flushed or like you need to pee.
7) Take X-rays.
8) Watch where the contrast agent goes on the X-ray monitor to see where and how well blood is moving in your blood vessels.

How long does an angiogram take?

An angiogram can take as little as 15 minutes. But some can take a few hours. It depends on what procedures your provider does after they find the issue.

If your provider finds a blockage, they may treat it right away with an angioplasty. This procedure uses a tiny balloon to force the blockage against your artery wall. An angioplasty may be all you need if it makes your blood flow better and there’s less than 30% of your blockage left after the procedure.

If an angioplasty doesn’t create a large enough opening for blood to get through, you may need a stent. This tiny metal tube stays in your blood vessel to keep it open. Your provider can place this right after your angioplasty.

Another treatment, surgery for your heart (coronary artery bypass) or legs (peripheral artery bypass), creates a way around your blockage. A provider will do this on a different day.

What to expect after angiography

Your healthcare provider will take out the catheter and bandage the area where they punctured your skin. They’ll press on the bandaged area for at least 15 minutes to stop or prevent bleeding.

If they put the catheter in through your leg, you’ll need to rest in bed for four to six hours. This will make your incision less likely to bleed.

Your provider will evaluate you and discuss at-home instructions with you before you go home.

Angiogram recovery

You should be able to go home the same day as your angiogram procedure or the next day, even if you had angioplasty and stenting. Because you received anesthesia, you’ll need someone to drive you home.

After you get home, don’t lift anything heavier than 10 pounds or stoop or bend for the next two days. This should keep your incision from bleeding.

A responsible adult should stay with you overnight after your procedure. Some people may need to spend the night in the hospital for their angiogram recovery.

If you have diabetes, don’t take metformin for 48 hours after the test. This reduces the risk of kidney complications.

Drinking water will help flush the contrast dye out of your system.

What are the risks of angiography?

Angiogram risks are low. But you can have complications in the area where your provider went through your skin to reach your artery. Angiogram complications happen in less than 1% of cases.

Risks of an angiogram procedure usually involve your puncture site and include:

* Bruises, which are common and go away in one to three weeks
* Bleeding
* Infection
* Pain
* Kidney issues
* An allergic reaction to the contrast material (dye)
* Injury to blood vessels
* Abnormal heart rhythm (arrhythmia) or cardiac arrest that requires resuscitation
* A blood vessel blockage from a blood clot that could cause a heart attack or stroke (rarely)
* A blood vessel leak (rarely).

Denali

Gist

Denali, officially renamed from Mount McKinley in 2015, is the highest mountain peak in North America, reaching a summit elevation of 20,310 feet above sea level. Located in Alaska's Denali National Park and Preserve, this massive granite block is known for extreme, unpredictable weather, and it is considered one of the most challenging, deadly, and scenic climbs in the world.

Mount McKinley is the crown jewel of Denali National Park and Preserve, the highest mountain in North America (at 20,310' above sea level), and a sought-after prize for sightseeing national park visitors and mountain climbing alpinists alike.

Denali, formerly known as Mount McKinley, is the highest mountain peak in North America, towering 20,310 feet above sea level in Alaska's Denali National Park & Preserve. Located in the Alaska Range, it is a premier destination for mountaineering and wilderness exploration, often considered one of the coldest and most challenging mountains in the world.

Summary

Denali, federally designated as Mount McKinley, is the highest mountain peak in North America, with a summit elevation of 20,310 feet (6,190 m) above sea level. It is the tallest mountain in the world from base to peak on land, measuring 18,000 ft (5,500 m). With a topographic prominence of 20,156 feet (6,144 m) and a topographic isolation of 4,621.1 miles (7,436.9 km), Denali is the third most prominent and third-most isolated peak on Earth, after Mount Everest and Aconcagua. Located in the Alaska Range in the interior of the U.S. state of Alaska, Denali is the centerpiece of Denali National Park and Preserve.

The Koyukon people who inhabit the area around the mountain have referred to the peak as "Denali" for centuries. In 1896, a gold prospector named it "Mount McKinley" in support of then–presidential candidate William McKinley, who later became the 25th president; McKinley's name was the official name recognized by the federal government of the United States from 1917 until 2015. In August 2015, 40 years after Alaska had officially named the mountain Denali, the United States Department of the Interior under the Obama administration changed the official federal name of the mountain also to Denali. In January 2025, the Department of the Interior under the Trump administration reverted the mountain's official federal name to Mount McKinley.

In 1903, James Wickersham recorded the first attempt at climbing Denali, which was unsuccessful. In 1906, Frederick Cook claimed the first ascent, but this ascent is unverified and its legitimacy questioned. The first verifiable ascent to Denali's summit was achieved on June 7, 1913, by climbers Hudson Stuck, Harry Karstens, Walter Harper, and Robert Tatum, who went by the South Summit. In 1951, Bradford Washburn pioneered the West Buttress route, considered to be the safest and easiest route, and therefore the most popular currently in use.

On September 2, 2015, the U.S. Geological Survey measured the mountain at 20,310 feet (6,190 m) high, 10 ft lower than the 20,320 feet (6,194 m) measured in 1952 using photogrammetry.

Details

Mount McKinley, highest peak in North America. It is located near the center of the Alaska Range, with two summits rising above the Denali Fault, in south-central Alaska, U.S.

Elevation and geology

Mount McKinley’s official elevation figure of 20,310 feet (6,190 meters), established by the United States Geological Survey in September 2015, was the product of a thorough remeasurement of the mountain’s height conducted earlier that year using state-of-the-art equipment. The new value superseded the long-standing figure of 20,320 feet (6,194 meters) that had been the official elevation since the early 1950s. Earlier attempts to measure the mountain’s height had yielded different values. One such survey, conducted in 2010 using advanced radar technology, was made public in September 2013 and gave its elevation as 20,237 feet (6,168 meters). However, that measurement was subsequently determined to be inaccurate.

Mount McKinley lies about 130 miles (210 km) north-northwest of Anchorage and some 170 miles (275 km) southwest of Fairbanks in Denali National Park and Preserve. The mountain is essentially a giant block of granite that was lifted above Earth’s crust during a period of tectonic activity that began about 60 million years ago. It rises abruptly some 18,000 feet (5,500 meters) from Denali Fault at its base to the higher, more southerly of its two summits. The upper half of the mountain is covered with permanent snowfields that feed many glaciers, some surpassing 30 miles (48 km) in length.

Exploration and climbing attempts

In 1794 the English navigator George Vancouver sighted the mountain from Cook Inlet (an arm of the Gulf of Alaska). The first attempt to climb it was made in 1903 by an American judge, James Wickersham, but it was unsuccessful. A much-publicized but fraudulent claim by the physician and explorer Frederick A. Cook that he had reached the top inspired the conquest of the North Peak in 1910, by two prospectors of what was dubbed the “Sourdough Expedition.” On June 7, 1913, Hudson Stuck and Harry Karstens led a party to the South Peak, the true summit. A climbing party was first airlifted onto the mountain’s flanks in 1932; beginning in the 1950s, that became the standard way to attempt a summit climb, as it reduced the trip by several weeks. Most climbers are now flown to a base camp on southern-facing Kahiltna Glacier at an elevation of 7,200 feet (2,195 meters), where the greatest number follow the West Buttress route. On average, several hundred climbers attempt to reach the summit each year.

Denali or McKinley?

The mountain was known to the Athabaskan Indians as Denali (“The High One” or “The Great One”) and to the Russians as Bolshaya Gora (“Great Mountain”). It was called Densmore’s Mountain in 1889 by Frank Densmore, a prospector. The name Mount McKinley was applied in 1896 by William A. Dickinson, another prospector, in honor of William McKinley (who was elected president of the United States later that year) and became the official name. Efforts began in the mid-1970s to restore the mountain’s original Native American name but faced opposition, mainly from lawmakers from Ohio, McKinley’s home state. However, the mountain’s original name was recognized by the state of Alaska, and it was adopted as the name of the national park and preserve when it was created in 1980.

Use of the name Denali for the mountain became increasingly common, and in 2015 it was officially renamed Denali. On January 20, 2025, as one of his first acts upon his return to the White House, Pres. Donald Trump issued an executive order that called for Denali to be reverted back to Mount McKinley. The following month, the Board on Geographic Names enacted that change. Denali National Park and Preserve retained its current name, however.

Additional Information

Denali (Mount McKinley) is the highest mountain in North America, but controversy surrounds both its height and name.

Denali, also called Mount McKinley, is the tallest mountain in North America, located in south-central Alaska. With a peak that reaches 6,190 meters (20,310 feet) above sea level, Denali is the third-highest of the Seven Summits (the tallest peaks on all seven continents).

Denali is about 210 kilometers (130 miles) north-northwest of Anchorage. Sixty million years ago, tectonic uplift pushed Earth's crust upward, forming Denali and the other Alaska Range mountains. Denali is the centerpiece of the Denali National Park and Preserve, which spans 2.4 million hectares (6 million acres) of land.

“Denali” comes from Koyukon, a traditional Native Alaskan language, and means “the tall one.” This name had been used for many generations and was used by early non-Native researchers and naturalists. But in 1896, William A. Dickinson, a prospector, began calling Denali “Mount McKinley,” in honor of William McKinley, a presidential candidate at the time. After McKinley became president and was later assassinated, Congress formally recognized the name in 1917, despite McKinley’s tenuous ties to Alaska (he had never visited). But Native Alaskans, as well as locals of varied backgrounds, continued to call the mountain Denali. In 1975, a movement began to rename the mountain Denali, but it was blocked by politicians in Ohio, McKinley’s home state. Finally, President Barack Obama and Secretary of the Interior Sally Jewell took action in 2015 to change the name back to Denali, which is now its official name.

In 2015, Denali was measured using state-of-the-art equipment by the United States Geological Survey (USGS), who determined the definitive and now widely accepted height of the mountain: 6,190 meters (20,310 feet). However, a report released in 2013 gave its elevation as 6,168 meters (20,237 feet). Both measurements were different from the long-standing figure of 6,194 meters (20,320 feet) that had been circulated since the 1950s, when the mountain was first measured.

Denali is considered an extremely difficult climb due to the severe weather and steep vertical climbs. In 1906, physician and explorer Frederick Cook was famously reported to have reached the summit, a claim that was later found false. Hudson Stuck, Harry Karstens, and their team of climbers were the first on record to actually reach the summit in 1913. Since then, several hundred people attempt to climb Denali each year.

Bonsai

Gist

Bonsai are trees and plants grown in containers in such a way so that they look their most beautiful – even prettier than those growing in the wild. Cultivating bonsai, therefore, is a very artistic hobby as well as a traditional Japanese art.

Bonsai are trees and plants grown in containers in such a way so that they look their most beautiful – even prettier than those growing in the wild. Cultivating bonsai, therefore, is a very artistic hobby as well as a traditional Japanese art. It's also a good illustration of the gentle respect Japanese have for living things and an expression of their sense of what is beautiful. It's much more involved than growing potted flowers, and requires a much bigger commitment – physically and emotionally.

Bonsai trees are expensive primarily due to the immense time, specialized labor, and expertise required to cultivate them, often taking decades or centuries to reach a high-quality, mature, and artistic form. Prices are driven by age, species rarity, detailed design, and expensive, often antique, imported pots.

Summary

Bonsai (lit. plantings in tray, from bon, a tray or low-sided pot and sai, a planting or plantings) is the Japanese art of growing small trees in pots. This is done by growing the tree in a small pot or tray and pruning (cutting) the branches and roots to keep the tree small over time. Bonsai trees are trained to grow into a shape that is pleasing to look at. The best bonsai trees appear to be old, and to have a shape that seems like a real tree except much smaller.

The word bonsai means "tree in tray" in the Japanese language. Bonsai is a very old art form in Japan. It is a Japanese form of the older Chinese art called penjing. Penjing is a Chinese art form that also uses trees growing in pots. Other nations also have arts like bonsai and penjing.

People like bonsai because it is nice to look at, and because it is fun to grow a bonsai tree. A bonsai tree can live for a very long time, longer than a person can live. In a family, a bonsai might be started by a grandparent, then given to a parent, then given to a child over many years.

A bonsai starts with a small tree. This tree can be grown from a seed, or can be found already growing in a yard or a park or the forest. It can also be bought from a plant store.

To make the bonsai, the small tree is taken out of the ground. Its roots are carefully cleaned of dirt. The roots may be trimmed (cut) a little to help them fit in a small pot. The branches may also be trimmed to make the tree smaller. Then it is put in a bonsai pot, which has low sides. Fresh soil (dirt) is put in the pot to cover the bonsai tree's roots. Then it is watered and put outdoors to live.

Good trees to make into bonsai have small leaves (pine tree needles are leaves too). If the leaves are too big, the bonsai will not look like a small tree. A good bonsai tree will have old-looking bark and old-looking roots too.

Details

Bonsai is the Japanese art of growing and shaping miniature trees in containers, with a long documented history of influences and native Japanese development over a thousand years, and with unique aesthetics, cultural history, and terminology derived from its evolution in Japan. Similar arts exist in other cultures, including Korea's bunjae, the Chinese art of penjing, and the miniature living landscapes of Vietnamese Hòn non bộ.

The loanword bonsai has become an umbrella term in English, attached to many forms of diminutive potted plants, and also on occasion to other living and non-living things. According to Stephen Orr in The New York Times, "in the West, the word is used to describe virtually all miniature container trees, whether they are authentically trained bonsai or just small rooted cuttings. Technically, though, the term should be reserved for plants that are grown in shallow containers following the precise tenets of bonsai pruning and training, resulting in an artful miniature replica of a full-grown tree in nature." In the most definitive sense, "bonsai" refers to miniaturized, container-grown trees adhering to Japanese bonsai tradition and principles.

Purposes of bonsai are primarily contemplation for the viewer, and the pleasant exercise of effort and ingenuity for the grower. Bonsai are not grown for the production of food or medicine.

A bonsai is created beginning with a specimen of source material. This may be a cutting, seedling, a tree from the wild (known as yamadori) or small tree of a species suitable for bonsai development. Bonsai can be created from nearly any perennial woody-stemmed tree or shrub species that produces true branches and can be cultivated to remain small through pot confinement with crown and root pruning. Some species are popular as bonsai material because they have characteristics, such as small leaves or needles or aged-looking bark, that make them appropriate for the compact visual scope of bonsai.

The source specimen is shaped to be relatively small and to meet the aesthetic standards of bonsai, which emphasizes not the entirety of a landscape but the unique form of a specimen bonsai tree or trees. When the candidate bonsai nears its planned final size, it is planted in a display pot, usually one designed for bonsai display in one of a few accepted shapes and proportions. From that point forward, its growth is restricted by the pot environment. Throughout the year, the bonsai is shaped to limit growth, redistribute foliar vigor to areas requiring further development, and meet the artist's detailed design.

The practice of bonsai is sometimes confused with dwarfing, but dwarfing generally refers to research, discovery, or creation of plants that are permanent, genetic miniatures of existing species. Plant dwarfing often uses selective breeding or genetic engineering to create dwarf cultivars. Bonsai does not require genetically dwarfed trees but rather depends on growing small trees from regular stock and seeds. Bonsai uses cultivation techniques like pruning, root reduction, potting, defoliation, and grafting to produce small trees that mimic the shape and style of mature, full-size trees.

Additional Information

Bonsai is a living dwarf tree or trees or the art of training and growing them in containers.

Bonsai specimens are ordinary trees and shrubs (not hereditary dwarfs) that are dwarfed by a system of pruning roots and branches and training branches by tying with wire. The art originated in China, where, perhaps over 1,000 years ago, trees were cultivated in trays, wooden containers, and earthenware pots and trained in naturalistic shapes. Bonsai, however, has been pursued and developed primarily by the Japanese. The first Japanese record of dwarfed potted trees is in the Kasuga-gongen-genki (1309), a picture scroll by Takashina Takakane.

The direct inspiration for bonsai is found in nature. Trees that grow in rocky crevices of high mountains, or that overhang cliffs, remain dwarfed and gnarled throughout their existence. The Japanese prize in bonsai an aged appearance of the trunk and branches and a weathered character in the exposed upper roots. These aesthetic qualities are seen to embody the philosophical concept of the mutability of all things.

Bonsai may live for a century or more and may be handed down from one generation to another as valued family possessions. Aesthetics of scale call for short needles on conifers and relatively small leaves on deciduous trees. Small-flowered, small-fruited varieties of trees are favoured. Open space between branches and between masses of foliage are also important aesthetically. In diminutive forests the lower portions of the trunks should be bare.

Good bonsai specimens are usually hardy species that can be kept outdoors the year round wherever winters are mild. They can be brought into the house occasionally for appreciation and enjoyment. In Japan they are customarily displayed in an alcove or on small tables in a living room and later returned to their outdoor bonsai stands.

The selection of the appropriate container in which to cultivate a bonsai is an essential element of the art. Bonsai pots are usually earthenware, with or without a colourful exterior glaze. They may be round, oval, square, rectangular, octagonal, or lobed and have one or more drainage holes in the bottom. Containers are carefully chosen to harmonize in colour and proportion with the tree. If the container is rectangular or oval, the tree is planted not quite halfway between the midpoint and one side, according to the spread of the branches. In a square or round container the tree is placed slightly off centre, except for cascade types, which are planted toward the opposite side of the container from which they overhang. Bonsai are trained to have a front, or viewing side, oriented toward the observer when on exhibit.

Although categorizations vary considerably, miniature bonsai are known broadly as shohin. The smallest of these (keishi and math) range in size up to about 2 inches (5–7 cm) in height and, started from seeds or cuttings, may take three to five years to come to quality stage. They may live several decades. Small bonsai (mame), 2 to 6 inches (7 to 15 cm) in height, require 5 to 10 or more years to train. Medium bonsai generally range from roughly 7 to 15 inches (20 to 40 cm) in height but can be up to about 2 feet (60 cm) tall and can be produced in as little as three years. Large (dai) bonsai can be as tall as 47 inches (120 cm) and require two or more people to move them.

Naturally dwarfed trees collected in the wild frequently fail to adapt to cultivation as bonsai because of the severe shock brought about by the change of environment and substrate.

Bonsai must be repotted every one to five years, depending on the species and extent of root growth. Gradual root pruning during transplanting in subsequent years reduces the size of the soil ball so that the tree can ultimately go into the desired small and shallow container. Water is usually provided on a daily basis; liquid fertilizer is also used. Pruning and nipping of shoots is performed through the growing season.

A bonsai industry of considerable size exists as part of the nursery industry in sections of Japan. The technique is also pursued on a small industrial scale in California.

Q: Where do peanut drivers go to fill their tanks?
A: The Shell station!
* * *
Q: How do you catch an elephant?
A: Hide in the grass and make a sound like a peanut!
* * *
Q: Where did the peanuts go to have a few drinks?
A: The Snack Bar!
* * *
Two peanuts were walking down a road.
One was assaulted
* * *
Q: What do you call a peanut in a spacesuit?
A: An astronut!
* * *

Hyperion Tree

Gist

Hyperion, the world's tallest known living tree at over 379 feet, is located in a remote area of Redwood National and State Parks in Northern California. To protect the fragile ecosystem and the tree from damage, its precise location is not disclosed, and visiting it is strictly prohibited, with violators facing fines up to $5000  and potential jail time.

Hyperion was discovered on August 25, 2006, by naturalists Chris Atkins and Michael Taylor. It was found in a remote area of Redwood National Park that was part of the original 1968 park boundaries. It is estimated to be 600 to 800 years old and contain 530 m^3 (18,600 cu ft) of wood.

Summary

‘Hyperion’ in Redwood national park, 380ft high and up to 800 years old, now off limits after damage done by trampling visitors.

Tree enthusiasts who make the trek to the world’s tallest tree deep in a northern California forest will face a fine and possible jail time after park officials declared the remote area off-limits because of damage done by trampling visitors to the tree and surrounding forest, a park official said on Monday.

The tree, a 380ft (115m) coast redwood, is in a remote area of Redwood national park and is not accessible by any trail. But that hasn’t stopped scores of visitors from hiking to the tree, said Leonel Arguello, the park’s manager for natural resources.

Arguello said the tree, known as Hyperion, was “discovered” by two amateur naturalists in 2006. By 2010, visitors started trekking to see the tall, skinny redwood after bloggers, travel writers and others shared its exact location online. In 2019, Guinness World Records declared the tree, estimated to be between 600 and 800 years old, the tallest in the world.

Tree enthusiasts who make the trek to the world’s tallest tree deep in a northern California forest will face a fine and possible jail time after park officials declared the remote area off-limits because of damage done by trampling visitors to the tree and surrounding forest, a park official said on Monday.

The tree, a 380ft (115m) coast redwood, is in a remote area of Redwood national park and is not accessible by any trail. But that hasn’t stopped scores of visitors from hiking to the tree, said Leonel Arguello, the park’s manager for natural resources.

Arguello said the tree, known as Hyperion, was “discovered” by two amateur naturalists in 2006. By 2010, visitors started trekking to see the tall, skinny redwood after bloggers, travel writers and others shared its exact location online. In 2019, Guinness World Records declared the tree, estimated to be between 600 and 800 years old, the tallest in the world.

Hikers have bushwhacked off-trail into dense vegetation to reach the tree, making many social trails. The tree has also been damaged by visitors who step on its base. The area around the tree no longer has ferns due to trampling, Arguello said.

“The social trails have grown in number, the amount of garbage has increased, there’s human waste that has been seen, and as more people go up to this tree, they create more social trails and all of that is having damage impacts to the vegetation, to the soils and, and all of the garbage just sits out there,” he said.

Details

Hyperion is a coast redwood (Sequoia sempervirens D.Don, Endl.) tree in California, which is the world's tallest known living tree, measured at 116.22 metres (381.3 ft) tall in 2026.

Hyperion was discovered on August 25, 2006, by the naturalists Chris Atkins and Michael Taylor. The tree height of 115.55 m (379.1 ft) was verified by Stephen Sillett in 2006 by use of both a laser range finder and a fiberglass tape to measure the tree from the base to the crown. The tree has grown since then to reach 116.07 metres (380.8 ft) recorded in 2019. Hyperion was found in a remote area of Redwood National Park, inside of the originally designated park boundaries of 1968.[9] The park also houses the second-, fourth- and fifth-tallest known trees, coast redwoods named Helios, Icarus, and Daedalus, which respectively measured 377, 371 and 363 feet in 2022.

The tree was named after the titan Hyperion from Greek mythology.

Hyperion is estimated to be between 600 and 800 years old and contain 530 m^3 (18,600 ft3) of wood; it was seeded when the Chilula (a Pacific Coast Athabaskan people) inhabited the region.

The exact location of Hyperion is nominally secret but is available via internet search. However, in July 2022, the Redwood Park superintendent closed the entire area around the tree, citing "devastation of the habitat surrounding Hyperion" caused by visitors. Its base was trampled by the overuse and as a result ferns no longer grow around the tree.

Measures to protect the Hyperion tree were officially implemented in 2022 when the National Park Service (NPS) closed public access to its location in Redwood National Park. Individuals who enter the closed area could face up to six months in jail and a $5,000 maximum fine.

Additional Information

Here at Verdissimo, the world’s largest producer of preserved plants and flowers, we’d like to tell you about Hyperion, the tree which, at a height of 115.55 meters (397.1 feet), has been recognized as the tallest tree in the world.

Hyperion is a Sequoia sempervirens, a plant which belongs to the Cupressaceae family. Sequoia sempervirens is commonly known as coast redwood or California redwood, since the vast majority of them are located there.

They are among the most long-lived trees in existence: their maximum lifespan can be anywhere from 2000 to 3000 years, during which time period they can grow to great heights.

The Location of the Hyperion Tree

Hyperion was discovered in August of 2006 by Chris Atkins and Michael Taylor in Redwood National Park while they were they were hiking.

Redwood National Park is in the United States, specifically, in California, in Humboldt County and Del Norte County. Along with state parks Del Norte Coast, Jedediah Smith, and Prairie Creek, Redwood National Park occupies an area of 540 km2.

About 45% of the redwood forests in the whole world are contained within these parks, and one of the highlights for many hikers is Hyperion, due to its great size.

Why Was It Named “Hyperion”?

The name “Hyperion” is meant to compare it to a titan of the same name from Greek mythology.

Hyperion, as the son of Uranus (god of the sky) and Gaea (goddess of the earth) was known as “he who walks in the high places” and “he who appears before the sun.” He was one of the twelve titans, and was considered to be a god of watchfulness, which is a good fit for the tallest tree on the planet, which seems to keep watch over its surroundings from its impressive, dominating height.

Command Quotes - III

1. It's always felt natural, because I'm generally very comfortable with people. - Bruce Springsteen

2. I have been learning English on the road since I started when I was 15, so it is a slow process but making some progress. Now I think I am much more comfortable with my English. However, it is difficult, still, when I speak about something that is not tennis. - Rafael Nadal

3. There's nothing wrong with a woman being comfortable, confident. - Selena Gomez

4. Working in 'Man Ka Meet', I noticed the dedication and sincerity of Sunil Dutt at his work. He encouraged every new comer and made me as well as others feel very comfortable on the sets. - Vinod Khanna

5. I never felt comfortable with myself, because I was never part of the majority. I always felt awkward and shy and on the outside of the momentum of my friends' lives. - Steven Spielberg

6. People can judge me for what I've done. And I think when somebody's out in the public eye, that's what they do. So I'm fully comfortable with who I am, what I stand for, and what I've always stood for. - Hillary Clinton

7. War is a way of shattering to pieces... materials which might otherwise be used to make the masses too comfortable and... too intelligent. - George Orwell

8. A broken heart is a very pleasant complaint for a man in London if he has a comfortable income. - George Bernard Shaw.

Command Quotes - II

1. Man is made to adore and to obey: but if you will not command him, if you give him nothing to worship, he will fashion his own divinities, and find a chieftain in his own passions. - Benjamin Disraeli

2. Have fun in your command. Don't always run at a breakneck pace. Take leave when you've earned it, spend time with your families. - Colin Powell

3. Your position never gives you the right to command. It only imposes on you the duty of so living your life that others can receive your orders without being humiliated. - Dag Hammarskjold

4. In our system leadership is by consent, not command. To lead a President must persuade. Personal contacts and experiences help shape his thinking. They can be critical to his persuasiveness and thus to his leadership. - Donald Rumsfeld

5. Justice is the first virtue of those who command, and stops the complaints of those who obey. - Denis Diderot

6. You see that even the enemy did not dare to declare war against us till they had seized our generals, for they were sensible that, while we had commanders and yielded obedience to them, we were able to conquer them; but, having seized our commanders, they concluded that we should, from a want of command and discipline, be destroyed. - Xenophon

7. The issues a president faces are not black and white, and cannot be boiled down into 140 characters. Because when you have the nuclear codes at your fingertips and the military at your command, you can't make snap decisions. You can't have a thin skin or the tendency to lash out. - Michelle Obama

8. If I had been censured every time I have run my ship, or fleets under my command, into great danger, I should have long ago been out of the Service and never in the House of Peers. - Horatio Nelson.

Pleurisy

Gist

Pleurisy is the inflammation of the membrane surrounding the lungs (pleura), causing sharp, stabbing chest pain that worsens with breathing, coughing, or sneezing. Primarily caused by infections (viral, bacterial pneumonia), it is treated by managing the underlying cause and reducing pain with NSAIDs. Recovery varies, often lasting a few days to weeks depending on the cause, with a generally good prognosis upon prompt treatment.

Pleurisy is inflammation around the lungs, which causes sharp chest pain. It's easy to treat and usually gets better in a few days, but can sometimes be a sign of something more serious, like pneumonia.

Summary

Pleurisy, also known as pleuritis, is inflammation of the membranes that surround the lungs and line the chest cavity (pleurae). This can result in a sharp chest pain while breathing. Occasionally the pain may be a constant dull ache. Other symptoms may include shortness of breath, cough, fever, and weight loss, depending on the underlying cause.

Pleurisy can be caused by a variety of conditions, including viral or bacterial infections, autoimmune disorders, and pulmonary embolism. The most common cause is a viral infection. Other causes include bacterial infection, pneumonia, pulmonary embolism, autoimmune disorders, lung cancer, following heart surgery, pancreatitis and asbestosis. Occasionally the cause remains unknown. The underlying mechanism involves the rubbing together of the pleurae instead of smooth gliding. Other conditions that can produce similar symptoms include pericarditis, heart attack, cholecystitis, pulmonary embolism, and pneumothorax. Diagnostic testing may include a chest X-ray, electrocardiogram (ECG), and blood tests.

Treatment depends on the underlying cause. Paracetamol (acetaminophen) and ibuprofen may be used to decrease pain. Incentive spirometry may be recommended to encourage larger breaths. About one million people are affected in the United States each year. Descriptions of the condition date from at least as early as 400 BC by Hippocrates.

Details:

What is pleurisy?

Pleurisy is an inflammation of the pleura, a large, thin sheet of tissue that wraps around the outside of your lungs and lines the inside of your chest cavity. Between the layer of the pleura that wraps around your lungs and the layer that lines your chest cavity is a very thin space called the pleural space. Normally this space is filled with a small amount of fluid that helps the two layers of the pleura glide smoothly past each other as your lungs breathe air in and out. Pleurisy occurs when the two layers of the pleura become red and inflamed, rubbing against each other every time your lungs expand to breathe in air. Infections like pneumonia are the most common cause of pleurisy.

Symptoms

The main symptom of pleurisy is a sharp or stabbing pain in your chest that gets worse when you breathe in deeply or cough or sneeze. The pain may stay in one place or it may spread to your shoulder or back. Sometimes it becomes a fairly constant dull ache. Depending on what's causing the pleurisy, you may have other symptoms, such as:

* Shortness of breath
* A cough
* Fever and chills
* Rapid, shallow breathing
* Unexplained weight loss
* A sore throat followed by pain and swelling in your joints

Diagnosis

Your doctor will find out if you have pleurisy or another pleural disorder by taking a detailed medical history and doing a physical exam and several diagnostic tests, including:

* Chest X-ray to show air or fluid in the pleural space, and what's causing the condition (for example, pneumonia, a fractured rib, or a lung tumor)

* CT scan that can show pockets of fluid, signs of pneumonia, a lung abscess or a tumor

* Ultrasound, which can show where fluid is located in your chest

* Magnetic resonance (MR) scan, which can show pleural effusions and tumors

* Blood tests, which can show whether you have a bacterial or viral infection, pneumonia, rheumatic fever, a pulmonary embolism or lupus

* Arterial blood gas tests, which show how well your lungs are taking in oxygen

Treatment

A procedure called thoracentesis is used to remove fluid from the pleural space. The doctor inserts a needle or a thin, hollow, plastic tube through the ribs in the back of your chest into your chest wall. A syringe is attached to draw fluid out of your chest.

To relieve symptoms, your doctor may recommend:

* Acetaminophen or anti-inflammatory agents, such as ibuprofen, to control pain

* Codeine-based cough syrups to control a cough

* Lying on the painful side to make you more comfortable

* Breathing deeply and coughing to clear mucus as the pain eases

Your doctor will look at the fluid under a microscope to determine what's causing the fluid buildup. If the fluid is infected, treatment involves antibiotics and draining the fluid. If the infection is tuberculosis or from a fungus, treatment involves long-term use of antibiotics or antifungal medicines. If the fluid is caused by tumors of the pleura, it may build up again quickly after it's drained. Sometimes antitumor medicines will prevent further fluid buildup. If they don't, the doctor may seal the pleural space.

Additional Information

Pleurisy is a condition in which the pleura — two large, thin layers of tissue that separate your lungs from your chest wall — becomes inflamed. Also called pleuritis, pleurisy causes sharp chest pain (pleuritic pain) that worsens during breathing.

One pleural layer of tissue wraps around the outside of the lungs. The other pleural layer lines the inner chest wall. Between these two layers is a small space (pleural space) that's usually filled with a very small amount of liquid. These layers act like two pieces of smooth satin gliding past each other, allowing your lungs to expand and contract when you breathe.

If you have pleurisy, these tissues swell and become inflamed. As a result, the two layers of the pleural lining rub against each other like two pieces of sandpaper. This causes pain when you breathe in and out. The pleuritic pain lessens or stops when you hold your breath.

Treatment of pleurisy involves pain control and treating the cause.

Symptoms:

Signs and symptoms of pleurisy might include:

* Chest pain that worsens when you breathe, cough or sneeze.
* Shortness of breath — often from trying to limit breathing in and out.
* Cough — only in some cases.
* Fever — only in some cases.

Pain caused by pleurisy might worsen with movement of your upper body and can spread to your shoulders or back.

Pleurisy can occur along with pleural effusion, atelectasis or empyema:

* Pleural effusion. In some cases of pleurisy, fluid builds up in the small space between the two layers of tissue. This is called pleural effusion. When there is a fair amount of fluid, pleuritic pain lessens or disappears because the two layers of pleura are no longer in contact and don't rub together.
* Atelectasis. A large amount of fluid in the pleural space can create pressure. This can compress your lung to the point that it partially or completely collapses (atelectasis). This makes breathing difficult and might cause coughing.
* Empyema. The extra fluid in the pleural space can also become infected, resulting in a buildup of pus. This is called an empyema. Fever often occurs along with an empyema.

When to see a doctor

Call your healthcare provider or seek emergency care right away if you experience unexplained, intense chest pain during breathing. You might have a problem with your lungs, heart or pleura or an underlying illness for which you need prompt medical care.

Causes

A variety of conditions can cause pleurisy. Causes include:

* Viral infection, such as the flu (influenza).
* Bacterial infection, such as pneumonia.
* Fungal infection.
* Autoimmune disorder, such as rheumatoid arthritis or lupus.
* Lung cancer near the pleural surface.
* Pulmonary embolism.
* Tuberculosis (TB).
* Rib fracture or trauma.
* Certain inherited diseases, such as sickle cell disease.
* Certain medications and recreational drugs.

Risk factors

The risk of pleurisy increases if you get certain infections, such as the flu or pneumonia. Some medical conditions, such as lupus, TB and sickle cell disease also can increase your risk. And taking certain medicines or certain recreational drugs raise the risk of pleurisy.

Diagnosis

Your healthcare provider will likely start by asking about your medical history and doing a physical exam that includes listening to your chest with a stethoscope.

To determine if you have pleurisy and identify the cause, your healthcare provider might recommend:

* Blood tests. A blood test might tell if you have an infection. Other blood tests might detect an autoimmune disorder, such as rheumatoid arthritis or lupus. In these conditions, pleurisy can be the first sign.
* Chest X-ray. A chest X-ray can show if your lungs are fully inflating or if there is air or fluid between the lungs and ribs.
* Computerized tomography (CT) scan. A CT scan combines a series of X-ray images taken from different angles around your body. It uses computer processing to create cross-sectional images that look like slices of your chest. These detailed images can show the condition of the pleura. They can also show if there are other causes of pain, such as a blood clot in the lung.
* Ultrasound. This imaging method uses high-frequency sound waves to produce precise images of structures within your body. An ultrasound might be used to determine whether you have a pleural effusion.
* Electrocardiogram (ECG or EKG). This heart-monitoring test might be recommended to rule out certain heart problems as a cause for your chest pain.

Diagnostic procedures

In some cases, your healthcare provider might remove fluid and tissue from the pleural space for testing. Procedures might include:

* Thoracentesis. In this procedure, a local numbing agent (anesthetic) is injected between your ribs to the area where fluid was seen on your imaging studies. Next a needle is inserted through your chest wall between your ribs to remove fluid for lab analysis. Removing fluid can also help you breathe better. The needle is usually inserted with the help of ultrasound guidance.
* Thoracoscopy. If TB or cancer is suspected, a thoracoscopy — also called a pleuroscopy — may be performed. During this procedure, a tiny camera (thoracoscope) is inserted through a small cut in your chest wall. This procedure allows for a direct view inside your chest to look for any problems or to get a tissue sample (biopsy).

Treatment

Treatment for pleurisy focuses primarily on the underlying cause. For example, if bacterial pneumonia is the cause, an antibiotic can be prescribed to manage the infection. If the cause is a viral infection, pleurisy may go away on its own.

The pain and inflammation associated with pleurisy is usually treated with nonsteroidal anti-inflammatory drugs (NSAIDs), such as ibuprofen (Advil, Motrin IB, others). Occasionally, your healthcare provider may prescribe steroid medication.

The outcome of pleurisy treatment depends on the seriousness of the underlying cause. Early diagnosis and treatment of the condition that caused pleurisy can help you feel better. Depending on the cause and the condition, you may make a full recovery.

Lifestyle and home remedies

These steps might help relieve symptoms related to pleurisy:

* Take medication. Take medication as recommended by your healthcare provider to relieve pain and inflammation.
* Get plenty of rest. Find the position that causes you the least discomfort when you rest. Even when you start to feel better, be careful not to overdo it.
* Don't smoke. Smoking can cause more irritation to your lungs. If you smoke and can't quit on your own, ask your healthcare provider for help.