The subject of mouthpiece pressure is closely related to the issue of embouchure collapse/embouchure overuse.

It has long been argued that excessive mouthpiece pressure is a cause of embouchure problems and can be a factor in causing embouchure collapse. However, the pressure of the mouthpiece is not static during playing: it increases the higher in the register a player plays and the louder volume level. Also, a little mouthpiece pressure is essential to provide a seal between the player's embouchure and the instrument; without this, all the air would escape before entering the instrument and no sound would be emitted (brass instruments are dependent on an airflow to produce sound).

Embouchure collapse is far more common among trumpet and horn players. Both of these instruments have mouthpieces with a small circumference, and therefore the pressure is presumably greater, as the force of the mouthpiece on the face is more concentrated. This is in accordance with the principle of physics that pressure is the amount of force divided by the area on which the force is exerted.

As a result of a lack of scientific evidence (no scientific study into mouthpiece pressure as a cause of embouchure collapse has ever been done), the equally valid argument that all brass players can suffer embouchure collapse, and the subjective (not static) nature of mouthpiece pressure, knowledge of mouthpiece pressure as a cause of embouchure collapse is limited.

Embouchure collapse caused by focal dystonia can be diagnosed medically; embouchure collapse caused by embouchure overuse, however, is generally speaking not considered to be a specifically medical issue. A difficulty in diagnosis is that when a brass player describes the symptoms to a doctor or dentist (as is often the case), the medical practitioner does not fully understand what the patient means. This is because brass players learn their embouchure by "feel," and therefore words have a limited ability to describe embouchure problems, especially if the person listening to the description is not a brass player and has a limited knowledge of the embouchure.

Also, in less severe cases, the player may only be able to feel what is wrong while playing. Many players with an embouchure problem will, once they have realized that it is more than a simple case of tired lips, wish to refrain from playing. The fact that around 24 muscles are employed in forming a brass embouchure, and that each will change slightly as a player struggles to play when experiencing embouchure problems, mean that what players describe as being wrong will have not only worsened their condition when they play, but will be different each time they do so.

In the severest cases, the pain caused by embouchure overuse can be felt even when not playing; in some cases, other symptoms will manifest, such as loss of tissue and damaged nerves. This, however, occurs only in the rarest and most extreme circumstances and usually signals the end of the player's career.

The exact cause of Kienböck's is not known, though there are thought to be a number of factors predisposing a person to Kienböck's.

Recent studies have made a correlation between Kienböck's sufferers and Western European ancestry, but no definitive link can be positively confirmed.

The necrosis of the lunate bone can frequently be traced to a trauma to the wrist, like a compound fracture, which could cause the lunate's blood supply to be interrupted. Blood flows to the lunate through several arteries, each supplying a percentage. When one of these pathways is severed, the likelihood the patient will develop necrosis increases.

Despite a preponderance of evidence, no particular cause has been conclusively verified.

Data exists on the internet that most people suffering from Kienböck's are affected in their dominant hand, though about one-third of sufferers report the condition in their non-dominant hand. In very few cases have there been people that have acquired it in both wrists.

Kienböck's disease is classified as a "rare disorder," meaning that it affects fewer than 200,000 people in the U.S. population.

Many Kienböck's patients are frustrated by the lack of consensus among hand surgeons about optimal treatments for Kienböck's. No matter what the disease's stage of progression, there is no one best treatment, and the decision is often based partially, or even mostly, on incidental factors such as the patient's pain tolerance, the patient's desire to return to active use of the hand (such as in manual occupations), and the surgeon's level of expertise with different treatments.

Though, since each case of Kienböck's is different, the makeup of the wrist and arm bones are important factors which are individualized to each patient. Therefore, one surgery will never be able to solve all the problems associated with the disease. Thus, no consensus can be reached among surgeons.

Operations that attempt to restore a blood supply to the lunate may be performed.

Depending on the stage the disease is in when it is discovered, varying treatments are applied.

If X-rays show a mostly intact lunate (not having lost a great deal of size, and not having been compressed into a triangular shape), but an MRI shows a lack of blood flow to the bone, then revascularization is normally attempted. Revascularization techniques, usually involving a bone graft taken elsewhere from the body — often held in place by an external fixator for a period of weeks or months — have been successful at stages as late as 3B, although their use at later stages (like most treatments for Kienböck's) is controversial.

One conservative treatment option would be using an Ultrasound Bone Stimulator, which uses low-intensity pulsed ultrasound to increase vascular endothelial growth factor (VEG-F) and increase blood flow to the bone.

Some Kienböck's patients present with an abnormally large difference in length between the radius and the ulna, termed "ulnar variance", which is hypothesized to cause undue pressure on the lunate, contributing to its avascularity. In cases with such a difference, "radial shortening" is commonly performed. In this procedure, the radius (the lateral long bone) is shortened by a given length, usually between 2 and 5 mm, to relieve the pressure on the dying lunate. A titanium plate is inserted to hold the newly shortened bone together.

During Stage 3, the lunate has begun to break apart due to the pressure of the surrounding bones. This causes sharp fragments of bone to float between the joints, causing excruciating pain. At this point, the lunate is ready for removal. The most frequently performed surgery is the "Proximal Row Carpectomy", where the lunate, scaphoid and triquetrum are extracted. This greatly limits the range of motion of the wrist, but pain relief can be achieved for longer than after the other surgeries.

Another surgical option for this stage is a titanium, silicon or pyrocarbon implant that takes place of the lunate, though doctors shy from this due to a tendency of the implant to smooth the edges of the surrounding bones, thus causing painful pinched nerves when the bones slip out of place.

After the lunate is removed, another procedure, "ulnar shortening" can be performed. This relieves pressure on the newly formed wrist joint of the pisiform, hamate and capitate. Depending on the surgeon, the procedure may be performed the same way as the "radial shortening" where a small section is removed, or the entire top of the ulna may be excised.

At Stage 4, the lunate has completely disintegrated and the other bones in the wrist have radiated downward to fill in the void. The hand now has a deformed, crippled appearance. The only procedure that can be done is the "total wrist fusion", where a plate is inserted on the top of the wrist from the radius to the carpals, effectively freezing all flexion and movement in the wrist. Rotation is still possible as it is controlled by the radius and ulna.

This is currently the last and most complete surgical option for Kienböck's sufferers.

Most of the treatments described here are not mutually exclusive — meaning that a single patient may receive many of them in his quest to relieve pain. For instance, some patients have had casting, bone graft, radial shortening, proximal row carpectomy, and wrist fusion, all on the same hand.

First described by Preiser in 1910 in 5 patients, all with previous history of wrist trauma, and scaphoid fractures in 3 of them.

Preiser disease, or (idiopathic) avascular necrosis of the scaphoid, is a rare condition where ischemia and necrosis of the scaphoid bone occurs without previous fracture. It is thought to be caused by repetitive microtrauma or side effects of drugs (e.g., steroids or chemotherapy) in conjunction with existing defective vascular supply to the proximal pole of the scaphoid. MRI coupled with CT and X-ray are the methods of choice for diagnosis.

Preiser's disease is initially treated by immobilising the wrist with a cast. However, in most cases the avascular scaphoid will start to collapse leading to degeneration within the wrist joints. This often requires surgical intervention to prevent the progression of arthris. Two commonly performed procedures are:

1. Proximal row carpectomy (PRC), which involves removing the first row of the carpal bones, i.e. the scaphoid, lunate and triquetrum. The wrist is immobilised in a cast for six weeks after the surgery and then physiotherapy is started.

2. Scaphoid excision and 4-corner fusion, which is a procedure consisting of the removal of the scaphoid and fixation of the remaining wrist bones with a plate (called a "spider plate") or wires in order to provide stability. The plate usually is left inside the patient's wrist, while the wires (usually K-wires) have to be removed in a second surgery. This procedure of partial wrist fusion allows for limited wrist movement, whereas total wrist fusion immobilizes the wrist permanently. Following surgery it can take several months for affected patients to regain strength.

Unfortunately both of these operations are salvage procedures and movements in the wrist will be significantly reduced.

The use of steroids (Dexamethasone) coupled with an antibiotic (Amoxicillin) will support the kitten in a number of ways, the steroid enhancing maturation and the antibiotic addressing the possibility of underlying infection and compensating for the immuno-depressant properties of the steroid. The steroid will also encourage the kitten to feed more energetically, keeping its weight up. Several breeders believe that Taurine plays a part in the condition, and it may be that some cases are Taurine-related. These breeders give the queen large doses of Taurine (1000 mg) daily until the kittens recover – apparently within a few days. Given that most FCKS cases take weeks rather than days to recover, this supplement may be relevant.

If the diver has not been exposed to excessive depth and decompression and presents as DON, there may be a predisposition for the condition. Diving should be restricted to shallow depths. Divers who have suffered from DON are at increased risk of future fracture of a juxta-articular lesion during a dive, and may face complications with future joint replacements. Because of the young age of the population normally affected, little data is available regarding joint replacement complications.

There is the potential for worsening of DON for any diving where there might be a need for decompression, experimental or helium diving. Physically stressful diving should probably be restricted, both in sport diving and work diving due to the possibility of unnecessary stress to the joint. Any diving should be less than 40 feet/12 meters. These risks are affected by the degree of disability and by the type of lesion (juxta-articular or shaft).

Splinting the kitten in a specially-constructed corset encourages the ribcage to a more normal position, and reported mortality seemed to decline when this practice was introduced. This may be because encouraging the chest to a more correct position helps the lungs to re-inflate. However a large proportion of kittens cannot tolerate a splint, and the distress it causes is extremely counterproductive. It can also be dangerous in cases where pressure on the sides causes the sternum to move inwards rather than outwards, and should only be undertaken with veterinary support and advice. Some kittens recover without intervention, so it is not known whether the various treatments based on encouraging the thorax to return to a normal shape contributed to recovery.

Some breeders have found that putting pressure on the sides of the ribcage can help, as the chest rounds out with encouragement (gentle pressure timed to coincide with the natural movement of the thorax in breathing), but usually the chest goes flat again as soon as massage is discontinued. It may however help in encouraging the lungs to inflate a little more with each breath, but should not be used if it causes distress to the kitten. Many breeders report that affected kittens seem to enjoy massage. Encouraging a kitten to lie on its side can be helpful, and draping another kitten (or the mother's arm) over it while it is sleeping places a gentle continuous pressure on the ribcage which may also be helpful. If the kitten is uncomfortable it will move away. (It is important to ensure that pressure is not placed on the kitten if it is lying flat on its chest.)

Over-handling FCKS kittens can lead to unnecessary weight loss and lethargy, so the use of massage, waking the kitten for extra feeds from the mother etc. should be checked against gains and losses in weight. Some vets believe that encouraging the kitten to cry and also to have to move more to reach its mother may be helpful. There is little or no data from breeders supporting this theory.

Prevention is a more successful strategy than treatment. By using the most conservative decompression schedule reasonably practicable, and by minimizing the number of major decompression exposures, the risk of DON may be reduced. Prompt treatment of any symptoms of decompression sickness (DCS) with recompression and hyperbaric oxygen also reduce the risk of subsequent DON.

Diagnosis is not very advanced and is based on the telltale nodding seizures of the victims. When stunted growth and mental disability are also present, probability of nodding syndrome is high. In the future, neurological scans may also be used in diagnosis. As there is no known cure for the disease, treatment has been directed at symptoms, and has included the use of anticonvulsants such as sodium valproate and phenobarbitol. Anti-malaria drugs have also been administered, to unknown effect.

Spinal shock was first defined by Whytt in 1750 as a loss of accompanied by motor paralysis with initial loss but gradual recovery of reflexes, following a spinal cord injury (SCI) – most often a complete transection. Reflexes in the spinal cord below the level of injury are depressed (hyporeflexia) or absent (areflexia), while those above the level of the injury remain unaffected. The 'shock' in spinal shock does not refer to circulatory collapse, and should not be confused with neurogenic shock, which is life-threatening

Children younger than 6 have the best prognosis, since they have time for the dead bone to revascularize and remodel, with a good chance that the femoral head will recover and remain spherical after resolution of the disease. Children who have been diagnosed with Perthes' disease after the age of 10 are at a very high risk of developing osteoarthritis and coxa magna. When an LCP disease diagnosis occurs after age 8, a better outcome results with surgery rather than nonoperative treatments. Shape of femoral head at the time when Legg-Calve Perthes disease heals is the most important determinant of risk for degenerative arthritis; hence, the shape of femoral head and congruence of hip are most useful outcome measures.

Collapse is a sudden and often unannounced loss of postural tone (going weak), often but not necessarily accompanied by loss of consciousness.

If the episode was accompanied by a loss of consciousness, the term syncope is used. The main causes are cardiac (e.g. due to irregular heart beat, low blood pressure), seizures or a psychological cause. The main tool in distinguishing the causes is careful history on the events before, during and after the collapse, from the patient as well as from any possible witnesses. Other investigations may be performed to further strengthen the diagnosis, but many of these have a low yield.

The goals of treatment are to decrease pain, reduce the loss of hip motion, and prevent or minimize permanent femoral head deformity so that the risk of developing a severe degenerative arthritis as adult can be reduced. Assessment by a pediatric orthopaedic surgeon is recommended to evaluate risks and treatment options. Younger children have a better prognosis than older children.

Treatment has historically centered on removing mechanical pressure from the joint until the disease has run its course. Options include traction (to separate the femur from the pelvis and reduce wear), braces (often for several months, with an average of 18 months) to restore range of motion, physiotherapy, and surgical intervention when necessary because of permanent joint damage. To maintain activities of daily living, custom orthotics may be used. Overnight traction may be used in lieu of walking devices or in combination. These devices internally rotate the femoral head and abduct the leg(s) at 45°. Orthoses can start as proximal as the lumbar spine, and extend the length of the limbs to the floor. Most functional bracing is achieved using a waist belt and thigh cuffs derived from the Scottish-Rite orthosis. These devices are typically prescribed by a physician and implemented by an orthotist. Clinical results of the Scottish Rite orthosis have not been good according to some studies, and its use has gone out of favor. Many children, especially those with the onset of the disease before age 6, need no intervention at all and are simply asked to refrain from contact sports or games which impact the hip. For older children (onset of Perthes after age 6), the best treatment option remains unclear. Current treatment options for older children over age 8 include prolonged periods without weight bearing, osteotomy (femoral, pelvic, or shelf), and the hip distraction method using an external fixator which relieves the hip from carrying the body's weight. This allows room for the top of the femur to regrow. The Perthes Association has a "library" of equipment which can be borrowed to assist with keeping life as normal as possible, newsletters, a helpline, and events for the families to help children and parents to feel less isolated.

While running and high-impact sports are not recommended during treatment for Perthes disease, children can remain active through a variety of other activities that limit mechanical stress on the hip joint. Swimming is highly recommended, as it allows exercise of the hip muscles with full range of motion while reducing the stress to a minimum. Cycling is another good option as it also keeps stress to a minimum. Physiotherapy generally involves a series of daily exercises, with weekly meetings with a physiotherapist to monitor progress. These exercises focus on improving and maintaining a full range of motion of the femur within the hip socket. Performing these exercises during the healing process is essential to ensure that the femur and hip socket have a perfectly smooth interface. This will minimize the long-term effects of the disease. Use of bisphosphonate such as zoledronate or ibandronate is currently being investigated, but definite recommendations are not yet available.

Perthes disease is self-limiting, but if the head of femur is left deformed, long-term problems can occur. Treatment is aimed at minimizing damage while the disease runs its course, not at 'curing' the disease. It is recommended not to use steroids or alcohol as these reduce oxygen in the blood which is needed in the joint. As sufferers age, problems in the knee and back can arise secondary to abnormal posture and stride adopted to protect the affected joint. The condition is also linked to arthritis of the hip, though this appears not to be an inevitable consequence. Hip replacements are relatively common as the already damaged hip suffers routine wear; this varies by individual, but generally is required any time after age 50.

It is ethically difficult when it comes to dealing with diagnosed patients, for many of them deny their poor conditions and refuse to accept treatment. The main objectives of the doctors are to help improve the patient’s lifestyle and wellbeing, so health care professionals must decide whether or not to force treatment onto their patient.

In some cases, especially those including the inability to move, patients have to consent to help, since they cannot manage to look after themselves. Hospitals or nursing homes are often considered the best treatment under those conditions.

When under care, patients must be treated in a way in which they can learn to trust the health care professionals. In order to do this, the patients should be restricted in the number of visitors they are allowed, and be limited to 1 nurse or social worker. Some patients respond better to psychotherapy, while others to behavioral treatment or terminal care.

Results after hospitalization tend to be poor. Research on the mortality rate during hospitalization has shown that approximately half the patients die while in the hospital. A quarter of the patients are sent back home, while the other quarter are placed in long time care. Patients under care in hospitals and nursing homes often slide back into relapse or face death.

There are other approaches to improve the patient’s condition. Day care facilities have often been successful with maturing the patient’s physical and emotional state, as well as helping them with socialization. Other methods include services inside the patient’s home, such as the delivery of food.

Laryngomalacia becomes symptomatic after the first few months of life (2–3 months), and the stridor may get louder over the first year, as the child moves air more vigorously. Most of the cases resolve spontaneously and less than 15% of the cases will need surgical intervention. Parents need to be supported and educated about the condition.

Time is the only treatment necessary in more than 90% of infant cases. In other cases, surgery may be necessary. Most commonly, this involves cutting the aryepiglottic folds to let the supraglottic airway spring open. Trimming of the arytenoid cartilages or the mucosa/ tissue over the arytenoid cartilages can also be performed as part of the supraglottoplasty. Supraglottoplasty can be performed bilaterally (on both the left and right sides at the same time), or be staged where only one side is operated on at a time.

Treatment of gastroesophageal reflux disease can also help in the treatment of laryngomalacia, since gastric contents can cause the back part of the larynx to swell and collapse even further into the airway.

In some cases, a temporary tracheostomy may be necessary.

Nodding syndrome is debilitating both physically and mentally. In 2004, Peter Spencer stated: "It is, by all reports, a progressive disorder and a fatal disorder, perhaps with a duration of about three years or more." While a few children are said to have recovered from it, many have died from the illness. Seizures can also cause children to collapse, potentially causing injury or death.

A series of 2009 studies published in the Journal of Cardiovascular Pharmacology suggest that Metformin may prevent cardiac reperfusion injury by inhibition of Mitochondrial Complex I and the opening of MPT pore and in rats.

There are some preliminary studies that seem to indicate that treatment with hydrogen sulfide (HS) can have a protective effect against reperfusion injury.

Some horse organizations have instituted rules to attempt to eliminate this widespread disease. The American Quarter Horse Association (AQHA) mandates testing for foals descended from Impressive if both of the foal's parents were not homozygous negative (N/N) for the gene, and, since 2007, has not registered foals homozygous (H/H) for the gene. Since 2007, the Appaloosa Horse Club (ApHC) has required foals descended from Impressive to be tested, so that the results may be recorded on its certificate. The American Paint Horse Association (APHA) mandated that, after 2017, stallions must be tested for HYPP so that mare owners may make an informed decision before choosing a stallion for breeding to their mare.

The origin of the syndrome is unknown, although the term “Diogenes” was coined by A. N. G. Clarke et al. in the mid‑1970s and has been commonly used since then. Diogenes syndrome was acknowledged more prominently as a media phenomenon in popular media rather than medical literature. The primary description of this syndrome has only been mentioned recently by geriatricians and psychiatrists.

Collapsed veins are a common result of chronic use of intravenous injections. They are particularly common where injecting conditions are less than ideal, such as in the context of drug abuse.

Veins may become temporarily blocked if the internal lining of the vein swells in response to repeated injury or irritation. This may be caused by the needle, the substance injected, or donating plasma. Once the swelling subsides, the circulation will often become re-established.

Permanent vein collapse occurs as a consequence of:

- Long-term injecting

- Repeated injections, especially with blunt needles

- Poor technique

- Injection of substances which irritate the veins; in particular, injection of liquid methadone intended for oral use.

Smaller veins may collapse as a consequence of too much suction being used when pulling back against the plunger of the syringe to check that the needle is in the vein. This will pull the sides of the vein together and, especially if they are inflamed, they may stick together causing the vein to block. Removing the needle too quickly after injecting can have a similar effect.

Collapsed veins may never recover. Many smaller veins are created by the body to circulate the blood, but they are not adequate for injections or IVs.

To properly treat a patient with tracheobronchomalacia, the subtype must be determined (primary or secondary). After the type is named, the cause must be identified, whether it is from genetics, a trauma accident, or chronic tracheal illness. If a trauma case or chronic tracheal illnesses were the cause, the first steps of treatment would be to fix or help these underlying issues. If the cause is genetic or the previous underlying issues could not be fixed, other treatments would be assessed. More severe treatments include silicone stenting to prevent tracheal constriction, surgery to strengthen or attempt to rebuild the walls, continuous positive airway pressure that has a machine blow small amounts of air into the trachea to keep it open (mainly at night), or a tracheostomy, which is surgically put into your neck that leads to your trachea to help with breathing. People with tracheobronchomalacia who do not experience symptoms do not need treatment and are often undiagnosed.