Central cyanosis is often due to a circulatory or ventilatory problem that leads to poor blood oxygenation in the lungs. It develops when arterial oxygen saturation drops to ≤85% or ≤75%.

Acute cyanosis can be as a result of asphyxiation or choking, and is one of the definite signs that respiration is being blocked.

Central cyanosis may be due to the following causes:

1. Central nervous system (impairing normal ventilation):

- Intracranial hemorrhage

- Drug overdose (e.g. heroin)

- Tonic–clonic seizure (e.g. grand mal seizure)

2. Respiratory system:

- Pneumonia

- Bronchiolitis

- Bronchospasm (e.g. asthma)

- Pulmonary hypertension

- Pulmonary embolism

- Hypoventilation

- Chronic obstructive pulmonary disease, or COPD (emphysema)

3. Cardiovascular diseases:

- Congenital heart disease (e.g. Tetralogy of Fallot, right to left shunts in heart or great vessels)

- Heart failure

- Valvular heart disease

- Myocardial infarction

4. Blood:

- Methemoglobinemia * Note this causes "spurious" cyanosis, in that, since methemoglobin appears blue, the patient can appear cyanosed even in the presence of a normal arterial oxygen level.

- Polycythaemia

- Congenital cyanosis (HbM Boston) arises from a mutation in the α-codon which results in a change of primary sequence, H → Y. Tyrosine stabilises the Fe(III) form (oxyhaemoglobin) creating a permanent T-state of Hb.

5. Others:

- High altitude, cyanosis may develop in ascents to altitudes >2400 m.

- Hypothermia

- Obstructive sleep apnea

Differential cyanosis is the bluish coloration of the lower but not the upper extremity and the head. This is seen in patients with a patent ductus arteriosus. Patients with a large ductus develop progressive pulmonary vascular disease, and pressure overload of the right ventricle occurs. As soon as pulmonary pressure exceeds aortic pressure, shunt reversal (right-to-left shunt) occurs. The upper extremity remains pink because the brachiocephalic trunk, left common carotid trunk and the left subclavian trunk is given off proximal to the PDA.

Although there is no definitive reporting on its incidence, acrocyanosis shows prevalence in children and young adults than in patients thirty years of age or older. Epidemiological data suggests that cold climate, outdoor occupation, and low body mass index are significant risk factors for developing acrocyanosis. As expected, acrocyanosis would be more prevalent in women than in men due to differences in BMI. However, the incidence rate of acrocyanosis often decreases with increasing age, regardless of regional climate. It completely resolves in many women after menopause implying significant hormonal influences.

This refers specifically to hypoxic states where the arterial content of oxygen is insufficient. This can be caused by alterations in respiratory drive, such as in respiratory alkalosis, physiological or pathological shunting of blood, diseases interfering in lung function resulting in a ventilation-perfusion mismatch, such as a pulmonary embolus, or alterations in the partial pressure of oxygen in the environment or lung alveoli, such as may occur at altitude or when diving.

Acrocyanosis is common initially after delivery in the preterm and full term newborn Intervention normally is not required, although hospitals opt to provide supplemental oxygen for precautionary measures.

Carbon monoxide competes with oxygen for binding sites on hemoglobin molecules. As carbon monoxide binds with hemoglobin hundreds of times tighter than oxygen, it can prevent the carriage of oxygen.

Carbon monoxide poisoning can occur acutely, as with smoke intoxication, or over a period of time, as with cigarette smoking. Due to physiological processes, carbon monoxide is maintained at a resting level of 4–6 ppm. This is increased in urban areas (7–13 ppm) and in smokers (20–40 ppm). A carbon monoxide level of 40 ppm is equivalent to a reduction in hemoglobin levels of 10 g/L.

CO has a second toxic effect, namely removing the allosteric shift of the oxygen dissociation curve and shifting the foot of the curve to the left. In so doing, the hemoglobin is less likely to release its oxygens at the peripheral tissues. Certain abnormal hemoglobin variants also have higher than normal affinity for oxygen, and so are also poor at delivering oxygen to the periphery.

Pallor mortis results from the cessation of capillary circulation throughout the body. Gravity then causes the blood to sink down into the lower parts of the body, creating livor mortis.

A living person can look deathly pale. This can happen when circumstances make the blood escape from the surface of the skin, as in deep shock. Also heart failure ("insufficientia cordis") can make the face look grey; the person then also has blue lips. Skin can also look deathly pale as a result of vasoconstriction as part of the body's homeostatic systems in cold conditions, or if the skin is deficient in vitamin D, as seen in people who spend most of the time indoors, away from sunlight.

The risk may be reduced by administering a non-particulate antacid (e.g. Sodium Citrate) or an H-antagonist like Ranitidine.

Historically it is said that a patient is at risk if they have:

- Residual gastric volume of greater than 25ml, with

- pH of less than 2.5

However these are indirect measurements and are not factors that directly influence aspiration risk.

Patients with a high risk should have a rapid sequence induction. High risk is defined as these factors:

1. Non-elective surgical procedure

2. Light anaesthesia/unexpected response to stimulation

3. Acute or chronic, upper or lower GI pathology

4. Obesity

5. Opioid medication

6. Neurological disease, impaired conscious level, or sedation

7. Lithotomy position

8. Difficult intubation/airway

9. Gastrointestinal reflux

10. Hiatal hernia

Atherosclerosis affects up to 10% of the Western population older than 65 years and for intermittent claudication this number is around 5%. Intermittent claudication most commonly manifests in men older than 50 years.

One in five of the middle-aged (65–75 years) population of the United Kingdom have evidence of peripheral arterial disease on clinical examination, although only a quarter of them have symptoms. The most common symptom is muscle pain in the lower limbs on exercise—intermittent claudication.

Pallor is a pale color of the skin that can be caused by illness, emotional shock or stress, stimulant use, or anemia, and is the result of a reduced amount of oxyhaemoglobin and is visible in skin conjuctivae or mucous membrane.

Pallor is more evident on the face and palms. It can develop suddenly or gradually, depending on the cause. It is not usually clinically significant unless it is accompanied by a general pallor (pale lips, tongue, palms, mouth and other regions with mucous membranes). It is distinguished from similar presentations such as hypopigmentation (lack or loss of skin pigment) or simply a fair complexion.

While recent case series (n=9-80) studies have found a mortality rate of 20-40%, a large (n=1641) 2009 study reported a mortality rate of 7.5%.

For individuals who survive the initial crush injury, survival rates are high for traumatic asphyxia.

Pneumopericardium is a medical condition where air enters the pericardial cavity. This condition has been recognized in preterm neonates, in which it is associated with severe lung pathology, after vigorous resuscitation, or in the presence of assisted ventilation. This is a serious complication, which if untreated may lead to cardiac tamponade and death. Pneumomediastinum, which is the presence of air in the mediastinum, may mimic and also coexist with pneumopericardium.

It can be congenital, or introduced by a wound.

This can be caused by taking medications that contain sulfonamides under certain conditions (i.e., overdosing of sumatriptan).

Sulfhemoglobinemia is usually drug induced. Drugs associated with sulfhemoglobinemia include sulphonamides and sulfasalazine. Another possible cause is occupational exposure to sulfur compounds.

It can be caused by phenazopyridine.

Sulfhemoglobinemia (or sulfhaemoglobinaemia) is a rare condition in which there is excess sulfhemoglobin (SulfHb) in the blood. The pigment is a greenish derivative of hemoglobin which cannot be converted back to normal, functional hemoglobin. It causes cyanosis even at low blood levels.

It is a rare blood condition that occurs when a sulfur atom is incorporated into the hemoglobin molecule. When hydrogen sulfide (HS) (or sulfide ions) and ferric ions combine in the blood, the blood is incapable of carrying oxygen.

The cause of TEC is unknown, but it thought to be triggered by a viral infection. While rare cases have been attributed to infection with Parvovirus B19, the majority of cases are not related to Parvovirus infection. This is in contrast to transient aplastic crisis, seen in patients with hemoglobinopathies such as sickle cell disease, which is usually caused by Parvovirus infection.

Raynaud's disease, or "Primary Raynaud's", is diagnosed if the symptoms are "idiopathic", that is, if they occur by themselves and not in association with other diseases. Some refer to Primary Raynaud's disease as "being allergic to coldness". It often develops in young women in their teens and early adulthood. Primary Raynaud's is thought to be at least partly hereditary, although specific genes have not yet been identified.

Smoking increases frequency and intensity of attacks, and there is a hormonal component. Caffeine, estrogen, and non-selective beta-blockers are often listed as aggravating factors, but evidence that they should be avoided is not solid. People with the condition are more likely to have migraines and angina.

The mechanism responsible for pneumopericardium is the ‘Macklin effect’ – There is initially an increased pressure gradient between the alveoli and the interstitial space. Increased pressure leads to alveolar rupture, resulting in air getting through to the pericapillary interstitial pulmonary space. This space is continuous with the peribronchial and pulmonary perivascular sheaths. From here, the air tracks to the hilum of the lung and then to the mediastinum. In case of a pericardial tear, this air enters the pericardial cavity and pneumopericardium develops. The condition may remain asymptomatic or may progress to life-threatening conditions like tension pneumopericardium or cardiac tamponade.

TIF is a rare condition with a .7% frequency, and an mortality rate approaching 100% without surgical intervention. Immediate diagnosis and intervention of an TIF is critical for the surgical intervention success. 25-30% of TIF patients who reach the operating room survive. Recently, the incidence of TIF may have declined due to advances in tracheostomy tube technology and the introduction of the bedside percutaneous dilatational tracheostomy (PDT).

The following factors increase some people's susceptibility to airsickness:

- Fatigue, stress, and anxiety, are some factors that can increase susceptibility to motion sickness of any type.

- The use of alcohol, drugs, and medications may also contribute to airsickness.

- Additionally, airsickness is more common in women (especially during menstruation or pregnancy), young children, and individuals prone to other types of motion sickness.

- Although airsickness is uncommon among experienced pilots, it does occur with some frequency in student pilots.

Most patients recover completely within 1–2 months.

However many reported cases have lasted 18–24 months and longer.

The sudden impact on the thorax causes an increase in intrathoracic pressure. In order for traumatic asphyxia to occur, a Valsalva maneuver is required when the traumatic force is applied. Exhalation against the closed glottis along with the traumatic event causes air that cannot escape from the thoracic cavity. Instead, the air causes increased venous back-pressure, which is transferred back to through the right atrium, to the superior vena cava and to the head and neck veins and capillaries.

Two pathophysiologic mechanisms are thought to play a role in the development of gray baby syndrome after exposure to the anti-microbial drug chloramphenicol. This condition is due to a lack of glucuronidation reactions occurring in the baby, thus leading to an accumulation of toxic chloramphenicol metabolites. :

1. The UDP-glucuronyl transferase enzyme system of infants, especially premature infants, is immature and incapable of metabolizing the excessive drug load.

2. Insufficient renal excretion of the unconjugated drug.

Due to these two reasons the chloramphenicol level in blood is increased, at higher concentration chloramphenicol blocks electron transport in the liver, myocardium, and skeletal muscles, resulting the above symptoms.