Nitroglycerin (medication)

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/Nitroglycerin_(medication)

 

Nitroglycerin

Clinical data
Trade names	Nitrol, others
AHFS/Drugs.com	Monograph
MedlinePlus	a601086
Routes of administration	Sublingual, transdermal, by mouth, intravenous
ATC code	C01DA02 (WHO) C05AE01 (WHO)
Legal status
Legal status	AU: S3 (Pharmacist only) UK: P (Pharmacy medicines) US: ℞-only
Pharmacokinetic data
Bioavailability	<1%
Metabolism	liver (rapid), red blood cells, vascular wall
Elimination half-life	3 minutes
Excretion	In urine, in bile
Identifiers

IUPAC name
CAS Number	55-63-0
PubChem CID	4510
IUPHAR/BPS	7053
DrugBank	DB00727
ChemSpider	4354
UNII	G59M7S0WS3
ChEBI	CHEBI:28787
ChEMBL	ChEMBL730
Chemical and physical data
Formula	C3H5N3O9
Molar mass	227.085 g·mol−1
3D model (JSmol)	Interactive image

SMILES

InChI

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Nitroglycerin, also known as glyceryl trinitrate (GTN), is a vasodilator used for heart failure, high blood pressure (hypertension), anal fissures, painful periods, and to treat and prevent chest pain caused by decreased blood flow to the heart (angina) or due to the recreational use of cocaine. This includes chest pain from a heart attack. It is taken by mouth, under the tongue, applied to the skin, or by injection into a vein.

Side effects and mechanism

Common side effects include headache and low blood pressure. The low blood pressure can be severe. It is unclear if use in pregnancy is safe for the fetus. It should not be used together with medications within the PDE5 inhibitor family such as sildenafil due to the risk of low blood pressure. Nitroglycerin is in the nitrate family of medications. While it is not entirely clear how it works, it is believed to function by dilating blood vessels.

History, society and culture

Nitroglycerin was written about as early as 1846 and came into medical use in 1878. The drug nitroglycerin is a dilute form of the same chemical used as the explosive, nitroglycerin. Dilution makes it non-explosive. In 2021, it was the 174th most commonly prescribed medication in the United States, with more than 2 million prescriptions.

Medical uses

Three different forms of nitroglycerin: intravenous, sublingual spray, and the nitroglycerin patch.

Nitroglycerin is used for the treatment of angina, acute myocardial infarction, severe hypertension, and acute coronary artery spasms. It may be administered intravenously, as a sublingual spray, or as a patch applied to the skin.

Angina

Glyceryl trinitrate is useful in decreasing angina attacks, perhaps more so than reversing angina once started, by supplementing blood concentrations of NO, also called endothelium-derived relaxing factor, before the structure of NO as the responsible agent was known. This led to the development of transdermal patches of glyceryl trinitrate, providing 24-hour release. However, the effectiveness of glyceryl trinitrate is limited by development of tolerance/tachyphylaxis within 2–3 weeks of sustained use. Continuous administration and absorption (such as provided by daily pills and especially skin patches) accelerate onset of tolerance and limit the usefulness of the agent. Thus, glyceryl trinitrate works best when used only in short-term, pulse dosing. Glyceryl trinitrate is useful for myocardial infarction (heart attack) and pulmonary edema, again working best if used quickly, within a few minutes of symptom onset, as a pulse dose. It may also be given as a sublingual or buccal dose in the form of a tablet placed under the tongue or a spray into the mouth for the treatment of an angina attack.

Other uses

Tentative evidence indicates efficacy of glyceryl trinitrate in the treatment of various tendinopathies, both in pain management and acceleration of soft tissue repair.

Glyceryl trinitrate is also used in the treatment of anal fissures, though usually at a much lower concentration than that used for angina treatment.

Glyceryl trinitrate has been used to decrease pain associated with dysmenorrhea.

Glyceryl trinitrate was once researched for the prevention and treatment of osteoporosis; however, the researcher Sophie Jamal was found to have falsified the findings, sparking one of the largest scientific misconduct cases in Canada.

Tolerance

After long-term use for chronic conditions, nitrate tolerance—tolerance to agents such as glyceryl trinitrate— may develop in a patient, reducing its effectiveness. Tolerance is defined as the loss of symptomatic and hemodynamic effects of glyceryl trinitrate and/or the need for higher doses of the drug to achieve the same effects, and was first described soon after the introduction of glyceryl trinitrate in cardiovascular therapy. Studies have shown that nitrate tolerance is associated with vascular abnormalities which have the potential to worsen patients' prognosis. These include endothelial and autonomic dysfunction.

The mechanisms of nitrate tolerance have been investigated over the last 30 years, and several hypotheses to explain tolerance have been offered, including:

1. plasma volume expansion
2. impaired transformation of glyceryl trinitrate into NO or related species
3. counteraction of glyceryl trinitrate vasodilation by neurohormonal activation
4. oxidative stress

Adverse events

Glyceryl trinitrate can cause severe hypotension, reflex tachycardia, and severe headaches that necessitate analgesic intervention for pain relief, the painful nature of which can have a marked negative effect on patient compliance.

Glyceryl trinitrate also can cause severe hypotension, circulatory collapse, and death if used together with vasodilator drugs that are used for erectile dysfunction, such as sildenafil, tadalafil, and vardenafil.

Glyceryl trinitrate transdermal patches should be removed before defibrillation due to the risk of explosion and/or burns, but investigations have concluded that glyceryl trinitrate patch explosions during defibrillation were due to the breakdown voltage of the metal mesh in some patches.

Mechanism of action

Glyceryl trinitrate is a prodrug which must be denitrated, with the nitrite anion or a related species further reduced to produce the active metabolite nitric oxide (NO). Organic nitrates that undergo these two steps within the body are called nitrovasodilators, and the denitration and reduction occur via a variety of mechanisms. The mechanism by which such nitrates produce NO is widely disputed. Some believe that organic nitrates produce NO by reacting with sulfhydryl groups, while others believe that enzymes such as glutathione S-transferases, cytochrome P450 (CYP), and xanthine oxidoreductase are the primary source of glyceryl trinitrate bioactivation. In recent years, a great deal of evidence has been produced that supports the conclusion that glyceryl trinitrate's clinically relevant denitration and reduction produce 1,2-glyceryl dinitrate (GDN) and NO, and that this reaction is catalysed by mitochondrial aldehyde dehydrogenase (ALDH2 or mtALDH).

The NO produced by this process is a potent activator of guanylyl cyclase (GC) by heme-dependent mechanisms; this activation results in formation of cyclic guanosine monophosphate (cGMP) from guanosine triphosphate (GTP). Among other roles, cGMP serves as a substrate for a cGMP-dependent protein kinase that activates myosin light chain phosphatase. Thus, production of NO from exogenous sources such as glyceryl trinitrate increases the level of cGMP within the cell, and stimulates dephosphorylation of myosin, which initiates relaxation of smooth muscle cells in blood vessels.

History

It was known almost from the time of the first synthesis of glyceryl trinitrate by Ascanio Sobrero in 1846 that handling and tasting of nitroglycerin could cause sudden intense headaches, which suggested a vasodilation effect (as suggested by Sobrero). Constantine Hering developed a form of nitroglycerin in 1847 and advocated for its dosing as a treatment of a number of diseases; however, its use as a specific treatment for blood pressure and chest pain was not among these. This is primarily due to his deep rooted focus in homeopathy.

Following Thomas Brunton's discovery that amyl nitrite could be used to treat chest pain, William Murrell experimented with the use of nitroglycerin to alleviate angina and reduce blood pressure, and showed that the accompanying headaches occurred as a result of overdose. Murrell began treating patients with small doses of glyceryl trinitrate in 1878, and the substance was widely adopted after he published his results in The Lancet in 1879.

The medical establishment used the name "glyceryl trinitrate" or "trinitrin" to avoid alarming patients, because of a general awareness that nitroglycerin was explosive.

Overdoses may generate methemoglobinemia.

Angina

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/Angina

 

Angina
Other names	Stenocardia, angina pectoris
Illustration depicting angina
Pronunciation	/ænˈdʒaɪnə, ˈændʒɪnə/ ann-JY-nə, AN-jin-ə
Specialty	Cardiology
Complications	Heart attack, unstable angina

Angina, also known as angina pectoris, is chest pain or pressure, usually caused by insufficient blood flow to the heart muscle (myocardium). It is most commonly a symptom of coronary artery disease.

Angina is typically the result of partial obstruction or spasm of the arteries that supply blood to the heart muscle. The main mechanism of coronary artery obstruction is atherosclerosis as part of coronary artery disease. Other causes of angina include abnormal heart rhythms, heart failure and, less commonly, anemia. The term derives from Latin angere 'to strangle' and pectus 'chest', and can therefore be translated as "a strangling feeling in the chest".

There is a relationship between severity of angina and degree of oxygen deprivation in the heart muscle. However, the severity of angina does not always match the degree of oxygen deprivation to the heart or the risk of a heart attack (myocardial infarction). Some people may experience severe pain even though there is little risk of a heart attack whilst others may have a heart attack and experience little or no pain. In some cases, angina can be quite severe. Worsening angina attacks, sudden-onset angina at rest, and angina lasting more than 15 minutes are symptoms of unstable angina (usually grouped with similar conditions as the acute coronary syndrome). As these may precede a heart attack, they require urgent medical attention and are, in general, treated similarly to heart attacks.

In the early 20th century, severe angina was seen as a sign of impending death. However, modern medical therapies have improved the outlook substantially. Middle-age patients who experience moderate to severe angina (grading by classes II, III, and IV) have a five-year survival rate of approximately 92%.

Classification

Stable angina

Also known as 'effort angina', this refers to the classic type of angina related to myocardial ischemia. A typical presentation of stable angina is that of chest discomfort and associated symptoms precipitated by some activity (running, walking, etc.) with minimal or non-existent symptoms at rest or after administration of sublingual nitroglycerin. Symptoms typically diminish several minutes after activity and recur when activity resumes. In this way, stable angina may be thought of as being similar to intermittent claudication symptoms. Other recognized precipitants of stable angina include cold weather, heavy meals, and emotional stress.

Unstable Angina

Main article: Unstable angina

See also: Variant angina

Unstable angina (UA) (also "crescendo angina"; this is a form of acute coronary syndrome) is defined as angina pectoris that changes or worsens.

It has at least one of these three features:

1. it occurs at rest (or with minimal exertion), usually lasting more than 10 minutes
2. it is severe and of new-onset (i.e., within the prior 4–6 weeks)
3. it occurs with a crescendo pattern (i.e., distinctly more severe, prolonged, or frequent than before).

UA may occur often unpredictably and even at rest, which may be a serious indicator of an impending heart attack. The primary factor differentiating unstable angina from stable angina (other than symptoms) is the underlying pathophysiology of the atherosclerosis. The pathophysiology of unstable angina is the reduction of coronary blood flow due to transient platelet aggregation on apparently normal endothelium, coronary artery spasms, or coronary thrombosis.

The process starts with atherosclerosis, progresses through inflammation to yield an active unstable plaque, which undergoes thrombosis and results in acute myocardial ischemia, which, if not reversed, results in cell necrosis (infarction). Studies show that 64% of all unstable anginas occur between 22:00 and 08:00 when patients are at rest.

In stable angina, the developing atheroma (a fatty plaque) is protected with a fibrous cap. This cap may rupture in unstable angina, allowing blood clots to precipitate and further decrease the area of the coronary vessel's lumen or the interior open space within an artery. This explains why, in many cases, unstable angina develops independently of activity.

Microvascular angina

Main article: Microvascular angina

Microvascular angina, also known as cardiac syndrome X, is characterized by angina-like chest pain, in the context of normal epicardial coronary arteries (the largest vessels on the surface of the heart, prior to significant branching) on angiography. The original definition of cardiac syndrome X also mandated that ischemic changes on exercise (despite normal coronary arteries) were displayed, as shown on cardiac stress tests. The primary cause of microvascular angina is unknown, but factors apparently involved are endothelial dysfunction and reduced flow (perhaps due to spasm) in the tiny "resistance" blood vessels of the heart. Since microvascular angina is not characterized by major arterial blockages, it is harder to recognize and diagnose.

Microvascular angina was previously considered a rather benign condition, but more recent data has changed this attitude. Studies, including the Women's Ischemia Syndrome Evaluation (WISE), suggest that microvascular angina is part of the pathophysiology of ischemic heart disease, perhaps explaining the higher rates of angina in females than in males, as well as their predilection towards ischemia and acute coronary syndromes in the absence of obstructive coronary artery disease.

Signs and symptoms

Diagram of discomfort caused by coronary artery disease. Pressure, fullness, squeezing or pain in the center of the chest. Discomfort can also be felt in the neck, jaw, shoulders, back or arms.

Angina pectoris can be quite painful, but many patients with angina complain of chest discomfort rather than actual pain: the discomfort is usually described as a pressure, heaviness, tightness, squeezing, burning, or choking sensation. Apart from chest discomfort, anginal pains may also be experienced in the epigastrium (upper central abdomen), back, neck area, jaw, or shoulders. This is explained by the concept of referred pain and is because the spinal level that receives visceral sensation from the heart simultaneously receives cutaneous sensation from parts of the skin specified by that spinal nerve's dermatome, without an ability to discriminate the two. Typical locations for referred pain are arms (often inner left arm), shoulders, and neck into the jaw. Angina is typically precipitated by exertion or emotional stress. It is exacerbated by having a full stomach and by cold temperatures. Pain may be accompanied by breathlessness, sweating, and nausea in some cases. In this case, the pulse rate and the blood pressure increases. Chest pain lasting only a few seconds is normally not angina (such as precordial catch syndrome).

Myocardial ischemia comes about when the myocardium (the heart muscle) receives insufficient blood and oxygen to function normally either because of increased oxygen demand by the myocardium or because of decreased supply to the myocardium. This inadequate perfusion of blood and the resulting reduced delivery of oxygen and nutrients are directly correlated to blocked or narrowed blood vessels.

Some experience "autonomic symptoms" (related to increased activity of the autonomic nervous system) such as nausea, vomiting, and pallor.

Major risk factors for angina include cigarette smoking, diabetes, high cholesterol, high blood pressure, sedentary lifestyle, and family history of premature heart disease.

A variant form of angina—Prinzmetal's angina—occurs in patients with normal coronary arteries or insignificant atherosclerosis. It is believed caused by spasms of the artery. It occurs more in younger women.

Coital angina, also known as angina d'amour, is angina subsequent to sexual intercourse. It is generally rare, except in patients with severe coronary artery disease.

Cause

Major risk factors

• Age (≥ 45 years for men, ≥ 55 for women)
• Smoking
• Diabetes mellitus
• Dyslipidemia
• Family history of premature cardiovascular disease (males <55 years, females <65 years old)
• Hypertension
• Kidney disease (microalbuminuria or GFR<60 mL/min)
• Obesity (BMI ≥ 30 kg/m2)
• Physical inactivity
• Prolonged psychosocial stress

Routine counseling of adults by physicians to advise them to improve their diet and increase their physical activity has, in general, been found to induce only small changes in actual behavior. Therefore, as of 2012, The U.S. Preventive Services Task Force does not recommend routine lifestyle counseling of all patients without known cardiovascular disease, hypertension, hyperlipidemia, or diabetes, and instead recommends selectively counseling only those patients who seem most ready to make lifestyle changes and using available time with other patients to explore other types of intervention that would be more likely to have a preventative impact.

Conditions that exacerbate or provoke angina

• Medications
  • Vasodilators
  • Excessive thyroid hormone replacement
• Vasoconstrictors
• Polycythemia, which thickens the blood, slowing its flow through the heart muscle
• Hypothermia
• Hypervolemia
• Hypovolemia

One study found that smokers with coronary artery disease had a significantly increased level of sympathetic nerve activity when compared to those without. This is in addition to increases in blood pressure, heart rate, and peripheral vascular resistance associated with nicotine, which may lead to recurrent angina attacks. In addition, the Centers for Disease Control and Prevention (CDC) reports that the risk of CHD (Coronary heart disease), stroke, and PVD (Peripheral vascular disease) is reduced within 1–2 years of smoking cessation. In another study, it was found that, after one year, the prevalence of angina in smokingmales under 60 after an initial attack was 40% less in those having quit smoking compared to those that continued. Studies have found that there are short-term and long-term benefits to smoking cessation.

Other medical problems

• Esophageal disorders
• Gastroesophageal reflux disease (GERD)
• Hyperthyroidism
• Hypoxemia
• Profound anemia
• Uncontrolled hypertension

Other cardiac problems

• Bradyarrhythmia
• Hypertrophic cardiomyopathy
• Tachyarrhythmia
• Valvular heart disease

Myocardial ischemia can result from:

1. a reduction of blood flow to the heart that can be caused by stenosis, spasm, or acute occlusion (by an embolus) of the heart's arteries.
2. resistance of the blood vessels. This can be caused by narrowing of the blood vessels; a decrease in radius. Blood flow is proportional to the radius of the artery to the fourth power.
3. reduced oxygen-carrying capacity of the blood, due to several factors such as a decrease in oxygen tension and hemoglobin concentration. This decreases the ability of hemoglobin to carry oxygen to myocardial tissue.

Atherosclerosis is the most common cause of stenosis (narrowing of the blood vessels) of the heart's arteries and, hence, angina pectoris. Some people with chest pain have normal or minimal narrowing of heart arteries; in these patients, vasospasm is a more likely cause for the pain, sometimes in the context of Prinzmetal's angina and syndrome X.

Myocardial ischemia also can be the result of factors affecting blood composition, such as the reduced oxygen-carrying capacity of blood, as seen with severe anemia (low number of red blood cells), or long-term smoking.

Pathophysiology

Angina results when there is an imbalance between the heart's oxygen demand and supply. This imbalance can result from an increase in demand (e.g., during exercise) without a proportional increase in supply (e.g., due to obstruction or atherosclerosis of the coronary arteries).

However, the pathophysiology of angina in females varies significantly as compared to males. Non-obstructive coronary disease is more common in females.

Diagnosis

Angina should be suspected in people presenting tight, dull, or heavy chest discomfort that is:

1. Retrosternal or left-sided, radiating to the left arm, neck, jaw, or back.
2. Associated with exertion or emotional stress and relieved within several minutes by rest.
3. Precipitated by cold weather or a meal.

Some people present with atypical symptoms, including breathlessness, nausea, or epigastric discomfort, or burning. These atypical symptoms are particularly likely in older people, women, and those with diabetes.

Anginal pain is not usually sharp or stabbing or influenced by respiration. Antacids and simple analgesics do not usually relieve the pain. If chest discomfort (of whatever site) is precipitated by exertion, relieved by rest, and relieved by glyceryl trinitrate, the likelihood of angina is increased.

In angina patients momentarily not feeling any chest pain, an electrocardiogram (ECG) is typically normal unless there have been other cardiac problems in the past. During periods of pain, depression, or elevation of the ST segment may be observed. To elicit these changes, an exercise ECG test ("treadmill test") may be performed, during which the patient exercises to his/her maximum ability before fatigue, breathlessness, or pain intervenes; if characteristic ECG changes are documented (typically more than 1 mm of flat or downsloping ST depression), the test is considered diagnostic for angina. Even constant monitoring of the blood pressure and the pulse rate can lead to some conclusions regarding angina. The exercise test is also useful in looking for other markers of myocardial ischemia: blood pressure response (or lack thereof, in particular, a drop in systolic blood pressure), dysrhythmia, and chronotropic response. Other alternatives to a standard exercise test include a thallium scintigram or sestamibi scintigram (in patients unable to exercise enough for the treadmill tests, e.g., due to asthma or arthritis or in whom the ECG is too abnormal at rest) or stress echocardiography.

In patients in whom such noninvasive testing is diagnostic, a coronary angiogram is typically performed to identify the nature of the coronary lesion, and whether this would be a candidate for angioplasty, coronary artery bypass graft (CABG), treatment only with medication, or other treatments. In hospitalized patients with unstable angina (or the newer term of "high-risk acute coronary syndromes"), those with resting ischaemic ECG changes or those with raised cardiac enzymes such as troponin may undergo coronary angiography directly.

Treatment

Further information: Antianginal

Angina pectoris occurs as a result of coronary blood flow insufficiency in the face of increased oxygen demand. The principal goal in the prevention and relief of angina is to limit the oxygen requirement of the heart so it can meet the inadequate oxygen supply derived through the blood supplied from the stenosed or constricted arteries. The main goals of treatment in angina pectoris are relief of symptoms, slowing progression of the disease, and reduction of future events, especially heart attacks and death. Beta blockers (e.g., carvedilol, metoprolol, propranolol) have a large body of evidence in morbidity and mortality benefits (fewer symptoms, less disability, and longer life) and short-acting nitroglycerin medications have been used since 1879 for symptomatic relief of angina. There are differing course of treatments for the patient depending on the type of angina the patient has. However, this second can provide a brief overview of the types of medications provided for angina and the purpose by which they are prescribed.

Beta blockers, specifically B1 adrenergic blockers without intrinsic sympathomimetic activity, are preferred for angina treatment, out of B1 selective and non-selective as well as B1 ISA agents. B1 blockers are cardioselective blocking agents (such as nevibolol, atenolol, metoprolol, bisoprolol, etc.) which result in blocking cAMP in the heart muscle cells. cAMP, which plays a vital role in phosphorylating the ryanodine receptor and LTCC, will usually increase Ca⁺² levels in the heart muscle cells, blocking contraction. Therefore, B1 blockade decreases the HR and contraction of the heart muscle, making it demand less oxygen. An important thing to note is that the B1 cardioselective blockers are cardioselective and not cardio-specific. This means that if the beta-adrenergic antagonist is prescribed in higher doses, it can lose the selectivity aspect and begin causing hypertension from B2 adrenergic stimulation of smooth muscle cells. This is why in therapy for patients with angina, the vasodilatory organonitrates complement the use of B-blockers when prescribed the use of angina. The preference for Beta-1 cardioselective blockers is for B1 cardioselective blockers without instrinsic sympathetic activity. Beta blockers with intrinsic sympathetic activity will still do the beta blockade of the heart muscle cells and have a decreased ionotrophic and chronotropic effect, but this effect will be to a lesser extent than if the beta blocker did not have the instrinsic sympathetic activity. A common beta-blocker with ISA prescribed for the treatment of angina is Acebutolol.

Non-selective beta-adrenergic antagonists will yield the same action on B1 receptors, however will also act on B2 receptors. These medications, such as Propranolol and Nadolol, act on B1 receptors on smooth muscle cells as well. B1 blockade occurs in the smooth muscle cells. Specifically cAMP is responsible for inhibiting Myosin Light Kinase, the enzyme responsible for acting on Actin-Myosin. The inhibition of B1 will result in decreased levels of cAMP which will lead to increased levels of Myosin Light Chain Kinase in the smooth muscle cells, the enzyme responsible for acting on Actin-Myosin and leading to contraction of the smooth muscle cell. This increased contraction of the smooth muscle cell from B1 blockade is not desirable since it explains the hypertension that may arise with patients taking that medication.

Calcium channel blockers act to decrease the heart's workload, and thus its requirement for oxygen by blocking the calcium channels of the heart muscle cell. With decreased intracellular calcium, the calcium-troponin complex does not form in the heart muscle cell and it does not contract, therefore reducing the need for oxygen.

The other class of medication that can be used to treat angina are the organic nitrates. Organic nitrates are used extensively to treat angina. They improve coronary blood flow of the coronary arteries (arteries which supply blood to the heart muscle) by reversing and preventing vasospasm, which increases the blood flow to the heart, improving perfusion and oxygen delivery to the heart associated with the pain of angina. These drugs also reduce systemic vascular resistance, of both veins and arteries but the veins to a greater extent. The decrease in the resistance of the arteries and veins decreases the myocardial oxygen demand, which also reduces myocardial oxygen demand. Nitroglycerin is a potent vasodilator that decreases myocardial oxygen demand by decreasing the heart's workload. Nitroglycerin should not be given if certain inhibitors such as sildenafil, tadalafil, or vardenafil have been taken within the previous 12 hours as the combination of the two could cause a serious drop in blood pressure.

Treatments for angina are balloon angioplasty, in which the balloon is inserted at the end of a catheter and inflated to widen the arterial lumen. Stents to maintain the arterial widening are often used at the same time. Coronary bypass surgery involves bypassing constricted arteries with venous grafts. This is much more invasive than angioplasty.

Calcium channel blockers (such as nifedipine (Adalat) and amlodipine), isosorbide mononitrate and nicorandil are vasodilators commonly used in chronic stable angina. A new therapeutic class, called If inhibitor, has recently been made available: Ivabradine provides heart rate reduction without affecting contractility leading to major anti-ischemic and antianginal efficacy. ACE inhibitors are also vasodilators with both symptomatic and prognostic benefit. Statins are the most frequently used lipid/cholesterol modifiers, which probably also stabilize existing atheromatous plaque. Low-dose aspirin decreases the risk of heart attack in patients with chronic stable angina, and was part of standard treatment. However, in patients without established cardiovascular disease, the increase in hemorrhagic stroke and gastrointestinal bleeding offsets any benefits and it is no longer advised unless the risk of myocardial infarction is very high.

Exercise is also a very good long-term treatment for the angina (but only particular regimens – gentle and sustained exercise rather than intense short bursts), probably working by complex mechanisms such as improving blood pressure and promoting coronary artery collateralisation.

Though sometimes used by patients, evidence does not support the use of traditional Chinese herbal products (THCP) for angina.

Identifying and treating risk factors for further coronary heart disease is a priority in patients with angina. This means testing for elevated cholesterol and other fats in the blood, diabetes and hypertension (high blood pressure), and encouraging smoking cessation and weight optimization.

The calcium channel blocker nifedipine prolongs cardiovascular event- and procedure-free survival in patients with coronary artery disease. New overt heart failures were reduced by 29% compared to placebo; however, the mortality rate difference between the two groups was statistically insignificant.

Microvascular angina in women

Women with myocardial ischemia often have either no or atypical symptoms, such as palpitations, anxiety, weakness, and fatigue. Additionally, many females with angina are found to have cardiac ischemia, yet no evidence of obstructive coronary artery disease on cardiac catheterization. Evidence is accumulating that nearly half of females with myocardial ischemia have coronary microvascular disease, a condition often called microvascular angina (MVA). Small intramyocardial arterioles constrict in MVA causing ischemic pain that is less predictable than with typical epicardial coronary artery disease (CAD).

The pathophysiology is complex and still being elucidated, but there is strong evidence that endothelial dysfunction, decreased endogenous vasodilators, inflammation, changes in adipokines, and platelet activation are contributing factors. The diagnosis of MVA may require catheterization during which there is an assessment of the microcirculatory response to adenosine or acetylcholine and measurement of coronary and fractional flow reserve. New techniques include positron emission tomography (PET) scanning, cardiac magnetic resonance imaging (MRI), and transthoracic Doppler echocardiography.

Managing MVA can be challenging, for example, females with this condition have less coronary microvascular dilation in response to nitrates than do those without MVA. Females with MVA often have traditional risk factors for CAD such as obesity, dyslipidemia, diabetes, and hypertension. Aggressive interventions to reduce modifiable risk factors are an important component of management, especially smoking cessation, exercise, and diabetes management. The combination of non-nitrate vasodilators, such as calcium channel blockers and angiotensin-converting enzyme (ACE) inhibitors along with HMG-CoA reductase inhibitors (statins), also is effective in many women, and new drugs, such as Ranolazine and Ivabradine, have shown promise in the treatment of MVA. Other approaches include spinal cord stimulators, adenosine receptor blockade, and psychiatric intervention.

Suspected angina

Hospital admission for people with the following symptoms is recommended, as they may have unstable angina: pain at rest (which may occur at night), pain on minimal exertion, angina that seems to progress rapidly despite increasing medical treatment. All people with suspected angina should be urgently referred to a chest pain evaluation service, for confirmation of the diagnosis and assessment of the severity of coronary heart disease.

Epidemiology

As of 2010, angina due to ischemic heart disease affects approximately 112 million people (1.6% of the global population) being slightly more common in males than females (1.7% to 1.5%).

In the United States, 10.2 million are estimated to experience angina with approximately 500,000 new cases occurring each year. Angina is more often the presenting symptom of coronary artery disease in females than in men. The prevalence of angina rises with increasing age, with a mean age of onset of 62.3 years. After five years post-onset, 4.8% of individuals with angina subsequently died from coronary heart disease. Males with angina were found to have an increased risk of subsequent acute myocardial infarction and coronary heart disease related death than women. Similar figures apply in the remainder of the Western world. All forms of coronary heart disease are much less-common in the Third World, as its risk factors are much more common in Western and Westernized countries; it could, therefore, be termed a disease of affluence.

History

The condition was named "hritshoola" in ancient India and was described by Sushruta (6th century BC).

The first clinical description of angina pectoris was by a British physician Dr. William Heberden in 1768.

Acute coronary syndrome

From Wikipedia, the free encyclopedia
https://en.wikipedia.org/wiki/Acute_coronary_syndrome

Acute coronary syndrome
Blockage of a coronary artery

Acute coronary syndrome (ACS) is a syndrome (a set of signs and symptoms) due to decreased blood flow in the coronary arteries such that part of the heart muscle is unable to function properly or dies. The most common symptom is centrally located pressure-like chest pain, often radiating to the left shoulder or angle of the jaw, and associated with nausea and sweating. Many people with acute coronary syndromes present with symptoms other than chest pain, particularly women, older people, and people with diabetes mellitus.

Acute coronary syndrome is subdivided in three scenarios depending primarily on the presence of electrocardiogram (ECG) changes and blood test results (a change in cardiac biomarkers such as troponin levels): ST elevation myocardial infarction (STEMI), non-ST elevation myocardial infarction (NSTEMI), or unstable angina. STEMI is characterised by complete blockage of a coronary artery resulting in necrosis of part of the heart muscle indicated by ST elevation on ECG, NSTEMI is characterised by a partially blocked coronary artery resulting in necrosis of part of the heart muscle that may be indicated by ECG changes, and unstable angina is characterised by ischemia of the heart muscle that does not result in cell injury or necrosis.

ACS should be distinguished from stable angina, which develops during physical activity or stress and resolves at rest. In contrast with stable angina, unstable angina occurs suddenly, often at rest or with minimal exertion, or at lesser degrees of exertion than the individual's previous angina ("crescendo angina"). New-onset angina is also considered unstable angina, since it suggests a new problem in a coronary artery.

Signs and symptoms

Symptoms of the acute coronary syndromes are similar. The cardinal symptom of critically decreased blood flow to the heart is chest pain, experienced as tightness, pressure, or burning. Localisation is most commonly around or over the chest and may radiate or be located to the arm, shoulder, neck, back, upper abdomen, or jaw. This may be associated with sweating, nausea, or shortness of breath. Previously, the word "atypical" was used to describe chest pain not typically heart-related, however this word is not recommended and has been replaced by "noncardiac" to describe chest pain that indicate a low likelihood of heart-related pain.

In unstable angina, symptoms may appear on rest or on minimal exertion. The symptoms can last longer than those in stable angina, can be resistant to rest or medicine, and can get worse over time.

Though ACS is usually associated with coronary thrombosis, it can also be associated with cocaine use. Chest pain with features characteristic of cardiac origin (angina) can also be precipitated by profound anemia, brady- or tachycardia (excessively slow or rapid heart rate), low or high blood pressure, severe aortic valve stenosis (narrowing of the valve at the beginning of the aorta), pulmonary artery hypertension and a number of other conditions.

Pathophysiology

In those who have ACS, atheroma rupture is most commonly found 60% when compared to atheroma erosion (30%), thus causes the formation of thrombus which block the coronary arteries. Plaque rupture is responsible for 60% in ST elevated myocardial infarction (STEMI) while plaque erosion is responsible for 30% of the STEMI and vice versa for Non ST elevated myocardial infarction (NSTEMI). In plaque rupture, the content of the plaque is lipid rich, collagen poor, with abundant inflammation which is macrophage predominant, and covered with a thin fibrous cap. Meanwhile, in plaque erosion, the plaque is rich with extracellular matrix, proteoglycan, glycoaminoglycan, but without fibrous caps, no inflammatory cells, and no large lipid core. After the coronary arteries are unblocked, there is a risk of reperfusion injury due spreading inflammatory mediators throughout the body. Investigations is still underway on the role of cyclophilin D in reducing the reperfusion injury.

Other, less common, causes of acute coronary syndrome include spontaneous coronary artery dissection, ischemia in the absence of obstructive coronary artery disease (INOCA), and myocardial infarction in the absence of obstructive coronary artery disease (MINOCA).

Diagnosis

Classification of acute coronary syndromes.

Electrocardiogram

In the setting of acute chest pain, the electrocardiogram (ECG or EKG) is the investigation that most reliably distinguishes between various causes. The ECG should be done as early as practicable, including in the ambulance if possible. ECG changes indicating acute heart damage include: ST elevation, new left bundle branch block and ST depression amongst others. The absence of ECG changes does not immediately distinguish between unstable angina and NSTEMI.

Blood tests

Change in levels of cardiac biomarkers, such as troponin I and troponin T, are indicative of myocardial infarction including both STEMI and NSTEMI, however their levels are not affected in unstable angina.

Prediction scores

A combination of cardiac biomarkers and risk scores, such as HEART score and TIMI score, can help assess the possibility of myocardial infarction in the emergency setting.

Prevention

Acute coronary syndrome often reflects a degree of damage to the coronaries by atherosclerosis. Primary prevention of atherosclerosis is controlling the risk factors: healthy eating, exercise, treatment for hypertension and diabetes, avoiding smoking and controlling cholesterol levels; in patients with significant risk factors, aspirin has been shown to reduce the risk of cardiovascular events. Secondary prevention is discussed in myocardial infarction.

After a ban on smoking in all enclosed public places was introduced in Scotland in March 2006, there was a 17% reduction in hospital admissions for acute coronary syndrome. 67% of the decrease occurred in non-smokers.

Treatment

Main article: Management of acute coronary syndrome

People with presumed ACS are typically treated with aspirin, clopidogrel or ticagrelor, nitroglycerin, and if the chest discomfort persists morphine. Other analgesics such as nitrous oxide are of unknown benefit. Angiography is recommended in those who have either new ST elevation or a new left or right bundle branch block on their ECG. Unless the person has low oxygen levels additional oxygen does not appear to be useful.

STEMI

If the ECG confirms changes suggestive of myocardial infarction (ST elevation in specific leads, a new left bundle branch block or a true posterior MI pattern), thrombolytics may be administered or percutaneous coronary intervention may be performed. In the former, medication is injected that stimulates fibrinolysis, destroying blood clots obstructing the coronary arteries. In the latter, a flexible catheter is passed via the femoral or radial artery and advanced to the heart to identify blockages in the coronary arteries. When occlusions are found, they can be intervened upon mechanically with angioplasty and usually stent deployment if a lesion, termed the culprit lesion, is thought to be causing myocardial damage. Data suggest that rapid triage, transfer and treatment is essential. The time frame for door-to-needle thrombolytic administration according to American College of Cardiology (ACC) guidelines should be within 30 minutes, whereas the door-to-balloon percutaneous coronary intervention (PCI) time should be less than 90 minutes. It was found that thrombolysis is more likely to be delivered within the established ACC guidelines among patients with STEMI as compared to PCI according to a 2009 case control study.

NSTEMI and NSTE-ACS

If the ECG does not show typical changes consistent with STEMI, the term "non-ST segment elevation ACS" (NSTE-ACS) may be used and encompasses "non-ST elevation MI" (NSTEMI) and unstable angina.

The accepted management of unstable angina and acute coronary syndrome is therefore empirical treatment with aspirin, a second platelet inhibitor such as clopidogrel, prasugrel or ticagrelor, and heparin (usually a low-molecular weight heparin), with intravenous nitroglycerin and opioids if the pain persists. The heparin-like drug known as fondaparinux appears to be better than enoxaparin.

If there is no evidence of ST segment elevation on the electrocardiogram, delaying urgent angioplasty until the next morning is not inferior to doing so immediately. Using statins in the first 14 days after ACS reduces the risk of further ACS.

Cocaine-associated ACS should be managed in a manner similar to other patients with acute coronary syndrome except beta blockers should not be used and benzodiazepines should be administered early.

Prognosis

Prediction scores

The TIMI risk score can identify high risk patients in ST-elevation and non-ST segment elevation MI ACS and has been independently validated.

Based on a global registry of 102,341 patients, the GRACE risk scoreestimates in-hospital, 6 months, 1 year, and 3-year mortality risk after a heart attack. It takes into account clinical (blood pressure, heart rate, EKG findings) and medical history. Nowadays, GRACE risk score is also used within non-ST elevation ACS patients as a high-risk criteria(GRACE score > 140), which may favor early invasive strategy within 24 hours of the heart attack.

Biomarkers

Coronary CT angiography combined with troponin levels is also helpful to triage those who are susceptible to ACS. F-fluoride positron emission tomography is also helpful in identifying those with high risk, lipid-rich coronary plaques.

Day of admission

Studies have shown that for ACS patients, weekend admission is associated with higher mortality and lower utilization of invasive cardiac procedures, and those who did undergo these interventions had higher rates of mortality and complications than their weekday counterparts. This data leads to the possible conclusion that access to diagnostic/interventional procedures may be contingent upon the day of admission, which may impact mortality. This phenomenon is described as weekend effect.