This patient is likely experiencing an acute coronary syndrome, possibly a non-ST-elevation myocardial infarction (NSTEMI) or unstable angina. The troponin test will help confirm the diagnosis. The patient’s ECG showed ST depression in the inferior leads, but this normalized after treatment with GTN and morphine, ruling out a ST-elevation myocardial infarction (STEMI).

Immediate pain relief should be provided. GTN (sublingual or buccal) can be used, but intravenous opioids like morphine should be considered, especially if a heart attack is suspected.

Aspirin should be given to all patients with unstable angina or NSTEMI as soon as possible and continued indefinitely, unless there are contraindications like bleeding risk or aspirin hypersensitivity. A loading dose of 300 mg should be administered right after presentation.

Fondaparinux should be given to patients without a high bleeding risk, unless coronary angiography is planned within 24 hours of admission. Unfractionated heparin can be an alternative to fondaparinux for patients who will undergo coronary angiography within 24 hours. For patients with significant renal impairment, unfractionated heparin can also be considered, with dose adjustment based on clotting function monitoring.

Routine administration of oxygen is no longer recommended, but oxygen saturation should be monitored using pulse oximetry as soon as possible, preferably before hospital admission. Supplemental oxygen should only be offered to individuals with oxygen saturation (SpO2) below 94% who are not at risk of hypercapnic respiratory failure, aiming for a SpO2 of 94-98%. For individuals with chronic obstructive pulmonary disease at risk of hypercapnic respiratory failure, a target SpO2 of 88-92% should be achieved until blood gas analysis is available.

Bivalirudin, a specific and reversible direct thrombin inhibitor (DTI), is recommended by NICE as a possible treatment for adults with STEMI undergoing percutaneous coronary intervention.

For more information, refer to the NICE guidelines on the assessment and diagnosis of chest pain of recent onset.

Adrenaline should be administered promptly once access to the circulatory system has been established in cases of non-shockable cardiac arrests such as PEA or asystole. The recommended dose is 1 mg, which can be given either as 10 mL of a 1:10,000 solution or as 1 mL of a 1:1000 solution through the intravenous (IV) or intraosseous (IO) routes.

In cases of shockable cardiac arrests like ventricular fibrillation (Vf) or pulseless ventricular tachycardia (pVT), adrenaline should be administered after the third shock has been delivered and chest compressions have been resumed. The same dose of 1 mg can be given using the same concentration options as mentioned earlier.

Subsequently, adrenaline should be administered every 3-5 minutes, alternating with chest compressions, without interrupting the compressions. The alpha-adrenergic effects of adrenaline cause constriction of blood vessels throughout the body, leading to increased pressures in the coronary and cerebral circulation.

The beta-adrenergic effects of adrenaline have positive effects on the heart, increasing its contractility (inotropic) and heart rate (chronotropic), which may also enhance blood flow to the coronary and cerebral arteries. However, it is important to note that these benefits may be counteracted by increased oxygen consumption by the heart, the potential for abnormal heart rhythms, temporary decrease in oxygen levels due to abnormal blood flow in the lungs, impaired microcirculation, and increased dysfunction of the heart after the cardiac arrest.

While there is no evidence supporting the long-term benefits of adrenaline use in cardiac arrest cases, some studies have shown improved short-term survival rates, which justifies its continued use.

A summary of the vessels involved in different types of myocardial infarction, along with the corresponding ECG leads and the location of the infarction.

For instance, an anteroseptal infarction involving the left anterior descending artery is indicated by ECG leads V1-V3. Similarly, an anterior infarction involving the left anterior descending artery is indicated by leads V3-V4.

In cases of anterolateral infarctions, both the left anterior descending artery and the left circumflex artery are involved, and this is reflected in ECG leads V5-V6. An extensive anterior infarction involving the left anterior descending artery is indicated by leads V1-V6.

Lateral infarcts involving the left circumflex artery are indicated by leads I, II, aVL, and V6. Inferior infarctions, on the other hand, involve either the right coronary artery (in 80% of cases) or the left circumflex artery (in 20% of cases), and this is shown by leads II, III, and aVF.

In the case of a right ventricular infarction, the right coronary artery is involved, and this is indicated by leads V1 and V4R. Lastly, a posterior infarction involving the right coronary artery is shown by leads V7-V9.

The most appropriate initial treatment for this patient would be intravenous labetalol. Labetalol is a non-selective beta blocker with alpha-blocking properties. It is the preferred initial treatment for aortic dissection because it helps to reduce blood pressure and heart rate, which can help to decrease the shear forces acting on the aortic wall and prevent further dissection. Intravenous administration of labetalol allows for rapid and effective control of blood pressure.

Other treatment options, such as intravenous magnesium sulphate, intravenous verapamil, GTN sublingual spray, and oral nifedipine, are not appropriate for the management of aortic dissection. Magnesium sulphate is used for the treatment of certain arrhythmias and pre-eclampsia, but it does not address the underlying issue of aortic dissection. Verapamil and nifedipine are calcium channel blockers that can lower blood pressure, but they can also cause reflex tachycardia, which can worsen the condition. GTN sublingual spray is used for the treatment of angina, but it does not address the underlying issue of aortic dissection.

Further Reading:

Aortic dissection is a life-threatening condition in which blood flows through a tear in the innermost layer of the aorta, creating a false lumen. Prompt treatment is necessary as the mortality rate increases by 1-2% per hour. There are different classifications of aortic dissection, with the majority of cases being proximal. Risk factors for aortic dissection include hypertension, atherosclerosis, connective tissue disorders, family history, and certain medical procedures.

The presentation of aortic dissection typically includes sudden onset sharp chest pain, often described as tearing or ripping. Back pain and abdominal pain are also common, and the pain may radiate to the neck and arms. The clinical picture can vary depending on which aortic branches are affected, and complications such as organ ischemia, limb ischemia, stroke, myocardial infarction, and cardiac tamponade may occur. Common signs and symptoms include a blood pressure differential between limbs, pulse deficit, and a diastolic murmur.

Various investigations can be done to diagnose aortic dissection, including ECG, CXR, and CT with arterial contrast enhancement (CTA). CT is the investigation of choice due to its accuracy in diagnosis and classification. Other imaging techniques such as transoesophageal echocardiography (TOE), magnetic resonance imaging/angiography (MRI/MRA), and digital subtraction angiography (DSA) are less commonly used.

Management of aortic dissection involves pain relief, resuscitation measures, blood pressure control, and referral to a vascular or cardiothoracic team. Opioid analgesia should be given for pain relief, and resuscitation measures such as high flow oxygen and large bore IV access should be performed. Blood pressure control is crucial, and medications such as labetalol may be used to reduce systolic blood pressure. Hypotension carries a poor prognosis and may require careful fluid resuscitation. Treatment options depend on the type of dissection, with type A dissections typically requiring urgent surgery and type B dissections managed by thoracic endovascular aortic repair (TEVAR) and blood pressure control optimization.

Some reversible metabolic causes of bradycardia include hypothyroidism, hyperkalaemia, hypermagnesemia, and hypothermia. These conditions can lead to a slow heart rate and can be treated or reversed.

Further Reading:

Causes of Bradycardia:
– Physiological: Athletes, sleeping
– Cardiac conduction dysfunction: Atrioventricular block, sinus node disease
– Vasovagal & autonomic mediated: Vasovagal episodes, carotid sinus hypersensitivity
– Hypothermia
– Metabolic & electrolyte disturbances: Hypothyroidism, hyperkalaemia, hypermagnesemia
– Drugs: Beta-blockers, calcium channel blockers, digoxin, amiodarone
– Head injury: Cushing’s response
– Infections: Endocarditis
– Other: Sarcoidosis, amyloidosis

Presenting symptoms of Bradycardia:
– Presyncope (dizziness, lightheadedness)
– Syncope
– Breathlessness
– Weakness
– Chest pain
– Nausea

Management of Bradycardia:
– Assess and monitor for adverse features (shock, syncope, myocardial ischaemia, heart failure)
– Treat reversible causes of bradycardia
– Pharmacological treatment: Atropine is first-line, adrenaline and isoprenaline are second-line
– Transcutaneous pacing if atropine is ineffective
– Other drugs that may be used: Aminophylline, dopamine, glucagon, glycopyrrolate

Bradycardia Algorithm:
– Follow the algorithm for management of bradycardia, which includes assessing and monitoring for adverse features, treating reversible causes, and using appropriate medications or pacing as needed.
https://acls-algorithms.com/wp-content/uploads/2020/12/Website-Bradycardia-Algorithm-Diagram.pdf

Aortic regurgitation is a condition where the aortic valve fails to close tightly, resulting in the backflow of blood from the aorta into the left ventricle during ventricular diastole. This valvular lesion presents with various clinical symptoms and signs.

The clinical symptoms of aortic regurgitation include exertional dyspnea, orthopnea, and paroxysmal nocturnal dyspnea. These symptoms are experienced by patients during physical activity, while lying flat, and during episodes of sudden nighttime breathlessness, respectively.

On the other hand, the clinical signs of aortic regurgitation can be observed during physical examination. These signs include a collapsing pulse, widened pulse pressure, hyperkinetic laterally displaced apex beat, and a thrill in the aortic area. Additionally, an early diastolic murmur can be heard, which is loudest at the lower left sternal edge when the patient is sitting forward and exhaling.

Aortic regurgitation is also associated with several eponymous signs, which are named after the physicians who first described them. These signs include Corrigan’s sign, which is characterized by visible and forceful neck pulsation. De Musset’s sign refers to head nodding in time with the heartbeat. Quincke’s sign is the observation of visible nail bed capillary pulsation. Duroziez’s sign is the presence of a diastolic murmur heard proximal to femoral artery compression. Traube’s sign is the perception of a pistol shot sound over the femoral arteries. The Lighthouse sign is the blanching and flushing of the forehead. Becker’s sign is the pulsation seen in retinal vessels. Rosenbach’s sign is the presence of a pulsatile liver. Lastly, Muller’s sign refers to pulsations of the uvula.

In summary, aortic regurgitation is a valvular lesion that leads to the incomplete closure of the aortic valve. It manifests with various clinical symptoms, signs, and eponymous findings, which can be identified through careful examination and observation.

Wolff-Parkinson-White (WPW) syndrome is a condition that affects the electrical system of the heart. It occurs when there is an abnormal pathway, known as the bundle of Kent, between the atria and the ventricles. This pathway can cause premature contractions of the ventricles, leading to a type of rapid heartbeat called atrioventricular re-entrant tachycardia (AVRT).

In a normal heart rhythm, the electrical signals travel through the bundle of Kent and stimulate the ventricles. However, in WPW syndrome, these signals can cause the ventricles to contract prematurely. This can be seen on an electrocardiogram (ECG) as a shortened PR interval, a slurring of the initial rise in the QRS complex (known as a delta wave), and a widening of the QRS complex.

There are two distinct types of WPW syndrome that can be identified on an ECG. Type A is characterized by predominantly positive delta waves and QRS complexes in the praecordial leads, with a dominant R wave in V1. This can sometimes be mistaken for right bundle branch block (RBBB). Type B, on the other hand, shows predominantly negative delta waves and QRS complexes in leads V1 and V2, and positive in the other praecordial leads, resembling left bundle branch block (LBBB).

Overall, WPW syndrome is a condition that affects the electrical conduction system of the heart, leading to abnormal heart rhythms. It can be identified on an ECG by specific features such as shortened PR interval, delta waves, and widened QRS complex.

Indications for drug treatment or pacing in patients with bradycardia include shock, syncope, myocardial ischemia, heart failure, and the presence of risk factors for asystole. If any of these adverse features are present, it is important to consider drug treatment or pacing. However, even if none of these adverse features are present, patients may still require drug treatment or pacing if they have risk factors for developing asystole, such as recent asystole, Mobitz II AV block, complete heart block with broad QRS, or a ventricular pause longer than 3 seconds.

Further Reading:

Causes of Bradycardia:
– Physiological: Athletes, sleeping
– Cardiac conduction dysfunction: Atrioventricular block, sinus node disease
– Vasovagal & autonomic mediated: Vasovagal episodes, carotid sinus hypersensitivity
– Hypothermia
– Metabolic & electrolyte disturbances: Hypothyroidism, hyperkalaemia, hypermagnesemia
– Drugs: Beta-blockers, calcium channel blockers, digoxin, amiodarone
– Head injury: Cushing’s response
– Infections: Endocarditis
– Other: Sarcoidosis, amyloidosis

Presenting symptoms of Bradycardia:
– Presyncope (dizziness, lightheadedness)
– Syncope
– Breathlessness
– Weakness
– Chest pain
– Nausea

Management of Bradycardia:
– Assess and monitor for adverse features (shock, syncope, myocardial ischaemia, heart failure)
– Treat reversible causes of bradycardia
– Pharmacological treatment: Atropine is first-line, adrenaline and isoprenaline are second-line
– Transcutaneous pacing if atropine is ineffective
– Other drugs that may be used: Aminophylline, dopamine, glucagon, glycopyrrolate

Bradycardia Algorithm:
– Follow the algorithm for management of bradycardia, which includes assessing and monitoring for adverse features, treating reversible causes, and using appropriate medications or pacing as needed.
https://acls-algorithms.com/wp-content/uploads/2020/12/Website-Bradycardia-Algorithm-Diagram.pdf

Marfan’s syndrome is a condition that greatly increases the risk of aortic dissection. This patient exhibits several characteristics commonly seen in individuals with Marfan syndrome, such as tall stature, low BMI, and pectoral abnormalities like pectus carinatum and excavatum. Additionally, their long limbs and fingers are also indicative of Marfan’s syndrome. It is important to note that aortic dissection tends to occur at a much younger age in individuals with Marfan syndrome compared to those without connective tissue diseases. The median age for type A dissection in Marfan’s patients is 36.7 years, while for type B dissection it is 40 years. In contrast, individuals without Marfan’s syndrome typically experience dissection at the ages of 63 and 62 years for type A and type B dissections, respectively.

Further Reading:

Aortic dissection is a life-threatening condition in which blood flows through a tear in the innermost layer of the aorta, creating a false lumen. Prompt treatment is necessary as the mortality rate increases by 1-2% per hour. There are different classifications of aortic dissection, with the majority of cases being proximal. Risk factors for aortic dissection include hypertension, atherosclerosis, connective tissue disorders, family history, and certain medical procedures.

The presentation of aortic dissection typically includes sudden onset sharp chest pain, often described as tearing or ripping. Back pain and abdominal pain are also common, and the pain may radiate to the neck and arms. The clinical picture can vary depending on which aortic branches are affected, and complications such as organ ischemia, limb ischemia, stroke, myocardial infarction, and cardiac tamponade may occur. Common signs and symptoms include a blood pressure differential between limbs, pulse deficit, and a diastolic murmur.

Various investigations can be done to diagnose aortic dissection, including ECG, CXR, and CT with arterial contrast enhancement (CTA). CT is the investigation of choice due to its accuracy in diagnosis and classification. Other imaging techniques such as transoesophageal echocardiography (TOE), magnetic resonance imaging/angiography (MRI/MRA), and digital subtraction angiography (DSA) are less commonly used.

Management of aortic dissection involves pain relief, resuscitation measures, blood pressure control, and referral to a vascular or cardiothoracic team. Opioid analgesia should be given for pain relief, and resuscitation measures such as high flow oxygen and large bore IV access should be performed. Blood pressure control is crucial, and medications such as labetalol may be used to reduce systolic blood pressure. Hypotension carries a poor prognosis and may require careful fluid resuscitation. Treatment options depend on the type of dissection, with type A dissections typically requiring urgent surgery and type B dissections managed by thoracic endovascular aortic repair (TEVAR) and blood pressure control optimization.

A summary of the vessels involved in different types of myocardial infarction, along with the corresponding ECG leads and the location of the infarction.

For instance, an anteroseptal infarction involving the left anterior descending artery is indicated by ECG leads V1-V3. Similarly, an anterior infarction involving the left anterior descending artery is indicated by leads V3-V4.

In cases of anterolateral infarctions, both the left anterior descending artery and the left circumflex artery are involved, and this is reflected in ECG leads V5-V6. An extensive anterior infarction involving the left anterior descending artery is indicated by leads V1-V6.

Lateral infarcts involving the left circumflex artery are indicated by leads I, II, aVL, and V6. Inferior infarctions, on the other hand, involve either the right coronary artery (in 80% of cases) or the left circumflex artery (in 20% of cases), and this is shown by leads II, III, and aVF.

In the case of a right ventricular infarction, the right coronary artery is involved, and this is indicated by leads V1 and V4R. Lastly, a posterior infarction involving the right coronary artery is shown by leads V7-V9.

Adenosine is a type of purine nucleoside that is primarily utilized in the diagnosis and treatment of paroxysmal supraventricular tachycardia. Its main mechanism of action involves stimulating A1-adenosine receptors and opening acetylcholine-sensitive potassium channels. This leads to hyperpolarization of the cell membrane in the atrioventricular (AV) node and slows down conduction in the AV node by inhibiting calcium channels.

When administering adenosine, it is given rapidly through an intravenous bolus, followed by a saline flush. The initial dose for adults is 6 mg, and if necessary, additional doses of 12 mg or 18 mg can be given at 1-2 minute intervals until the desired effect is observed. It is important to note that the latest ALS guidelines recommend 18 mg for the third dose, while the BNF/NICE guidelines suggest 12 mg.

One of the advantages of adenosine is its very short half-life, which is less than 10 seconds. This means that its effects are rapid, typically occurring within 10 seconds. However, the duration of action is also short, lasting only 10-20 seconds. Due to its short half-life, any side effects experienced are usually brief. These side effects may include a sense of impending doom, facial flushing, dyspnea, chest discomfort, and a metallic taste.

There are certain contraindications to the use of adenosine. These include 2nd or 3rd degree AV block, sick sinus syndrome, long QT syndrome, severe hypotension, decompensated heart failure, chronic obstructive lung disease, and asthma. It is important to exercise caution when administering adenosine to patients with a heart transplant, as they are particularly sensitive to its effects. In these cases, a reduced initial dose of 3 mg is recommended, followed by 6 mg and then 12 mg.

It is worth noting that the effects of adenosine can be potentiated by dipyridamole, a medication commonly used in combination with adenosine. Therefore, the dose of adenosine should be adjusted and reduced in patients who are also taking dipyridamole.

When managing newly diagnosed atrial fibrillation, a rate control strategy is often used. In this approach, beta blockers are typically the first line of treatment. However, sotalol is not recommended, and instead, other beta blockers like atenolol, acebutolol, metoprolol, nadolol, oxprenolol, and propranolol are preferred. Among these options, atenolol is commonly chosen in NHS trusts due to its cost-effectiveness.

For patients with signs of hemodynamic instability or adverse features, rhythm control (cardioversion) may be considered if they present within 48 hours of likely onset. However, in the case of this patient, their symptoms started a week ago, and there are no indications of hemodynamic instability or adverse features.

Digoxin monotherapy is typically reserved for individuals who have limited physical activity or are unable to take other first-line rate control medications due to other health conditions or contraindications.

Further Reading:

Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia, affecting around 5% of patients over the age of 70-75 years and 10% of patients aged 80-85 years. While AF can cause palpitations and inefficient cardiac function, the most important aspect of managing patients with AF is reducing the increased risk of stroke.

AF can be classified as first detected episode, paroxysmal, persistent, or permanent. First detected episode refers to the initial occurrence of AF, regardless of symptoms or duration. Paroxysmal AF occurs when a patient has 2 or more self-terminating episodes lasting less than 7 days. Persistent AF refers to episodes lasting more than 7 days that do not self-terminate. Permanent AF is continuous atrial fibrillation that cannot be cardioverted or if attempts to do so are deemed inappropriate. The treatment goals for permanent AF are rate control and anticoagulation if appropriate.

Symptoms of AF include palpitations, dyspnea, and chest pain. The most common sign is an irregularly irregular pulse. An electrocardiogram (ECG) is essential for diagnosing AF, as other conditions can also cause an irregular pulse.

Managing patients with AF involves two key parts: rate/rhythm control and reducing stroke risk. Rate control involves slowing down the irregular pulse to avoid negative effects on cardiac function. This is typically achieved using beta-blockers or rate-limiting calcium channel blockers. If one drug is not effective, combination therapy may be used. Rhythm control aims to restore and maintain normal sinus rhythm through pharmacological or electrical cardioversion. However, the majority of patients are managed with a rate control strategy.

Reducing stroke risk in patients with AF is crucial. Risk stratifying tools, such as the CHA2DS2-VASc score, are used to determine the most appropriate anticoagulation strategy. Anticoagulation is recommended for patients with a score of 2 or more. Clinicians can choose between warfarin and novel oral anticoagulants (NOACs) for anticoagulation.

Before starting anticoagulation, the patient’s bleeding risk should be assessed using tools like the HAS-BLED score or the ORBIT tool. These tools evaluate factors such as hypertension, abnormal renal or liver function, history of bleeding, age, and use of drugs that predispose to bleeding.

Hypothermia can cause various changes in an electrocardiogram (ECG). These changes include a slower heart rate (bradycardia), the presence of Osborn waves (also known as J waves), a prolonged PR interval, a widened QRS complex, and a prolonged QT interval. Additionally, shivering artifact, ventricular ectopics (abnormal heartbeats originating from the ventricles), and even cardiac arrest (ventricular tachycardia, ventricular fibrillation, or asystole) may occur.

Further Reading:

Hypothermic cardiac arrest is a rare situation that requires a tailored approach. Resuscitation is typically prolonged, but the prognosis for young, previously healthy individuals can be good. Hypothermic cardiac arrest may be associated with drowning. Hypothermia is defined as a core temperature below 35ºC and can be graded as mild, moderate, severe, or profound based on the core temperature. When the core temperature drops, basal metabolic rate falls and cell signaling between neurons decreases, leading to reduced tissue perfusion. Signs and symptoms of hypothermia progress as the core temperature drops, initially presenting as compensatory increases in heart rate and shivering, but eventually ceasing as the temperature drops into moderate hypothermia territory.

ECG changes associated with hypothermia include bradyarrhythmias, Osborn waves, prolonged PR, QRS, and QT intervals, shivering artifact, ventricular ectopics, and cardiac arrest. When managing hypothermic cardiac arrest, ALS should be initiated as per the standard ALS algorithm, but with modifications. It is important to check for signs of life, re-warm the patient, consider mechanical ventilation due to chest wall stiffness, adjust dosing or withhold drugs due to slowed drug metabolism, and correct electrolyte disturbances. The resuscitation of hypothermic patients is often prolonged and may continue for a number of hours.

Pulse checks during CPR may be difficult due to low blood pressure, and the pulse check is prolonged to 1 minute for this reason. Drug metabolism is slowed in hypothermic patients, leading to a build-up of potentially toxic plasma concentrations of administered drugs. Current guidance advises withholding drugs if the core temperature is below 30ºC and doubling the drug interval at core temperatures between 30 and 35ºC. Electrolyte disturbances are common in hypothermic patients, and it is important to interpret results keeping the setting in mind. Hypoglycemia should be treated, hypokalemia will often correct as the patient re-warms, ABG analyzers may not reflect the reality of the hypothermic patient, and severe hyperkalemia is a poor prognostic indicator.

Different warming measures can be used to increase the core body temperature, including external passive measures such as removal of wet clothes and insulation with blankets, external active measures such as forced heated air or hot-water immersion, and internal active measures such as inhalation of warm air, warmed intravenous fluids, gastric, bladder, peritoneal and/or pleural lavage and high volume renal haemofilter.

Given the patient’s symptoms and physical findings, the most appropriate initial treatment would be to administer Furosemide 40 mg intravenously. Furosemide is a loop diuretic that helps remove excess fluid from the body, which can alleviate symptoms of fluid overload such as shortness of breath and edema. By reducing fluid volume, Furosemide can help improve the patient’s breathing and relieve the strain on the heart.

Further Reading:

Cardiac failure, also known as heart failure, is a clinical syndrome characterized by symptoms and signs resulting from abnormalities in the structure or function of the heart. This can lead to reduced cardiac output or high filling pressures at rest or with stress. Heart failure can be caused by various problems such as myocardial, valvular, pericardial, endocardial, or arrhythmic issues.

The most common causes of heart failure in the UK are coronary heart disease and hypertension. However, there are many other possible causes, including valvular heart disease, structural heart disease, cardiomyopathies, certain drugs or toxins, endocrine disorders, nutritional deficiencies, infiltrative diseases, infections, and arrhythmias. Conditions that increase peripheral demand on the heart, such as anemia, pregnancy, sepsis, hyperthyroidism, Paget’s disease of bone, arteriovenous malformations, and beriberi, can also lead to high-output cardiac failure.

Signs and symptoms of heart failure include edema, lung crepitations, tachycardia, tachypnea, hypotension, displaced apex beat, right ventricular heave, elevated jugular venous pressure, cyanosis, hepatomegaly, ascites, pleural effusions, breathlessness, fatigue, orthopnea, paroxysmal nocturnal dyspnea, nocturnal cough or wheeze, and Presyncope.

To diagnose heart failure, NICE recommends three key tests: N-terminal pro-B-type natriuretic peptide (NT‑proBNP), transthoracic echocardiography, and ECG. Additional tests may include chest X-ray, blood tests (U&Es, thyroid function, LFT’s, lipid profile, HbA1C, FBC), urinalysis, and peak flow or spirometry.

Management of cardiogenic pulmonary edema, a complication of heart failure, involves ensuring a patent airway, optimizing breathing with supplemental oxygen and non-invasive ventilation if necessary, and addressing circulation with loop diuretics to reduce preload, vasodilators to reduce preload and afterload, and inotropes if hypotension or signs of end organ hypoperfusion persist.

In summary, cardiac failure is a clinical syndrome resulting from abnormalities in cardiac function. It can have various causes and is characterized by specific signs and symptoms. Diagnosis involves specific tests, and management focuses on addressing

The first heart sound (S1) is created by vibrations produced when the mitral and tricuspid valves close. It occurs at the end of diastole and the start of ventricular systole, coming before the upstroke of the carotid pulsation.

A sample of the normal heart sounds can be listened to here (courtesy of Littman stethoscopes).

A loud S1 can be associated with the following conditions:
– Increased transvalvular gradient (e.g. mitral stenosis, tricuspid stenosis)
– Increased force of ventricular contraction (e.g. tachycardia, hyperdynamic states like fever and thyrotoxicosis)
– Shortened PR interval (e.g. Wolff-Parkinson-White syndrome)
– Mitral valve prolapse
– Thin individuals

A soft S1 can be associated with the following conditions:
– Inappropriate apposition of the AV valves (e.g. mitral regurgitation, tricuspid regurgitation)
– Prolonged PR interval (e.g. heart block, digoxin toxicity)
– Decreased force of ventricular contraction (e.g. myocarditis, myocardial infarction)
– Increased distance from the heart (e.g. obesity, emphysema, pericardial effusion)

A split S1 can be associated with the following conditions:
– Right bundle branch block
– LV pacing
– Ebstein anomaly

The characteristic with the highest likelihood ratio for AMI is the radiation of chest pain to the right arm or both arms. Additionally, the history characteristics of cardiac pain also have a high likelihood ratio for AMI.

Further Reading:

Acute Coronary Syndromes (ACS) is a term used to describe a group of conditions that involve the sudden reduction or blockage of blood flow to the heart. This can lead to a heart attack or unstable angina. ACS includes ST segment elevation myocardial infarction (STEMI), non-ST segment elevation myocardial infarction (NSTEMI), and unstable angina (UA).

The development of ACS is usually seen in patients who already have underlying coronary heart disease. This disease is characterized by the buildup of fatty plaques in the walls of the coronary arteries, which can gradually narrow the arteries and reduce blood flow to the heart. This can cause chest pain, known as angina, during physical exertion. In some cases, the fatty plaques can rupture, leading to a complete blockage of the artery and a heart attack.

There are both non modifiable and modifiable risk factors for ACS. non modifiable risk factors include increasing age, male gender, and family history. Modifiable risk factors include smoking, diabetes mellitus, hypertension, hypercholesterolemia, and obesity.

The symptoms of ACS typically include chest pain, which is often described as a heavy or constricting sensation in the central or left side of the chest. The pain may also radiate to the jaw or left arm. Other symptoms can include shortness of breath, sweating, and nausea/vomiting. However, it’s important to note that some patients, especially diabetics or the elderly, may not experience chest pain.

The diagnosis of ACS is typically made based on the patient’s history, electrocardiogram (ECG), and blood tests for cardiac enzymes, specifically troponin. The ECG can show changes consistent with a heart attack, such as ST segment elevation or depression, T wave inversion, or the presence of a new left bundle branch block. Elevated troponin levels confirm the diagnosis of a heart attack.

The management of ACS depends on the specific condition and the patient’s risk factors. For STEMI, immediate coronary reperfusion therapy, either through primary percutaneous coronary intervention (PCI) or fibrinolysis, is recommended. In addition to aspirin, a second antiplatelet agent is usually given. For NSTEMI or unstable angina, the treatment approach may involve reperfusion therapy or medical management, depending on the patient’s risk of future cardiovascular events.

This patient has developed a non-ST elevation myocardial infarction (NSTEMI). The electrocardiogram (ECG) reveals widespread ST depression, indicating widespread subendocardial ischemia. Additionally, the troponin test results are positive, indicating myocyte necrosis.

The acute coronary syndromes consist of unstable angina, non-ST elevation myocardial infarction (NSTEMI), and ST-elevation myocardial infarction (STEMI).

Unstable angina is characterized by one or more of the following: angina of effort occurring over a few days with increasing frequency, angina episodes occurring recurrently and predictably without specific provocation, or an unprovoked and prolonged episode of cardiac chest pain. The ECG may show T-wave/ST-segment changes, similar to this case. Cardiac enzymes are typically normal, and the troponin test is negative in unstable angina.

Non-ST elevation myocardial infarction (NSTEMI) typically presents with sustained cardiac chest pain lasting more than 20 minutes. The ECG often shows abnormalities in T-waves or ST-segments. Cardiac enzymes are elevated, and the troponin test is positive.

ST-elevation myocardial infarction (STEMI) usually presents with typical cardiac chest pain suggestive of an acute myocardial infarction. The ECG reveals ST-segment elevation and the development of Q waves. Cardiac enzymes are elevated, and the troponin test is positive.

Patients with mitral regurgitation can go for extended periods without experiencing any symptoms. They may have a normal exercise tolerance and show no signs of congestive cardiac failure. However, when cardiac failure does occur, patients often complain of breathlessness, especially during physical exertion. They may also experience fatigue, difficulty breathing while lying flat (orthopnoea), and sudden episodes of difficulty breathing at night (paroxysmal nocturnal dyspnoea).

In terms of clinical signs, mitral regurgitation can be identified through various indicators. These include a displaced and volume loaded apex beat, which can be felt during a physical examination. A palpable thrill may also be detected at the apex. Additionally, a pansystolic murmur, which is loudest at the apex and radiates to the axilla, can be heard. This murmur is typically most pronounced when the patient holds their breath during expiration. Furthermore, a soft first heart sound and signs of left ventricular failure may be present.

A collapsing pulse, also known as a water hammer pulse, is a common clinical feature associated with aortic regurgitation (AR). In AR, the pulse rises rapidly and forcefully before quickly collapsing. This pulsation pattern may also be referred to as Watson’s water hammer pulse or Corrigan’s pulse. Heart sounds in AR are typically quiet, and the second heart sound (S2) may even be absent if the valve fails to fully close. A characteristic early to mid diastolic murmur is often present. Other typical features of AR include a wide pulse pressure, a mid-diastolic Austin-Flint murmur in severe cases, a soft S1 and S2 (with S2 potentially being absent), a hyperdynamic apical pulse, and signs of heart failure such as lung creases, raised jugular venous pressure (JVP), and tachypnea.

Further Reading:

Valvular heart disease refers to conditions that affect the valves of the heart. In the case of aortic valve disease, there are two main conditions: aortic regurgitation and aortic stenosis.

Aortic regurgitation is characterized by an early diastolic murmur, a collapsing pulse (also known as a water hammer pulse), and a wide pulse pressure. In severe cases, there may be a mid-diastolic Austin-Flint murmur due to partial closure of the anterior mitral valve cusps caused by the regurgitation streams. The first and second heart sounds (S1 and S2) may be soft, and S2 may even be absent. Additionally, there may be a hyperdynamic apical pulse. Causes of aortic regurgitation include rheumatic fever, infective endocarditis, connective tissue diseases like rheumatoid arthritis and systemic lupus erythematosus, and a bicuspid aortic valve. Aortic root diseases such as aortic dissection, spondyloarthropathies like ankylosing spondylitis, hypertension, syphilis, and genetic conditions like Marfan’s syndrome and Ehler-Danlos syndrome can also lead to aortic regurgitation.

Aortic stenosis, on the other hand, is characterized by a narrow pulse pressure, a slow rising pulse, and a delayed ESM (ejection systolic murmur). The second heart sound (S2) may be soft or absent, and there may be an S4 (atrial gallop) that occurs just before S1. A thrill may also be felt. The duration of the murmur is an important factor in determining the severity of aortic stenosis. Causes of aortic stenosis include degenerative calcification (most common in older patients), a bicuspid aortic valve (most common in younger patients), William’s syndrome (supravalvular aortic stenosis), post-rheumatic disease, and subvalvular conditions like hypertrophic obstructive cardiomyopathy (HOCM).

Management of aortic valve disease depends on the severity of symptoms. Asymptomatic patients are generally observed, while symptomatic patients may require valve replacement. Surgery may also be considered for asymptomatic patients with a valvular gradient greater than 40 mmHg and features such as left ventricular systolic dysfunction. Balloon valvuloplasty is limited to patients with critical aortic stenosis who are not fit for valve replacement.

Cardiac enzymes do not increase in unstable angina. However, if cardiac markers do rise, it is classified as a non-ST elevation myocardial infarction (NSTEMI). Both unstable angina and NSTEMI can have a normal ECG. An extended ventricular activation time indicates damage to the heart muscle. This occurs because infarcting myocardium conducts electrical impulses at a slower pace, resulting in a prolonged interval between the start of the QRS complex and the apex of the R wave. A positive troponin test indicates the presence of necrosis in cardiac myocytes.

Summary:
Marker | Initial Rise | Peak | Normal at
Creatine kinase | 4-8 hours | 18 hours 2-3 days | CK-MB = main cardiac isoenzyme
Myoglobin | 1-4 hours | 6-7 hours | 24 hours | Low specificity due to skeletal muscle damage
Troponin I | 3-12 hours | 24 hours | 3-10 days | Appears to be the most sensitive and specific
HFABP | 1-2 hours | 5-10 hours | 24 hours | HFABP = heart fatty acid binding protein
LDH | 10 hours | 24-48 hours | 14 days | Cardiac muscle mainly contains LDH

Wolff-Parkinson-White (WPW) syndrome is a condition that affects the electrical system of the heart. It occurs when there is an abnormal pathway, known as the bundle of Kent, between the atria and the ventricles. This pathway can cause premature contractions of the ventricles, leading to a type of rapid heartbeat called atrioventricular re-entrant tachycardia (AVRT).

In a normal heart rhythm, the electrical signals travel through the bundle of Kent and stimulate the ventricles. However, in WPW syndrome, these signals can cause the ventricles to contract prematurely. This can be seen on an electrocardiogram (ECG) as a shortened PR interval, a slurring of the initial rise in the QRS complex (known as a delta wave), and a widening of the QRS complex.

There are two distinct types of WPW syndrome that can be identified on an ECG. Type A is characterized by predominantly positive delta waves and QRS complexes in the praecordial leads, with a dominant R wave in V1. This can sometimes be mistaken for right bundle branch block (RBBB). Type B, on the other hand, shows predominantly negative delta waves and QRS complexes in leads V1 and V2, and positive in the other praecordial leads, resembling left bundle branch block (LBBB).

Overall, WPW syndrome is a condition that affects the electrical conduction system of the heart, leading to abnormal heart rhythms. It can be identified on an ECG by specific features such as shortened PR interval, delta waves, and widened QRS complex.

Adrenaline and isoprenaline are considered as second-line medications for the treatment of bradycardia. If atropine fails to improve the condition, transcutaneous pacing is recommended. However, if pacing is not available, the administration of second-line drugs becomes necessary. Adrenaline is typically given intravenously at a dosage of 2-10 mcg/minute, while isoprenaline is given at a dosage of 5 mcg/minute. It is important to note that glucagon is not mentioned as a treatment option for this patient’s bradycardia, as the cause of the condition is not specified as a beta-blocker overdose.

Further Reading:

Causes of Bradycardia:
– Physiological: Athletes, sleeping
– Cardiac conduction dysfunction: Atrioventricular block, sinus node disease
– Vasovagal & autonomic mediated: Vasovagal episodes, carotid sinus hypersensitivity
– Hypothermia
– Metabolic & electrolyte disturbances: Hypothyroidism, hyperkalaemia, hypermagnesemia
– Drugs: Beta-blockers, calcium channel blockers, digoxin, amiodarone
– Head injury: Cushing’s response
– Infections: Endocarditis
– Other: Sarcoidosis, amyloidosis

Presenting symptoms of Bradycardia:
– Presyncope (dizziness, lightheadedness)
– Syncope
– Breathlessness
– Weakness
– Chest pain
– Nausea

Management of Bradycardia:
– Assess and monitor for adverse features (shock, syncope, myocardial ischaemia, heart failure)
– Treat reversible causes of bradycardia
– Pharmacological treatment: Atropine is first-line, adrenaline and isoprenaline are second-line
– Transcutaneous pacing if atropine is ineffective
– Other drugs that may be used: Aminophylline, dopamine, glucagon, glycopyrrolate

Bradycardia Algorithm:
– Follow the algorithm for management of bradycardia, which includes assessing and monitoring for adverse features, treating reversible causes, and using appropriate medications or pacing as needed.
https://acls-algorithms.com/wp-content/uploads/2020/12/Website-Bradycardia-Algorithm-Diagram.pdf

Mitral stenosis is a condition characterized by a narrowing of the mitral valve, which can lead to various symptoms. One common symptom is a mid-late diastolic murmur, which can be heard during a physical examination. This murmur may also be described as mid-diastolic, late-diastolic, or mid-late diastolic. Additionally, patients with chronic mitral stenosis may not experience any symptoms, and the murmur may only be detected incidentally.

A significant risk associated with mitral stenosis is the development of atrial fibrillation (AF). When AF occurs in patients with mitral stenosis, it can trigger acute pulmonary edema. This happens because the left atrium, which is responsible for pumping blood across the narrowed mitral valve into the left ventricle, needs to generate higher pressure. However, when AF occurs, the atrial contraction becomes inefficient, leading to impaired emptying of the left atrium. This, in turn, causes increased back pressure in the pulmonary circulation.

The elevated pressure in the left atrium and pulmonary circulation can result in the rupture of bronchial veins, leading to the production of pink frothy sputum. This symptom is often observed in patients with mitral stenosis who develop acute pulmonary edema.

Further Reading:

Mitral Stenosis:
– Causes: Rheumatic fever, Mucopolysaccharidoses, Carcinoid, Endocardial fibroelastosis
– Features: Mid-late diastolic murmur, loud S1, opening snap, low volume pulse, malar flush, atrial fibrillation, signs of pulmonary edema, tapping apex beat
– Features of severe mitral stenosis: Length of murmur increases, opening snap becomes closer to S2
– Investigation findings: CXR may show left atrial enlargement, echocardiography may show reduced cross-sectional area of the mitral valve

Mitral Regurgitation:
– Causes: Mitral valve prolapse, Myxomatous degeneration, Ischemic heart disease, Rheumatic fever, Connective tissue disorders, Endocarditis, Dilated cardiomyopathy
– Features: pansystolic murmur radiating to left axilla, soft S1, S3, laterally displaced apex beat with heave
– Signs of acute MR: Decompensated congestive heart failure symptoms
– Signs of chronic MR: Leg edema, fatigue, arrhythmia (atrial fibrillation)
– Investigation findings: Doppler echocardiography to detect regurgitant flow and pulmonary hypertension, ECG may show signs of LA enlargement and LV hypertrophy, CXR may show LA and LV enlargement in chronic MR and pulmonary edema in acute MR.

For patients suspected of having acute coronary syndromes (ACS), it is recommended that they receive 300 mg of aspirin and pain relief in the form of glyceryl trinitrate (GTN) with the option of intravenous opioids such as morphine. However, if the patient is pain-free after taking GTN, there is no need to administer morphine. The next steps in medical management or intervention will be determined once the diagnosis is confirmed.

Further Reading:

Acute Coronary Syndromes (ACS) is a term used to describe a group of conditions that involve the sudden reduction or blockage of blood flow to the heart. This can lead to a heart attack or unstable angina. ACS includes ST segment elevation myocardial infarction (STEMI), non-ST segment elevation myocardial infarction (NSTEMI), and unstable angina (UA).

The development of ACS is usually seen in patients who already have underlying coronary heart disease. This disease is characterized by the buildup of fatty plaques in the walls of the coronary arteries, which can gradually narrow the arteries and reduce blood flow to the heart. This can cause chest pain, known as angina, during physical exertion. In some cases, the fatty plaques can rupture, leading to a complete blockage of the artery and a heart attack.

There are both non modifiable and modifiable risk factors for ACS. non modifiable risk factors include increasing age, male gender, and family history. Modifiable risk factors include smoking, diabetes mellitus, hypertension, hypercholesterolemia, and obesity.

The symptoms of ACS typically include chest pain, which is often described as a heavy or constricting sensation in the central or left side of the chest. The pain may also radiate to the jaw or left arm. Other symptoms can include shortness of breath, sweating, and nausea/vomiting. However, it’s important to note that some patients, especially diabetics or the elderly, may not experience chest pain.

The diagnosis of ACS is typically made based on the patient’s history, electrocardiogram (ECG), and blood tests for cardiac enzymes, specifically troponin. The ECG can show changes consistent with a heart attack, such as ST segment elevation or depression, T wave inversion, or the presence of a new left bundle branch block. Elevated troponin levels confirm the diagnosis of a heart attack.

The management of ACS depends on the specific condition and the patient’s risk factors. For STEMI, immediate coronary reperfusion therapy, either through primary percutaneous coronary intervention (PCI) or fibrinolysis, is recommended. In addition to aspirin, a second antiplatelet agent is usually given. For NSTEMI or unstable angina, the treatment approach may involve reperfusion therapy or medical management, depending on the patient’s risk of future cardiovascular events.

Amiodarone is recommended to be administered after the third shock in a shockable cardiac arrest (Vf/pVT) while performing chest compressions. The prescribed dose is 300 mg, which should be given as an intravenous bolus. To ensure proper administration, the medication should be diluted in 20 mL of 5% dextrose solution.

In cases where VF/pVT continues after five defibrillation attempts, an additional dose of 150 mg of Amiodarone should be administered. It is important to note that Amiodarone is not suitable for treating PEA or asystole, and its use is specifically indicated for shockable cardiac arrest situations.

Acute aortic dissection is characterized by the rapid formation of a false, blood-filled channel within the middle layer of the aorta. It is estimated to occur in 3 out of every 100,000 individuals per year.

Patients with aortic dissection typically experience intense chest pain that spreads to the area between the shoulder blades. The pain is often described as tearing or ripping and may also extend to the neck. Sweating, paleness, and rapid heartbeat are commonly observed at the time of presentation. Other possible symptoms include focal neurological deficits, weak pulses, fainting, and reduced blood flow to organs.

A significant difference in blood pressure between the arms, greater than 20 mmHg, is a highly sensitive indicator. If the dissection extends backward, it can involve the aortic valve, leading to the early diastolic murmur of aortic regurgitation.

Risk factors for aortic dissection include hypertension, atherosclerosis, aortic coarctation, the use of sympathomimetic drugs like cocaine, Marfan syndrome, Ehlers-Danlos syndrome, Turner’s syndrome, tertiary syphilis, and pre-existing aortic aneurysm.

Aortic dissection can be classified according to the Stanford classification system:
– Type A affects the ascending aorta and the arch, accounting for 60% of cases. These cases are typically managed surgically and may result in the blockage of coronary arteries and aortic regurgitation.
– Type B begins distal to the left subclavian artery and accounts for approximately 40% of cases. These cases are usually managed with medication to control blood pressure.

In stable patients with SVT, it is recommended to first try vagal manoeuvres before resorting to drug treatment. This approach is particularly applicable to patients who do not exhibit any adverse features, as mentioned in the case above.

Further Reading:

Supraventricular tachycardia (SVT) is a type of tachyarrhythmia that originates from the atria or above the bundle of His in the heart. It includes all atrial and junctional tachycardias, although atrial fibrillation is often considered separately. SVT typically produces a narrow QRS complex tachycardia on an electrocardiogram (ECG), unless there is an underlying conduction abnormality below the atrioventricular (AV) node. Narrow complex tachycardias are considered SVTs, while some broad complex tachycardias can also be SVTs with co-existent conduction delays.

SVT can be classified into three main subtypes based on where it arises: re-entrant accessory circuits (the most common type), atrial tachycardias, and junctional tachycardias. The most common SVTs are AVNRT (AV nodal re-entry tachycardia) and AVRT (AV re-entry tachycardia), which arise from accessory circuits within the heart. AVNRT involves an accessory circuit within the AV node itself, while AVRT involves an accessory pathway between the atria and ventricles that allows additional electrical signals to trigger the AV node.

Atrial tachycardias originate from abnormal foci within the atria, except for the SA node, AV node, or accessory pathway. Junctional tachycardias arise in the AV junction. The ECG features of SVTs vary depending on the type. Atrial tachycardias may have abnormal P wave morphology, an isoelectric baseline between P waves (in atrial flutter), and inverted P waves in certain leads. AVNRT may show pseudo R waves in V1 or pseudo S waves in certain leads, with an RP interval shorter than the PR interval. AVRT (WPW) may exhibit a delta wave on a resting ECG and retrograde P waves in the ST segment, with an RP interval shorter than the PR interval. Junctional tachycardias may have retrograde P waves before, during, or after the QRS complex, with inverted P waves in certain leads and upright P waves in others.

Treatment of SVT follows the 2021 resuscitation council algorithm for tachycardia with a pulse. The algorithm provides guidelines for managing stable patients with SVT.

Wolff-Parkinson-White (WPW) syndrome is a condition that affects the electrical system of the heart. It occurs when there is an abnormal pathway, known as the bundle of Kent, between the atria and the ventricles. This pathway can cause premature contractions of the ventricles, leading to a type of rapid heartbeat called atrioventricular re-entrant tachycardia (AVRT).

In a normal heart rhythm, the electrical signals travel through the bundle of Kent and stimulate the ventricles. However, in WPW syndrome, these signals can cause the ventricles to contract prematurely. This can be seen on an electrocardiogram (ECG) as a shortened PR interval, a slurring of the initial rise in the QRS complex (known as a delta wave), and a widening of the QRS complex.

There are two distinct types of WPW syndrome that can be identified on an ECG. Type A is characterized by predominantly positive delta waves and QRS complexes in the praecordial leads, with a dominant R wave in V1. This can sometimes be mistaken for right bundle branch block (RBBB). Type B, on the other hand, shows predominantly negative delta waves and QRS complexes in leads V1 and V2, and positive in the other praecordial leads, resembling left bundle branch block (LBBB).

Overall, WPW syndrome is a condition that affects the electrical conduction system of the heart, leading to abnormal heart rhythms. It can be identified on an ECG by specific features such as shortened PR interval, delta waves, and widened QRS complex.

This patient is displaying symptoms consistent with a diagnosis of an acute myocardial infarction. It is important to provide pain relief as soon as possible. One option for pain relief is GTN, which can be taken sublingually or buccally. However, if there is suspicion of an acute myocardial infarction, it is recommended to offer intravenous opioids such as morphine.

Aspirin should be offered to all patients with unstable angina or NSTEMI as soon as possible and should be continued indefinitely, unless there are contraindications such as a bleeding risk or aspirin hypersensitivity. A loading dose of 300 mg should be administered promptly after presentation.

For patients without a high bleeding risk who do not have coronary angiography planned within 24 hours of admission, fondaparinux should be administered. However, for patients who are likely to undergo coronary angiography within 24 hours, unfractionated heparin can be offered as an alternative to fondaparinux. In cases of significant renal impairment (creatinine above 265 micromoles per litre), unfractionated heparin with dose adjustment guided by clotting function monitoring can also be considered as an alternative to fondaparinux.

Routine administration of oxygen is no longer recommended, but it is important to monitor oxygen saturation using pulse oximetry as soon as possible, preferably before hospital admission. Supplemental oxygen should only be offered to individuals with an oxygen saturation (SpO2) of less than 94% who are not at risk of hypercapnic respiratory failure, with a target SpO2 range of 94-98%. For individuals with chronic obstructive pulmonary disease who are at risk of hypercapnic respiratory failure, a target SpO2 range of 88-92% should be aimed for until blood gas analysis is available.

Bivalirudin, a specific and reversible direct thrombin inhibitor (DTI), is recommended by NICE as a possible treatment for adults with STEMI who are undergoing percutaneous coronary intervention.

For more information, please refer to the NICE guidelines on the assessment and diagnosis of chest pain of recent onset.

Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia, affecting around 5% of patients over the age of 70-75 years and 10% of patients aged 80-85 years. While AF can cause palpitations and inefficient cardiac function, the most important aspect of managing patients with AF is reducing the increased risk of stroke.

AF can be classified as first detected episode, paroxysmal, persistent, or permanent. First detected episode refers to the initial occurrence of AF, regardless of symptoms or duration. Paroxysmal AF occurs when a patient has 2 or more self-terminating episodes lasting less than 7 days. Persistent AF refers to episodes lasting more than 7 days that do not self-terminate. Permanent AF is continuous atrial fibrillation that cannot be cardioverted or if attempts to do so are deemed inappropriate. The treatment goals for permanent AF are rate control and anticoagulation if appropriate.

Symptoms of AF include palpitations, dyspnea, and chest pain. The most common sign is an irregularly irregular pulse. An electrocardiogram (ECG) is essential for diagnosing AF, as other conditions can also cause an irregular pulse.

Managing patients with AF involves two key parts: rate/rhythm control and reducing stroke risk. Rate control involves slowing down the irregular pulse to avoid negative effects on cardiac function. This is typically achieved using beta-blockers or rate-limiting calcium channel blockers. If one drug is not effective, combination therapy may be used. Rhythm control aims to restore and maintain normal sinus rhythm through pharmacological or electrical cardioversion. However, the majority of patients are managed with a rate control strategy.

Reducing stroke risk in patients with AF is crucial. Risk stratifying tools, such as the CHA2DS2-VASc score, are used to determine the most appropriate anticoagulation strategy. Anticoagulation is recommended for patients with a score of 2 or more. Clinicians can choose between warfarin and novel oral anticoagulants (NOACs) for anticoagulation.

Before starting anticoagulation, the patient’s bleeding risk should be assessed using tools like the HAS-BLED score or the ORBIT tool. These tools evaluate factors such as hypertension, abnormal renal or liver function, history of bleeding, age, and use of drugs that predispose to bleeding.