Outline of cardiology

The following outline is provided as an overview of and topical guide to cardiology, the branch of medicine dealing with disorders of the human heart.[1] The field includes medical diagnosis and treatment of congenital heart defects, coronary artery disease, heart failure, valvular heart disease and electrophysiology. Physicians who specialize in cardiology are called cardiologists.

What type of thing is cardiology

Cardiology can be described as all of the following:

Branches of cardiology

  • Adult cardiology
    • Cardiac electrophysiology study of the electrical properties and conduction diseases of the heart.
      • Clinical cardiac electrophysiology Clinical cardiac electrophysiology, is a branch of the medical specialty of cardiology and is concerned with the study and treatment of rhythm disorders of the heart. Cardiologists with expertise in this area are usually referred to as electrophysiologists. Electrophysiologists are trained in the mechanism, function, and performance of the electrical activities of the heart.
    • Cardiogeriatrics (geriatric cardiology) Cardiogeriatrics, or geriatric cardiology, is the branch of cardiology and geriatric medicine that deals with the cardiovascular disorders in elderly people.
    • Echocardiography use of ultrasound to study the mechanical function/physics of the heart.
    • Interventional cardiology use of catheters for the treatment of structural and ischemic diseases of the heart.
    • Nuclear cardiology use of nuclear medicine to visualize the uptake of an isotope by the heart using radioactive sources.
  • Pediatric cardiology Pediatric cardiologists specialize in diagnosing and treating heart problems in children.

Anatomy of the heart

Heart

Physical exam

The cardiac physical exam focuses on portions of the physical exam that elucidate information about diseases and disorders outlined below. Clinical judgment, of course, should guide the physical exam but the following are pertinent things related to a general / broad cardiac exam.

Heart disorders

  • Cardiac arrhythmias conditions in which the heartbeat is irregular, too fast, or too slow. Many types of arrhythmia have no symptoms. When symptoms are present these may include palpitations or feeling a pause between heartbeats. More seriously there may be lightheadedness, passing out, shortness of breath, or chest pain.[4] While most types of arrhythmia are not serious, some predispose a person to complications such as stroke or heart failure. Others may result in cardiac arrest.
    • Atrial fibrillation (afib or AF) Fibrillation of the atria is fairly common and more common with increased age and overall disease of the heart. If the ventricular rate exceeds 100 then the afib is further classified as "afib with RVR" meaning rapid ventricular response.
    • Atrial flutter (AFL) A re-entrant tachycardia greater than 240 beats per minute and produces a characteristic saw-tooth pattern on ECG. It often degenerates to atrial fibrillation.
    • Heart block A decrease in the ability of the conduction system to transmit action pulses in the orderly manner. Blockage of the signal at different areas results in different types of heart block (e.g., first-degree AV block, left bundle branch block).
    • Long QT syndrome Lengthening of the QT interval can result in arrhythmias and sudden cardiac death. Specifically, it can lead to torsades de pointes than can then lead to ventricular fibrillation. It can be an inherited disorder or be acquired. Certain medications are associated with lengthening of the QT interval — drug-induced QT prolongation — and an EKG may be warranted before starting the medication to ensure a normal QT interval, but this practice is debated.
    • Premature atrial contractions (PACs or APCs) Normal beats originate in the SA node and extra beats originating from the atria are called PACs. They can be found in normal hearts and be asymptomatic; symptomatic PACs can be treated with beta blockers. PACs, like PVCs, can pair up with normal beats in a pattern called bigeminy.
    • Premature ventricular contractions (PVCs) Normal beats are conducted through the AV node to the ventricles resulting in a narrow QRS complex. With PVCs, the extra beat originates within the ventricles and results in a wide QRS complex. Like PACs, they can be found in healthy hearts but are more likely to be found in bigeminy than PACs.
    • Sick sinus syndrome, Bradycardia-tachycardia syndrome (BTS) Disease of the SA node that results in irregular changes in heart rate and in the case of BTS the arrhythmia alternates between bradycardia and tachycardia.
    • Supraventricular tachycardia (SVT) A collection of tachycardia rhythms that originate before the ventricles and include the SA node, atria, and AV node. It is a broad, encompassing term that includes other rhythms in this list (e.g., afib with RVR) and others.
    • Torsades de pointes A polymorphic arrhythmia that can be symptomatic and tends to resolve to a normal sinus rhythm. However, there is a concern
    • Ventricular fibrillation (vfib) Fibrillation of the ventricles is a life-threatening arrhythmia and should be treated by defibrillation and is a medical emergency. Vfib results from uncoordinated contraction of the ventricles and defibrillation acts as a 'reset' to synchronize contraction (i.e., a normal rhythm).
    • Ventricular tachycardia (vtach) Tachycardia that originates from within the ventricles. Typically, "vtach" implies monomorphology but it can be an umbrella term for both monomorphic and polymorphic (i.e., torsade de pointes). To classify a ventricular rhythm as vtach, at least 3 beats in a row must originate from the ventricles and have a rate over 100. If it lasts longer than 30 seconds, it can additionally be labelled as a sustained vtach.
  • Coronary circulation disorders
    • Atherosclerosis Atherosclerosis is the condition in which an artery wall thickens as the result of a build-up of fatty materials (e.g., cholesterol) and white blood cells ("foam cells"). Atherosclerosis of a coronary artery leads to coronary artery disease (CAD). Atherosclerosis is a broad term referring to loss of elasticity of arteries and more specific terms exist — arteriosclerosis and arteriolosclerosis — to narrow which arteries are diseased and can easily be confused due to similar spelling. Overall, atherosclerosis tends to affect the arteries of highest pressure: aorta, coronary, renal, femoral, cerebral, and carotid.
    • Coronary artery disease (CAD) Coronary artery disease is a general term for any reduction in coronary circulation. One such cause is atherosclerosis. CAD can lead to ischemia (angina pectoris) or infarction (myocardial infarction). Treatment of CAD includes angioplasty, stenting, and coronary artery bypass surgery (CABG).
      • Acute coronary syndrome (ACS) ACS is a medical emergency and is a broad term encompassing many acute myocardial infarction symptoms. As a syndrome, it consists of a constellation of symptoms and can have many causes. The top three causes of ACS are ST elevation myocardial infarction (STEMI, 30%), non ST elevation myocardial infarction (NSTEMI, 25%), or unstable angina (38%). The first two are myocardial infarctions which are more commonly known as "heart attacks."
      • Angina pectoris Angina pectoris literally means "chest pain" that refers to pain caused by ischemia of the heart. The main cause of angina is coronary artery disease, but can result from other non-atherosclerotic causes such as anemia and heart failure. Stable angina results if the angina resolves with rest or nitroglycerin, but can progress to unstable angina which is a form of acute coronary syndrome.
      • Myocardial infarction (a.k.a. heart attack) A myocardial infarction is the death of a part of the heart which is typically caused by a blockage of the coronary circulation but can be caused by other insufficiency such as cardiogenic shock.
    • Restenosis Recurrence of stenosis after being treated (e.g., stenting).
  • Cardiac arrest cessation of normal systemic circulation due to failure in proper contraction of the heart. There are several conditions that can cause cardiac arrest. Treatment of cardiac arrest includes cardiopulmonary resuscitation (CPR), defibrillation, and advanced cardiac life support (ACLS), and treatment of the underlying cause of arrest.
    • Asystole ("flatline") Asystole refers to the absence of electrical activity of the heart and is sometimes referred to as a "flatline" because the electrocardiogram shows a solid line due to the absence of electrical activity. This flatline is commonly used in television and movies to signal death. There are numerous causes of asystole that may be reversible if determined quickly enough, however, survival is very unlikely (~2% if not in a hospital). In contrast, asystole is desired and induced during cardiopulmonary bypass through a cardioplegia solution containing very high amounts of potassium. One additional example is the use of high potassium in lethal injection that results in asystole, cardiac arrest, and then death.
    • Pulseless electrical activity (PEA) Pulseless electrical activity is when the electrocardiogram shows a rhythm that should produce a pulse but it does not. PEA is commonly caused by the 6 H's and 6 T's (see PEA article) and results in decreased cardiac output and insufficient oxygen delivery to the body.
    • Pulseless ventricular tachycardia Pulseless ventricular tachycardia (VT) Is one classification of VT such that no pulse is felt because of an ineffective cardiac output which causes cardiac arrest, which also results in insufficient oxygen delivery to the body.
    • Sudden cardiac death (SCD) concept of natural death rather than a specific medical condition. There are several causes of sudden cardiac death and it is distinct from cardiac arrest. The leading cause of SCD in young athletes is hypertrophic cardiomyopathy but can also result from commotio cordis that is often sustained during athletic activity.
    • Ventricular fibrillation Ventricular fibrillation is fibrillation of the ventricles of the heart. Rhythmic contraction is necessary for efficient movement of blood, and fibrillation disrupts this rhythm sufficiently to cause cardiac arrest.
  • Disorders of the pericardium
    • Pericarditis Inflammation of the pericardium that is typically idiopathic or infectious in nature. Treatment of viral & idiopathic pericarditis is NSAIDs or aspirin.
    • Pericardial effusion The serous pericardium normally contains fluid that reduces friction, but an abnormal accumulation of fluid in the pericardium is called a pericardial effusion. The list of causes is lengthy but includes pericarditis, rheumatic diseases (e.g., systemic lupus erythematosus), trauma, and blood from myocardial rupture. If an effusion worsens then the fluid can inhibit heart function and symptoms of cardiac tamponade appear. Treatment includes pericardiocentesis to drain the fluid, if necessary, and treatment of the underlying cause.
    • Pericardial tamponade Tamponade is a medical emergency resulting from accumulation of fluid in the pericardium that inhibits heart function. Tamponade is a consequence of the fibrous pericardium being too inelastic to permit adequate heart expansion during diastole. The classic finding is pulsus paradoxus as well as Beck's triad (low arterial blood pressure, distended neck veins, & soft heart sounds). Treatment is supportive until in a hospital where pericardiocentesis or a pericardial window can be performed to drain the fluid.
  • Diseases of blood vessels diseases of the blood vessels can be multidisciplinary in nature. For example, medical treatment of atherosclerosis tends to be managed by cardiologists while vascular surgery repairs aneurysms and stenotic arteries.
    • Atherosclerosis Thickening of an arterial wall due to increased cholesterol and macrophages (see above).
    • Aneurysm Balloon-like bulging of arteries (also possible of the heart: see ventricular aneurysm above).
    • Aortic dissection Dissection along the length of the aorta between the layers of the aortic wall. Dissection of the ascending aorta (type A) is a surgical emergency while dissection of the descending aorta (type B) can possibly be managed medically. Dissection of the ascending aorta is an emergency because dissection may interrupt coronary blood flow and blood flow to the brain, neither of which tolerate ischemia particularly well.
    • Aortic rupture Frank rupture of the aorta is often fatal from internal bleeding. Rupture of the aorta can occur at the sites of aneurysm, but is also due to trauma and results in a traumatic aortic rupture.
    • Carotid artery Diseases of the carotid arteries:
      • Carotid artery stenosis / carotid artery disease Narrowing of the carotid artery, typically due to atherosclerosis.
      • Carotid artery dissection Dissection along the length of the carotid artery between the layers of the carotid wall and filled with blood.
    • Deep vein thrombosis (DVT) and pulmonary embolism (PE) Formation of a thrombus in a deep vein, commonly in the legs that may break loose, travel to the lungs, and occlude blood flow (pulmonary embolism) sufficient to interrupt oxygenation to the body.
    • Traveller's thrombosis / economy class syndrome: A DVT due to being sedentary during air travel.
    • Microangiopathy Disease of capillaries in which the walls become thick and weak, and result in bleeding and decreased blood flow. One very common cause is diabetes mellitus in which microangiopathy results in diabetic nephropathy, diabetic retinopathy, and diabetic neuropathy.
    • Varicose veins Veins that have become enlarged and tortuous with failed valves, commonly in the legs. Vericose veins have cosmetic concerns, but they may become painful. Surgery and sclerotherapy are two options for treating varicose veins.
    • Vasculitis Inflammation of blood vessels (veins & arteries) with a long list of causes.
      • Aortitis Inflammation of the aorta that can be seen in giant cell arteritis, polymyalgia rheumatica, rheumatoid arthritis, syphilis and Takayasu's arteritis.
      • Behçet's disease Affects small-sized vessels that often initially presents with oral aphthous ulcers, genital ulcers and uveitis, and can be fatal from ruptured aneurysms. Pericarditis is commonly seen with Behçet's.
      • Eosinophilic granulomatosis with polyangiitis (EGPA; formerly known as Churg–Strauss syndrome) Affects small- & medium-sized vessels that often affects lungs, kidneys, & heart in those with a history of airway allergic hypersensitivity and p-ANCA antibodies.
      • Giant-cell arteritis (GCA) / Temporal arteritis Affects medium- & large-sized vessels of the head, typically branches of the external carotid artery and namely the temporal artery. Occlusion of the ophthalmic artery results in blindness. Suspicion of GCA necessitates immediate treatment with glucocorticoids and temporal artery biopsy.
      • Granulomatosis with polyangiitis (GPA) Affects small- & medium-sized vessels that often affects the lung & kidneys (RPGN) with classic saddle nose and c-ANCA antibodies.
      • IgA vasculitis (IgAV; formerly known as Henoch-Schönlein purpura) Affects small-sized vessels and produces palpable purpura and proteinuria from immunocomplex (IgA) deposition.
      • Kawasaki disease Affects medium-sized vessels mostly seen in young children with myocarditis, & pericarditis, and is the most common cause of acquired heart disease in children (results in coronary artery aneurysms). Myocardial infarction from coronary thrombosis is the most common cause of death from Kawasaki disease.
      • Thromboangiitis obliterans Affects small- & medium-sized vessels that is strongly associated with tobacco products. Pain, diminished pulses, gangrene and eventual amputation of affected hands and feet.

Procedures to counter coronary artery disease

An example of a drug-eluting stent. This is the TAXUS Express2 Paclitaxel-Eluting Coronary Stent System, which releases paclitaxel.

Coronary artery disease is not currently reversible and eventually requires surgical management if it progresses.

  • Coronary artery bypass surgery (CABG): Grafting an artery or vein from elsewhere to bypass a stenotic coronary artery. Performed by cardiothoracic surgeons, a sternotomy is performed to open the chest and then grafts are performed. Cardiopulmonary bypass may be necessary. The internal mammary artery or saphenous vein can be used as grafts. The grafts are used to provide an alternate path for blood flow around a stenosis.
  • Enhanced external counterpulsation (EECP): Pneumatically assisting the heart to move blood using inflatable cuffs on the legs.
  • Percutaneous coronary intervention (PCI) Procedures to treat stenotic coronary arteries by accessing through a blood vessel. Angioplasty in this manner is PTCA (described below) but may also involve the insertion of stents to keep vessels open.
  • Percutaneous Transluminal Coronary Angioplasty (PTCA): Insertion of a catheter through the skin ("percutaneous") into a blood vessel ("transluminal") to enlarging the lumen of a coronary artery by forcibly expanding it with a balloon ("angioplasty"), hence the name. It is a form of PCI and generally what is implied when referring to "PCI."
  • Atherectomy Enlarging the lumen of an artery by removal of atherosclerotic plaque by means of catheterization. This is in contrast to angioplasty that does not remove the plaque but merely pushes it out of the way to increase the lumen size. This method is primarily used in peripheral disease, but has been used for coronary disease as well.
  • Endarterectomy Enlarging the lumen of an artery by removal of atherosclerotic plaque by means of open surgery. This is primarily done on the carotid arteries (Carotid endarterectomy or CEA) but was first performed on the superficial femoral artery. While not performed on coronary arteries, it is mentioned here for completeness.
  • Stenting: Enlarging the lumen of an artery by forcibly expanding it with a metal wire tube by means of catheterization. Typically, the artery is expanded first through angioplasty (see PTCA above).

Devices used in cardiology

A stethoscope.
  • Stethoscope Acoustic device for hearing internal sounds including heart sounds. The stethoscope is the quintessential medical icon, regardless of specialty. Modern stethoscopes can have a diaphragm and a bell, and be sized for adults or children. In cardiology, it is primarily used to listen to heart sounds it can also be used to listen for bruits (carotid & renal for renal artery stenosis), bowel sounds, and lung sounds. Electronic stethoscopes can amplify and record sounds.
  • EKG calipers A type of divider caliper that can be used to measure intervals and compare intervals on EKGs. Special rulers can be used to measure the intervals as well.
  • Devices used to maintain normal electrical rhythm:
    • Pacemaker An implanted electrical device that replaces the heart's natural pacemaker.
    • Defibrillator Electrical devices to alter the heart's rhythm with electrical energy. As the name implies, a defibrillator is used to stop fibrillation of the heart. It can be used to cardiovert atrial fibrillation if certain conditions are met, but is mainly used to cardiovert ventricular fibrillation which is life-threatening. Contrary to popular media's use, a defibrillator cannot and should not be used for asystole (a "flatline") as it has been shown to be ineffective in restoring a rhythm. If a person is in a rhythm not convertible by a defibrillator, then cardiopulmonary resuscitation (CPR) or more advanced care should be started.
  • Devices used to maintain blood pressure:
    • Artificial heart An internal pump that wholly replaces the pumping action of the heart.
    • Cardiopulmonary bypass (CPB) / heart-lung machine: External pump to take over the function of both the heart and lungs. Commonly used in cardiothoracic surgery when the heart is being operated on for such surgeries like open valve replacement or CABG on the posterior side of the heart. The bypass machine is responsible for oxygenation of blood, removal of carbon dioxide, heating the blood (heat is lost from being outside the body) to maintain core body temperature or cooling blood for controlled hypothermia, and providing volatile anesthetics (e.g., isoflurane) if the lungs are not ventilated during bypass (the movement can be problematic while performing surgery). A cardioplegic solution is used to stop the heart from beating and combination with hypothermia reduces oxygen demand of the heart significantly (>97%) such that surgery is possible without causing damage.
    • Intra-aortic balloon pump (IABP): A balloon placed in the thoracic aorta to supplement cardiac output from the heart. It pulsates opposite to the heart such that it inflates during diastole and relaxes during systole. Deflation during systole decreases afterload (vacuum effect), thus decreasing myocardial oxygen demand, and inflates during diastole to increase diastolic pressure which increases coronary artery perfusion of the endocardium (the heart perfuses itself during diastole, not systole).
    • Ventricular assist device (VAD) Internal pump to supplement or replace the pumping action of a ventricle. Can be referred to RVAD or LVAD depending on if it's attached to the right or left ventricle.

Diagnostic tests and procedures

Cardiologists use diagrams like this: a heart with an ECG indicator

Various cardiology diagnostic tests and procedures.

Drugs

There are several classes of pharmaceutical drugs used in cardiology to manage various diseases and a lot of drugs have cardiovascular side effects.

Drugs for the cardiovascular system

Drugs that manipulate the cardiovascular system do so through several ways. The first is ion channels, which are often manipulated to manage arrhythmias. The second is receptors of various types. The third is manipulation of enzymes.

Ion channels

Ion channels are responsible for cell membrane voltage, depolarization, and repolarization. These actions lead to conduction of signals down nerves and contraction of cardiomyocytes. Perhaps the most prominent manipulation of ion channels is through antiarrhythmic agents. These agents are commonly classified by the type of ion they manipulate and named the Vaughan Williams classification:

Specifically, types I, III, & IV manipulate ion channels while the others are not.

Receptors

The adrenergic receptor is a set of receptors that are commonly manipulated. Four properties of the heart — chronotropy, dromotropy, inotropy, & lusitropy — are manipulated by adrenergic receptors. For example, the β1 receptor increases all four of these properties: chronotropy at the SA node, dromotropy through the AV node, inotropy of the cardiomyocytes through increased calcium, and lusitropy through phosphorylation of phospholamban. Catecholamines are a set of drugs and hormones that manipulate the adrenergic receptors. The natural catecholamines are norepinephrine, epinephrine, and dopamine. There are numerous other drugs (e.g., dobutamine, ephedrine, isoproterenol) that manipulate the adrenergic receptors and have variable specificity for the receptors and are, thus, used for various reasons.

Angiotensin II receptor antagonists (ARBs) block the angiotensin II receptors that are linked to hypertension and heart failure, mainly through vasodilation & heart remodeling inhibition.

Enzymes

ACE inhibitors works upstream from angiotensin II receptor antagonists and have similar effects on management of hypertension and heart failure.

Sodium nitroprusside and nitroglycerin function by causing vasodilation through nitric oxide, which manipulates cGMP levels through guanylate cyclase.

COX inhibitors (namely aspirin), warfarin, direct Xa inhibitors, direct thrombin inhibitors, heparin, low-molecular weight heparins, antibodies (e.g., abciximab), and a few others are used for anticoagulation therapy. This is important in those predisposed to blood clots (e.g., Factor V Leiden) but also for thrombus formation when an atherosclerotic plaque rupture that would, otherwise, lead to myocardial infarction.

Drugs with cardiovascular side effects

Numerous drug classes have well-known cardiovascular side effects.

  • Anesthetics As a general rule, all agents used in anesthesia have depressant effects on the cardiovascular system with notable exception of ketamine.
  • Diuretics The primary effect of diuretics is removal of intravascular volume, which then has secondary benefits to the cardiovascular system in diseases like heart failure.
  • Lithium Teratogenic effect of causing Ebstein's anomaly in mothers taking lithium.
  • Opioids Decreases blood pressure.
  • Tricyclic antidepressants (TCAs) TCAs behave like type Ia antiarrhythmics and could terminate ventricular fibrillation and decrease contractility. They can also cause tachycardia and hypotension.

Cardiology organizations

Cardiology publications

  • Acta Cardiologica
  • American Journal of Cardiology
  • Annals of Cardiac Anaesthesia
  • Cardiology
  • Cardiology in Review
  • Circulation
  • Circulation Research
  • Clinical and Experimental Hypertension
  • Clinical Cardiology
  • EP – Europace
  • European Heart Journal
  • Experimental & Clinical Cardiology
  • Heart
  • Heart Rhythm
  • International Journal of Cardiology
  • Journal of the American College of Cardiology
  • Pacing and Clinical Electrophysiology

Persons influential in cardiology

  • Robert Atkins (1930–2003) known for the Atkins diet
  • Eugene Braunwald (born 1929) editor of Braunwald's Heart Disease and 1000+ publications
  • Wallace Brigden (1916-2008) identified cardiomyopathy
  • Willem Einthoven (1860–1927) a physiologist who built the first practical ECG and won the 1924 Nobel Prize in Physiology or Medicine ("for the discovery of the mechanism of the electrocardiogram")
  • Werner Forssmann (1904–1979) who infamously performed the first human catheterization on himself that led to him being let go from Berliner Charité Hospital, quitting cardiology as a speciality, and then winning the 1956 Nobel Prize in Physiology or Medicine ("for their discoveries concerning heart catheterization and pathological changes in the circulatory system")
  • Andreas Gruentzig (1939–1985) first developed balloon angioplasty
  • Max Holzmann (1899-1994) co-founder of the Swiss Society of Cardiology, president from 1952–1955
  • Samuel A. Levine (1891–1966) recognized the sign known as Levine's sign as well as the current grading of the intensity of heart murmurs, known as the Levine scale
  • Bernard Lown (born 1921) known for being the original developer of the Defibrillator
  • Henry Marriott (1917–2007) ECG interpretation and Marriott's Practical Electrocardiography
  • Jacqueline Noonan (born 1928) discoverer of Noonan syndrome that is the top syndromic cause of congenital heart disease
  • John Parkinson (1885–1976) known for Wolff–Parkinson–White syndrome
  • Helen B. Taussig (1898–1986) founder of pediatric cardiology and extensively worked on blue baby syndrome
  • Paul Dudley White (1886–1973) known for Wolff–Parkinson–White syndrome
  • Louis Wolff (1898–1972) known for Wolff–Parkinson–White syndrome
  • Stewart Wolf (1914–2005) known for his research into the Roseto effect

See also

References

  1. Ashley, Euan A.; Niebauer, Josef (1 January 2004). "Cardiology Explained". Remedica. Retrieved 19 February 2017. {{cite journal}}: Cite journal requires |journal= (help)
  2. Lackland, DT; Weber, MA (May 2015). "Global burden of cardiovascular disease and stroke: hypertension at the core". The Canadian Journal of Cardiology. 31 (5): 569–71. doi:10.1016/j.cjca.2015.01.009. PMID 25795106.
  3. Mendis, Shanthi; Puska, Pekka; Norrving, Bo (2011). Global atlas on cardiovascular disease prevention and control (PDF) (1st ed.). Geneva: World Health Organization in collaboration with the World Heart Federation and the World Stroke Organization. p. 38. ISBN 9789241564373.
  4. "What Are the Signs and Symptoms of an Arrhythmia?". National Heart, Lung and Blood Institute. July 1, 2011. Retrieved 7 March 2015.
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