Myocardial abscess: Difference between revisions

Myocardial abscess
Myocardial abscess: Candida: Gross, natural color excellent depiction myocardial abscesses caused by Candida tropicalis. A 51yo man with acute monocytic leukemia. Image courtesy of Professor Peter Anderson DVM PhD and published with permission © PEIR, University of Alabama at Birmingham, Department of Pathology

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1] Associate Editor(s)-in-Chief: Syed Musadiq Ali M.B.B.S.[2]

overview

A cardiac abscess is a suppurative infection of the myocardium, endocardium, native or prosthetic valve tissue. Similar to other abscesses, it develops either by dissemination from a distant source such as bacteremia or sepsis or by direct extension of a pre-existing cardiac infective focus. Infective endocarditis has long been identified as the main cause of the latter. Although the incidence of cardiac abscesses continues to be investigated, it is presumably higher than noted postmortem and is of great importance when deciding the prognosis and management of patients. A single organism causes cardiac abscesses, usually Staphylococcus aureus or Escherichia coli. Less typically, polymicrobial abscesses have been noted. Important complications of a cardiac abscess, whether alone or with valve tissue, are conduction abnormalities on electrocardiogram (ECG). The incidence of perivalvular abscess among patients with infective endocarditis is between 30% to 40%, with the aortic valve having a higher predisposition than the mitral valve and annulus. Native aortic valve endocarditis, usually located in a weak part of the annulus near the atrioventricular node (AV), clearly demonstrates the anatomic predisposition and exemplifies why abscesses and heart block presents as frequent sequelae. Perivalvular abscesses are also more common with prosthetic valves. In this case, the annulus instead of the leaflet is usually the primary site of infection. The degree of conduction disruption, therefore, depends on the extent of the involvement of the conduction system and is more commonly seen in perivalvular aortic abscesses. Additionally, the severe extension of perivalvular infection can also result in extrinsic coronary compression, or disruption, leading to an acute coronary syndrome. Thus far, only aortic valve involvement and current IV drug use have been prospectively identified as independent risk factors for a perivalvular abscess. Any patient with a cardiac abscess, regardless of all other factors, has an increased risk of embolization, morbidity, and mortality.

Historical perspective

• In 1933, Cossio and Berconsky reported a case of coronary occlusion with myocardial infarction in which an abscess was found in the infarcted area at post-mortem examination.^[1]

Pathophysiology

Myocardial abscess is a pus-containing infection of the endocardium, myocardium, prosthetic or native valves, perivalvular structures or the cardiac conduction system. ^{[2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15]}

Pathogenesis

• Development of infective endocarditis and subsequent myocardial abscess involves interaction of multiple factors, as follows:
  • Vascular endothelium
  • Hemostatic mechanisms
  • Host immune system
  • Gross anatomic abnormalities in the heart
  • Surface properties of microorganisms
  • Extracardiac events that introduce bacteremia
• The rarity of endocarditis despite the relatively high prevalence of transient asymptomatic and symptomatic bacteremia suggests that the intact endothelium is resistant to infection.If the endothelium on the valve surface is damaged, hemostasis is stimulated and the deposition of platelets and fibrin complex begins. This complex, called non-bacterial thrombotic endocarditis (NBTE), is more susceptible to bacterial colonization when bacteremia develops from an extracardiac source that allows the organisms access to the NBTE.
• The intracardiac consequences of endocarditis range from trivial, characterized by an infected vegetation with no attendant tissue damage, to catastrophic, when infection is locally destructive or extends beyond the valve leaflet. Distortion or perforation of valve leaflets, rupture of chordae tendineae, and perforations or fistulas may result in progressive congestive heart failure (CHF). Infection, particularly that involving the aortic valve or prosthetic valves, may extend into paravalvular tissue and result in myocardial abscesses and persistent fever due to the infection's unresponsiveness to the antibiotic; disruption of the conduction system, with electrocardiographic conduction abnormalities; and clinically relevant arrhythmias or purulent pericarditis.

Post-mortem examination,of myocardial abscess, showed following pathological changes:

Macroscopic finding

• The cardiac area was greatly enlarged, and when the pericardial sac was opened, it was found to contain 600 cc of partially clotted blood.
• The parietal pericardium was blood tinged but smooth and glistening throughout.
• The epicardium was normal in appearance over the anterior aspect of the heart but glassy and coated with a thin layer of fibrinous exudate in the posterior aspect.
• The tear involved the entire thickness of the myocardium so that a probe could be passed through it into the left ventricular cavity without resistance.
• The surrounding myocardium was infiltrated by blood and flabby in consistence in an area about 6 cm in diameter.
• Externally and on cut section this area displayed a variegated tinge from reddish brown to yellowish gray.
• Clusters of honey-combed pockets, each pin head in size or larger, were scattered throughout this area.
• Grossly, these pockets were suggestive of small abscesses and contained a thick, golden-yellow material.
• The coronary arteries were diffusely narrowed, with atheroma formation and calcification.
• The right coronary artery was occluded a short distance below its main stem by a firmly adherent, friable, yellowish-brown thrombotic mass.
• Examination of the cardiac chambers revealed a laminated thrombus on the posterior aspect of the left ventricle^[16].

Images courtesy of Professor Peter Anderson DVM PhD and published with permission © PEIR, University of Alabama at Birmingham, Department of Pathology

Microscopic finding

• Myocardial infarct the microscopical sections showed an almost complete obliteration of the normal architecture.
• The muscle fibers displayed loss of striations and of nuclear patterns and seemed fused together into an amorphous mass of eosinophilic material.
• The capillaries in the area were congested, and extravasated red cells were present throughout.
• There was a concomitant marked infiltration of polymorphonuclear leukocytes either scattered or in clusters, and this extended into the epicardium.
• The leukocytes were not well preserved; the majority were fused together or showed karyorrhexis and karyolysis resulting in a scattering of cellular débris.
• The endocardial mural thrombus consisted of amorphous eosinophilic material and was interspersed with white cells and cellular débris.
• The mural thrombus merged indistinctly into the adjacent necrotic myocardium.
• The thrombotic mass in the lumen of the right coronary artery showed incipient organization with intimal histiocytic and fibroblastic proliferation and atheromatous changes.

Causes

• Cardiac abscesses are rare in the United States. Cardiac abscesses are most commonly thought to occur primarily by the extent of a pre-existing cardiac infection, as it is with the case of infective endocarditis (IE). Secondary causes of cardiac abscess are believed to be due to bacteremia (persistent or transient) without a known cardiac source, as well as susceptible heart tissue soon after myocardial infarction (MI), or prosthetic valve disease, usually in the setting of bacteremia. Staphylococcus aureus is the most common pathogen when the disease is present.The following are organisms noted to be involved in cardiac abscess formation:
  • Staphylococcus aureus
  • Haemophilus species
  • Enterococci
  • Escherichia coli
  • Beta-hemolytic streptococci
  • Streptococcus pneumoniae

Endocarditis

• The most common clinical setting for myocardial abscess is as a complication of endocarditis involving either native or prosthetic valves.
• In a review of 40 cases of infective endocarditis, Gonzalez Vilchez et al (1991) found that 67.5% (27 cases) involved native valves.
• The most common site was the aortic valve, followed in descending order by the ventricular septa, mitral valves, and papillary muscles.
• Approximately one third of cases involved the base of the aortic valve.
• Staphylococcus was the most prevalent species involved, isolated from one third of all cases.
• Prosthetic valve abscess comprised 34% of cases, and 50% of these were caused by staphylococcal infection.
• An infected coronary artery stent may be a rare source of multiple myocardial abscesses.

Bacteremia

• In the past, the most common setting for myocardial abscess was generalized bacteremia, as described in older autopsy reports.
• Sanson and colleagues (1963) described 23 cases, 21 of which exhibited multiple abscesses in lungs, kidneys, brain, and myocardium. Myocardial abscesses were small in these patients, and the authors postulated that the patients died too early to develop larger abscesses.

Myocardial infarction

• Myocardial abscess may develop at the site of a myocardial infarction (MI) but usually develops in the setting of bacteremia.
• Cossio et al (1933) reported a myocardial abscess at the site of an acute MI.
• In the case records of the Massachusetts General Hospital, Castleman and McNeely (1970) reported a secondary infection within an inferior wall MI in a patient with Bacteroides bacteremia following genitourinary surgery and placement of an infected indwelling catheter.
• In a review of 13 cases of myocardial abscess in acute MI, Weisz and Young (1977) found bronchopneumonia to be the probable source in 4 cases, gastrointestinal and renal sepsis in 2, and no definable source in the others. Organisms included Staphylococcus aureus, Clostridium perfringens, Bacteroides species, Escherichia coli, beta-hemolytic streptococci, and Streptococcus pneumoniae, in order of decreasing frequency.
• The propensity of cardiac muscle to develop myocardial abscess in the setting of acute MI and septicemia may be due to the presence of necrosis of the muscular fibers and surrounding inflammatory exudates, decreased or absent perfusion, and lack of cell-mediated immunity secondary to decreased blood flow. Such myocardium also appears to be at a greater risk of rupture than healthy myocardium (7-fold higher per Weisz and Young [1977], with a catastrophic outcome.

Other settings associated with myocardial abscesses that have been reported in the literature include the following:

• Trauma
• Deep penetrating wounds
• Deep burns
• Infected pseudoaneurysms
• Suppurative pericarditis
• Infected transplanted hearts
• Extension from sternal abscess
• HIV-associated myocarditis and suppuration
• Parasitic infections
• Infection of a left ventricular aneurysm or tumor

Epidemiology and Demographics

• Myocardial abscess rarely occurs in the United States.
• Murdoch et al (2009) published a contemporary report on the presentation, etiology, and outcome of infective endocarditis in a large patient cohort from multiple locations worldwide.
• They analyzed a prospective cohort study of 2781 adults (median age 57.9 y) with definite infective endocarditis (72.1% of the native valve) who were admitted to 58 hospitals in 25 countries over a 5-year period.
• Seventy-seven percent of the patients presented early in the disease course (ie, within the first month), with few of the classic clinical hallmarks of infective endocarditis. Recent health care exposure was found in one quarter of the patients.
• S aureus was the most common pathogen found (31.2% of patients). The mitral valve was found to be infected in 41.1% of cases and the aortic valve in 37.6%. The common complications included stroke (16.9%), embolization other than stroke (22.6%), heart failure (32.3%), and intracardiac abscess (14.4%). Surgical therapy was performed in 48.2% of the patients, and in-hospital mortality rates were high (17.7%).
• Several factors portended a high fatality risk, including prosthetic valve involvement (odds ratio [OR], 1.47), increasing age (OR, 1.30), pulmonary edema (OR, 1.79), S aureus infection (OR, 1.54), coagulase-negative staphylococcal infection (OR, 1.50), mitral valve vegetation (OR, 1.34), and paravalvular complications (OR, 2.25). Streptococcus viridans infection (OR, 0.52) and surgery (OR, 0.61) were associated with a decreased fatality risk. In summary, in the early 21st century, infective endocarditis continues to be more often an acute disease, characterized by a high rate of S aureus infection and an unacceptably high mortality rate. [7]
• The incidence of infective endocarditis remained relatively stable from 1950-1987, at approximately 4.2 cases per 100,000 patient-years. [8] During the early 1980s, the yearly incidence of infective endocarditis was 2 cases per 100,000 population in the United Kingdom and Wales and 1.9 cases per 100,000 population in the Netherlands. A higher incidence was noted from 1984-1990; 5.9 and 11.6 episodes per 100,000 population were reported from Sweden and metropolitan Philadelphia, respectively. [9]
• Infections involving prosthetic valves, especially mechanical prostheses, in which the infection is entirely periannular, often extend into the adjacent myocardium, resulting in paravalvular abscess formation and partial dehiscence of the prosthetic valve with paravalvular regurgitation.
• Among 85 patients with endocarditis involving a mechanical prosthesis, annulus invasion and myocardial abscess were noted in 42% and 14% of patients, respectively. [10]
• Ben Ismail et al (1987) found annulus infection and valve dehiscence in 38 of 41 (82%) infected mechanical valves examined at surgery or autopsy. [11]
• Myocardial abscess formation profoundly worsens the prognosis in patients with infective endocarditis.
• The mortality rate associated with S aureus infective endocarditis is 42% overall. If treated with antibiotics only, the mortality rate is 75%, while a regimen that combines antibiotics and surgery reduces the mortality rate to 25%.
• The presence of an intracardiac abscess or complications increases the mortality rate 13.7-fold.
• Myocardial abscess has no substantial racial predilection. However, the condition may be more prevalent in African Americans in urban settings.
• The relative risk ranges from 3.5-8.2. Because mitral valve prolapse (MVP) is more common in women than in men, myocardial abscess is also more common in women than in men. Among persons who abuse intravenous drugs, myocardial abscess is more prevalent in men (65%-80%).
• In adults, MVP has emerged as a prominent predisposing structural abnormality that may account for 7%-30% of cases of nonvalvular endocarditis (NVE). However, myocardial abscess developing in such cases is exceedingly rare.
• Involvement of cardiac structures with endocarditis and myocardial abscess mainly depends on the incidence of various underlying structural heart conditions among different age groups.
• The incidence of infective endocarditis among hospitalized children ranges from 1 case in 4500 to 1 case in 1280. In the Netherlands, incidences of 1.7 cases per 100,000 persons in boys and 1.2 cases per 100,000 persons in girls have been noted. [8] In neonates, the rate has been increasing because of contaminated intravenous lines and the increased use of right-sided heart catheters. Infective endocarditis usually involves the tricuspid valve and is caused primarily by S aureus. Congenital heart defects are predisposing conditions in toddlers and older children.
• In adults, MVP is the most common structural heart abnormality associated with infectious endocarditis, found in as many as 7%-30% of patients with NVE, and the risk increases in patients older than 45 years.
• Those who abuse intravenous drugs are increasingly susceptible (2%-5% per patient-year).

Risk Factors

Any septic focus can theoretically lead to myocardial abscess. These are the primary foci in order of frequency of causing myocardial abscess.

• Renal infections:

Spread from the urinary tract is the most common cause.

• Gastrointestinal diseases:

Spread from the gastrointestinal tract is the second common cause (e.g. perforated appendix, perforated colon cancer, diverticulitis ,and cohn’s disease.)

• Bone infection:

e.g. pott's disease or osteomyelitis

• Hematogenous spread:

From distant septic foci.

• Iatrogenic:

Following chest abdominal or pelvic surgery.

Any condition compromising the immune system is a risk factor for developing myocardial abscess. The following were the risk factors in observed patients. ^[17]

• Diabetes Mellitus
• Cirrhosis
• Malignancy
• Remote infection
• Glucocorticoids administration
• Chronic renal failure

Screening

According to the USPSTF, screening for retroperitoneal abscess is not recommended.

Natural History, Complications and Prognosis:

Natural history

If left untreated, myocardial abscess may cause heart block, septal rupture with very high incidence of morbidity and mortality.

Complications :

The following are potential complications of myocardial abscess:

• Myocardial perforation
• Significant clinical deterioration
• Worsening CHF
• Worsening heart sounds and murmurs
• New-onset valvular regurgitation (100% of cases) [12]
• Poor response to antibiotics
• Development of conduction defects or progression of heart block, such as bundle-branch block and atrioventricular block (45%) [2]
• Sudden onset of complete heart block or Mobitz type II block (highly specific)
• Type of valve involvement, eg, aortic valve endocarditis (40%-85%)
• Miscellaneous (severe recurrent ventricular arrhythmias, pericarditis [uncommon], infection of the prosthetic valves, right-sided endocarditis in patients with congenital heart disease)

Prognosis

• Depending on the extent of the abscess at the time of diagnosis, the prognosis may vary.
• The condition carries a very high mortality ranging from 30% to 75% without treatment. To reduce the morbidity and mortality of this disorder, it is imperative that a structured approach is developed to make an early diagnosis and begin treatment.[10]
• Even with therapy, mortality rates of 5% to 15% are not uncommon.

Diagnosis

History

• A detailed history should be obtained from the patient presenting with infective endocarditis and chest pain.
• Patients who have longstanding persistent bacteremia and who do not respond to antibiotic therapy.
• Myocardial abscess is more prevalent in the period following mechanical interventions or surgery and in patients with HIV/AIDS-related myocarditis.

Symptoms

One must bear in mind certain constellations of symptoms that may raise the suggestion of myocardial abscess. For example, fever is the most common symptom, presenting in 80%-85% of patients. It is absent in some patients who are elderly; those who have CHF, severe debility, or chronic renal failure; and in patients with coagulase-negative staphylococcal infection and abscess. Another characteristic symptom is chills, which occurs in 42%-75% of cases.

Common symptoms:

• Fever is the most common complaint and usually it is more than 101 F.
• Constitutional symptoms : chills, malaise, anorexia and weight loss.

Less common symptoms:

• Myalgia
• Arthralgia
• Abdominal pain
• Back pain
• Confusion
• Sweats

Physical Exam

General Appearance

Physical examination findings commonly encountered in myocardial abscess are mainly due to the underlying infective endocarditis. These include the following: Fever, Tachycardia, Murmur, especially changing or new murmur, Neurological abnormalities, Embolic event, Splenomegaly, Clubbing, Peripheral manifestations,Osler nodes, Splinter hemorrhages, Petechiae, Janeway lesions, Retinal lesions (Roth spots),Widening pulse pressure, especially with involvement of the aortic valve and progression of aortic regurgitation The patient is usually fatigued & looking ill due to the preexisting risk factor. In advanced cases with septicemia, the patient may be drowsy with decreased level of consciousness.^[17]

Vital signs

• Fever
• Tachycardia
• Tachypnea
• Hypotension (if patient is presenting with shock)

Chest Examination

• Chest tenderness is often present (localized).
• Alteration of heart sounds and murmurs (new-onset valvular regurgitation [100% of cases]) [12]

Lab Findings

• Complete blood cell count findings commonly are abnormal.
• Anemia with normochromic normocytic red cell indices is present.
• A low serum iron level is also observed. A low serum iron-binding capacity is observed in 70-90% of patients.
• Anemia worsens with increased duration of illness.
• In subacute endocarditis, the white blood cell count is usually normal.
• In contrast, a leukocytosis with increased segmented granulocytes is common in acute endocarditis and myocardial abscess.
• The erythrocyte sedimentation rate (ESR) is elevated (on average approximately 55 mm/h) in almost all patients with endocarditis and myocardial abscess; the exceptions are those with CHF, renal failure, or disseminated intravascular coagulation.
• Blood cultures are the crucial laboratory tests for confirming the diagnosis of the underlying endocarditis.
• Urinalysis results are often abnormal, even when renal function remains normal. Proteinuria and microscopic hematuria are noted in 50% of patients. Urinalysis also plays a standard role in the evaluation of azotemia, which is frequently associated with myocardial abscess.

Radiological Findings

• In the past, most cases of myocardial abscess were found during autopsy. however, detection of myocardial abscess can now be achieved antemortem using multiple noninvasive imaging modalities, including transthoracic echocardiography (TTE) and transesophageal echocardiography (TEE), indium In 111 radionuclide scintigraphy, computed tomography (CT) scan, and magnetic resonance imaging (MRI).

Chest radiography

• chest radiography is perform to look for associated pulmonary infection.

Chest radiographic findings help assess for CHF.

Transthoracic echocardiography

• TTE helps evaluate patients in whom endocarditis or myocardial abscess is suggested clinically. Findings frequently allow the morphologic confirmation of infection and increasingly aid in making decisions regarding management.
• One must perform an echocardiographic evaluation in all patients suspected of having an intracardiac or pericardial infection, including those with negative blood culture findings.
• TTE has a sensitivity of 23% and specificity of 98.6%.
• According to Ellis et al (1985), the following 5 criteria are 86% sensitive and 88% specific for myocardial abscess: [13]

• • Evidence of prosthetic valve rocking
  • Aneurysmal dilatation of the sinus of Valsalva
  • Posterior aortic root thickness greater than 10 mm
  • Perivalvular density in the septum of greater than 14 mm
  • The presence of "echo-free space" - Very specific but found relatively infrequently

• Walker et al report a rare case of a myocardial abscess in valvular endocarditis that was difficult to assess with 2-dimensional TTE; however, real-time 3-dimensional contrast TTE allowed visualization of the full extent of the defect and its precise anatomical location, prior to successful surgical resection. [14]

Transesophageal echocardiography Although many patients with NVE involving the aortic or mitral valve can be adequately assessed using TTE, TEE with color flow and continuous pulsed Doppler is the state-of-the-art technique. Doppler and color-flow Doppler or contrast 2-dimensional echocardiography helps optimally define fistulas and abscess pockets and extensions. See the image below. TEE has a sensitivity of 87% and specificity of 94.6%. Patients in whom an abscess is suggested but has not been detected using TEE should undergo MRI, including magnetic resonance angiography. ADD PIC Scintigraphy Indium In 111 leukocyte scintigraphy is especially useful in prosthetic valve endocarditis, in which echocardiography shows too much scatter.

A few milliliters of venous blood is drawn and mixed with an anticoagulant solution. The white blood cells are separated and labeled with radioactive isotope111 In, centrifuged, resuspended in isotonic sodium chloride solution, and reinjected into the patient. Images are then obtained with a gamma-ray camera within 16-24 hours. The viable radioactive leukocytes potentially accumulate in the areas of inflammation or abscess. Obtain oblique views to avoid overshadowing by sternal accumulation.

The need for111 In scintigraphy is very low if TEE is used.

MRI This is a good modality for helping delineate myocardial abscess. However, the portability and excellent resolution of echocardiography make it more practical than MRI.

CT scan Only anecdotal reports of diagnosis are available. It is not very sensitive.

Intraoperative echocardiography Although invasive, small abscesses can be detected in the operating room by means of intraoperative echocardiography, which may enable the operating surgeon to drain the abscess effectively. Electrocardiography New-onset and persistent electrocardiographic conduction abnormalities may be observed. Gradual PR prolongation may be observed, and it may suggest development of valve ring abscess.

Although not a sensitive indicator of perivalvular infection or abscess (28%), these findings are relatively specific (85-90%). See the image below. Tests of immune system stimulation Tests results may show disease activity, but the tests are costly and not very efficient for diagnosis or monitoring response to therapy

These may include testing of circulating immune complexes, rheumatoid factor, quantitative immune globulin, cryoglobulins, and C-reactive protein.

Serologic tests Serological test findings are used to evaluate cardiac sepsis in which blood culture findings are negative.

Tests to detect antibodies to ribitol teichoic acids from staphylococci may help distinguish uncomplicated S aureus bacteremia from that associated with cardiac involvement.

These tests have not been used in clinical applications because of their lack of adequate specificity or predictive value. Cardiac catheterization may add very little to the imaging studies and is not recommended unless coronary angiography is needed for patients undergoing valve surgery who also may have significant coronary artery disease.

References

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