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Endocarditis

Endocarditis is an inflammation of the endocardium, the inner lining of the heart's chambers and valves. It can be classified as infective, caused by microorganisms such as bacteria or fungi entering the bloodstream and forming vegetations on damaged heart tissue, or non-infective, associated with conditions like autoimmune diseases (e.g., Libman–Sacks endocarditis in systemic lupus erythematosus) or hypercoagulable states (e.g., nonbacterial thrombotic endocarditis). Infective endocarditis, the most common form, is the primary focus of this article and can lead to impaired cardiac function, systemic embolization, and high mortality if untreated. Infective endocarditis is relatively rare, with an incidence of approximately 3 to 15 cases per 100,000 population annually as of the early 2020s, though rates continue to increase due to aging populations, expanded use of cardiac devices, and rising intravenous drug use. It predominantly affects individuals with predisposing heart conditions, such as damaged or prosthetic valves and congenital defects. Additional risk factors include advanced age, male sex, injection drug use, intravascular catheters, poor , and certain invasive procedures. is further classified by acuity (acute vs. subacute), valve type (native vs. prosthetic), and location (left-sided vs. right-sided). Common pathogens include and species, which form biofilms on endothelial surfaces. Symptoms range from subacute (fever, fatigue over weeks) to acute (rapid ). Diagnosis uses modified criteria, blood cultures (positive in 70-80% of cases), and . involves prolonged s and in 25-50% of cases. In-hospital mortality is 15-20%, higher with complications. Prevention includes targeted antibiotic prophylaxis and risk factor modification.

Overview

Definition

Endocarditis is an of the , the inner lining of the heart's chambers and valves. This condition often involves the heart valves themselves, where the inflammatory process can lead to structural damage. The term endocarditis and its key features were first described in the early by Jean-Nicolas Corvisart, who in 1806 coined the word "vegetations" to characterize the soft excrescences observed on heart valves during autopsies of affected patients. Building on these observations, the modern clinical understanding of the disease advanced significantly through the work of in the late , particularly his 1885 Gulstonian Lectures, which differentiated acute and subacute forms and emphasized its infectious nature. A hallmark of endocarditis is the development of vegetations—friable masses composed primarily of , platelets, inflammatory cells, and, in infective cases, microorganisms—that adhere to the endocardial surface. These vegetations may cause valve dysfunction through regurgitation or , embolization of fragments to distant organs such as the or kidneys, and dissemination of leading to systemic complications. Endocarditis encompasses both infective and noninfective forms, though the former predominates in clinical practice.

Classification

Endocarditis is broadly classified into infective and noninfective forms based on , with further subdivisions reflecting clinical course, associated conditions, and diagnostic challenges. , the most common type, is subdivided into acute and subacute categories. Acute presents with rapid onset over days to weeks, often caused by aggressive pathogens such as , leading to severe systemic symptoms and high mortality if untreated. In contrast, subacute has an insidious progression over weeks to months, typically involving less virulent organisms like viridans group streptococci, and is more likely to occur on previously damaged valves. Noninfective endocarditis encompasses sterile vegetations without microbial involvement, arising from hypercoagulable states, immune-mediated processes, or . Marantic endocarditis, also known as nonbacterial thrombotic endocarditis, is characterized by small, sterile fibrin-platelet vegetations, often associated with underlying malignancies such as adenocarcinomas of the , , or , or chronic wasting diseases; these lesions frequently embolize to distant organs. Libman-Sacks endocarditis, a form of verrucous endocarditis, features wart-like vegetations on valve surfaces due to immune complex deposition and is classically linked to systemic lupus erythematosus, though it may also occur in ; unlike infective forms, it rarely causes significant valvular dysfunction but can lead to regurgitation. Culture-negative endocarditis represents 5-30% of infective cases where standard blood cultures fail to identify a , complicating diagnosis and management. This subtype often results from prior exposure sterilizing cultures, fastidious organisms such as the HACEK group (Haemophilus, Aggregatibacter, Cardiobacterium, Eikenella, Kingella), or nonbacterial causes like or species; advanced diagnostics like or are essential for identification. Prosthetic valve endocarditis is distinguished by timing relative to valve implantation, influencing microbiology and prognosis. Early prosthetic valve endocarditis, occurring within 6 months after valve implantation, is typically nosocomial, involving skin flora like coagulase-negative staphylococci or Staphylococcus aureus, and carries a higher risk of perivalvular complications due to surgical site involvement. Late prosthetic valve endocarditis, more than 6 months after implantation, resembles community-acquired native valve disease with pathogens such as streptococci or enterococci, though staphylococci remain common.

Etiology and Risk Factors

Infectious Causes

is predominantly caused by microbial infections, with accounting for the vast majority of cases, estimated at over 90% worldwide. Among these, gram-positive organisms such as staphylococci, streptococci, and enterococci are responsible for approximately 80% of infections, reflecting their prevalence in transient bacteremia events. Fungal and other rare pathogens contribute to the remainder, often in specific high-risk populations, and are associated with more aggressive disease courses due to diagnostic challenges and treatment resistance. Bacterial pathogens dominate the etiology, with Staphylococcus aureus emerging as the most common cause, implicated in about 30% of cases in developed countries and often leading to acute, destructive forms of the disease. This organism typically originates from or contaminated intravenous lines, particularly in patients with healthcare-associated infections or intravenous drug use. The viridans group streptococci, part of normal oral flora, are responsible for roughly 20-30% of cases and are classically linked to subacute presentations following dental procedures or poor . Enterococci, accounting for 10-15% of infections, frequently arise from gastrointestinal or genitourinary sources, such as invasive procedures or underlying bowel pathology. The HACEK group (Haemophilus, Aggregatibacter, Cardiobacterium, Eikenella, and Kingella species), comprising slow-growing, fastidious gram-negative bacilli from oropharyngeal sources, cause 3-10% of cases and were historically a leading cause of culture-negative endocarditis before advanced diagnostics. Fungal causes are rare, representing only 1-5% of all infective endocarditis cases, but carry high mortality rates exceeding 50% due to their propensity for large vegetations and embolic complications. species, particularly C. albicans, are the most frequent fungal pathogens, involved in over 50% of fungal endocarditis and often associated with intravenous drug use, indwelling catheters, or prolonged exposure in critically ill patients. species rank second, typically affecting immunocompromised individuals or those with prosthetic valves, and are linked to disseminated infections from pulmonary sources. Other rare pathogens include intracellular bacteria such as , the agent of endocarditis, which accounts for up to 20% of culture-negative cases in endemic areas and stems from exposure to infected or unpasteurized . Bartonella species, notably B. henselae (from cat scratches) and B. quintana (from body lice in homeless populations), cause 5-10% of culture-negative endocarditis and present insidiously with vascular complications. Mycobacteria, such as or nontuberculous species like M. chimaera, are exceptionally uncommon, primarily affecting immunocompromised patients and often linked to contaminated medical devices or disseminated . These microorganisms typically gain access to the bloodstream via portals of entry that facilitate transient bacteremia or , allowing seeding on damaged endocardial surfaces. Common sources include dental manipulations for oral streptococci, intravenous for staphylococci and fungi, intravascular catheters for nosocomial pathogens, and or for S. aureus. Gastrointestinal or genitourinary interventions serve as entry points for enterococci, while HACEK and rare pathogens often involve oropharyngeal or environmental exposures. This classification into acute (virulent pathogens like S. aureus) and subacute (less virulent, like ) forms underscores the role of pathogen aggressiveness in disease progression.

Noninfectious Causes

Noninfectious endocarditis encompasses a range of sterile inflammatory processes affecting the , primarily driven by immune-mediated mechanisms, hypercoagulability, or underlying systemic diseases, rather than microbial invasion. These conditions lead to the formation of vegetations composed of , platelets, and inflammatory cells without bacterial or fungal elements, often resulting in valve dysfunction or . Unlike infectious forms, noninfectious endocarditis typically lacks systemic signs of infection such as fever and positive blood cultures, though it can mimic infective presentations through valvular regurgitation or embolic complications. A prominent autoimmune-related cause is Libman-Sacks endocarditis, most commonly associated with systemic lupus erythematosus (SLE). In this condition, sterile verrucous vegetations develop predominantly on the mitral and aortic valves, consisting of immune complex deposits, , and hematoxylin bodies, which can lead to valve thickening, regurgitation, or . These lesions are often asymptomatic but may contribute to cardiovascular morbidity in SLE patients, with prevalence reported in up to 10-15% of cases among those with the disease. The pathogenesis involves antiphospholipid antibodies and complement activation, distinguishing it from infectious vegetations. Malignancy-associated noninfectious endocarditis, known as nonbacterial thrombotic endocarditis (NBTE) or marantic endocarditis, is frequently linked to advanced adenocarcinomas, particularly of the , , or . It features small, sterile fibrin-platelet vegetations on valve closures, which are highly prone to systemic , affecting up to 1-2% of cancer patients at . The underlying hypercoagulable state, driven by tumor-related procoagulant factors and endothelial damage, promotes formation without , often presenting with embolic strokes or peripheral ischemia rather than overt cardiac symptoms. Other sterile forms of endocarditis arise in hypercoagulable or inflammatory states, including (), where recurrent and valve lesions occur due to autoantibodies against phospholipids, leading to Libman-Sacks-like vegetations in 30-40% of cases. Flares of rheumatic heart disease can also cause sterile valvulitis with fibrinous exudates, exacerbating prior valvular damage. Additionally, disseminated intravascular coagulation (DIC) in conditions like or may trigger endocardial thrombi through widespread coagulopathy, though these are less specific to the heart. These etiologies share a lack of microbial involvement, with relying on exclusion of and identification of the underlying disorder.14528-8/fulltext)

Predisposing Risk Factors

Predisposing factors for endocarditis encompass a range of structural, behavioral, , and demographic elements that heighten susceptibility to endocardial by promoting conditions favorable for microbial and . These factors often involve underlying vulnerabilities in the cardiovascular system or , leading to an estimated 10- to 25-fold increased in affected individuals compared to the general . Structural heart abnormalities represent the most significant predisposing category, accounting for up to 75% of cases in some cohorts. Pre-existing valve damage from conditions such as creates turbulent blood flow and endothelial injury, facilitating bacterial attachment. Congenital defects, including , further elevate risk by altering valve hemodynamics and promoting calcification or regurgitation. Prosthetic valves, whether mechanical or bioprosthetic, introduce foreign material that serves as a nidus for infection, with prosthetic valve endocarditis comprising 20-30% of all cases and carrying higher mortality. Behavioral risks also play a critical role, particularly intravenous drug use, which is associated with 10-20% of endocarditis cases and predominantly affects the right-sided valves due to direct injection of contaminated substances into the venous circulation. Poor dental hygiene contributes through recurrent transient bacteremia from oral flora, with studies showing that individuals with gingival disease experience up to 5 times higher rates of bacteremia following routine oral activities like toothbrushing. Medical conditions that impair immune function or involve invasive procedures substantially increase vulnerability. Immunosuppression from HIV infection heightens risk, especially in those with low CD4 counts (<200 cells/μL), where endocarditis prevalence can reach 6-34% among intravenous drug users. Diabetes mellitus compromises host defenses and endothelial integrity, doubling the odds of infection in susceptible patients. Chemotherapy-induced immunosuppression further exacerbates this by neutropenia and mucosal barrier disruption. Chronic kidney disease requiring dialysis poses a 40-60 times greater risk due to frequent vascular access and uremia-related immune dysfunction. Recent cardiac surgery, within the prior 6-12 months, elevates incidence through surgical site healing and prosthetic implantation. Demographic factors influence overall susceptibility, with endocarditis incidence being 2-3 times higher in males, attributed to greater prevalence of behaviors and structural heart disease. The elderly population (>60 years) experiences elevated rates, up to 150-300 cases per million annually, owing to age-related degeneration and comorbidities. Indwelling catheters and pacemakers or implantable cardioverter-defibrillators introduce biofilm-forming surfaces, increasing device-related endocarditis by 1-2% per year of implantation. These factors collectively damage the endocardial surface, enabling as detailed in the of endocardial injury.

Pathophysiology

Mechanisms of Endocardial Damage

Endocardial damage in infective endocarditis typically begins with disruption of the endothelial lining, often due to turbulent blood flow over abnormal cardiac structures such as damaged or prosthetic valves. This hemodynamic stress causes denudation of the endothelium, exposing underlying subendothelial components like collagen and von Willebrand factor (vWF).00303-8/fulltext) The exposure of these matrix proteins initiates platelet adhesion and activation, leading to the formation of a sterile platelet-fibrin thrombus on the valve surface. This initial nonbacterial thrombotic endocarditis (NBTE) provides a nidus for further microbial colonization.00303-8/fulltext) During episodes of bacteremia, circulating microorganisms from transient infections adhere preferentially to these damaged sites. Pathogens such as utilize surface adhesins, including fibronectin-binding proteins (FnBPs), to bind exposed and within the , facilitating stable attachment despite high shear forces. This adhesion is enhanced on inflamed or injured , where upregulated host proteins further promote bacterial docking. Host immune responses exacerbate local endocardial injury through activation of complement and release of pro-inflammatory . Bacterial components trigger receptors on endothelial cells, platelets, and leukocytes, leading to complement deposition and cytokine production (e.g., IL-6, TNF-α), which amplify inflammation and endothelial permeability. In susceptible individuals, such as those with predisposing valvular abnormalities, this inflammatory cascade promotes ongoing tissue damage. In high-risk patients, repeated microtrauma from persistent nonlaminar flow contributes to chronic endothelial injury and recurrent formation. Over time, this progressive damage creates a vulnerable environment for persistent bacterial seeding, particularly in the context of underlying cardiac conditions that sustain turbulent .

Formation of Vegetations

Vegetations in endocarditis form as a consequence of endothelial injury, where an initial nidus develops on the damaged endocardial surface, serving as a site for subsequent deposition and microbial adherence. This process begins with the exposure of subendothelial , which triggers platelet adhesion and activation, leading to the formation of a platelet-fibrin . In infective cases, circulating microorganisms adhere to this , initiating . The structure of vegetations consists of layered masses anchored to cardiac , primarily composed of platelets, , inflammatory cells such as neutrophils and macrophages, and, in , dense aggregates of microorganisms embedded within the matrix. These masses form irregular, amorphous excrescences that adhere firmly to the valvular , often on the low-pressure side of the leaflets. In mature vegetations, erythrocyte debris and cellular contribute to the heterogeneous composition, creating a protective biofilm-like for pathogens in infectious forms. Growth of vegetations occurs through dynamic interactions between host responses and microbial factors, with the initial nidus expanding via continuous cycles of bacterial replication and host-mediated thrombus deposition. Bacteria within the vegetation produce virulence factors that promote further platelet aggregation and inhibit phagocytosis, allowing the mass to enlarge progressively over days to weeks. This iterative process results in vegetations that can reach several millimeters in size, depending on the pathogen's aggressiveness and the host's immune response. Complications arising from vegetations include fragmentation, where portions break off to form septic emboli that disseminate to distant organs such as the , lungs, or , potentially causing or formation. Additionally, the destructive action of microbial enzymes and toxins within the vegetation can erode valvular tissue, leading to and resultant valvular regurgitation. These events contribute significantly to the morbidity of endocarditis. Vegetations differ by endocarditis type: in acute , often caused by highly virulent pathogens like , they are typically larger (often exceeding 10 mm) and friable, increasing embolic risk, whereas in noninfective forms such as nonbacterial thrombotic endocarditis, they are typically small sterile masses, often less than 1 cm but ranging up to several centimeters, composed primarily of and platelets without microorganisms, and usually located along closure lines.

Clinical Presentation

Symptoms

Patients with endocarditis often experience a spectrum of symptoms that reflect , cardiac involvement, and potential embolic complications, with presentations differing between infectious and noninfectious forms. In , constitutional symptoms predominate and include persistent fever typically exceeding 38°C, , profound , and unintentional , often developing subacutely over weeks. These manifestations arise from the ongoing bacteremia or and release, affecting up to 90% of patients. Cardiac symptoms in infective endocarditis frequently involve new-onset or worsening , presenting as dyspnea on exertion, , or paroxysmal nocturnal dyspnea due to acute valvular regurgitation from vegetation-related damage. may also occur, particularly if or complicates the infection. Embolic symptoms are a key feature, resulting from fragments of valvular vegetations detaching and occluding distant vessels; these can manifest as acute stroke-like neurological deficits from cerebral emboli, pleuritic or from pulmonary infarcts in right-sided disease, or flank or from renal or splenic involvement. Such events occur in approximately 20-25% of cases at presentation. Additional symptoms in encompass arthralgias, myalgias, and anorexia, contributing to overall and reflecting immune-mediated responses. In noninfectious endocarditis, symptoms are generally milder or absent, though embolic events or symptoms like dyspnea may predominate, varying by underlying such as or .

Physical Examination Findings

Physical examination in patients with endocarditis often reveals a combination of cardiac, peripheral, and systemic signs that suggest valvular involvement, embolic phenomena, or immune-mediated responses. Fever is a common finding, present in up to 90% of cases, accompanied by reflecting the systemic inflammatory response. Evidence of embolic occlusion may manifest as unequal pulses or neurological deficits, while signs of , such as jugular venous distension or , indicate complications from valvular regurgitation. Cardiac auscultation frequently identifies new or changing due to valvular destruction or vegetations, with regurgitant murmurs—particularly aortic insufficiency—being the most common, occurring in approximately 85% of left-sided cases. Signs of congestive may include an S3 gallop or pulmonary rales on lung , especially in subacute presentations where progressive valve incompetence leads to . Peripheral are classic but less prevalent in modern cohorts, appearing in about 10-25% of patients. Janeway lesions present as nontender, erythematous macules on the palms or soles, resulting from septic emboli to dermal arterioles. Osler's nodes appear as tender, pea-sized nodules on the finger pads or toes, attributed to immune complex deposition rather than direct . Splinter hemorrhages, linear subungual streaks, are found under the nails in up to 15% of cases and may indicate microemboli. Ocular findings include Roth spots, which are retinal hemorrhages with pale centers visible on fundoscopy, occurring in 5-10% of patients due to embolic or vasculitic processes. Conjunctival petechiae or splinter hemorrhages in the nail beds further support microvascular involvement. Abdominal examination may reveal in 20-50% of cases, particularly in , from chronic immune stimulation.

Diagnosis

Diagnostic Criteria

The diagnosis of relies on standardized criteria that integrate clinical, microbiological, and imaging findings to confirm the presence of infection on cardiac structures. The modified Duke criteria, established in 2000, serve as the cornerstone for this process by categorizing cases as definite, possible, or rejected based on major and minor criteria. Major criteria encompass two categories: microbiological evidence and evidence of endocardial involvement. Microbiological major criteria include blood cultures positive for typical infective endocarditis pathogens, such as Staphylococcus aureus, viridans group streptococci, enterococci, HACEK organisms, or community-acquired enterococci from two separate cultures; persistently positive blood cultures (defined as cultures drawn more than 12 hours apart or at least 70% of multiple cultures positive for the same organism); or a single positive blood culture for Coxiella burnetii or an antiphase I IgG antibody titer greater than 1:800. Evidence of endocardial involvement includes echocardiographic findings of vegetations, abscesses, new partial dehiscence of a prosthetic valve, or new valvular regurgitation (worsening or changing of pre-existing murmur not sufficient). Minor criteria include predisposing heart conditions or intravenous drug use; fever greater than 38°C; vascular phenomena such as major arterial emboli, septic pulmonary infarcts, , , conjunctival hemorrhages, or Janeway's lesions; immunologic phenomena like , Osler's nodes, , or positive ; and microbiological evidence that does not meet major criteria, such as a positive for a consistent with or serological evidence of active infection. Classification under the modified criteria defines definite as the presence of two major criteria, one major criterion and three minor criteria, or five minor criteria; possible as one major criterion and one minor criterion or three minor criteria; and rejected as a firm alternative explaining evidence of , resolution of manifestations after four days or less of , or no pathologic evidence at or after preoperative lasting more than four days, or failure to meet criteria for possible . The original criteria were proposed in 1994 to standardize , emphasizing blood cultures and , but were updated in 2000 to better accommodate prosthetic valve endocarditis, culture-negative cases, and intracardiac complications like abscesses. These modifications addressed limitations in early disease detection and improved applicability across diverse presentations. In 2023, the -International Society for Cardiovascular Infectious Diseases (ISCVID) criteria further refined the framework by incorporating advanced imaging like 18F-FDG and expanded microbiological diagnostics, such as enzyme immunoassays for Bartonella species, to enhance sensitivity in challenging cases. The modified Duke criteria demonstrate a of approximately 80% and high specificity, making them valuable for guiding the initiation of empiric antimicrobial therapy while integrating supportive and data. Limitations persist in early-stage , where criteria may underperform, underscoring the need for clinical judgment alongside these frameworks.

Laboratory Tests

Laboratory tests play a crucial role in supporting the diagnosis of infective endocarditis by identifying the causative , assessing inflammation, and detecting associated complications. Blood cultures remain the cornerstone of microbiological diagnosis, with guidelines recommending the collection of at least three separate sets from different sites prior to initiating therapy to maximize yield. In untreated cases, this approach achieves a diagnostic yield exceeding 90%, detecting up to 96-98% of bacteremic episodes when properly performed. Inflammatory markers are routinely elevated and provide supportive evidence, though they are nonspecific. The erythrocyte sedimentation rate (ESR) is typically greater than 30 mm/h in most patients, while (CRP) levels often exceed 10 mg/L, reflecting the systemic inflammatory response. frequently reveals , with levels below 11 g/dL in up to 70-90% of cases, alongside (white blood cell count >11,000/μL) or, less commonly, . These findings contribute to minor criteria in diagnostic frameworks like the modified criteria. Additional laboratory investigations include , which often shows microscopic due to renal emboli or immune complex-mediated , present in approximately 50% of cases. is positive in about 50% of subacute endocarditis cases, likely due to polyclonal B-cell activation. Serologic testing for atypical pathogens, such as species (IgG titer >1:800) or , is recommended in culture-negative scenarios to identify fastidious organisms. Despite optimal techniques, blood cultures are negative in 10-20% of cases, primarily due to prior exposure, fastidious or non-culturable organisms like HACEK group bacteria, or intracellular pathogens. In such instances, molecular methods like 16S rRNA () on blood or excised valvular tissue can identify the etiologic agent with sensitivities up to 70-85%, aiding definitive diagnosis.

Imaging Modalities

Transthoracic echocardiography () is the initial non-invasive imaging modality recommended for screening suspected , allowing visualization of vegetations, assessment of function, and evaluation of chamber sizes. It has a of 60-70% for detecting vegetations greater than 5 mm on native valves, though performance decreases for smaller lesions or prosthetic valves. is particularly useful in hemodynamically stable patients without contraindications, providing a rapid bedside assessment without radiation exposure. Transesophageal echocardiography (TEE) offers superior resolution due to its esophageal probe placement closer to cardiac structures, achieving sensitivities of 90-100% for identifying small vegetations, perivalvular abscesses, and complications in prosthetic valves. As a semi-invasive , TEE is preferred when TTE is inconclusive but clinical suspicion is high, in cases involving prosthetic valves or intracardiac devices, or to detect new regurgitant lesions. Its specificity ranges from 91-100%, making it essential for confirming diagnosis and guiding management in complex scenarios. Advanced imaging techniques complement echocardiography in challenging cases. Cardiac computed tomography (CT) excels at delineating perivalvular complications like abscesses, pseudoaneurysms, and fistulas, with high spatial resolution for prosthetic valve evaluation. Fluorine-18 fluorodeoxyglucose positron emission tomography/computed tomography (18F-FDG PET/CT) detects metabolic activity of infection, offering high sensitivity (up to 90%) for prosthetic valve endocarditis and device-related infections, though specificity may be limited by physiologic uptake. Cardiac magnetic resonance imaging (MRI) is valuable for assessing cerebral emboli in patients with neurologic symptoms, providing detailed tissue characterization without ionizing radiation. According to the 2023 () guidelines, is the first-line imaging tool, with recommended for high-risk patients or negative initial studies; multimodality approaches incorporating and are advised for prosthetic or device-related suspicions to improve diagnostic yield. Serial imaging with these modalities monitors vegetation progression, response to therapy, and complication development, integrating into frameworks like the modified criteria for overall .

Management

Antimicrobial Therapy

Antimicrobial therapy is the cornerstone of for (IE), aiming to eradicate the infecting while minimizing and complications. Empiric regimens are initiated promptly upon suspicion of IE to cover the most likely pathogens, typically streptococci, staphylococci, and enterococci, pending results. For community-acquired IE in patients with native valves, vancomycin combined with ceftriaxone is recommended to cover likely pathogens including (MRSA), streptococci, enterococci, and , while ampicillin plus ceftriaxone is suitable for subacute native valve IE suspected to be streptococcal or enterococcal. In prosthetic valve endocarditis (PVE) or nosocomial cases, includes vancomycin, ceftriaxone, gentamicin, and rifampin to address staphylococci, including coagulase-negative species, enterococci, streptococci, HACEK, and potential involvement. Once the is identified and confirmed, is tailored to the specific organism, administered intravenously for 4 to 6 weeks to achieve bactericidal activity and prevent relapse. For native valve IE caused by highly penicillin-susceptible viridans group streptococci ( [MIC] ≤0.12 μg/mL), penicillin G or alone for 4 weeks is standard; a 2-week regimen with gentamicin may be used in uncomplicated cases without renal impairment. Enterococcal IE requires with or penicillin G plus gentamicin for 4 to 6 weeks, with substituting for beta-lactams in resistant strains. Staphylococcal IE, whether methicillin-sensitive (using or oxacillin) or resistant ( or at 8-10 mg/kg/day), typically demands 6 weeks of , often with initial gentamicin addition for , though its routine use is debated due to risks. Fungal IE, less common but highly morbid, is treated with (with or without ) for at least 6 weeks post-valve replacement, or echinocandins/ for specific molds like . For stable patients without complications, outpatient parenteral antimicrobial (OPAT) can facilitate completion of the course after initial hospitalization, reducing costs and improving without compromising outcomes. Additionally, for clinically stable patients meeting specific criteria (e.g., no complications, susceptible pathogens), partial oral may be considered after an initial period of (≥10 days, or ≥7 days post-surgery), as supported by the POET trial. Therapeutic monitoring ensures efficacy and safety, with blood cultures repeated weekly until clearance (typically within 7-10 days) to confirm response. Drug levels are monitored for agents with narrow therapeutic indices: troughs of 15-20 mcg/mL for staphylococcal IE to optimize bactericidal activity while avoiding , and gentamicin peak levels of 3-4 mcg/mL with once-daily dosing. Serum bactericidal titers, assessing peak and trough inhibition, may guide therapy in challenging cases like enterococcal IE but are not routinely required due to limited prognostic value. In culture-negative IE, comprising 10-20% of cases often due to prior antibiotics or fastidious organisms, broad-spectrum is adjusted based on clinical context and advanced diagnostics. Recent advances, including 16S rRNA and metagenomic sequencing as per the 2025 scientific statement, enhance identification in culture-negative cases. For native valve culture-negative IE, plus (or ) covers streptococci, enterococci, and ; rifampin is added if PVE is suspected. () on blood or excised valve tissue, along with serology for or species, guides de-escalation; for example, plus for IE or gentamicin plus / for . Therapy duration remains 4-6 weeks or longer for intracellular pathogens, with multidisciplinary input essential.

Surgical Interventions

Surgical interventions play a crucial role in the management of infective endocarditis (IE), particularly when medical therapy alone is insufficient to address structural cardiac damage or persistent infection. These procedures are typically considered in conjunction with antimicrobial therapy to eradicate the infection and restore cardiac function. According to the 2023 European Society of Cardiology (ESC) guidelines, surgery is indicated in approximately 50% of left-sided IE cases to improve outcomes and prevent complications. Indications for surgery in IE are primarily driven by three categories: hemodynamic compromise due to heart failure, uncontrolled infection, and risk of systemic embolization. Heart failure resulting from severe valve regurgitation, obstruction, or perforation warrants urgent surgical intervention, classified as a class I recommendation (level of evidence A) in the ESC guidelines, as it directly threatens life if untreated. Uncontrolled infection, evidenced by persistent bacteremia for more than 7 days despite appropriate antibiotics, locally uncontrolled complications such as abscesses, false aneurysms, or fistulae, also mandates surgery (class I, level B). Additionally, large vegetations exceeding 10 mm, particularly those associated with prior embolic events or in cases of fungal or multiresistant organisms, indicate surgery to prevent further emboli (class IIa, level B). Periannular extension or prosthetic valve involvement further supports surgical referral. Common surgical procedures for IE focus on excision of infected tissue and restoration of valve function, with valve repair preferred over replacement when feasible to preserve native anatomy and reduce long-term complications. involves thorough removal of vegetations, abscesses, and necrotic tissue, often requiring of the annulus or root with patches. is performed using mechanical prostheses for younger patients or bioprosthetic valves for those at higher bleeding risk, with choices guided by patient age, comorbidities, and infection site (class I, level C). In cases of coronary artery involvement, such as septic emboli causing , concomitant coronary artery bypass grafting (CABG) may be necessary. For right-sided IE, repair or replacement is less common but indicated for severe regurgitation or persistent . These interventions are ideally conducted by multidisciplinary endocarditis teams to optimize results. Timing of surgery is stratified based on clinical urgency to balance risks of delay against complications. Emergent within 24 hours is recommended for patients with refractory cardiogenic or , or uncontrolled local causing hemodynamic instability such as perivalvular leading to (class I, level C). Urgent within 3 to 5 days is advised for new heart failure due to dysfunction, persistent after systemic , or large mobile vegetations greater than 10 mm in left-sided IE (class I, level B). , planned after 1 to 2 weeks of stabilization, is appropriate for stable patients with large vegetations without prior emboli or for prosthetic IE without acute complications. Delays are cautioned in cases of recent neurological events, such as hemorrhagic , to mitigate intracranial risks. Outcomes following surgical intervention for IE have improved with advances in techniques and multidisciplinary care, though mortality remains significant in high-risk subsets. In-hospital mortality rates for surgically treated left-sided IE range from 15% to 25%, a substantial reduction from the 40% to 60% observed with medical management alone in complicated cases. Long-term survival at 5 years approaches 70% to 80% in patients without major comorbidities, with lower reinfection rates after valve repair compared to replacement. However, elderly patients, those with infections, or extensive perivalvular involvement face higher operative risks, with mortality exceeding 30% in such groups. Recent studies emphasize that adherence to guideline-directed early surgery correlates with decreased short- and long-term mortality.

Supportive Measures

Supportive measures in endocarditis encompass a range of ancillary interventions aimed at stabilizing patients, managing complications, and optimizing outcomes during acute treatment. For patients with experiencing hemodynamic instability due to heart failure, intravenous fluids are administered to maintain adequate preload, while inotropic agents such as are used to support when systolic dysfunction is present. In cases of respiratory distress secondary to pulmonary emboli, is employed to ensure oxygenation and ventilatory support, particularly in (ICU) settings for critically ill individuals. Management of complications requires careful consideration of risks and benefits. Anticoagulation is recommended for patients with prosthetic valve endocarditis who were already on therapy prior to , to prevent systemic emboli, but it should be used cautiously due to the heightened risk of , especially in those with involvement; routine initiation of anticoagulation is not advised for native valve endocarditis. For extracardiac septic foci, such as splenic abscesses complicating endocarditis, may be indicated to eradicate persistent sources, often coordinated with overall care to avoid delaying cardiac stabilization. Unstable patients benefit from multidisciplinary ICU management involving cardiologists, infectious disease specialists, and critical care teams to facilitate close monitoring of , organ function, and response to , which has been shown to improve rates. Nutritional support is provided through enteral or parenteral routes to address catabolic states from prolonged illness, while with analgesics helps maintain patient comfort without interfering with diagnostic assessments. Thrombosis prophylaxis with is routinely implemented in immobilized patients to prevent venous , unless contraindicated by risks. In noninfective forms of endocarditis, such as Libman-Sacks endocarditis associated with systemic lupus erythematosus, immunosuppressive therapy including corticosteroids is utilized to control underlying autoimmune activity and reduce valvular inflammation, potentially mitigating vegetation progression. For marantic endocarditis linked to underlying malignancies, supportive measures focus on treating the primary cancer through or other modalities to address the hypercoagulable state driving sterile vegetations.

Prevention

Prophylactic Antibiotic Regimens

Antibiotic prophylaxis for (IE) is recommended by major guidelines only for a select group of high-risk patients undergoing procedures associated with significant bacteremia, primarily dental procedures that involve manipulation of gingival tissue or the periapical region of teeth or perforation of the . The (AHA) 2007 guidelines, reaffirmed in subsequent statements including 2023, and the (ESC) 2023 guidelines restrict prophylaxis to patients with prosthetic heart valves or prosthetic material used for cardiac valve repair, a history of IE, certain congenital heart diseases (such as unrepaired cyanotic congenital heart disease, completely repaired congenital heart defects with prosthetic material or device for the first 6 months after the procedure, or repaired congenital heart disease with residual defects at or adjacent to the site of a prosthetic patch or prosthetic device), and cardiac transplant recipients who develop cardiac valvulopathy. Prophylaxis is not routinely advised for gastrointestinal or genitourinary procedures, a change implemented in the AHA 2007 update based on evidence showing no significant association with IE risk in these contexts. The standard regimen for oral administration in adults is amoxicillin 2 g (or 50 mg/kg for children, up to the adult dose) taken 30 to 60 minutes before the ; if unable to take oral , ampicillin 2 g or / 1 g may be given intravenously or intramuscularly. For patients with penicillin , alternatives include oral clindamycin 600 mg, or 500 mg, or intravenous clindamycin 600 mg, 15 mg/kg (maximum 1.5 g), or / 1 g. These regimens target common oral flora such as viridans group streptococci, which are implicated in a subset of IE cases.
RegimenStandard (Adults)Penicillin Allergy Alternative (Adults)Pediatric Dose (if applicable)
OralAmoxicillin 2 gClindamycin 600 mg; or 500 mgAmoxicillin 50 mg/kg (max 2 g); Clindamycin 20 mg/kg (max 600 mg); 15 mg/kg (max 500 mg)
Parenteral 2 g IV/IM; or Cefazolin/ 1 g IV/IMClindamycin 600 mg IV; or 15 mg/kg IV (max 1.5 g); or Cefazolin/ 1 g IV/IM 50 mg/kg IV/IM; Clindamycin 20 mg/kg IV; 20 mg/kg IV
Evidence supporting prophylaxis derives primarily from observational data and expert consensus rather than randomized trials, as ethical challenges preclude such studies. Prophylaxis effectively reduces the incidence of viridans streptococcal bacteremia following dental procedures ( 0.53, 95% CI 0.49-0.57 in meta-analyses), but population-level studies show no significant reduction in overall IE incidence, likely due to the rarity of procedure-related IE cases. Overuse of antibiotics for prophylaxis has been linked to increased risks of , , and adverse drug reactions, prompting guidelines to emphasize targeted use. Recent updates, including the 2023 guidelines and a 2024 National Institute for Health and Care Excellence () amendment, underscore shared decision-making, particularly advising against routine prophylaxis in lower-risk conditions such as without regurgitation, due to insufficient evidence of benefit outweighing harms.

Lifestyle and Risk Modification

Maintaining optimal dental is a cornerstone of endocarditis prevention, as poor oral can lead to bacteremia from oral entering the bloodstream during routine activities or dental procedures. Regular professional dental cleanings, daily brushing, flossing, and the use of antimicrobial mouthwashes are recommended to minimize the risk of viridans group streptococcal infections, which account for a significant portion of community-acquired cases. Similarly, skin practices, including thorough handwashing and prompt treatment of any cutaneous infections or wounds, help reduce the entry of such as into the circulation, thereby lowering the incidence of endocarditis associated with skin breaches. For individuals engaging in intravenous drug use, cessation through counseling and access to programs is essential to prevent right-sided , which is often caused by repeated injections introducing contaminated . Behavioral interventions, including and referral to treatment services, have shown efficacy in reducing injection frequency and associated risks. Needle programs provide sterile equipment, on safe injection techniques, and disposal options, significantly decreasing the transmission of pathogens and bacterial seeding of heart valves. Patients with cardiac devices such as pacemakers or implantable cardioverter-defibrillators (ICDs) face elevated risks of device-related endocarditis and should receive targeted on infection signs, including fever, chills, or device site redness, to facilitate early intervention. Routine follow-up with cardiologists for device integrity checks and surveillance is advised. Additionally, for immunocompromised individuals or those with underlying heart conditions, annual and pneumococcal (using conjugate vaccines like PCV20 or PCV21) are recommended to prevent respiratory infections that may precipitate bacteremia and subsequent endocarditis. High-risk patients, including those with prosthetic valves or prior endocarditis, benefit from pre-procedure counseling before invasive interventions like dental work or surgeries, where education on recognizing early symptoms—such as unexplained fever, fatigue, or new heart murmurs—promotes timely medical evaluation and improves outcomes. This awareness integrates with broader prophylaxis strategies to enhance overall risk mitigation.

Epidemiology and Prognosis

Incidence and Demographics

Infective endocarditis (IE) has a global incidence estimated at 3 to 10 cases per 100,000 person-years, though age-standardized incidence rates have shown an upward trend, rising from approximately 9.91 per 100,000 in 1990 to 13.80 per 100,000 in 2019 worldwide. As of , global cases exceeded 1 million, with prevalence increasing by 40% since , reflecting ongoing growth in burden. This increase is attributed to an aging population, which elevates risks associated with degenerative valve diseases and prosthetic valves, as well as rising intravenous drug use (IVDU) epidemics that contribute to higher rates among younger adults. Between 1990 and , the absolute number of IE cases globally surged by 34%, reflecting these demographic and behavioral shifts. Demographically, IE predominantly affects males, with a male-to-female ratio of approximately 2:1, and peaks in incidence among individuals aged 50 to 70 years, though cases in those over 65 have become increasingly common. In developing countries, the disease burden is heightened by prevalent rheumatic heart disease, which accounts for a larger proportion of cases compared to high-income regions where degenerative and prosthetic valve involvement predominates. Overall, the median age at has trended upward, aligning with broader aging and a shift from acute rheumatic fever-related to chronic valvular degeneration. Regional variations underscore these patterns: in and , healthcare-associated IE drives higher rates, often linked to invasive procedures and prosthetic devices following the expansion of cardiac surgeries. In contrast, IVDU-related surges have been prominent in urban areas of during the opioid crisis of the and , with notable increases in the Midwest and Eastern regions. Developing regions experience elevated incidence tied to untreated rheumatic disease, though global projections indicate that by 2030, developed countries will bear the largest case burden due to aging demographics.

Mortality Rates and Long-Term Outcomes

In-hospital mortality for ranges from 13% to 25%, with overall rates typically reported at 15% to 20% across large cohorts. Cases involving Staphylococcus aureus exhibit particularly high lethality, with mortality exceeding 20% and reaching up to 40% in severe instances. Similarly, prosthetic valve endocarditis carries elevated risks, with in-hospital mortality estimates of 20% to 40%, and up to 40% to 80% when caused by S. aureus. Early surgical intervention can substantially mitigate these risks, reducing in-hospital mortality to below 10% in selected patients by addressing complications such as severe valvular regurgitation or formation. Long-term survival following remains guarded, with 1-year survival rates approximating 70% to 80% among hospital survivors, influenced by the need for ongoing cardiac management. Recurrence risk is notable, occurring at an annual rate of 0.3% to 2.5% per patient-year, though cumulative incidence can reach 5% to 10% within the first few years post-discharge, particularly in those with persistent risk factors. Many survivors experience residual valve dysfunction, such as moderate to severe regurgitation, necessitating lifelong echocardiographic monitoring to detect progression toward or the need for reintervention. Several prognostic factors adversely affect outcomes in . Advanced age greater than 65 years is associated with higher mortality due to reduced physiological reserve and increased burden. , including renal failure, further worsen by complicating therapy and surgical candidacy, with low estimated glomerular rates correlating to elevated rates. Delayed , often exceeding 14 days from symptom onset, heightens risks through unchecked vegetation growth and embolic events, contributing to poorer . Fungal etiologies, such as species, confer the most dismal outlook, with mortality rates of 30% to 80% attributable to diagnostic challenges and therapeutic resistance. Implementation of multidisciplinary endocarditis teams, as recommended by the , has led to measurable improvements in prognosis by optimizing diagnostic timing, surgical referrals, and . These teams are linked to a 20% to 30% relative reduction in short-term mortality through coordinated care, shorter stays, and decreased complications compared to traditional management approaches.