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Constrictive pericarditis

Constrictive pericarditis is a rare inflammatory condition of the , the sac-like membrane surrounding the heart, in which chronic leads to thickening, , and of the , resulting in restricted diastolic filling of the heart ventricles and impaired . This process often manifests as a of right-sided , with symptoms including , dyspnea on exertion, , and due to elevated systemic venous pressures. Unlike , which is typically self-limiting, constrictive pericarditis develops over months to years and requires specific diagnostic and therapeutic interventions to prevent progressive deterioration. The etiology of constrictive pericarditis varies by region and population, with tuberculosis remaining the predominant cause worldwide, accounting for up to 70% of cases in endemic areas, while in developed countries, it is most often idiopathic or post-viral (42%-80%) or linked to prior (11%-37%), (9%-31%), or viral infections. Other contributors include connective tissue disorders such as or , , and post-infectious states, though it rarely occurs in children. Pathophysiologically, the inflamed undergoes formation and , obliterating the pericardial space and creating a rigid shell that limits ventricular expansion during early diastole, leading to equalization of intracardiac diastolic and a characteristic " sign" on pressure tracings. This restriction disproportionately affects the right ventricle, mimicking conditions like , but the pericardial involvement distinguishes it. Clinically, patients present with signs of systemic congestion, such as elevated , Kussmaul's sign (paradoxical rise in venous pressure during inspiration), hepatomegaly, and a pericardial knock—a high-pitched early diastolic sound heard in about 50% of cases. Diagnosis relies on a combination of clinical suspicion, multimodality imaging, and invasive ; echocardiography reveals pericardial thickening (>4 mm), septal bounce, and abnormal hepatic vein flow, while computed tomography (CT) or cardiac magnetic resonance imaging (MRI) confirms , , and with high sensitivity. Cardiac catheterization demonstrates concordant respiratory variations in ventricular pressures, differentiating it from effusive-constrictive pericarditis, which involves both effusion and constriction and shows persistent elevated right atrial pressure after . Management focuses on symptom relief and addressing the underlying cause, with diuretics and salt restriction used initially to reduce congestion, and anti-inflammatory agents like NSAIDs or trialed in transient or subacute forms for 3-6 months if is present. Definitive is surgical pericardiectomy, preferably at high-volume centers, which involves excision of the constricting —potentially using in complex cases—and offers the best outcomes when performed early, though operative mortality ranges from 5%-12% and is higher in radiation-induced cases. is guarded without , with untreated disease carrying a mortality exceeding 90% within years, but post-surgical five-year survival can reach 70%-80% in optimal candidates. Early recognition remains crucial, as delayed diagnosis can lead to irreversible complications like hepatic or renal failure.

Overview

Definition

Constrictive pericarditis is a cardiac syndrome characterized by the thickening and fusion of the visceral and parietal layers of the pericardium, resulting in a rigid, noncompliant sac that impairs diastolic filling of the heart ventricles while preserving systolic function. This condition arises from chronic inflammation leading to granulation tissue formation, fibrosis, and often calcification of the pericardium, which encases and restricts the heart's expansion during diastole. The resultant hemodynamic compromise manifests as elevated and equalized diastolic pressures across cardiac chambers, mimicking right heart failure. The syndrome is classified into distinct subtypes based on its temporal evolution and underlying pathology. Transient constrictive pericarditis is a reversible form that resolves with medical therapy, such as agents, typically within weeks to months following acute pericardial injury. Subacute constrictive pericarditis represents an inflammatory phase, often involving effusive components, where may spontaneously remit or respond to targeted over 3 to 6 months. In contrast, chronic constrictive pericarditis features advanced fibrotic and calcified changes that are generally irreversible without surgical pericardiectomy. Differentiation from is essential, as both present with diastolic dysfunction but differ fundamentally in and management: constrictive pericarditis involves extrinsic constraint by the , allowing normal myocardial relaxation, whereas stems from intrinsic myocardial stiffness and . This distinction relies on and invasive , with constrictive pericarditis showing pericardial thickening and respiratory variations in flow, unlike the uniform myocardial involvement in restrictive disease. The recognition of constrictive pericarditis as an end-stage of pericardial inflammation dates to the mid-18th century, when Morgagni associated with pericardial thickening, but the term was formally coined in the 1870s by von Volkmann, who emphasized the role of a fibrotic in diastolic restriction. Early 20th-century surgical interventions, such as pericardiectomy, further established its treatable nature despite its inflammatory origins.

Epidemiology

Constrictive pericarditis is a rare condition, with an overall incidence of approximately 0.2-0.4% following . In large cohorts of patients with pericardial diseases, progression to constrictive pericarditis occurs in about 1.7%, as observed in a 2025 study of 45,445 patients where 763 cases were identified. Demographically, the condition predominantly affects individuals with a median age of 64 years and shows a male predominance of around 63%. In developing countries, particularly in , cases tend to present at a younger mean age of about 47 years, with a male-to-female ratio of 1.5:1. Geographic distribution varies significantly by etiology and socioeconomic context. In low- and middle-income countries, accounts for 38-83% of cases and up to 55% in specific cohorts, such as a 2025 multicenter study in . In contrast, developed nations report tuberculosis in only 4% of cases, with idiopathic or post-surgical etiologies comprising 70-80%. A 2024 analysis indicated that about 54% of constrictive pericarditis cases worldwide are idiopathic, 17% follow , and 11% are tuberculosis-related. Recent trends from 2025 data show a decline in -related constrictive pericarditis in high-income countries, mirroring reductions in overall prevalence. In low-income settings, remains the dominant cause, highlighting persistent disparities. Mortality statistics indicate an in-hospital rate of approximately 7% if untreated. Geographic variations persist, with higher rates in low-income settings due to delayed and limited access to pericardiectomy, though specific 2025 cohorts report intrahospital mortality as low as 5%.

Etiology

Infectious Causes

Infectious causes of constrictive pericarditis primarily involve pathogens that trigger acute pericardial , leading to and constriction of the . Tuberculosis, caused by , remains the leading infectious etiology, particularly in developing regions where it accounts for up to 70% of cases. The pathogen typically reaches the via hematogenous spread from a primary pulmonary focus or direct extension from adjacent mediastinal lymph nodes, initiating a granulomatous inflammatory response. Other bacterial infections contribute less frequently but can progress to purulent pericarditis and subsequent constriction, especially in cases of contiguous spread from pneumonia or endocarditis. Common organisms include Staphylococcus aureus, Streptococcus pneumoniae, and Haemophilus influenzae, which provoke a suppurative reaction with pus accumulation in the pericardial space, often requiring urgent drainage to prevent fibrotic encasement. Fungal pathogens, such as Histoplasma capsulatum, Aspergillus species, Candida species, and Coccidioides immitis, are rare causes but predominate in immunocompromised hosts, including those with HIV/AIDS or post-transplant immunosuppression; these lead to necrotizing inflammation and adhesions through hyphal invasion or systemic dissemination. Viral infections represent a significant proportion of cases in developed countries, where they account for 40-60% of etiologies, often evolving from idiopathic . Key viruses include coxsackieviruses (particularly type B), echoviruses, virus, and adenovirus, which cause lymphocytic infiltration and myopericardial involvement that may resolve subclinically before progressing to . HIV-associated , frequently compounded by opportunistic co-infections like , can advance to in up to 20-30% of untreated cases, though antiretroviral has mitigated this risk by reducing overall TB incidence. Historically, dominated in the pre-antibiotic era, with mortality rates of 80-90% and developing in 30-60% of survivors; modern declines in incidence reflect widespread antitubercular , BCG , and antiretrovirals, shifting the burden toward causes in low-prevalence areas. The pathogenic process in infectious constrictive pericarditis generally begins with acute exudative , characterized by serosanguinous or purulent and inflammatory cell infiltration. Over months to years, unresolved inflammation promotes formation, deposition, and pericardial thickening, ultimately impairing diastolic filling without myocardial involvement. In tuberculous cases, and exacerbate this , while bacterial and fungal infections accelerate adhesion formation through intense neutrophilic or responses.

Noninfectious Causes

Noninfectious causes of constrictive pericarditis encompass a range of iatrogenic, autoimmune, idiopathic, neoplastic, uremic, and emerging drug-related factors that trigger pericardial and subsequent . These etiologies are particularly prevalent in developed countries, where they account for the majority of cases outside of infectious origins. Iatrogenic causes are among the most common noninfectious triggers. Post-cardiac , such as coronary artery bypass grafting or , leads to constrictive pericarditis in 0.2-0.4% of cases, often due to formation or persistent . for mediastinal malignancies, including and Hodgkin's lymphoma, carries a of 2-30% for developing , typically manifesting after a latency period of 5-20 years following doses exceeding 30 Gy. Autoimmune and diseases contribute through chronic systemic inflammation affecting the . involves pericardial inflammation in 30-50% of cases, with rare progression to constriction if untreated. Similarly, systemic lupus erythematosus and can lead to fibrotic pericardial changes via ongoing immune-mediated damage. Idiopathic cases represent 40-50% of constrictive pericarditis in developed nations, often linked to subclinical episodes that resolve acutely but evolve into over time. Neoplastic causes include primary tumors like or secondary involvement from malignancies, which directly infiltrate or indirectly scar the . Uremic pericarditis in end-stage renal disease promotes through toxin-mediated , occurring either before initiation or as a dialysis-associated complication after 8 weeks. Recent reviews highlight increasing modern etiologies, such as post-percutaneous coronary interventions causing rare cases of via localized or , as documented in case reports. Drug-induced , notably from in patients, can progress to constrictive forms, as seen in reported cases of effusive-constrictive disease. These factors culminate in the chronic pericardial fibrosis detailed in discussions.

Pathophysiology

Pericardial Changes

Constrictive pericarditis is characterized by progressive structural alterations in the , beginning with acute inflammatory responses that lead to the formation of fibrinous exudates or serofibrinous effusions following an inciting event such as or . During the healing phase, develops within the pericardial cavity, resulting in adhesions between the visceral and parietal layers and eventual obliteration of the pericardial space. This process evolves into dense deposition and , markedly reducing the pericardium's elasticity and compliance without direct myocardial involvement. Pericardial thickness, normally ranging from 1 to 2 mm, often exceeds 4 mm in constrictive cases due to , though imaging may reveal in approximately 25-30% of instances, particularly along the atrioventricular grooves or right ventricle. However, up to 18% of patients exhibit histologically proven with normal pericardial thickness (≤2 mm), where focal and adhesions suffice to impair function. In subacute phases, plays a key role, contributing to visceral-pericardial fusion and potential reversibility with interventions. Histologically, the changes involve proliferation, crosslinking, and deposition, accompanied by leukocyte infiltration and mesothelial cell activation, which shifts cells from a flat to cuboidal morphology. These features manifest temporally from within weeks post-insult to scarring over years, with transient forms resolving spontaneously or via in select cases.

Hemodynamic Effects

Constrictive pericarditis primarily impairs diastolic function by imposing an external constraint on the heart, restricting ventricular filling during early diastole and leading to elevated end-diastolic pressures across cardiac chambers. This limitation arises from the rigid pericardium, which prevents normal expansion and equalization of diastolic pressures between the left and right ventricles, typically within 5 mmHg. As a result, the heart operates under a fixed volume constraint, reducing preload and stroke volume while preserving systolic function. Characteristic hemodynamic signatures include elevated and equalized intracardiac diastolic pressures, often exceeding 15 mmHg in the right atrium, right ventricle, pulmonary capillary wedge, and left ventricle. Jugular venous waveforms exhibit prominent x and y descents, reflecting rapid early diastolic filling followed by abrupt cessation, sometimes producing an M- or W-shaped pattern. Ventricular pressure tracings display the "square root" sign, characterized by a rapid early diastolic decline (dip) and subsequent plateau due to the pericardial barrier halting further filling. These alterations culminate in systemic effects such as reduced , fostering low-flow states and symptoms of . may develop secondary to compressed left atrial filling and elevated pulmonary venous pressures, though it is typically mild with systolic pressures below 55 mmHg. In differentiation from , constrictive pericarditis features discordant ventricular septal motion and a pericardial knock (an early diastolic sound from sudden ventricular halt), contrasting with concordant motion and an S3 gallop in restriction, alongside preserved systolic performance.

Clinical Presentation

Symptoms

Constrictive pericarditis typically presents with an insidious onset of symptoms that develop gradually over months to years, often beginning with subtle as an early marker. The cardinal symptoms stem from chronic low and include progressive dyspnea on exertion, fatigue, and generalized weakness due to inadequate tissue perfusion. These manifestations reflect the impaired ventricular filling caused by the rigid , leading to reduced during activity. Fluid retention is a prominent feature, driven by right-sided heart failure, and manifests as peripheral edema in the legs and ankles, often accompanied by ascites that causes abdominal distension and discomfort; notably, the ascites may be disproportionately severe compared to lower extremity swelling. Patients frequently report weight gain from fluid accumulation, alongside increasing abdominal girth. Additional symptoms can include and paroxysmal nocturnal dyspnea, particularly as the condition advances and systemic congestion worsens. Due to prominent and , the condition is often initially misdiagnosed as hepatic or other abdominal pathologies. may occur in some cases, often linked to residual . In instances related to , patients may experience alongside constitutional symptoms like and . These symptoms are associated with elevated venous pressures from restricted cardiac filling, exacerbating the sense of breathlessness and .

Physical Findings

Patients with constrictive pericarditis often exhibit characteristic abnormalities in the jugular venous pulse during . The is typically elevated, reflecting systemic venous congestion, though it may be normal in early stages of the disease. A prominent feature is the rapid y descent, known as Friedreich's sign, resulting from abrupt early diastolic filling of the right ventricle halted by the constricted ; this descent is often deeper than the x descent. Additionally, is frequently observed, characterized by a paradoxical rise or failure to decrease in during inspiration due to impaired right ventricular filling. On cardiac , a pericardial knock—an early diastolic sound occurring 0.09 to 0.12 seconds after the second —can be heard in approximately half of patients, distinguishing it from the later (S3) gallop associated with other forms of . may appear muffled if a concomitant is present. Abdominal examination commonly reveals hepatomegaly and ascites, detectable by percussion and palpation, alongside peripheral pitting edema in the lower extremities due to chronic venous congestion. Pulsus paradoxus, defined as an exaggerated drop of more than 10 mm Hg in systolic during inspiration, occurs in about 20% to 30% of cases, though it is more prevalent in . In chronic untreated disease, advanced findings may include cachexia with muscle wasting from prolonged low cardiac output and malnutrition. In severe low-output states, peripheral cyanosis can develop secondary to inadequate tissue perfusion.

Diagnosis

Imaging and Laboratory Tests

Echocardiography serves as the initial noninvasive imaging modality for evaluating suspected constrictive pericarditis, providing key hemodynamic insights into ventricular interdependence and diastolic filling patterns. Characteristic findings include a septal bounce, representing respirophasic shifts in the interventricular septum due to enhanced ventricular coupling during respiration, observed in up to 93% of cases with high sensitivity but moderate specificity. Respiratory variations in mitral and tricuspid inflows exceed 25% for mitral E-velocity and often surpass 40% for tricuspid, reflecting exaggerated inspiratory augmentation of right ventricular filling at the expense of left ventricular inflow. Hepatic vein flow demonstrates expiratory diastolic reversal, with a reversal ratio greater than 0.79 distinguishing constriction from other conditions. Tissue Doppler imaging aids differentiation from restrictive cardiomyopathy by showing preserved or elevated medial e' velocity (typically >8-9 cm/s), contrasting with reduced velocities in myocardial restriction, alongside annulus reversus where lateral e' exceeds medial. These features, combined with pericardial thickening if visible, support early diagnostic suspicion in patients with compatible symptoms. Chest radiography offers a simple initial assessment, often revealing cardiomegaly or a normal cardiac silhouette, with pericardial calcification evident in approximately 50% of chronic cases, particularly along the atrioventricular groove or right heart border, though this finding lacks specificity. Laboratory evaluation includes brain natriuretic peptide (BNP) measurement, which is typically mildly elevated or normal (<100-150 pg/mL) in constrictive pericarditis, reflecting predominantly extrinsic compression rather than intrinsic myocardial stress; levels exceeding 400-650 pg/mL favor restrictive cardiomyopathy instead. Computed tomography (CT) excels in delineating pericardial anatomy, identifying thickening greater than 4 mm—suggestive of constriction when diffuse or localized—and detecting s with superior resolution compared to other modalities, aiding surgical planning. Cardiac magnetic resonance imaging (MRI) complements CT by assessing pericardial thickness (>4 mm), via late gadolinium enhancement indicating active or , and dynamic septal shifts, with T2-weighted imaging highlighting in subacute cases. The 2025 ACC and ESC guidelines emphasize multimodality imaging integration—echo for , CT for , and MRI for tissue characterization—as essential for confirming and excluding mimics. The 2025 guidelines also highlight the role of serial imaging in detecting transient constrictive pericarditis, a reversible inflammatory form responsive to medical therapy within 3-6 months, to monitor resolution of edema and hemodynamic abnormalities.

Invasive and Functional Assessments

Cardiac catheterization serves as the invasive gold standard for confirming the hemodynamic physiology of constrictive pericarditis, particularly in cases where noninvasive imaging yields equivocal results. Simultaneous right- and left-heart catheterization reveals characteristic findings, including equalization of diastolic pressures across cardiac chambers, with left ventricular end-diastolic pressure (LVEDP) approximating right ventricular end-diastolic pressure (RVEDP) within 5 mmHg. Ventricular pressure tracings demonstrate the "dip-and-plateau" or square root sign, reflecting early rapid diastolic filling followed by an abrupt halt due to the constricted pericardium. These patterns, along with ventricular interdependence shown by discordant changes in left- and right-sided pressures during respiration, distinguish constriction from restrictive cardiomyopathies. Endomyocardial biopsy is rarely performed but may be considered to exclude myocardial mimicking constriction, such as or . In constrictive pericarditis, typically shows normal myocardium, whereas restrictive conditions reveal , eosinophilic infiltrates, or amyloid deposits. Obtaining at least four samples enhances diagnostic sensitivity, helping to avoid unnecessary pericardiectomy in patients with significant intrinsic myocardial disease. Exercise testing, often via cardiopulmonary exercise testing (CPX), evaluates functional capacity and can provoke symptoms in patients with suspected constrictive pericarditis. Peak oxygen consumption (VO2) below 50% of predicted correlates with advanced Heart Association class and identifies candidates for surgical intervention. This assessment provides objective data on exercise limitation, guiding therapeutic decisions beyond resting . According to 2025 guideline updates from the and , is emphasized for equivocal noninvasive cases to confirm , with integration of recommended for high-risk patients to optimize diagnostic accuracy. These approaches prioritize multimodality evaluation while reserving invasive procedures for definitive confirmation.

Treatment

Medical Management

Medical management of constrictive pericarditis focuses on symptomatic and in transient or subacute cases, particularly those with evidence of ongoing , while avoiding therapies that may exacerbate hemodynamic compromise in fibrotic forms. A subset of cases, particularly those with transient constrictive pericarditis, may resolve spontaneously or with alone. Treatment of the underlying is crucial; for tuberculous cases, standard antitubercular multidrug for 6 months is recommended, often combined with agents, to promote and prevent . Initial conservative approaches aim to alleviate and without addressing the underlying pericardial . Diuretics, especially such as , serve as the cornerstone for managing , , and by reducing preload and relieving systemic venous . Dietary restriction is recommended alongside to enhance fluid management and prevent recurrent . For subacute or transient constrictive pericarditis with inflammatory features, therapies are indicated in hemodynamically patients to potentially halt progression and promote resolution. Nonsteroidal drugs (NSAIDs), such as ibuprofen or aspirin, combined with , are recommended as first-line agents per the 2025 ESC Guidelines, typically for 3-6 months depending on response. Corticosteroids may be used cautiously in autoimmune-associated cases but are generally avoided in chronic fibrotic constrictive pericarditis due to risks of worsening . Recent advances include interleukin-1 (IL-1) inhibitors, such as , for refractory inflammatory to prevent evolution to , as endorsed in the 2025 ACC Expert Consensus for cases unresponsive to NSAIDs and . Supportive measures, including (ACE) inhibitors for reduction in select patients with preserved preload, can be considered if tolerated to optimize . Close monitoring with is essential to assess for transient resolution, with escalation to surgical intervention if symptoms persist despite optimized medical therapy.

Surgical Intervention

Surgical intervention for constrictive pericarditis primarily involves pericardiectomy, the definitive curative procedure aimed at relieving constriction by excising the rigid . According to the 2025 () expert consensus guidelines, radical total pericardiectomy is recommended over partial resection for noninflammatory chronic constrictive pericarditis and for inflammatory cases refractory to therapy (Class I recommendation), as partial approaches are associated with higher recurrence rates and incomplete hemodynamic improvement (Class III: no benefit). This procedure is indicated for patients with symptomatic chronic constrictive pericarditis, particularly those in New York Heart Association (NYHA) class III or IV who remain refractory to medical management, with optimal candidacy determined through multidisciplinary evaluation at high-volume centers to ensure favorable risk-benefit profiles. Contraindications include advanced age, significant comorbidities such as end-stage (e.g., Child-Pugh class B/C or MELD-XI score >13.6), or mixed constrictive-restrictive with severe underlying , where operative risks may outweigh potential benefits. The standard surgical approach is via , which provides optimal exposure for extensive dissection, often performed with (CPB) in 40-63% of cases to maintain hemodynamic stability during complex resections. Alternative techniques include left anterolateral or bilateral for select cases, particularly when sternotomy is not feasible due to prior surgeries. Intraoperative considerations emphasize meticulous adhesiolysis to separate the pericardial shell from adjacent structures like the pleura, , and epicardium, while scrupulously avoiding injury to the phrenic nerves through anterior and posterior dissection planes—phrenic preservation is critical to prevent postoperative diaphragmatic paralysis. If the epicardium is thickened and contributing to , concomitant epicardiectomy may be required; preoperative medical optimization with agents for 3-6 months is briefly employed if transient is suspected to reduce intraoperative . In highly selected patients, modern minimally invasive options such as robotic-assisted approaches are emerging but remain limited by the need for extensive pericardial mobilization and are not yet standard. Historically, pericardiectomy carried high rates of 20-30% in early series, particularly for advanced disease, due to limited diagnostic , incomplete resections, and challenges in managing low . Contemporary outcomes have improved markedly with advancements in preoperative (e.g., cardiac /MRI for mapping), high-volume expertise, and CPB utilization, reducing 30-day mortality to 5-10% overall, though risks remain elevated (up to 27%) in post-radiation cases. These enhancements underscore the importance of timely intervention in suitable candidates to optimize long-term survival and symptom relief.

Prognosis and Complications

Treatment Outcomes

Surgical pericardiectomy offers substantial benefits for patients with chronic constrictive pericarditis (CP), with approximately 80% achieving freedom from class III/IV symptoms at 5 years postoperatively. Overall 5-year survival rates following pericardiectomy reach 87% across studied cohorts, rising above 80% in cases of idiopathic etiology and optimal surgical candidates. These outcomes reflect data from large series encompassing over 600 patients, underscoring the procedure's efficacy in restoring cardiac function when performed in specialized centers. Medical management, primarily involving anti-inflammatory therapies such as NSAIDs and , can lead to transient resolution of CP in 10-20% of cases, particularly those with evidence of active pericardial inflammation on imaging. However, for chronic, non-inflammatory CP, medical approaches provide only symptomatic palliation with diuretics, and untreated disease carries a high mortality , exceeding 90% over time due to progressive . The 2025 ACC guidelines emphasize trialing therapy for 3-6 months in suspected transient CP before considering . Prognostic factors significantly influence post-treatment results, with earlier surgical intervention in patients comprising less than 50% in NYHA class IV yielding superior and functional recovery compared to delayed operations in advanced disease. The 2025 ACC guidelines highlight the role of preoperative , including cardiac magnetic for detecting and computed for assessing pericardial , in predicting surgical outcomes and guiding patient selection. Post-treatment quality of life improves markedly, with patients demonstrating enhanced exercise tolerance through increased peak oxygen uptake and cardiopulmonary capacity six months after pericardiectomy. This functional gain correlates with reduced hospitalizations for exacerbations, as symptom relief diminishes the need for frequent medical interventions.

Potential Complications

Constrictive pericarditis can lead to progressive right due to impaired diastolic filling and elevated venous pressures, resulting in systemic congestion. This condition is associated with an approximately 30% incidence of , often linked to pericardial calcification and prolonged disease duration. Chronic hepatic congestion from right-sided failure may progress to cardiac cirrhosis, characterized by and micronodular changes, as seen in case reports where pericardiectomy reversed early hepatic derangements. Surgical management via pericardiectomy carries perioperative risks, including mortality rates of 5-15%, primarily from low or incomplete resection. Common complications encompass , , and persistent in 10-20% of cases, often due to incomplete pericardial removal leading to ongoing hemodynamic impairment. Long-term sequelae include recurrence of constriction following partial pericardiectomy, necessitating reoperation in select patients with comparable functional improvements but elevated risks. In cases of radiation-induced constrictive pericarditis, 2025 guidelines emphasize ongoing multimodality imaging surveillance for cardiovascular toxicities, alongside monitoring for secondary radiation-induced malignancies given the shared in cancer survivors. The 2025 ESC guidelines recommend multimodality imaging for early detection and surveillance in high-risk cases, such as radiation-induced , to monitor for progression and secondary malignancies. Preventive measures focus on early diagnosis using , cardiac MRI, and as recommended by the 2025 ESC guidelines, which advocate multimodality imaging to detect promptly and avert end-stage complications like or refractory . Treating underlying etiologies, such as with antituberculous therapy and adjunctive steroids, can reduce the risk of progression to from approximately 30-50% to 10-20%.