Surgical pathology of the parietal pericardium: a study of 344 cases (1993-1999)

Pericardial Calcification: An Uncommon Case with Intraventricular Extension

An 80-year-old man presented to the cardiology outpatient clinic due to shortness of breath. His past medical history included alcohol intake, hypertension, inferior wall myocardial infarction (five years ago), an ischemic stroke, and permanent atrial fibrillation (diagnosed three years before the current examination). A physical exam revealed a decreased intensity of S1 and S2, irregular rate and rhythm, and no murmurs nor friction rub. X-rays, Computed Tomography, and echocardiography exhibited pericardial calcification, involving mostly the inferior wall and protruding into the left ventricle. A diagnosis of constrictive pericarditis due to pericardial calcification was established and considered idiopathic. Even when it may be related to ischemic heart disease, post-infarction pericarditis could explain how the calcification extended to adjacent territory perfused by the circumflex coronary artery. Combined imaging studies were crucial not only for identifying calcium deposits in the pericardium but also in assessing a patient inherently prone to co-existing and exacerbating conditions. Even though pericardiectomy allows for removal of the clinical manifestations of congestive pericarditis in the most symptomatic patients with pericardial calcification, among patients like ours, with tolerable symptoms, cardiologists should discuss the therapeutic options considering the patient's choices, potentially including a rehabilitation plan as part of non-pharmacological management.

Tuberculosis of the Heart: A Diagnostic Challenge

Tuberculosis of the heart is relatively rare and presents a significant diagnostic difficulty for physicians. It is the leading cause of death from infectious illness. It is one of the top 10 leading causes of death worldwide, with a disproportionate impact in low- and middle-income nations. The radiologist plays a pivotal role as CMR is a non-invasive radiological method that can aid in identifying potential overlap and differential diagnosis between tuberculosis, mass lesions, pericarditis, and myocarditis. Regardless of similarities or overlap in observations, the combination of clinical and certain particular radiological features, which are also detected by comparison to earlier and follow-up CMR scans, may aid in the differential diagnosis. CMR offers a significant advantage over echocardiography for detecting, characterizing, and assessing cardiovascular abnormalities. In conjunction with clinical presentation, knowledge of LGE, feature tracking, and parametric imaging in CMR may help in the early detection of tuberculous myopericarditis and serve as a surrogate for endomyocardial biopsy resulting in a quicker diagnosis and therapy. This article aims to explain the current state of cardiac tuberculosis, the diagnostic utility of CMR in tuberculosis (TB) patients, and offer an overview of the various imaging and laboratory procedures used to detect cardiac tuberculosis.

Depressed right ventricular systolic function in heart failure due to constrictive pericarditis

Aims

Heart failure in constrictive pericarditis (CP) is attributed to impaired biventricular diastolic filling. However, diseases that cause CP due to myocardial infiltration and fibrosis can also impair biventricular systolic function (sf) and contribute to heart failure. This study of patients with CP examined biventricular sf and the effect of myocardial infiltration by pericardial diseases and the resulting fibrosis on ventricular sf.

Methods and results

Histopathologic examinations of right ventricular (RV) and left ventricular (LV) myocardia and pericardia were performed on three autopsied hearts of patients with pericardial diseases. Additionally, in 40 adults with clinical heart failure and 40 healthy adults (controls), sf of both ventricles was examined by echocardiography, including strain measurements, and biventricular diastolic filling and pulmonary artery pressures were assessed by cardiac catheterization. Cardiac histopathology indicated thickening of the pericardium with fibrosis, disease infiltrating the myocardium, greater infiltration of the RV than the LV, and an association of pericardial thickness with myocardial infiltrations. Functional analysis indicated that RVsf was impaired on all echo indices, including strain measurement, but LVsf was preserved.

Conclusions

Diseases causing CP are not restricted to the pericardium but also infiltrate the biventricular myocardium and affect the thin‐walled RV more than the thick‐walled LV, resulting in depressed RVsf. The present results help explain clinical heart failure in the presence of restricted diastolic filling in CP. Depression of RVsf due to progression of fibrosis in the RV myocardium may increase the risk of delayed pericardiectomy.

Multimodality approach to the diagnosis and management of constrictive pericarditis

Despite advances in cardiovascular imaging, the diagnosis of constrictive pericarditis remains challenging. A multimodality approach to the diagnosis of CP is essential to (a) fully assess the extent of pericardial thickening and calcification, (b) detect the functional and hemodynamic consequences of the constricting pericardium, and (c) implement the optimal management strategy in these often complex cases. This case-based review highlights the role and diagnostic ambiguities of multimodality imaging.

Diagnostic Utility of Cyfra 21-1 and Cea Assays in Pericardial Fluid for the Recognition of Neoplastic Pericarditis

A positive cytology result in pericardial fluid is the gold standard for recognition of malignant pericardial effusion. Unfortunately, in 30–50% of patients with malignant pericardial effusion cytological examination of the pericardial fluid is negative. Tumor marker assessment in pericardial fluid may help to recognize malignant pericardial effusion. The aim of our study was to estimate the value of CYFRA 21-1 and CEA measurement in pericardial fluid for the recognition of malignant pericardial effusion. To our knowledge this is the first study on CYFRA 21-1 assessment in pericardial effusion. The examined group consisted of 50 patients with malignant pericardial effusion and 34 patients with non-malignant pericardial effusion. Median CEA concentrations in malignant pericardial effusion and non-malignant pericardial effusion were 80 ng/mL (0–317) and 0.5 ng/mL (0–18.4), respectively (p<0.001). Median CYFRA 21-1 concentrations in malignant pericardial effusion and non-malignant pericardial effusion were 260 ng/mL (5.3–10080) and 22.4 ng/mL (1.87–317.6), respectively (p<0.001). The optimal cutoff value for CYFRA 21-1 in pericardial effusion was 100 ng/mL. CYFRA 21-1 >100 ng/mL or CEA >5 ng/mL were found in 14/15 patients with malignant pericardial effusion and negative pericardial fluid cytology. We therefore strongly recommend the use of CYFRA 21-1 and/or CEA in addition to pericardial fluid cytology for the recognition of malignant pericardial effusion.

Clinical features, management and outcome of patients with constrictive pericarditis - Experience from a third world country

Objectives

To study the clinical features, management and outcome of patients with constrictive pericarditis, at a tertiary care hospital of Pakistan.

Design

Descriptive study.

Material & method

All consecutive patients with the final diagnosis of constrictive pericarditis, admitted at Aga Khan University Hospital Karachi, during the year 2005 to 2015 were included in the study.

Results

A total of 21 patients were diagnosed and managed as constrictive pericarditis during the above mentioned period. Mean age was 39 + 19.9 years. There was a male preponderance with a male to female ratio of 2.5:1.The most common clinical features were those of right heart failure. Only 2 (9.5%) patients showed pericardial calcification on X-ray chest. Dilated atria and septal bounce were the most common echo features present in 15 (71.4%). MRI/CT was done in only 11 patients, of which eight showed increased pericardial thickness. Three had normal pericardial thickness on MRI/CT but were proved to have constriction surgically. Cardiac catheterization was done in nine patients only. Elevated filling pressures and square root sign were the most common findings, present in all (100%). Pericardiectomy was performed in 12 (57%) patients. Five more patients were advised surgery but two died before the surgery and three were taken to other hospitals as they wanted to explore other options beside surgery. Pericardial tissue histopathology was available in only 11 patients. It revealed tuberculosis in three cases, while in 8 cases it was nonspecific. Six patients died with an overall mortality of 28.6%. Five patients died during hospitalization, four without surgery and one after the surgery. One patient died during follow up (was considered unfit for the surgery). Mean follow up duration was 7.3 + 9.3 months. No death occurred on follow up in surgically treated patients.

Conclusion

Features of right heart failure is the most common mode of presentation of CP. The most probable etiology in this part of the world is tuberculosis, although difficult to prove on histopathology. Pericardiectomy is the usual recommended treatment due to advanced disease at the time of presentation.

Pericardial interstitial cell senescence responsible for pericardial structural remodeling in idiopathic and postsurgical constrictive pericarditis

OBJECTIVE

Idiopathic and postsurgical constrictive pericarditis is characterized by pericardial structural remodeling that involves fibrosis, calcification, and inflammation. This study aimed to determine whether cell senescence was responsible for pericardial structural remodeling.

METHODS

Pericardial interstitial cells derived from patients with idiopathic or postsurgical pericarditis (pericarditis cells) were harvested. Timing of senescence and differences in telomere length were compared between age- and sex-matched controls (nonpericarditis cells). Pericardial interstitial cells derived from normal pericardia were serially passaged until senescence (senescent cells). Apoptosis, collagen matrix, calcium deposition, chemoattractant properties, gene expression profiles, and paracrine effects of senescent cells were compared with nonsenescent cells of passage 2 (nonsenescent cells).

RESULTS

Pericarditis cells displayed senescent changes, including short telomere length, large flattened cell sizes, positive staining for senescence-associated β-galactosidase, and limited growth capacity. These senescent cells were resistant to apoptosis, produced more collagen matrix, deposited more calcium, and attracted more monocytes/lymphocytes than the nonsenescent cells. A cluster of genes involved in extracellular matrix deposition (connective tissue growth factor, fibronectin, collagen type I, collagen type III, and tissue inhibitors of metalloproteinase-1), calcium deposition (osteopontin, bone sialoprotein, osteonectin, and matrix Gla protein), and inflammatory cell recruitment (interleukin-6, chemoattractant protein-1, and tumor necrosis factor-α) were upregulated in senescent cells, whereas extracellular matrix-degrading enzyme (metalloproteinase-1 and metalloproteinase-3) was downregulated. Furthermore, senescent cells had the ability to promote the proliferation, differentiation, and senescence of neighboring cells.

CONCLUSIONS

These findings suggest that senescent cells have characteristics promoting pericardial structural remodeling, but further work is needed to establish causation.

Histologic Evaluation of Explanted Tissue-Engineered Bovine Pericardium (CardioCel)

CardioCel is a bovine pericardium that is subjected to a novel anticalcification tissue-engineering process. We present the histopathologic findings of human explants of CardioCel that were used in operations for congenital heart disease in children. Six explants were identified from 140 patients undergoing CardioCel implants from October 2012 to March 2015. CardioCel explants were evaluated histologically using hematoxylin and eosin, Masson trichrome, and immunohistochemical staining. A variable inflammatory response was seen in the surrounding native tissue, but not within the CardioCel graft in any of the explants. A neointimal layer of varying thickness developed on the visceral surface of 5 CardioCel explants with endothelialization of the longest duration explant. A granulation tissue layer developed on the parietal surface of the graft (consistently thicker than the neointima). Maintained collagen fiber architecture (laminated) and variable fibroblastic invasion (which increased with the age of the implant) were identified in all 6 cases. Scattered capillary vessels were noted in the majority of the explants with new collagen fibers in one, suggesting early remodeling. Calcium was seen in 1 explant at the interface of the graft and inflammatory response on its parietal surface. Evidence of graft remodeling was noted in the majority of the explants without inflammatory cells or calcification within the explanted graft material. A noticeable feature was the differential thickness of the host reaction to the parietal compared with the visceral surface of the graft. We will continue to evaluate CardioCel as a cardiovascular substitute for extracardiac and intracardiac reconstructions.

MR imaging evaluation of pericardial constriction

Abnormal thickening or rigidity of the pericardium may compromise normal cardiac function. This condition is known as pericardial constriction, or constrictive pericarditis. Several imaging modalities are used to evaluate the pericardium, including MR, computed tomography, and echocardiography, which can all play a complementary role aiding diagnosis. This article focuses on MR imaging and its role in the detection and evaluation of pericardial constriction. MR imaging has many advantages compared with other modalities including precise delineation of the pericardial thickness, evaluation of ventricular function, detection of wall motion abnormalities, and provision of information about common (and potentially harmful) sequelae of pericardial constriction.

Constrictive pericarditis--a curable diastolic heart failure

Constrictive pericarditis can result from a stiff pericardium that prevents satisfactory diastolic filling. The distinction between constrictive pericarditis and other causes of heart failure, such as restrictive cardiomyopathy, is important because pericardiectomy can cure constrictive pericarditis. Diagnosis of constrictive pericarditis is based on characteristic haemodynamic and anatomical features determined using echocardiography, cardiac catheterization, cardiac MRI, and CT. The Mayo Clinic echocardiography and cardiac catheterization haemodynamic diagnostic criteria for constrictive pericarditis are based on the unique features of ventricular interdependence and dissociation of intrathoracic and intracardiac pressures seen when the pericardium is constricted. A complete pericardiectomy can restore satisfactory diastolic filling by removing the constrictive pericardium in patients with constrictive pericarditis. However, if inflammation of the pericardium is the predominant constrictive mechanism, anti-inflammatory therapy might alleviate this transient condition without a need for surgery. Early diagnosis of constrictive pericarditis is, therefore, of paramount clinical importance. An improved understanding of how constrictive pericarditis develops after an initiating event is critical to prevent this diastolic heart failure. In this Review, we discuss the aetiology, pathophysiology, and diagnosis of constrictive pericarditis, with a specific emphasis on how to differentiate this disease from conditions with similar clinical presentations.

Pericardial disease: value of CT and MR imaging

The pericardium represents an important focus of morbidity and mortality in patients with cardiovascular disease. Fortunately, in recent years knowledge regarding this enigmatic part of the heart and the diagnosis of related diseases has substantially advanced. To a large extent, this can be attributed to the availability of several noninvasive cardiac imaging modalities. Transthoracic echocardiography, which combines structural and physiologic assessment, is the first-line technique for examination of patients suspected of having or known to have pericardial disease; however, cardiac computed tomography (CT) and magnetic resonance (MR) imaging are becoming increasingly popular for the study of this part of the heart. Modern multidetector CT scanners merge acquisition speed and high spatial and contrast resolution, with volumetric scanning to provide excellent anatomic detail of the pericardium. Multidetector CT is by far the modality of choice for depiction of pericardial calcifications. MR imaging is probably the best imaging modality for the acquisition of a comprehensive view of the pericardial abnormalities. MR imaging combines cardiac and pericardial anatomic assessment with tissue characterization and appraisal of the effects of pericardial abnormalities on cardiac performance. This review aims to elucidate the role of the pericardium and its interaction with the remainder of the heart in normal and pathologic conditions. It focuses on the rapidly evolving insights regarding pericardial disease provided by modern imaging modalities, not infrequently necessitating reconsideration of evidence that has thus far been taken for granted.

SUPPLEMENTAL MATERIAL

http://radiology.rsna.org/lookup/suppl/doi:10.1148/radiol.13121059/-/DC1.

Constrictive pericarditis with a calcific mass invading into the right ventricular myocardium

We present a rare and unique case of calcific constrictive pericarditis with a calcified pericardial mass invading the right ventricular myocardium. Perioperative two-dimensional and three-dimensional transesophageal echocardiography revealed the extent and structure of the pericardial mass and led to the repair of the right ventricular free wall as a surgical intervention.

MR imaging findings in 76 consecutive surgically proven cases of pericardial disease with CT and pathologic correlation

To describe findings of patients with surgically confirmed pericardial disease on state of the art MR sequences. Retrospective review was performed for patients who underwent pericardiectomy and preoperative MR over a 5 year period ending in 2009. Patients' records were reviewed to confirm the diagnosis of chronic recurrent pericarditis, constrictive pericarditis, or pericardial tumor. MR imaging findings of pericardial thickness, IVC diameter, presence or absence of pericardial or pleural effusion, pericardial edema, pericardial enhancement, and septal "bounce" were recorded. Patients with constriction had a larger IVC diameter (3.1 ± 0.4 cm) than patients with recurrent pain and no constriction (2.0 ± 0.4 cm). Mean pericardial thickness for the 16 patients with chronic recurrent pericarditis but no evidence of constriction was 4.8 ± 2.9 mm. Mean pericardial thickness for patients with constriction was 9.2 ± 7.0 cm with calcification, and 4.6 ± 2.1 cm without calcification. 94% of patients with chronic recurrent pericarditis had gadolinium enhancement of the pericardium, while 76% of patients with constriction had pericardial enhancement. Septal "bounce" was present in 19% of chronic recurrent pericarditis cases and 86% of constriction cases. 5 patients had a pericardial neoplasm, 1 of which was not identified preoperatively. State of the art MR techniques can identify significant and distinct findings in patients with chronic recurrent pericarditis, constrictive pericarditis, and pericardial tumors.

[Restrictive cardiomyopathy versus constrictive pericarditis in patients with diastolic dysfunction: MR imaging features]

Restrictive cardiomyopathies are characterized by diastolic dysfunction while systolic function is usually preserved. MRI is helpful by its ability to characterize tissues, especially the demonstration of interstitial or nodular fibrosis based on the underlying etiology. In the presence of constrictive pericarditis from pericardial inflammation, fibrosis or calcifications, diastolic expansion is impaired resulting in poor diastolic ventricular filling, resulting in a characteristic type of diastolic impairment, adiastole. MRI can demonstrate the underlying anatomical lesion: pericardial thickening, though the presence of a pericardium or normal thickness does not entirely exclude the possibility of constriction. As such, the presence of additional imaging features such as abnormal right ventricular shape, vena cava dilatation, and paradoxical movement of the intraventricular septum, during operator-guided deep respiration.

Magnetic resonance imaging of pericardial disease and intracardiac thrombus

Magnetic resonance is known to be a superior modality for the evaluation of pericardial disease and intracardiac masses because of its unmatched capacity for tissue characterization and high spatial resolution. New real-time sequences complement the standard morphologic imaging of the pericardium with dynamic image acquisitions that also can provide hemodynamic information indicative of constriction. Magnetic resonance also is becoming increasingly recognized as a superior modality for the detection and characterization of intracardiac thrombus. This article reviews the use of magnetic resonance imaging for the evaluation of pericardial disease and the detection of intracardiac thrombus, with particular emphasis on the newer pulse sequences currently available for cardiac imaging.

Tuberculous constrictive pericarditis with concurrent active pulmonary tuberculous infection: a case report

Introduction

In some particular endemic area, it is not uncommon to see patients with tuberculosis pericarditis. However, it takes a period of time from tuberculous pericarditis to constrictive pericarditis. There is still no report of tuberculous constrictive pericarditis concurrent with active pulmonary TB infection in a patient without previous pulmonary TB infection history. Therefore, we reported a TB constrictive pericarditis with rare disease progress.

Case presentation

We report the case of a 63-year-old Taiwanese man with tuberculous constrictive pericarditis concurrent with active pulmonary tuberculous infection presenting with progressive extremities edema, puffy face, abdominal distension and dyspnea on exertion found to be caused by right heart failure. The patient was cured by pericardial stripping and anti-tuberculosis chemotherapy. We reviewed other cases of tuberculous constrictive pericarditis from the literature and described the peculiarities of this case.

Conclusions

Rapid diagnosis and treatment of constrictive pericarditis are crucial to reduce mortality. In some endemic areas, Mycobacterium tuberculosis infection should be taken into consideration during diagnostic evaluations for constrictive pericarditis. Surgical intervention is still the treatment of choice when the patient has the symptoms or signs of pericardial constriction and right heart failure. Our case is a constant reminder that active Mycobacterium tuberculosis infection does present itself with uncommon presentations.

Cardiovascular magnetic resonance in pericardial diseases

The pericardium and pericardial diseases in particular have received, in contrast to other topics in the field of cardiology, relatively limited interest. Today, despite improved knowledge of pathophysiology of pericardial diseases and the availability of a wide spectrum of diagnostic tools, the diagnostic challenge remains. Not only the clinical presentation may be atypical, mimicking other cardiac, pulmonary or pleural diseases; in developed countries a shift for instance in the epidemiology of constrictive pericarditis has been noted. Accurate decision making is crucial taking into account the significant morbidity and mortality caused by complicated pericardial diseases, and the potential benefit of therapeutic interventions. Imaging herein has an important role, and cardiovascular magnetic resonance (CMR) is definitely one of the most versatile modalities to study the pericardium. It fuses excellent anatomic detail and tissue characterization with accurate evaluation of cardiac function and assessment of the haemodynamic consequences of pericardial constraint on cardiac filling. This review focuses on the current state of knowledge how CMR can be used to study the most common pericardial diseases.

Constrictive pericarditis: Detection of mycobacterium tuberculosis in paraffin-embedded pericardial tissues by polymerase chain reaction

BACKGROUND

Although the utility of polymerase chain reaction (PCR) for diagnosis of acute pleuro-pericardial tuberculosis has been well established, its use for chronic constrictive pericarditis is yet to be reported.

AIMS

To define the sensitivity and specificity of PCR for diagnosis of tuberculosis (TB) in patients with constrictive pericarditis.

METHODS

The medical records of 30 consecutive patients with constrictive pericarditis were reviewed. In addition their historical paraffin-embedded pericardial tissues were used for new histopathologic examination and PCR amplification for Mycobacterium tuberculosis genome.

RESULTS

There were 23 males and 7 females with a mean age of 35+/-19.5 years. The anticipated causes of constriction included idiopathic (n=21), tuberculosis (n=5), cardiac surgery (n=2) and post traumatic (n=2). PCR became positive in nine patients. Four out of 5 patients with tuberculous granuloma had a positive test result. In addition all 4 patients with non-tuberculous constrictive pericarditis had a negative test result. Therefore considering the presence or absence of granuloma as a diagnostic criteria, the sensitivity and specificity of PCR were 4/5 (80%) and 20/25 (80%), respectively.

[Pericardioperitoneal shunt in the treatment of pericardial effusions in neoplasic patients]

Neoplasia-related pericardial effusions are a frequent finding and pose diagnostic and therapeutic challenges. Although they appear in the context of an underlying neoplastic disease, 50% of these effusions have a benign etiology; they are indirectly caused by the tumor. The remaining cases (neoplastic pericardial effusions - NPE) derive from extension of tu- moral disease to the epi and/or pericardium and have, therefore, a worst prognosis. Despite several treatment options, the lack of appropriate guidelines difficults the evaluation of their efficacy and safety. Pericardioperitoneal shunt (PPS) is a surgical pericardial drainage method, which has demonstrated its usefulness in the management of NPE. At the CHC, this procedure is performed under videoassisted toracoscopic guidance (VATS). During the last 8 years, 18 patients have been submitted to this therapeutic option, which proved to be safe, efficacious and with low morbimortality rates.

Magnetic Resonance Imaging of Pericardial Disease and Cardiac Masses

MRI is known to be a superior modality for evaluating pericardial disease and masses because of its unmatched capacity for tissue characterization and high spatial resolution. New real-time sequences now complement the standard morphologic imaging of the pericardium with dynamic image acquisitions that also can provide hemodynamic information indicative of constriction. In the evaluation of masses, recently developed rapid imaging sequences have shortened examination times and improved lesion characterization. The full spectrum of pericardial disease and cardiac masses is reviewed, and the role of MRI explored.

Constrictive pericarditis: A reminder of a not so rare disease

Constrictive pericarditis is a rare condition characterized by clinical signs of right heart failure subsequent to loss of pericardial compliance. The etiology of constrictive pericarditis has changed during the last decades in developed countries. While, in the past, tuberculosis and idiopathic pericardial constriction were the prevalent causes of the disease, cardiac surgery has become one of the main reasons for its development in recent years. However, cases defined as idiopathic constrictive pericarditis are still observed. In addition to the classical chronic and subacute forms, new presentations, such as effusive-constrictive, localized, transient, occult, and constrictive pericarditis with normal pericardial thickness, have been described. Although conservative treatment may alleviate the patient's symptoms, pericardiectomy remains the only definitive treatment for the disease. It is worth noting that the sooner the diagnosis of pericardial constriction is established, the better the outcome is. The pathophysiological features, clinical findings, diagnostic tools, and therapeutic approach to constrictive pericarditis are detailed in this review.

Tuberculous pericardial abscess: a case report

We present the case of a 71-year-old diabetic man who came to us complaining of dyspnea for 1 month. Chest X-ray showed cardiomegaly and bilateral pleural effusion. Echocardiography showed a pericardial cystic mass with external compression of the right ventricle. Because of clinically impending cardiac tamponade, we performed urgent sternotomy and removed the pericardial mass without event. Pathologic examination of the excised pericardial specimen showed caseous necrosis compatible with tuberculosis infection. The patient was put on a 1-year treatment regimen of anti-tuberculosis medication. This case is an important reminder that tuberculosis can occur as a pericardial abscess.

Severe heart failure due to subacute effusive-constrictive pericarditis in a child

We report a 9-year-old boy with progressive heart failure due to effusive-constrictive pericarditis. The patient was successfully rescued by extensive surgical removal of the thickened pericardium. The histopathological examination revealed degenerative changes of myocardium without significant inflammation, indicating that surgical pericardiectomy should be performed for subacute effusive-constrictive pericarditis before progression to definite constrictive pericarditis.

CT and MR imaging of pericardial disease

The diagnosis and therapy of pericardial diseases are still a physician's challenge. Advanced CT and MR imaging technologies can display the complete morphology of the heart and the pericardium and of the adjacent thoracic structures with a spatial and contrast resolution below 1 mm. All the macromorphologic determinants of pericardial constriction and their functional sequels may be identified by these remarkable technologies. A careful systematic image analysis defines not only a precise diagnosis but also determines the optimal surgical or conservative therapy for the individual patient and minimizes the risk of perisurgical mortality.

Constrictive pericarditis in 26 patients with histologically normal pericardial thickness

BACKGROUND

Traditionally, increased pericardial thickness has been considered an essential diagnostic feature of constrictive pericarditis. Although constriction with a normal-thickness pericardium has been demonstrated clinically by noninvasive imaging, the details of clinicopathological correlates have not been described.

METHODS AND RESULTS

A total of 143 patients with proven constriction underwent pericardiectomy at Mayo Clinic between 1993 and 1999. Their baseline characteristics, operative data, and pathological specimens were reviewed retrospectively. The pericardium was of normal thickness (< or =2 mm) in 26 patients (18%; group 1) and was thickened (>2 mm) in 117 (82%; group 2). The most common causes of constriction in group 1 included previous cardiac surgery, chest irradiation, previous infarction, and idiopathic disease. There was little difference in symptoms and findings on physical examination between the 2 groups. Microscopically, no patient had an entirely normal pericardium. Histopathological abnormalities in group 1 were mild and focal, including fibrosis, inflammation, calcification, fibrin deposition, and focal noncaseating granulomas. Pericardiectomy was equally effective in relieving symptoms regardless of the presence or absence of increased thickness.

CONCLUSIONS

Pericardial thickness was not increased in 18% of patients with surgically proven constrictive pericarditis, although the histopathological appearance was focally abnormal in all cases. When clinical, echocardiographic, or invasive hemodynamic features indicate constriction in patients with heart failure, pericardiectomy should not be denied on the basis of normal thickness as demonstrated by noninvasive imaging.

Imaging of pericardial disease

Pericardial pathology is most often identified by its effect on cardiac function. Echocardiography is usually performed first in evaluation of pericardial disease, but is occasionally limited or indeterminate. MR imaging is often helpful in these cases, offering superior soft tissue contrast and the ability to image the entire pericardium and its relationship to cardiac structure and function. Many of the techniques recently developed for myocardial imaging are equally applicable to the pericardium and frequently assist in the diagnosis of pericardial disease. In this article, the authors review MR imaging techniques for pericardial imaging, discuss the appearance of the normal pericardium, and illustrate pathologic and congenital conditions of the pericardium.

Iatrogenic cardiac papillary fibroelastoma: a study of 12 cases (1990 to 2000)

Cardiac papillary fibroelastoma (PFE) is a rare, benign, slow-growing tumor of the endocardium. Whether it represents a reactive tumoral lesion or a true neoplasm remains a matter of debate. However, an anecdotal association of PFEs with previous cardiac surgery has been reported. The current study was undertaken to determine the frequency and nature of iatrogenic events associated with PFEs and to provide a comprehensive review of the topic. The study group comprised 12 cases seen between 1990 and 2000, with specimens from 7 women and 5 men. Six developed postoperatively and 6 developed after thoracic irradiation. The 9 Mayo cases represented 18% of all surgically excised PFEs during the study period. The mean age at operation was 54 years (range, 29 to 79 years). The mean interval between the iatrogenic event and excision of the tumor was 18 years (range, 9 to 31 years). In 58% of cases, the presence of multiple tumors was either confirmed pathologically (41.7%) or strongly suggested by echocardiography (16.6%). Among patients who had undergone previous cardiac surgery, PFEs were found in the chamber closest to the procedure. Similarly, in patients who had received radiation therapy, tumors developed in the left atrium, in the right ventricle and atrium, and on the tricuspid valve within the radiation field. In conclusion, iatrogenic PFEs may be relatively common among all such tumors, are frequently multiple, and often involve nonvalvular endocardial surfaces.