Value of dynamic respiratory changes in left and right ventricular pressures for the diagnosis of constrictive pericarditis

Multimodality Imaging in Differentiating Constrictive Pericarditis From Restrictive Cardiomyopathy: A Comprehensive Overview for Clinicians and Imagers

In the evaluation of heart failure, 2 differential diagnostic considerations include constrictive pericarditis and restrictive cardiomyopathy. The often outwardly similar clinical presentation of these 2 pathologic entities routinely renders their clinical distinction difficult. Consequently, initial assessment requires a keen understanding of their separate pathophysiology, epidemiology, and hemodynamic effects. Following a detailed clinical evaluation, further assessment initially rests on comprehensive echocardiographic investigation, including detailed Doppler evaluation. With the combination of mitral inflow characterization, tissue Doppler assessment, and hepatic vein interrogation, initial differentiation of constrictive pericarditis and restrictive cardiomyopathy is often possible with high sensitivity and specificity. In conjunction with a compatible clinical presentation, successful differentiation enables both an accurate diagnosis and subsequent targeted management. In certain cases, however, the diagnosis remains unclear despite echocardiographic assessment, and additional evaluation is required. With advances in noninvasive tools, such evaluation can often continue in a stepwise, algorithmic fashion noninvasively, including both cross-sectional and nuclear imaging. Should this additional evaluation itself prove insufficient, invasive assessment with appropriate expertise may ultimately be necessary.

Lack of "ventricular interdependence" in constrictive pericarditis and atrial septal defect

Ventricular interdependence, i.e., reciprocal variations in the left and right ventricle pressures with respiration, is a hallmark of the hemodynamic diagnosis of constrictive pericarditis (CP). Similarly, respiratory variations in the mitral and tricuspid valve Doppler inflow velocities on echocardiogram are very helpful in the diagnosis of CP. We document the absence of such variations in a patient with CP and associated atrial septal defect. It is important to be mindful of this intuitively obvious fact; otherwise, the diagnosis of CP might be missed.

Echocardiographic Criteria to Differentiate Constrictive Pericarditis From Restrictive Cardiomyopathy: A Meta-analysis

Background

To assess the diagnostic accuracy of the Mayo Clinic echocardiographic criteria for differentiating between constrictive pericarditis and restrictive cardiomyopathy.

Methods

We searched electronic databases for the date range from their inception to July 1, 2022. The index tests were the Mayo Clinic echocardiographic criteria. We performed a bivariate random-effects model to estimate the pooled sensitivity and specificity, each with 95% confidence interval (CI). The area under the curve of the summary receiver operator characteristic curves, with 95% CI, was also calculated.

Results

We included 17 case-control studies involving 889 patients. The pooled sensitivity and specificity (95% CI), respectively, were as follows: ventricular septal shift, 82% (60%-94%) and 78% (65%-87%); respiratory variation in mitral inflow ≥ 14.6%, 71% (51%-85%) and 82% (66%-91%); septal e' velocity ≥ 8 cm/s, 83% (80%-87%) and 90% (83%-95%); septal e' velocity/lateral e' velocity ≥ 0.88, 74% (64%-82%) and 81% (70%-88%); and hepatic vein ratio in expiration ≥ 0.79, 73% (65%-81%) and 71% (19%-96%). The area under the curve of the summary receiver operator characteristic curves varied from 0.75 to 0.85, with overlapping CIs across index tests.

Conclusions

Our meta-analysis suggests that all echocardiographic parameters from the Mayo Clinic criteria have good diagnostic accuracy for differentiating between constrictive pericarditis and restrictive cardiomyopathy.

Cardiovascular complications of mantle field radiation: a case series

Background

Mantle field radiotherapy has been known to cause cardiovascular complications even years after therapy. Complications include pericardial disease, coronary artery disease, and conduction abnormalities.

Case summary

We present a case series of two patients who developed cardiovascular complications years after receiving mantle radiation. Patient 1 is a 52-year-old man who presented with symptoms of heart failure. He had a neurostimulator which precluded him from cardiac magnetic resonance imaging. Haemodynamic findings on right heart catheterization raised suspicion for constrictive pericarditis and pericardiectomy was performed. Histopathological analysis reported dense, sclerotic fibrous tissue consistent with radiation-related changes. Patient 2 is a 37-year-old man with a 2-month history of chest pain and exertional dyspnoea who was admitted for management of coronary artery disease. Coronary angiography demonstrated bilateral subclavian artery stenosis and an elevated left ventricular end-diastolic pressure (50 mmHg). He had bilateral percutaneous subclavian artery stenting. Both patients had complete resolution of symptoms on follow-up.

Discussion

Our case series emphasizes the need for an index of suspicion for radiation-related cardiovascular changes in patients who have a history of mantle radiation, especially in younger patients. This was especially pertinent in the case of our first patient who presented a diagnostic challenge due to certain patient factors. Our second patient is a case of subclavian artery stenosis which is less frequently reported as a complication of mantle radiation in the literature.

Left ventricular strain-curve morphology to distinguish between constrictive pericarditis and restrictive cardiomyopathy

Aims

To distinguish between constrictive pericarditis (CP) and restrictive cardiomyopathy (RCM) using cardiac magnetic resonance feature tracking (CMR‐FT) left ventricle (LV) diastolic time–strain curve patterns and myocardial strain.

Methods and Results

A total of 32 CP patients, 27 RCM patients, and 25 control subjects were examined by CMR‐FT and analysed for global strain, segmental strain, and LV time–strain curve patterns in the longitudinal, circumferential, and radial directions. Speckle tracking echocardiography (STE) strain imaging was performed in some cases. The peak global longitudinal strain (GLS) and global circumferential strain (GCS) of the RCM group were lower than those of the CP group. GLS [median (interquartile range) CP vs. RCM: −11.15 (−12.85, −9.35) vs. −6.5 (−8.75, −4.85), P < 0.001] and GCS (CP vs. RCM: −16.89 ± 5.11 vs. −13.37 ± 5.79, P < 0.001). In circumferential and radial directions, the strain ratios of the LV lateral/septal wall (LW/SW) of the CP group were significantly lower than those of the RCM group at the basal and mid segments. The CS ratio of LW/SW at the basal segment [CP vs. RCM: 0.95 (0.85, 1.25) vs. 1.43 (1.18, 1.89), P < 0.001] and mid segment [CP vs. RCM: 1.05 (0.92, 1.15) vs. 1.18 (1.06, 1.49), P = 0.026]. The RS ratio of LW/SW at the basal segment [CP vs. RCM: 0.97 (0.76, 1.37) vs. 1.55 (1.08, 2.31), P = 0.006] and mid segment [CP vs. RCM: 0.95 (0.70, 1.28) vs. 1.79 (1.32, 2.92), P < 0.001]. In the longitudinal and circumferential directions, the characteristic ‘plateau’ pattern of time–strain curves could be seen in the CP but not in the RCM during the diastole. The GCS ratio of 0–50%/50–75% diastolic period of the CP was higher than that of the RCM [CP vs. RCM: 17.01 (8.67, 23.75) vs. 5.38 (1.93, 11.24), P = 0.001], while the GCS ratio of 50–75%/75–100% diastolic period was lower than that of the RCM [CP vs. RCM: 0.36 (0.15, 1.67) vs. 1.12 (0.70, 5.58), P < 0.001]. The peak GLS (sensitivity, 85%; specificity, 78%) and the GCS ratio of 0–50%/50–75% diastolic period (sensitivity, 88%; specificity, 73%) had higher differential diagnosis value.

Conclusions

The CMR‐FT could distinctly differentiate CP from RCM based on LV myocardial strain and LV time–strain curve patterns. The characteristic ‘plateau’ pattern of the time–strain curve is specific for CP and not RCM and this curve can also be duplicated by STE.

Established and Emerging Techniques for Pericardial Imaging with Cardiac Magnetic Resonance

PURPOSE OF REVIEW

Pericardial diseases include a wide range of pathologies and their diagnosis can often be challenging. The goal of this review is to describe the established and emerging CMR imaging techniques used in the assessment of common pericardial diseases and explain the role of pericardial characterization in their diagnosis and management.

RECENT FINDINGS

CMR is indicated in cases of diagnostic uncertainty and for a comprehensive evaluation of the pericardium and its impact on the heart. This includes assessment of pericardial anatomy and associated cardiac hemodynamics, quantification and characterization of an effusion, disease staging, tissue characterization, guiding management, and even prognostication in some diseases of the pericardium. An emerging technique, pericardial characterization, utilizes various sequences to diagnose and stage pericardial inflammation, act as a biomarker in recurrent pericarditis, and guide management in inflammatory pericardial conditions. Beyond imaging, it has ushered in an era of tailored therapy for patients with pericardial diseases. Future directions should aim at exploring the role of tissue characterization in various pericardial diseases.

A Simplified Method for the Diagnosis of Constrictive Pericarditis in the Cardiac Catheterization Laboratory

Importance

Enhanced ventricular interdependence is a highly sensitive and specific criterion for the diagnosis of constrictive pericarditis (CP), but simultaneous ventricular measurements can be challenging at cardiac catheterization. Ejection times (ETs) correlate with stroke volumes and can be easily measured from arterial pressure tracings.

Objective

To assess respirophasic changes in pulmonary artery (PA) ETs and aorta (Ao) ETs as a marker for enhanced ventricular interdependence.

Design, Setting, and Participants

Retrospective analysis of simultaneous left-side and right-side heart catheterizations between January 2006 and January 2017 was performed. The data were analyzed in June 2020. All catheterizations were performed at the Mayo Clinic, Rochester, Minnesota. This study evaluated patients undergoing left-side and right-side heart catheterization for assessment of CP after noninvasive evaluation was inconclusive.

Main Outcomes and Measures

Measurements of the PA and Ao ETs were made during inspiration and expiration. Ventricular interaction was mainly assessed by evaluating the difference of ETs from expiration to inspiration as well as the difference in Ao minus the difference in PA.

Results

A total of 10 patients with surgically proven CP and 10 patients without CP (restrictive cardiomyopathy or severe tricuspid regurgitation) were identified. Of these 20 included patients, 10 (50%) were female, and the median (interquartile range) age was 59.5 (47.0-67.5) years. There were no significant differences in demographic characteristics or baseline hemodynamic measurements. In patients with CP compared with those without CP, there was a significantly greater decrease in PA ET (mean [SD], -31.8 [28.6] vs 5.1 [9.5]; P < .001) and a nonsignificantly greater increase in Ao ET (mean [SD], 19.0 [15.7] vs 10.5 [9.1]; P = 0.20) during expiration vs inspiration. Thus, the difference in Ao ET minus the difference in PA ET during expiration vs inspiration was significantly greater in those with CP compared with those without CP (mean [SD], 50.8 [22.5] milliseconds vs 5.4 [15.2] milliseconds; P < .001).

Conclusions and Relevance

In this study, PA and Ao measurements of ETs throughout the respiratory cycle were a simple, easily obtainable, and accurate parameter for the diagnosis of CP.

Prognostic importance of mitral e' velocity in constrictive pericarditis

AIMS

Increased medial mitral annulus early diastolic velocity (e') plays an important role in the echocardiographic diagnosis of constrictive pericarditis (CP) and mitral e' velocity is also a marker of underlying myocardial disease. We assessed the prognostic implication of mitral e' for long-term mortality after pericardiectomy in patients with CP.

METHODS AND RESULTS

We studied 104 surgically confirmed CP patients who underwent echocardiography and cardiac catheterization within 7 days between 2005 and 2013. Patients were classified as primary CP (n = 45) or mixed CP (n = 59) based on the clinical history of concomitant myocardial disease. On multivariable analysis, medial e' velocity and mean pulmonary artery pressure were independently associated with long-term mortality post-pericardiectomy. There were significant differences in survival rates among the groups divided by cut-off values of 9.0 cm/s and 29 mmHg for medial e' and mean pulmonary artery pressure, respectively (both P < 0.001). Ninety-two patients (88.5%) had elevated pulmonary artery wedge pressure (PAWP) (≥15 mmHg); there was no significant correlation between medial E/e' and PAWP (r = 0.002, P = 0.998). However, despite the similar PAWP between primary CP and mixed CP groups (21.6 ± 5.4 vs. 21.2 ± 5.8, P = 0.774), all primary CP individuals with elevated PAWP had medial E/e' <15 as opposed to 34 patients (57.6%) in the mixed CP group (P < 0.001).

CONCLUSION

Increased mitral e' velocity is associated with better outcomes in patients with CP. A paradoxical distribution of the relationship between E/e' and PAWP is present in these patients but there is no direct inverse correlation between them.

Cardiac magnetic resonance imaging in unclear cases of ventricular interdependence: a case series

BACKGROUND

Diagnosis of constrictive pericarditis requires demonstration of interventricular interdependence which can prove difficult even with invasive haemodynamics. Its treatment requires invasive surgical procedures prior to which diagnostic certainty is necessary. Cardiac magnetic resonance imaging (MRI) is an underutilized tool for identification of this pathology.

CASE SUMMARY

We present two cases of heart failure due to interventricular interdependence with inconclusive invasive haemodynamic. Prior to recommending invasive surgical treatment, confirmation of the diagnosis was required. This was achieved using cardiac MRI leading to pericardiectomy followed by clinical improvement.

DISCUSSION

These cases demonstrate the clinical utility, sensitivity, and specificity of cardiac MRI for ventricular interdependence.

ACR Appropriateness Criteria® Nonischemic Myocardial Disease with Clinical Manifestations (Ischemic Cardiomyopathy Already Excluded)

Nonischemic cardiomyopathies encompass a broad spectrum of myocardial disorders with mechanical or electrical dysfunction without evidence of ischemia. There are five broad variants of nonischemic cardiomyopathies; hypertrophic cardiomyopathy (Variant 1), restrictive or infiltrative cardiomyopathy (Variant 2), dilated or unclassified cardiomyopathy (Variant 3), arrhythmogenic cardiomyopathy (Variant 4), and inflammatory cardiomyopathy (Variant 5). For variants 1, 3, and 4, resting transthoracic echocardiography, MRI heart function and morphology without and with contrast, and MRI heart function and morphology without contrast are the usually appropriate imaging modalities. For variants 2 and 5, resting transthoracic echocardiography and MRI heart function and morphology without and with contrast are the usually appropriate imaging modalities. The American College of Radiology Appropriateness Criteria are evidence-based guidelines for specific clinical conditions that are reviewed annually by a multidisciplinary expert panel. The guideline development and revision include an extensive analysis of current medical literature from peer reviewed journals and the application of well-established methodologies (RAND/UCLA Appropriateness Method and Grading of Recommendations Assessment, Development, and Evaluation or GRADE) to rate the appropriateness of imaging and treatment procedures for specific clinical scenarios. In those instances where evidence is lacking or equivocal, expert opinion may supplement the available evidence to recommend imaging or treatment.

What pulmonologists need to know about extrapulmonary tuberculosis

Extrapulmonary tuberculosis (EPT) can affect all organs. Its diagnosis is often challenging, especially when the lung is not involved. Some EPT locations, such as when the central nervous system is involved, are a medical emergency, and some have implications for treatment options and length. This review describes clinical features of EPT, diagnostic tests and treatment regimens.

Extrapulmonary tuberculosis can affect any organ, can be potentially life threatening or disabling, poses diagnostic difficulties and may change the type and length of treatment. Looking for concomitant pulmonary tuberculosis is essential.https://bit.ly/2YEaRVb

An unusual presentation of dyspnea following septal ablation for obstructive hypertrophic cardiomyopathy

Residual or recurrent symptoms after septal reduction therapy are most often related to inadequate relief of left ventricular outflow gradients. We recently encountered a 71-year-old woman with hypertrophic cardiomyopathy and prior alcohol septal ablation who had a unique constellation of findings causing her symptoms. She was found to have four potential causes for her symptoms, residual midventricular obstruction, apical distribution of hypertrophy reducing end-diastolic volume, constrictive pericarditis, and marked arterial stiffness, as reflected by aortic atherosclerosis. She underwent complete pericardiectomy, transaortic septal myectomy, transapical myectomy, and replacement of a heavily calcified ascending aorta.

Constrictive Pericarditis: A Commonly Missed Cause of Treatable Diastolic Heart Failure

Constrictive pericarditis arises as a result of the fibrous thickening of the pericardium due to chronic inflammatory changes from various injuries. Increased pulmonary and systemic venous pressures manifest clinical features of left and right heart failure. Idiopathic or post-viral pericarditis is the most common cause followed by postpericardiotomy, radiation-induced causes. Right-sided heart failure symptoms predominate over left-sided heart failure symptoms due to the equalization of pressures. No single diagnostic test can provide a definitive diagnosis or evidence of constrictive pericarditis. Medical management is difficult for constrictive pericarditis. The treatment of choice for constrictive pericarditis is pericardiectomy.

Clinical Utility of Cardiac Magnetic Resonance Imaging in Pericardial Diseases

Background:

Pericardial diseases are relatively common in clinical practice and encountered in various clinical settings with consequent significant morbidity and mortality. However, the diagnosis as well as management can be complex and challenging, as the clinical presentation is usually non-specific. Therefore, there is an increasing role for Cardiac Magnetic Resonance Imaging (CMR) as an imaging tool to facilitate the diagnosis of pericardial diseases.

Conclusion:

Herein we describe conventional and unique CMR approaches to provide an increased non-invasive understanding of the pericardium in health and disease including a novel method to diagnose constrictive pericarditis via radio-frequency tissue tagging by defining unique visceral-parietal adherence patterns easily learned by the cardiologist and radiologist.

Effusive-Constrictive Pericarditis

Effusive-constrictive pericarditis (ECP) corresponds to the coexistence of a hemodynamically significant pericardial effusion and decreased pericardial compliance. The hallmark of ECP is the persistence of elevated right atrial pressure postpericardiocentesis. The prevalence of ECP seems higher in tuberculous pericarditis and lower in idiopathic cases. The diagnosis of ECP is traditionally based on invasive hemodynamics but the presence of echocardiographic features of constrictive pericarditis post-pericardiocentesisis can also identify ECP. Data on the prognosis and optimal treatment of ECP are still limited. Anti-inflammatory agents should be the first line of treatment. Pericardiectomy should be reserved for refractory cases.

Occult constrictive pericardial disease emerging 40 years after chest radiation therapy: a case report

Background

The main etiology of constrictive pericarditis (CP) has changed from tuberculosis to therapeutic mediastinal radiation and cardiac surgery. Occult constrictive pericardial disease (OCPD) is a covert disease in which CP is manifested in a condition of volume overload.

Case presentation

A 60-year-old patient with a history of thoracic radiation therapy for non-Hodgkin’s lymphoma (40 years earlier) was transferred to our hospital for treatment of repeated congestive heart failure. For a preoperative hemodynamic study, pre-hydration with intravenous normal saline (50 mL/hour) was used to manifest the pericardial disease and prevent contrast-induced nephropathy. The hemodynamic study showed a right ventricular dip-plateau pattern and discordance of right and left ventricular systolic pressures during inspiration, which was not seen in the volume-controlled state. These responses were concordant with OCPD. A pericardiectomy, aortic valve replacement, and mitral and tricuspid valve repair were performed. Postoperatively, the heart failure was controlled with standard medication.

Conclusions

This case revealed a volume-induced change in hemodynamics in OCPD with severe combined valvular heart disease, which suggests the importance of considering OCPD in patients who had undergone radiation therapy 40 years before.

Constrictive pericarditis: diagnosis, management and clinical outcomes

Constrictive pericarditis (CP) is a form of diastolic heart failure that arises because an inelastic pericardium inhibits cardiac filling. This disorder must be considered in the differential diagnosis for unexplained heart failure, particularly when the left ventricular ejection fraction is preserved. Risk factors for the development of CP include prior cardiac surgery and radiation therapy, but most cases are still deemed to be idiopathic. Making the diagnosis may be challenging and requires meticulous echocardiographic assessment, often supplemented by cross-sectional cardiac imaging and haemodynamic catheterisation. The key pathophysiological concepts, which serve as the basis for many of the diagnostic criteria, remain: (1) dissociation of intrathoracic and intracardiac pressures and (2) enhanced ventricular interaction. Complete surgical pericardiectomy is the only effective treatment for chronic CP. A subset of patients with subacute inflammatory CP, often identified by cardiac MRI, may respond to anti-inflammatory treatments.

Invasive Hemodynamics of Pericardial Disease

Pericardial diseases can be classified broadly as 3 entities: acute pericarditis, cardiac tamponade, and constrictive pericarditis. These disorders can be diagnosed and managed with noninvasive studies following a comprehensive history and physical examination, without the need for cardiac catheterization in most patients. Despite the advances in noninvasive cardiac imaging, there are limitations to their diagnostic accuracy. The invasive hemodynamic study offers the advantage of simultaneous, direct pressure measurement across multiple chambers, with direct examination of blood flow. Herein, the authors review the techniques for obtaining and interpreting invasive hemodynamic data in patients with suspected pericardial disease.

Redefining Effusive-Constrictive Pericarditis with Echocardiography

Background

Effusive-constrictive pericarditis (ECP) is traditionally diagnosed by using the expensive and invasive technique of direct pressure measurements in the pericardial space and the right atrium. The aim of this study was to assess the diagnostic role of echocardiography in tuberculous ECP.

Methods

Intrapericardial and right atrial pressures were measured pre- and post-pericardiocentesis, and right ventricular and left ventricular pressures were measured post-pericardiocentesis in patients with tuberculous pericardial effusions. Echocardiography was performed post-pericardiocentesis. Traditional, pressure-based diagnostic criteria were compared with post-pericardiocentesis systolic discordance and echocardiographic evidence of constriction.

Results

Thirty-two patients with tuberculous pericardial disease were included. Sixteen had ventricular discordance (invasively measured), 16 had ECP as measured by intrapericardial and right atrial invasive pressure measurements and 17 had ECP determined echocardiographically. The sensitivity and specificity of pressure-guided measurements (compared with discordance) for the diagnosis of ECP were both 56%. The positive and negative predictive values were both 56%. The sensitivity of echocardiography (compared with discordance) for the diagnosis of ECP was 81% and the specificity 75%, while the positive and the negative predictive values were 76% and 80%, respectively.

Conclusion

Echocardiography shows a better diagnostic performance than invasive, pressure-based measurements for the diagnosis of ECP when both these techniques are compared with the gold standard of invasively measured systolic discordance.

Echocardiographic parameters in clinical responders to surgical pericardiectomy - A single center experience with chronic constrictive pericarditis

BACKGROUND

Chronic constrictive pericarditis (CCP) is the end result of chronic inflammation of the pericardium. Developing countries continue to face a significant burden of CCP secondary to tuberculous pericarditis. Surgical pericardiectomy offers potential cure. However, there is paucity of echocardiography data in post-pericardiectomy patients vis-a-vis their clinical status. We studied the changes in multiple echocardiographic parameters in these patients before and after pericardiectomy.

METHODS

Twenty-three patients (14 men, 9 women) who underwent pericardiectomy for CCP in the last 5 years (from January 2009 to December 2014) were subjected to detailed clinical and echocardiographic evaluation during the study period (between June 2013 and December 2014). Patients with residual symptoms of NYHA class II and below were considered as 'responders'. The data thus obtained were compared to the pre-operative parameters.

RESULTS

After pericardiectomy, the incidence of vena caval congestion decreased from 100% to 15% (p<0.001). There was significant reduction in the mean left atrial size from 39.33±10.52mm to 34.45±10.08mm (p<0.001) and also the ratio of left atrium to aortic annulus from 1.93 to 1.69 (p<0.001) among 'responders' to pericardiectomy. Septal bounce was observed to persist in 5 (25%) patients after pericardiectomy. There was significant respiratory variation of 39.23±15.11% in the mitral E velocity before pericardiectomy. After pericardiectomy, this variation reduced to 14.43±7.76% (p<0.001). There was also significant reduction in the respiratory variation in tricuspid E velocities from 31.33±18.81% to 17.35±16.26% (p<0.001). After pericardiectomy, the mean ratio of mitral annular velocities, medial e': lateral e', reduced from 1.08 to 0.87 (p<0.03). The phenomenon of 'annulus reversus' was found to persist in 6 'responders', thereby reflecting a 50% reduction in its incidence after pericardiectomy (p<0.001). The ratio of mitral E to medial e' (E/e') increased from 4.21±1.35 before pericardiectomy to 6.91±2.62 after pericardiectomy (p=0.001).

CONCLUSION

Among clinical responders to surgical pericardiectomy, echocardiographic assessment revealed a significant reduction in vena caval congestion, LA size, ratio of LA to aortic annulus, septal bounce, respiratory variation in mitral and tricuspid E velocities, mitral annular medial e' and the phenomenon of annulus reversus. Also, there was a significant rise in minimum tricuspid and mitral E velocities and the E/e' ratio.

Case report: pericardial effusion with constrictive physiology in a patient with wet beriberi

Wet beriberi-induced pericardial effusion has rarely been previously described. Little is known about the effect of beriberi-induced pericardial effusion on hemodynamics. Here we present a case of wet beriberi with pericardial effusion that exhibited constrictive physiology, which was dramatically improved after treatment. A 61-year-old male patient was admitted to our hospital for progressive leg edema, dyspnea on exertion, and lower-extremity muscle weakness. Echocardiography showed a hyperkinetic left ventricle and a moderate amount of pericardial effusion. Hemodynamic measurements, including simultaneous measurement of left and right ventricular pressures, revealed high output heart failure and constrictive physiology. Blood test showed lactic acidosis, and low level of serum thiamine levels; consistent with a diagnosis of wet beriberi. After thiamine replacement therapy, the patient’s hemodynamic state rapidly improved. Additionally, pericardial effusion decreased and constrictive physiology was successfully resolved. No other possible causes of pericardial effusion could be identified, with the exception of thiamine deficiency. This case illustrates the importance of considering wet beriberi as a possible cause of pericardial effusion with constrictive physiology.

Characteristics, Complications, and Treatment of Acute Pericarditis

Acute pericarditis occurs most frequently after a viral attack. Other causes are autoimmune conditions, infection, chest trauma, cardiac surgery, or cardiac procedure. The presenting symptom is retrosternal chest pain. A pericardial rub is characteristic. Diffuse upward sloping ST segments are found with electrocardiogram. Pericardial effusions may be demonstrated with an echocardiogram. High-dose nonsteroidal antiinflammatory medications are the primary treatment. Adding colchicine reduces recurrence. It responds well to pharmacologic therapy within 1 to 2 weeks. Monitoring for complications is essential. The most serious complication is cardiac tamponade. For this, prompt diagnosis and treatment can be life-saving.

A Potential Echocardiographic Classification for Constrictive Pericarditis Based on Analysis of Abnormal Septal Motion

BACKGROUND

Constrictive pericarditis is an uncommon condition that could be easily confused with congestive heart failure. In symptomatic patients, septal "wobble" on echocardiography may be an important sign of constrictive physiology. This study was planned to investigate the effects of constriction on septal motion as identified by echocardiography.

METHODS

In this retrospective observational study, nine consecutive patients with constriction underwent careful echocardiographic analysis of the interventricular septum (IVS) with slow motion 2-dimensional echocardiography and inspiratory manoeuvres. Six patients who had undergone cardiac magnetic resonance imaging underwent similar analysis. Findings were correlated with haemodynamic data in five patients who had undergone cardiac catheterisation studies.

RESULTS

In mild cases of constriction a single wobble of the IVS was seen during normal respiration. In more moderate cases a double motion of the septum (termed "double wobble") was seen where the septum bowed initially into the left ventricle (LV) cavity in diastole then relaxed to the middle only to deviate again into the LV cavity late in diastole after atrial contraction. In severe cases, the septum bowed into the LV cavity for the full duration of diastole (pan-diastolic motion). We describe how inspiration also helped to characterize the severity of constriction especially in mild to moderate cases.

CONCLUSION

Echocardiography appears a simple tool to help diagnose constriction and grade its severity. Larger studies are needed to confirm whether the type of wobble motions helps to grade the severity of constrictive pericarditis.

Invasive hemodynamics of constrictive pericarditis

Cardiac catheterization and hemodynamic study is the gold standard for the diagnosis of pericardial constriction. Careful interpretation of the hemodynamic data is essential to differentiate it from other diseases with restrictive physiology. In this hemodynamic review we shall briefly discuss the physiologic basis of various hemodynamic changes seen in a patient with constrictive pericarditis.

Respiratory hemodynamics in the hepatic veins--abnormal patterns

The flow pattern in the hepatic veins (HVs) is dependent on the cardiac cycle and right heart hemodynamics and influenced by the respiratory cycle and the liver parenchyma. Most disease states that affect the right heart alter the HV Doppler in a manner independent of the respiratory cycle. Some diseases that typically involve the pericardium, right ventricular myocardium, or respiratory system confer characteristic changes to the HV flow in a manner dependent on the respiratory cycle. Analysis of the HV Doppler with assessment of the respiratory changes in flow and their timing helps to distinguish among the various disease states. In this manuscript, we discuss the effect of respiration on HV flow in patients with abnormal right heart function and illustrate the use of the respiratory changes in the HV Doppler as a tool for diagnosis.

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.

Echocardiographic investigation of the mechanism underlying abnormal interventricular septal motion after open heart surgery

Background

Abnormal interventricular septal motion (ASM) is frequently observed after open heart surgery (OHS). The aim of this study was to investigate the incidence and temporal change of ASM, and its underlying mechanism in patients who underwent OHS using transthoracic echocardiography (TTE).

Methods

In total, 165 patients [60 ± 13 years, 92 (56%) men] who underwent coronary bypass surgery or heart valve surgery were consecutively enrolled in a prospective manner. TTE was performed preoperatively, at 3--6-month postoperatively, and at the 1-year follow-up visit. Routine TTE images and strain analysis were performed using velocity vector imaging.

Results

ASM was documented in 121 of 165 patients (73%) immediately after surgery: 26 patients (17%) presented concomitant expiratory diastolic flow reversal of the hepatic vein, 11 (7%) had inferior vena cava plethora, and 11 (7%) had both. Only 2 patients (1%) showed clinically discernible constriction. ASM persisted 3--6 months after surgery in 38 patients (25%), but only in 23 (15%) after 1 year. There was no difference in preoperative and postoperative peak systolic strain of all segments of the left ventricle (LV) between groups with or without ASM. However, systolic radial velocity (V_Rad) of the mid anterior-septum and anterior wall of the LV significantly decreased in patients with ASM.

Conclusion

Although ASM was common (74%) immediately after OHS, it disappeared over time without causing clinically detectable constriction. Furthermore, we consider that ASM might not be caused by myocardial ischemia, but by the decreased systolic V_Rad of the interventricular septum after pericardium incision.

A case of recurrent pericardial constriction presenting with severe pulmonary hypertension

Chronic constrictive pericarditis (CP) is a relatively rare condition in which the pericardium becomes fibrotic and noncompliant, eventually resulting in heart failure due to impaired ventricular filling. The only curative treatment is pericardiectomy. Classically, CP does not usually cause severe pulmonary hypertension. When attempting to differentiate CP from restrictive cardiomyopathy, the presence of severely elevated pulmonary arterial pressure is used as a diagnostic criterion ruling against CP. We present a case of proven recurrent pericardial constriction following pericardiectomy presenting with severe pulmonary hypertension.

Hemodynamics of large ventricular septal defect and coexisting chronic constrictive pericarditis masquerading as Eisenmenger's syndrome

The presence of right to left shunting due to elevated pulmonary vascular resistance (PVR) in a patient with large ventricular septal defect (VSD) is conventionally considered as Eisenmenger's syndrome. The recognition of reversible causes of elevated PVR is important. We report hemodynamics of a child in whom unusual coexistence of large VSD and chronic constrictive pericarditis (CCP) mimicked Eisenmeneger's syndrome. The strategy of stepwise hemodynamic evaluation led to good clinical outcome.

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.

Hiding in plain sight; constrictive pericarditis

We present a case of constrictive pericarditis that was especially difficult to diagnose. The patient presented with generalised oedema, dyspnoea and pleural effusions. History was significant for prior polysubstance abuse but was otherwise unremarkable. Physical examination revealed only jugular venous distention. CT demonstrated a normal pericardium with pleural effusions. Echocardiography showed mildly elevated right ventricular pressures with dyssynergic motion of the ventricular septum. No intervention was being carried out, but 1 month later further evaluation with a right and left heart catheterisation showed the classical square-root sign with equalisation of diastolic pressures in both ventricles as well as ventricular interdependence. Idiopathic constrictive pericarditis was thus diagnosed with a subsequent pericardial stripping which confirmed a thickened pericardium encasing the heart.

Chronic constrictive pericarditis

Constrictive pericarditis (CP) is a rare clinical entity that can pose diagnostic problems. The diagnosis of CP requires a high degree of clinical suspicion. The gold standard for diagnosis is cardiac catheterization with analysis of intracavitary pressure curves, which are high and, in end diastole, equal in all chambers. We present a patient with unexplained dyspnea, recurrent right-side pleural effusion, and ascites. Analysis of the ascitic fluid revealed a high protein content and an elevated serum-ascites gradient. Echocardiography, computed tomography, and cardiac catheterization revealed the diagnosis of CP. He underwent complete pericardiectomy and to date has made a good recovery. The diagnosis of CP is often neglected by admitting physicians, who usually attribute the symptoms to another disease process. This case exemplifies the difficulty in diagnosing this condition, as well as the investigation required, and provides a discussion of the benefit and outcomes of prompt treatment.

Simultaneous right and left heart real-time, free-breathing CMR flow quantification identifies constrictive physiology

OBJECTIVES

The purpose of this study was to evaluate the ability of a novel cardiac magnetic resonance (CMR) real-time phase contrast (RT-PC) flow measurement technique to reveal the discordant respirophasic changes in mitral and tricuspid valve in flow indicative of the abnormal hemodynamics seen in constrictive pericarditis (CP).

BACKGROUND

Definitive diagnosis of CP requires identification of constrictive hemodynamics with or without pericardial thickening. CMR to date has primarily provided morphological assessment of the pericardium.

METHODS

Sixteen patients (age 57 ± 13 years) undergoing CMR to assess known or suspected CP and 10 controls underwent RT-PC that acquired simultaneous mitral valve and tricuspid valve inflow velocities over 10 s of unrestricted breathing. The diagnosis of CP was confirmed via clinical history, diagnostic imaging, cardiac catheterization, intraoperative findings, and histopathology.

RESULTS

Ten patients had CP, all with increased pericardial thickness (6.2 ± 1.0 mm). RT-PC imaging demonstrated discordant respirophasic changes in atrioventricular valve inflow velocities in all CP patients, with mean ± SD mitral valve and tricuspid valve inflow velocity variation of 46 ± 20% and 60 ± 15%, respectively, compared with 16 ± 8% and 24 ± 11% in patients without CP (p < 0.004 vs. patients with CP for both) and 17 ± 5% and 31 ± 13% in controls (p < 0.001 vs. patients with CP for both). There was no difference in atrioventricular valve inflow velocity variation between patients without CP compared with controls (p > 0.3 for both). Respiratory variation exceeding 25% across the mitral valve yielded a sensitivity of 100%, a specificity of 100%, and an area under the receiver-operating characteristic curve of 1.0 to detect CP physiology. Using a cutoff of 45%, variation of transtricuspid valve velocity had a sensitivity of 90%, a specificity of 88%, and an area under the receiver-operating characteristic curve of 0.98.

CONCLUSIONS

Accentuated and discordant respirophasic changes in mitral valve and tricuspid valve inflow velocities characteristic of CP can be identified noninvasively with RT-PC CMR. When incorporated into existing CMR protocols for imaging pericardial morphology, RT-PC CMR provides important hemodynamic evidence with which to make a definite diagnosis of CP.

Constrictive pericarditis and restrictive cardiomyopathy in the modern era

The differentiation between constrictive pericarditis and restrictive cardiomyopathy can be clinically challenging. Pericardial constriction results from scarring and consequent loss of pericardial elasticity leading to impaired ventricular filling. Restrictive cardiomyopathy is characterized by a nondilated rigid ventricle, severe diastolic dysfunction and restrictive filling producing hemodynamic changes, similar to those in constrictive pericarditis. While constrictive pericarditis is usually curable by surgical treatment, restrictive cardiomyopathy requires medical therapy and in appropriate patients, the definitive treatment is cardiac transplantation. Sufficient differences exist between the two conditions to allow noninvasive differentiation, but no single diagnostic tool can be relied upon to make this distinction. Newer echocardiographic techniques such as speckle-track imaging, velocity vector imaging, as well as cardiac computed tomography and cardiac MRI can help differentiate constriction from restriction with high sensitivity and specificity. Outcomes are better with early diagnosis of constriction in particular and early surgical resection.

Cardiovascular MRI for the assessment of heart failure: focus on clinical management and prognosis

Cardiovascular MR (CMR) has an emerging role in the noninvasive diagnostic assessment of heart failure (HF). Different imaging sequences allow for a detailed assessment of cardiac morphology, function, myocardial perfusion, tissue characterization, and blood flow measurement. This article reviews the key applications of CMR in HF, with special focus on how CMR may influence the diagnostic and therapeutic approach of HF patients.