Clinical clues to the causes of large pericardial effusions

PURPOSE

To examine whether the size of the effusion, the presence of tamponade, and inflammatory signs are useful in determining the causes of moderate or severe pericardial effusions.

SUBJECTS AND METHODS

All echocardiograms performed at a general hospital between January 1990 and April 1996 were screened for pericardial effusion. Patients with moderate (echo-free space of 10 to 20 mm during diastole) or severe (echo-free space >20 mm) effusions were studied.

RESULTS

We identified 322 patients (166 [52%] men, mean [+/- SD] age 56 +/- 17 years [range 15 to 88 years]), 132 (41%) with moderate and 190 (59%) with severe pericardial effusion. The most frequent etiologic diagnoses were acute idiopathic pericarditis (n = 66 [20%]), iatrogenic effusions (n = 50 [16%]), cancer (n = 43 [13%]), and chronic idiopathic pericardial effusion (n = 29 [9%]). In 192 (60%) of the patients, the cause of the effusion was a known medical condition. In the 130 other patients, inflammatory signs were associated with acute idiopathic pericarditis (likelihood ratio = 5. 4, P < 0.001), severe effusions without inflammatory signs or tamponade were associated with chronic idiopathic pericardial effusion (likelihood ratio = 20, P < 0.001), and tamponade without inflammatory signs was associated with malignant effusions (likelihood ratio = 2.9, P < 0.01).

CONCLUSIONS

In many patients, pericardial effusions are due to a known underlying disease or condition. In patients without underlying diseases, inflammatory signs, the size of effusion, and the presence or absence of cardiac tamponade can be helpful in establishing cause.

Management of Acute and Recurrent Pericarditis: JACC State-of-the-Art Review

Pericarditis refers to the inflammation of the pericardial layers, resulting from a variety of stimuli triggering a stereotyped immune response, and characterized by chest pain associated often with peculiar electrocardiographic changes and, at times, accompanied by pericardial effusion. Acute pericarditis is generally self-limited and not life-threatening; yet, it may cause significant short-term disability, be complicated by either a large pericardial effusion or tamponade, and carry a significant risk of recurrence. The mainstay of treatment of pericarditis is represented by anti-inflammatory drugs. Anti-inflammatory treatments vary, however, in both effectiveness and side-effect profile. The objective of this review is to summarize the up-to-date management of acute and recurrent pericarditis.

C.A.U.S.E.: Cardiac arrest ultra-sound exam—A better approach to managing patients in primary non-arrhythmogenic cardiac arrest

Cardiac arrest is a condition frequently encountered by physicians in the hospital setting including the Emergency Department, Intensive Care Unit and medical/surgical wards. This paper reviews the current literature involving the use of ultrasound in resuscitation and proposes an algorithmic approach for the use of ultrasound during cardiac arrest. At present there is the need for a means of differentiating between various causes of cardiac arrest, which are not a direct result of a primary ventricular arrhythmia. Identifying the cause of pulseless electrical activity or asystole is important as the underlying cause is what guides management in such cases. This approach, incorporating ultrasound to manage cardiac arrest aids in the diagnosis of the most common and easily reversible causes of cardiac arrest not caused by primary ventricular arrhythmia, namely; severe hypovolemia, tension pneumothorax, cardiac tamponade, and massive pulmonary embolus. These four conditions are addressed in this paper using four accepted emergency ultrasound applications to be performed during resuscitation of a cardiac arrest patient with the aim of determining the underlying cause of a cardiac arrest. Identifying the underlying cause of cardiac arrest represents the one of the greatest challenges of managing patients with asystole or PEA and accurate determination has the potential to improve management by guiding therapeutic decisions. We include several clinical images demonstrating examples of cardiac tamponade, massive pulmonary embolus, and severe hypovolemia secondary to abdominal aortic aneurysm. In conclusion, this protocol has the potential to reduce the time required to determine the etiology of a cardiac arrest and thus decrease the time between arrest and appropriate therapy.

Pericardial effusion after cardiac surgery: incidence, site, size, and haemodynamic consequences

OBJECTIVE

To evaluate the incidence, characteristics, and haemodynamic consequences of pericardial effusion after cardiac surgery.

DESIGN

Clinical, echocardiographic, and Doppler evaluations before and 8 days after cardiac surgery; with echocardiographic and Doppler follow up of patients with moderate or large pericardial effusion after operation.

SETTING

Patients undergoing cardiac surgery at a tertiary centre.

PATIENTS

803 consecutive patients who had coronary artery bypass grafting (430), valve replacement (330), and other types of surgery (43). 23 were excluded because of early reoperation.

MAIN OUTCOME MEASURES

Size and site of pericardial effusion evaluated by cross sectional echocardiography and signs of cardiac tamponade detected by ultrasound (right atrial and ventricular diastolic collapse, left ventricular diastolic collapse, distension of the inferior vena cava), and Doppler echocardiography (inspiratory decrease of aortic and mitral flow velocities).

RESULTS

Pericardial effusion was detected in 498 (64%) of 780 patients and was more often associated with coronary artery bypass grafting than with valve replacement or other types of surgery; it was small in 68.4%, moderate in 29.8%, and large in 1.6%. Loculated effusions (57.8%) were more frequent than diffuse ones (42.2%). The size and site of effusion were related to the type of surgery. None of the small pericardial effusions increased in size; the amount of fluid decreased within a month in most patients with moderate effusion and in a few (7 patients) developed into a large effusion and cardiac tamponade. 15 individuals (1.9%) had cardiac tamponade; this event was significantly more common after valve replacement (12 patients) than after coronary artery bypass grafting (2 patients) or other types of surgery (1 patient after pulmonary embolectomy). In patients with cardiac tamponade aortic and mitral flow velocities invariably decreased during inspiration; the echocardiographic signs were less reliable.

CONCLUSIONS

Pericardial effusion after cardiac surgery is common and its size and site are related to the type of surgery. Cardiac tamponade is rare and is more common in patients receiving oral anticoagulants. Echo-Doppler imaging is useful for the evaluation of pericardial fluid accumulations after cardiac surgery. It can identify effusions that herald cardiac tamponade.

Rapid cardiac ultrasound of inpatients suffering PEA arrest performed by nonexpert sonographers

Cardiac arrest presenting as pulseless electrical activity (PEA) currently has a very low survival rate. Many of the conditions underlying PEA (cardiac tamponade, hypovolemia, and pulmonary embolus) are associated with specific cardiac ultrasound findings. The aim of this study was to evaluate a rapid cardiac ultrasound assessment performed by trained nonexpert sonographers integrated into the ACLS response system at a major medical center.

METHODS

An emergency sonography system was created and deployed to each inpatient cardiac arrest occurring at Dartmouth Hitchcock Medical Center between November 1, 2003 and April 30, 2004. Thirteen internal medicine house officers received training to perform a limited subcostal cardiac ultrasound examination designed to diagnose cardiac tamponade, pulmonary embolus, severe hypovolemia, and lack of cardiac motion. Time from arrest alert to sonographic result, and correlation with over-reading by blinded echocardiography physicians were assessed.

RESULTS

A complete emergency ultrasound examination was performed in five PEA arrests. The average time from arrest alert to interpretation was 7.75 min. (95% CI 2.8-18.3 min). Three of these examinations (60%, 95% CI 14.7-94.7%) were adequate for interpretation. Agreement between the nonexpert sonographer and echocardiography physician occurred in four of five (kappa=0.706) cases.

CONCLUSION

Rapid cardiac sonography can be successfully integrated in the ACLS response. Nonexpert sonographers may be able to provide useful interpretive information when sufficiently trained.

Diagnostic accuracy of transesophageal echocardiography during cardiopulmonary resuscitation

OBJECTIVES

We sought to establish the diagnostic accuracy of transesophageal echocardiography (TEE) during cardiopulmonary resuscitation.

BACKGROUND

Because of its bedside diagnostic capabilities, excellent cardiac images and lack of interference with resuscitation efforts, TEE is ideally suited to determine the cause of a circulatory arrest that is not due to severe arrhythmia. However, the diagnostic accuracy of TEE during resuscitation is unknown.

METHODS

TEE was performed in patients with prolonged circulatory arrest. The TEE diagnoses were compared with diagnoses from autopsy, surgery and clinical follow-up.

RESULTS

Of the 48 study patients (29 male, 19 female, mean age +/- SD 61 +/- 20 years), 28 had an in-hospital cardiac arrest and 20 an out-of-hospital onset of arrest. Forty-four patients eventually died; four survived to discharge. The diagnoses made with TEE were cardiac tamponade (n = 6), myocardial infarction (n = 21), pulmonary embolism (n = 6), ruptured aorta (n = 1), aortic dissection (n = 4), papillary muscle rupture (n = 1), other diagnosis (n = 2) and absence of structural cardiac abnormalities (n = 7). A definite diagnosis from a reference standard was available in 31 patients. The TEE diagnosis was confirmed in 27 of the 31-by postmortem examination (n = 19), operation (n = 2), angiography (n = 2) or clinical course (n = 4). In the other four patients the TEE diagnosis proved incorrect by postmortem examination. The sensitivity, specificity and positive predictive value of TEE were 93%, 50% and 87%, respectively. In 15 patients (31%), major therapeutic decisions were based on TEE findings.

CONCLUSIONS

TEE can reliably establish the cause of a circulatory arrest during cardiopulmonary resuscitation.

The risk of pericardiocentesis

The risk and potential risk factors of pericardiocentesis were assessed by a review of a series of 52 pericardiocenteses comprising all those performed in the cardiac catheterization laboratory of one institution from 1971 to 1978. On the basis of the operative results, the patients were separated into two groups for comparison; Group I comprised all patients with a successful uncomplicated (35) pericardiocentesis and Group II all those with a nonproductive (16), nontherapeutic (1) or complicated (8) pericardiocentesis. Complications consisted of one death, one cardiac arrest, one aspiration of a subdiaphragmatic abscess and five ventricular punctures without adverse sequelae. Among the patients who had a nonproductive pericardiocentesis, the condition of 11 had probably been misdiagnosed but at least 4 had a false negative pericardiocentesis. Comparison of the two groups showed no significant difference in the incidence of cardiac tamponade or in the clinical presentation based on historical, physical, electrocardiographic, roentgenographic or echocardiographic findings of pericardial disease. Pericardiocentesis was usually successful when performed for suspected malignant pericardial effusion but often unsuccessful when performed for suspected hemopericardium. Anatomically, all patients in Group II had either minimal or loculated posterior pericardial effusion. It is concluded that pericardiocentesis can be performed at a low risk that can be further minimized by consideration of the disease process and the anatomic location of the pericardial fluid.

Cardiac tamponade. A clinical or an echocardiographic diagnosis?

In most patients, cardiac tamponade should be diagnosed by a clinical examination that shows elevated systemic venous pressure, tachycardia, dyspnea, and paradoxical arterial pulse. Systemic blood pressure may be normal, decreased, or even elevated. The diagnosis is confirmed by echocardiographic demonstration of moderately large or large circumferential pericardial effusion and in most instances, of right atrial compression, abnormal respiratory variation in right and left ventricular dimensions, and in tricuspid and mitral valve flow velocities. Pulsus paradoxus may be absent with left ventricular dysfunction, atrial septal defect, regional tamponade, and positive-pressure breathing. Systemic venous pressure may be normal with localized tamponade of the left atrium or ventricle. Patients with moderately large or large pericardial effusions may have echocardiographic evidence of right atrial compression without clinical signs of elevated venous pressure or pulsus paradoxus. The majority of these patients have mild or moderate tamponade and if not subjected to pericardial drainage, should be observed closely. In some of these patients, when the etiology is known and the disease can be treated effectively with medication, e.g., nonsteroidal anti-inflammatory agents or adrenal corticosteroids in Dressler's syndrome or relapsing pericarditis, pericardial drainage may not be necessary.

Atypical presentations and echocardiographic findings in patients with cardiac tamponade occurring early and late after cardiac surgery

Cardiac tamponade, a potentially lethal complication following cardiac surgery, may present either early or late postoperatively and may be difficult to diagnose due to atypical clinical, hemodynamic, or echocardiographic findings. To determine the frequency and clinical features of postoperative cardiac tamponade, we performed a review of 510 consecutive patients who underwent cardiac surgery. The incidence of postoperative cardiac tamponade was 2.0 percent (10/510 patients) and occurred following valvular, bypass, and aortic surgery. Nine of ten patients had either atypical clinical, hemodynamic, and/or echocardiographic findings. The diagnosis of tamponade was made 1 to 30 days (mean = 8.5 days) postoperatively. Presenting symptoms were often mild and nonspecific. Classic signs including hypotension, pulsus paradoxus greater than 12 mm Hg, and elevated jugular venous pressure were present in 7, 6, and 5 patients, respectively. Right heart hemodynamics revealed elevated and equalized diastolic pressures in three of six patients. Two-dimensional echocardiography revealed selective compression of the left ventricle (LV) (four patients), right ventricle (RV) (one patient), left atrium (LA)/RV (one patient), LA/LV (one patient), LA/LV/RV (one patient), all four chambers (one patient), and no diastolic collapse of any chamber (one patient). There was often an absence of anterior pericardial fluid (six patients) with tethering of a portion of the RV to the chest wall anteriorly (five patients). Coagulation parameters were "supratherapeutic" in only three of eight patients who were receiving systemic anticoagulants at the time of diagnosis. The initial diagnosis was confused with congestive heart failure in one patient, pulmonary embolism in three patients, acute myocardial infarction in two patients, and sepsis in one patient. Eight of ten patients survived; all of these patients underwent surgical removal of fluid and/or hematoma in the operating room. We conclude that postoperative tamponade after cardiac surgery may have varied clinical and hemodynamic presentations, often due to selective chamber compression by loculated fluid or clot. Due to its frequently atypical features and presentation that may simulate other disorders, the diagnosis of tamponade should be considered whenever hemodynamic deterioration or signs of low output failure occur in the postcardiotomy patient.

Postoperative cardiac tamponade in the modern surgical era

BACKGROUND

Pericardial effusions resulting in cardiac tamponade (CT) are uncommon after open heart surgery (OHS) and are associated with significant morbidity and mortality. Characteristics and outcomes of patients who develop postoperative CT are poorly defined. Our objective was to further analyze the population at risk for developing postoperative CT, identify potential perioperative and surgical risk factors, and evaluate the impact of CT on patient outcomes.

METHODS

A retrospective analysis of 4,561 consecutive patients undergoing OHS at our institution was performed. Patients with clinical suspicion of pericardial effusion following surgery were evaluated by transthoracic or transesophageal echocardiography, and clinical parameters were analyzed.

RESULTS

Forty-eight (1%) of the 4,561 patients were found to have echocardiographic evidence of a moderate or large pericardial effusion, of whom 36 (74%) had evidence of CT. The mean age of the patients with CT was 61 years. Coronary artery bypass grafting (CABG) had been performed in 24% of these patients, valve +/- CABG in 73%, and other OHS procedures in 3%. The incidence of CT following CABG alone was 0.2%, whereas it was 0.6% after valve +/- CABG. Females had a higher risk for developing CT, and this occurred earlier in the postoperative period when compared with men. Aspirin, heparin, or warfarin were given to 84% of patients within 3 days of surgery. Mean time to diagnosis of CT was 10 +/- 1 days after OHS. Prior to diagnosis of CT, the maximum international normalized ratio (INR) and partial thromboplastin time (PTT) were 2.7 +/- 0.3 and 68 +/- 5 seconds, respectively. Forty-nine percent of pericardial effusions were posterior and 46% were circumferential; one-third of the effusions were considered large by echocardiography. There was one in-hospital cardiovascular death.

CONCLUSIONS

CT after OHS is more common following valve surgery than CABG alone and may be related to the preoperative use of anticoagulants. Females appear to be at higher risk for developing early postoperative CT. When diagnosed and treated promptly, postoperative CT should not significantly increase mortality.

Correlation between clinical and Doppler echocardiographic findings in patients with moderate and large pericardial effusion: implications for the diagnosis of cardiac tamponade

BACKGROUND

Clinical data are of unquestionable value for management purposes in cardiac tamponade, whereas the precise value of Doppler echocardiographic findings is not yet fully understood. We aimed to prospectively assess the correlation between clinical and Doppler echocardiographic signs in the diagnosis of cardiac tamponade in a large series of patients with pericardial effusion.

METHODS

During a 2-year period, all patients with moderate and large pericardial effusion were prospectively assessed. The presence of clinical findings suggesting cardiac tamponade, right cardiac chamber collapse on the echocardiogram, and Doppler venous flow pattern were simultaneously evaluated.

RESULTS

One hundred ten patients were included (49 with moderate and 61 with large effusions). Thirty-eight patients showed clinical features suggestive of cardiac tamponade and 72 did not. In patients with clinical tamponade, 90% had collapse of one or more right cardiac chambers, but 4 (10%) did not have any collapse. Venous flow was analyzable in 63%, suggesting tamponade in 75% of the patients. In patients without clinical tamponade, 34% showed collapse of one or more cardiac chambers. Venous flow pattern was normal in 80%, inconclusive in 11%, and only suggestive of tamponade in 9% of patients. If clinical features of tamponade were considered the diagnostic standard, sensitivity and specificity would be 90% and 65% for the presence of any collapse, 68% and 66% for right atrial collapse, 60% and 90% for right ventricular collapse, and 45% and 92% for simultaneous collapse of both chambers. Sensitivity and specificity of venous flow analysis would be 75% and 91%, respectively.

CONCLUSIONS

There is a good correlation between absence of collapse and absence of tamponade, but the correlation is poor between collapse and tamponade. Abnormal venous flow has a good correlation with clinical features of tamponade, with a higher sensitivity than right ventricular collapse and a much higher specificity than right atrial collapse.

The UHP ultrasound protocol: a novel ultrasound approach to the empiric evaluation of the undifferentiated hypotensive patient

This report describes a novel sonographic protocol for the evaluation of the undifferentiated hypotensive patient. This protocol combines components of 3 sonographic applications: free fluid, cardiac, and abdominal aorta into a single protocol. We believe this protocol and its underlying principles should be a routine part of the empiric evaluation of the patient with undifferentiated hypotension or pulseless electrical activity.

Concomitant new diagnosis of systemic lupus erythematosus and COVID-19 with possible antiphospholipid syndrome. Just a coincidence? A case report and review of intertwining pathophysiology

In the midst of the COVID-19 pandemic, further understanding of its complications points towards dysregulated immune response as a major component. Systemic lupus erythematosus (SLE) is also a disease of immune dysregulation leading to multisystem compromise. We present a case of new-onset SLE concomitantly with COVID-19 and development of antiphospholipid antibodies. An 18-year-old female that presented with hemodynamic collapse and respiratory failure, progressed to cardiac arrest, and had a pericardial tamponade drained. She then progressed to severe acute respiratory distress syndrome, severe ventricular dysfunction, and worsening renal function with proteinuria and hematuria. Further studies showed bilateral pleural effusions, positive antinuclear and antidouble-stranded DNA antibodies, lupus anticoagulant, and anticardiolipin B. C3 and C4 levels were low. SARS-Cov-2 PCR was positive after 2 negative tests. She also developed multiple deep venous thrombosis, in the setting of positive antiphospholipid antibodies and lupus anticoagulant. In terms of pathophysiology, COVID-19 is believed to cause a dysregulated cytokine response which could potentially be exacerbated by the shift in Th1 to Th2 response seen in SLE. Also, it is well documented that viral infections are an environmental factor that contributes to the development of autoimmunity; however, COVID-19 is a new entity, and it is not known if it could trigger autoimmune conditions. Additionally, it is possible that SARS-CoV-2, as it happens with other viruses, might lead to the formation of antiphospholipid antibodies, potentially contributing to the increased rates of thrombosis seen in COVID-19.

Intrapericardial tetracycline sclerosis in the treatment of malignant pericardial effusion: an analysis of thirty-three cases

Thirty-three unselected patients with cardiac tamponade secondary to malignant pericardial effusion were treated by intrapericardial instillation of tetracycline hydrochloride. Complete control of the initial signs and symptoms of tamponade was obtained in 30 patients without concomitant chemotherapy or radiotherapy. The procedure did not result in clinically significant complications. Failure of the technique was related to premature removal of the catheter by the patient (one patient) or the inability to totally remove hemorrhagic, clot-filled pericardial fluid (two patients). Survival ranged between 28-704 days and extended survival was related to the performance status and/or chemoradiosensitivity of the primary cancer. No patient successfully treated subsequently developed recurrent cardiac tamponade or alternatively, constrictive pericarditis. Tetracycline pericardial instillation remains a safe, simple, and efficacious treatment of tamponade secondary to malignant disease.

Evaluation of pericardial effusion with computed tomography

Evaluation of pericardial effusion was attempted with computed tomography in 11 patients. The volume and distribution of pericardial fluid were assessed with satisfactory resolution and the nature of the fluid was estimated by the difference in x-ray transparency (CT numbers). The volume of pericardial fluid calculated by tomographic methods ranged from 25 ml. to 585 ml. and agreed well with the surgically drained fluid volume. The CT numbers of the pericardial effusion due to renal or heart failure, acute viral pericarditis, hypothyroidism, and hemopericardium were +12 to +13, +20, +28 to +30, and +26 to +40, respectively. Therefore the volume and gross nature of the pericardial fluid could be estimated noninvasively with computed tomography.

Diagnosis and management of cardiac tamponade in the era of echocardiography

Cardiac tamponade is a life-threatening condition. Accurate diagnosis and prompt intervention are necessary. Classically, clinical features of tamponade include pulsus paradoxus, tachycardia, increased jugular venous pressure, and hypotension. With the advent of echocardiography, confirmation of an effusion and accurate assessment of its hemodynamic impact can be achieved, frequently in the absence of overt clinical manifestations. The decision regarding treatment and timing of intervention must take into account the clinical presentation and echocardiographic findings, along with careful weighing of risks and benefits to the individual patient. Echocardiographically guided pericardiocentesis is the best available therapy for initial management of cardiac tamponade. It is simple, safe, and effective for removing pericardial fluid and reversing hemodynamic instability, and the use of a pericardial catheter for extended drainage has been associated with significant reduction in recurrence of fluid accumulation.

Changes in QRS voltage in cardiac tamponade and pericardial effusion: reversibility after pericardiocentesis and after anti-inflammatory drug treatment

OBJECTIVES

The goal of this study was to define the association between low QRS voltage and cardiac tamponade or pericardial effusion and to assess the reversibility of low QRS voltage after therapeutic procedures.

BACKGROUND

It is unclear whether low QRS voltage is a sign of cardiac tamponade or whether it is a sign of pericardial effusion per se.

METHODS

In a prospective study design, we recorded consecutive 12-lead electrocardiograms and echocardiograms in 43 patients who were referred to our institution for evaluation and therapy of a significant pericardial effusion. Cardiac tamponade was present in 23 patients (53%). Low QRS voltage (defined as maximum QRS amplitude <0.5 mV in the limb leads) was found in 14 of these 23 subjects (61%). Nine of these 14 patients were treated by pericardiocentesis (group A). Five patients received anti-inflammatory medication (group B). Group C consisted of nine patients with pericarditis and significant pericardial effusion who had no clinical evidence of tamponade.

RESULTS

In group A, low QRS voltage remained largely unchanged immediately after successful pericardiocentesis (0.36 +/- 0.17 mV before vs. 0.42 +/- 0.21 mV after, p = NS), but QRS amplitude recovered within a week (0.78 +/- 0.33 mV, p < 0.001). In group B, the maximum QRS amplitude increased from 0.40 +/- 0.20 mV to 0.80 +/- 0.36 mV (p < 0.001) within six days. In group C, all patients had a normal QRS amplitude initially (1.09 +/- 0.55 mV) and during a seven-day follow-up (1.10 +/- 0.56 mV, p = NS).

CONCLUSIONS

Low QRS voltage is a feature of cardiac tamponade but not of pericardial effusion per se. Our findings indicate that the presence and severity of cardiac tamponade, in addition to inflammatory mechanisms, may contribute to the development of low QRS voltage in patients with large pericardial effusions.

Diagnosis of cardiac tamponade after cardiac surgery: relative value of clinical, echocardiographic, and hemodynamic signs

Early detection and treatment of cardiac tamponade is crucial in management of patients after cardiac surgery. Because of the atypical features of this condition and paucity of data on relative frequency of different signs, we evaluated the sensitivity of various clinical, echocardiographic, and hemodynamic signs. We retrospectively evaluated the relative frequency of clinical, echocardiographic, and hemodynamic signs in 29 patients with cardiac tamponade after cardiac surgery. In our study 66% had a localized, posterior pericardial effusion, and the other 34% had circumferential pericardial effusion. In the whole group 24% of patients had hypotension, and pulsus paradoxus was noted in 48%, right atrial collapse in 34%, right ventricular diastolic collapse in 27%, left ventricular diastolic collapse in 65%, and left atrial collapse in 13%. Elevation with equalization of pressures was noted in 81% patients. In the patient group with circumferential pericardial effusion and cardiac tamponade 40% patients were hypotensive and 50% patients had pulsus paradoxus. RA collapse was present in 70%, RV diastolic collapse in 70%, and LV diastolic collapse in 20%. Elevated diastolic pressures with equalization of these pressures was present in 71%. In the group with regional pericardial effusion and cardiac tamponade hypotension was present in 16% and pulsus paradoxus in 47%. RA collapse was present in 16%, RV diastolic collapse in 5%, LV diastolic collapse in 89%, and LA collapse in 21% of the patients with regional tamponade. Elevated diastolic pressures with equalization of these pressures was noted in 86% of the patients. Our observations indicate that among patients who have undergone cardiac surgery the presentation of cardiac tamponade is usually atypical.(ABSTRACT TRUNCATED AT 250 WORDS)

Pleural effusion as a cause of right ventricular diastolic collapse

BACKGROUND

We hypothesized, after seeing several suggestive clinical examples, that a process leading to a large bilateral pleural effusion in the presence of an otherwise insignificant pericardial effusion could result in right ventricular diastolic collapse (RVDC) as seen by two-dimensional echocardiography. This noninvasive marker for hemodynamically significant cardiac tamponade occurs when pericardial fluid is under pressure. Therefore, RVDC resulting from a large pleural effusion would represent a false-positive indication of cardiac tamponade caused by excessive pericardial fluid.

METHODS AND RESULTS

Seven spontaneously breathing dogs were chronically instrumented to measure ascending aortic, right atrial, intrapericardial, intrapleural, left atrial, and pulmonary artery pressures and cardiac output. Intravascular volume was adjusted before each experiment to the euvolemic range with saline solution. The onset of RVDC was observed in each animal by two-dimensional echocardiography during seven paired episodes of tamponade induced by infusions of warm saline into the pericardial space alone and, after drainage of the pericardial fluid and complete recovery, into the pleural space in the presence of a small pericardial effusion. The onset of RVDC occurred at the same intrapericardial (8.17 versus 9.47 mm Hg) and right atrial (7.41 versus 7.46 mm Hg) blood pressures regardless of whether it was produced by an intrapericardial or an intrapleural effusion but began in expiration during the former and in inspiration during the latter. Intrapericardial pressure increased in the same manner as intrapleural pressure during intrapleural saline infusion. Nevertheless, cardiac output and aortic blood pressure were better preserved, and at the onset of RVDC, the pulmonary artery systolic blood pressure was higher (p less than 0.0001) and the degree of pulsus paradoxus lower (p less than 0.01) with intrapleural infusion.

CONCLUSIONS

These results indicate that a large bilateral pleural effusion can elevate intrapericardial pressure sufficiently to cause RVDC and, perhaps, lead to misdirected therapy of an otherwise insignificant pericardial effusion.

The diagnosis of pericardial effusion and cardiac tamponade by 12-lead ECG. A technology assessment

OBJECTIVE

This study was designed to determine the diagnostic value of 12-lead ECG for pericardial effusion and cardiac tamponade.

DESIGN

Cross-sectional study.

SETTING

University hospital.

PATIENTS

Hospitalized patients with and without pericardial effusion and cardiac tamponade.

MEASUREMENTS AND RESULTS

In a blinded manner, we reviewed 12-lead ECGs from 136 patients with echocardiographically diagnosed pericardial effusions (12 of whom had cardiac tamponade) and from 19 control subjects without effusions. We examined the diagnostic value of three ECG signs: low voltage, PR segment depression, and electrical alternans. We found that all three ECG signs were specific but not sensitive for pericardial effusion (specificity, 89 to 100%; sensitivity, 1 to 17%) and cardiac tamponade (specificity, 86 to 99%; sensitivity, 0 to 42%). None of the ECG signs were associated with pericardial effusions of all sizes, but low voltage was associated with large and moderate pericardial effusions (odds ratio = 2.5; 95% confidence interval [CI] = 0.9 to 6.5; p = 0.06) and with cardiac tamponade (odds ratio = 4.7; 95% CI = 1.1 to 21.0; p = 0.004). In contrast, PR segment depression was associated only with cardiac tamponade (odds ratio = 2.0; 95% CI = 1.0 to 4.0; p = 0.05), while electrical alternans was not associated with either pericardial effusion or cardiac tamponade.

CONCLUSIONS

Low voltage and PR segment depression are ECG signs that are suggestive, but not diagnostic, of pericardial effusion and cardiac tamponade. Because these ECG findings cannot reliably identify these conditions, we conclude that 12-lead ECG is poorly diagnostic of pericardial effusion and cardiac tamponade.

Evolution of the postoperative pericardial effusion after day 15: the problem of the late tamponade

STUDY OBJECTIVES

To evaluate, through clinical and transthoracic echocardiography (TTE) follow-up, the natural history of persistent pericardial effusion (PE) after postoperative day 15 in patients who were given and were not given anticoagulant therapy.

DESIGN AND PATIENTS

We retrospectively studied a cohort of 1,277 patients who were hospitalized between May 1997 and May 1999 in our center a mean (+/- SD) time period of 15 +/- 3 days after undergoing coronary artery bypass graft (CABG) surgery (856 patients) or valve replacement (VR) surgery (421 patients).

MEASUREMENTS

TTE was performed on mean (+/- SD) postoperative day 20 +/- 1 (TTE(1)) and postoperative day 30 +/- 2 (TTE(2)). PE severity was classified on a scale from grade 1 to grade 4.

RESULTS

On postoperative day 20 +/- 1, PE was present in 22% of the 1,277 patients and was more frequent after patients underwent CABG surgery than after undergoing VR surgery (25% vs 17%, respectively; p < 0.01). On postoperative day 30 +/- 2, the overall incidence of late tamponade in patients with PE was 4%. The incidence increased with the severity grade of PE at TTE(1) (p < 0.001). The negative predictive value of a severity grade < 2 at TTE(1) for late tamponade was 100%. Late tamponade incidence was higher after VR surgery than after CABG surgery (11% vs 2%, respectively; p < 0.01), and was higher in patients who had received anticoagulation therapy than in those who had not (8% vs 2%, respectively; p < 0.05).

CONCLUSION

Persisting PE is common after postoperative day 15 and is more frequent after undergoing CABG surgery than after undergoing VR surgery. The incidence of late tamponade is usually underestimated, and it increases with the presence of VR, anticoagulation therapy, and/or higher postoperative TTE severity grade. Our data suggest that only patients with a PE severity grade of >/= 2 (< 10% of patients) require TTE follow-up after postoperative day 20.

'Tamponade' following cardiac surgery: terminology and echocardiography may both mislead

OBJECTIVE

Echocardiography is widely considered the gold standard for the diagnosis of tamponade. While a relatively common complication of cardiac surgery in adults, determining whether haemodynamics are compromised by a pericardial collection early post-operatively can be difficult. The aim of the current study was to determine the nature and magnitude of the diagnostic challenge posed by cardiac tamponade following cardiac surgery. We therefore examined the accuracy of echocardiography in the diagnosis of tamponade in this patient group.

METHODS

From January 2000 to January 2002, 2297 adult patients underwent cardiac surgery in a tertiary referral cardiothoracic centre. A retrospective analysis of prospectively collected data, from all patients diagnosed with post-operative bleeding and/or tamponade was performed. Data included demographics, surgery, anticoagulation/anti-platelet medication, clinical/echocardiographic features of tamponade and surgical findings at re-exploration.

RESULTS

The diagnosis of 'tamponade' was confirmed at re-exploration in 148 patients. When it occurred early (<72 h) following cardiac surgery trans-thoracic echocardiography failed to visualise the majority of collections (60%), necessitating trans-esophageal echocardiography. Effusions were small (160+/-17 ml) and localised (92%), showing no echocardiographic features of classical tamponade (79%). Where patients developed tamponade late (>72 h) following cardiac surgery, clinical features were atypical, effusions larger (640+/-71 ml, P<0.0001)) and global (77%). Classical echocardiographic features of tamponade were usually present (70%) and readily visualised using trans-thoracic echocardiography.

CONCLUSIONS

Haemodynamically significant pericardial collections occurring early following cardiac surgery rarely cause classical clinical or echocardiographic features of tamponade. Recognition of this as a separate diagnostic entity is necessary to ensure appropriate surgical intervention is not delayed.

Clinical features and long-term outcome of type A and type B intramural hematoma of the aorta

OBJECTIVE

Most previous reports on intramural hematoma of the aorta have focused on the initial episode. The purpose of this study was to clarify the long-term outcome of intramural hematoma of the aorta.

METHODS

Ninety-four cases of intramural hematoma of the aorta (41 type A and 53 type B) were reviewed. There were 69 male and 25 female patients, and their mean age was 66.7 +/- 8.7 years (range, 46-88 years).

RESULTS

Eleven (27%) of the patients with type A hematoma and 1 (2%) of the patients with type B hematoma underwent early surgical intervention. Others were treated medically, and the overall hospital mortality was 7% for patients with type versus 2% for patients with type B intramural hematomas of the aorta (P =.315). Twenty-three patients, 9 (22%) with type A and 14 (26%) with type B intramural hematomas of the aorta, underwent late surgical intervention during the follow-up period, and there were no hospital deaths. A total of 23 patients died during the follow-up period, including 6 of intramural hematoma of the aorta-related deaths (3 in the type A group and 3 in the type B group). The estimated freedom from intramural hematoma of the aorta-related events at 1 and 5 years was 70% +/- 8% and 54% +/- 11% for the type A group versus 73% +/- 6% and 58% +/- 8% for the type B group, respectively (P =.972). After excluding the nonintramural hematoma of the aorta-related deaths, the survival rates at 5 and 10 years were 80% +/- 9% and 80% +/- 9% for the type A group and 91% +/- 8% and 81% +/- 11% for the type B group (P =.211).

CONCLUSIONS

Intramural hematoma of the aorta-related events occur equally in both types of intramural hematoma of the aorta. We recommend close follow-up for at least 5 years because most intramural hematoma of the aorta-related events occur during this period.