Pericardiocentesis

Review Box 16-1 Pericardiocentesis: indications, contraindications, complications, and equipment.

Definition

Pericardial effusion, the presence of fluid within the pericardial space, has a number of causes. As fluid accumulates, a critical point is reached at which pericardial pressure negatively affects cardiac filling and causes circulatory insufficiency. This is called pericardial tamponade. Once compensatory mechanisms begin to fail, obstructive shock ensues and failure to restore hemodynamics leads to cardiac arrest. Only removal of fluid can stabilize hemodynamics at this point.

The pericardium is a two-layered fibroelastic sac surrounding the heart.¹ The pericardium is avascular but well innervated, so inflammation induces severe pain. The visceral pericardium is a single-cell layer that adheres to the epicardium. The outer parietal pericardium consists mostly of collagen with some elastin. These two layers create the pericardial space, which normally contains 15 to 50 mL of serous fluid.² Pericardial fluid provides lubrication for cardiac contractility and acts as a “shock absorber” for deceleration forces.

The pericardium is a tense structure, but it also has some elasticity. These properties limit the amount of cardiac dilation that is possible during diastole and enhance mechanical interactions between the atria and ventricles during systole.³ This semi-elastic property can also tolerate an acute (i.e., over a period of hours to days) accumulation of pericardial fluid (80 to 120 mL) without significantly increasing intrapericardial pressure, which is the flat portion of the pressure-volume curve for pericardial pressure (Fig. 16-1).^4,5 Once a critical volume is reached, adding as little as 20 to 40 mL can double intrapericardial pressure (the steep portion of the pressure-volume curve [see Fig. 16-1]) and cause clinical decompensation (cardiac tamponade). Cardiac tamponade typically occurs with an intrapericardial pressure of 15 to 20 mm Hg.⁶

Figure 16-1 Production of cardiac tamponade by injection of saline into the pericardial sac. The pericardial space can accommodate the acute introduction of 80 to 120 mL of fluid without a significant increase in pericardial pressure, but with about 200 mL of saline, pressure increases steeply and blood pressure (BP) drops. Once critical volumes are reached, very small increases cause significant hemodynamic compromise. (From Fowler NO. Physiology of cardiac tamponade and pulsus paradoxus. II: physiological, circulatory, and pharmacological responses in cardiac tamponade. Mod Concepts Cardiovasc Dis. 1978;47:116. Reproduced by permission of the American Heart Association, Inc.)

Slow and chronic accumulation of pericardial fluid (over a period of weeks to months) causes the pericardium to expand circumferentially, and it can accommodate several liters of fluid with minimal alteration in intrapericardial pressure. Patients with this condition may be asymptomatic despite large effusions. No specific pericardial volume predicts the hemodynamic consequences of an effusion. Such consequences depend on the acuity of accumulation of the fluid.

Pathophysiology of Pericardial Tamponade

To generate an effective stroke volume, the left ventricle (LV) must be filled, and this process relies primarily on adequate filling of the right ventricle (RV). Normal inspiration promotes RV filling. Negative intrathoracic pressure increases venous return to the right side of the heart. This reduces wall tension in the RV, which causes dilation and more filling of the chamber.

Elevated intrapericardial pressure (i.e., early tamponade) results in abnormal RV filling and then abnormal LV filling. In this situation, the free wall of the RV cannot expand against the pericardial fluid during inspiration. To accommodate the filling, the interventricular septum bows abnormally into the LV, which reduces its volume. LV filling, stroke volume, and ultimately cardiac output are reduced.⁷ This phenomenon is responsible for pulsus paradoxus (PP, described later in this chapter), which is sometimes observed with tamponade.⁸ LV filling is also reduced by the collapse of right-sided structures. After a critical volume is reached on the pressure-volume curve (see Fig. 16-1), the intrapericardial pressure is transmitted to the inferior vena cava (IVC) and right atrium. These thin-walled structures then become compressed and reduce filling of the RV.

The atria and pulmonary circulation are at much lower pressure than systemic arterial pressure and are also vulnerable to rising intrapericardial pressure (Fig. 16-2). Late in tamponade a “pressure plateau” occurs in which right atrial pressure, RV diastolic pressure, pulmonary artery diastolic pressure, and pulmonary capillary wedge pressure are virtually identical. This equalization of chamber pressure leads to a reduction in venous return and the echocardiographic hallmark of tamponade: diastolic collapse of the RV. At this point, hemodynamic collapse is imminent, with severe hypotension, bradycardia, and potentially pulseless electrical activity (PEA) developing. Unless intrapericardial pressure is decreased immediately, cardiac arrest will ensue.⁹

Figure 16-2 Summary of physiologic changes in tamponade. RV, right ventricular. (From Shoemaker WC, Carey JS, Yao ST, et al. Hemodynamic monitoring for physiological evaluation, diagnosis, and therapy of acute hemopericardial tamponade from penetrating wounds. J Trauma. 1973;13:363; and Spodick D. Acute cardiac tamponade: pathologic physiology, diagnosis, and management. Prog Cardiovasc Dis. 1967;10:65. Reproduced by permission.)

Compensatory Mechanisms and Pericardiocentesis

To maintain physiologic cardiac output, the sympathetic nervous system increases the heart rate, arterial vasoconstriction (to maintain mean arterial blood pressure), and venoconstriction (to maintain normal venous-atrial and atrioventricular filling gradients). Early in tamponade, these compensatory mechanisms are usually effective in maintaining adequate cardiac output.

Compensatory mechanisms also preserve normal cardiac contractility and myocardial perfusion.7,10,11 However, when pericardial pressure overwhelms the compensatory mechanisms, coronary perfusion pressure is reduced, which leads to myocardial ischemia. Experimental induction of severe tamponade demonstrated microscopic ischemic cardiac injury.¹² Lactic acidosis (resulting from reduced cardiac output and systemic hypoperfusion) may directly cause cardiac depression and thereby reduce cardiac contractility and, ultimately, cardiac output.⁹

Removal of pericardial fluid (i.e., pericardiocentesis) reverses the pathophysiologic processes just described by improving cardiac filling and output. Interestingly, the pressure-volume relationship of the pericardial space demonstrates hysteresis; that is, withdrawing a certain quantity of fluid reduces intrapericardial pressure more than addition of the same amount of fluid increases intrapericardial pressure. This effect, however, is not universal and may vary among patients and in various disease states (Fig. 16-3).²

Figure 16-3 Relationship of intrapericardial pressure to volume of pericardial fluid. Pressure drops rapidly when a small amount of fluid is removed. (From Pories W, Gaudiani V. Cardiac tamponade. Surg Clin North Am. 1975;55:573. Reproduced by permission.)

Special Considerations in Patients with Pericardial Effusion and Tamponade

Under normal circumstances, positive pressure ventilation (e.g., mechanical ventilation) reduces venous return to the right side of the heart by increasing intrathoracic pressure. This could be detrimental for patients with tamponade because right-sided filling is already compromised and further reductions can lead to severe hemodynamic instability.¹³ Therefore, positive pressure ventilation should be avoided in patients with known or suspected tamponade unless it is absolutely necessary.

Low-pressure pericardial tamponade is defined as a hemodynamically significant effusion with lower than expected intrapericardial pressure.¹⁴ This category of tamponade occurs in certain hypovolemic patients with subacute or chronic effusions (e.g., associated with long-term diuretic use, dehydration, excessive dialysis).¹⁵ The diagnosis may be challenging because the classic symptoms and findings on physical examination (e.g., distended neck veins) may be absent.¹⁶ Fluid boluses may temporize the hemodynamic compromise while pericardial decompression is being arranged.

Epidemiology

The major categories of pericardial effusion include infection, malignancy, trauma, and metabolic abnormalities. Effusion may also be associated with aortic disease, connective tissue disease, or idiopathic causes. It is often difficult to report the exact incidence of each type of pericardial effusion because of variations in patient populations, local epidemiology, and the diagnostic protocols used during evaluation. The prevalence of a chronic effusion is also difficult to ascertain because it is often asymptomatic and underreported. General autopsy studies demonstrate an overall prevalence of 3.4%.¹⁷

Causes of Pericardial Effusion (Box 16-1)

Acute Hemopericardium

Acute hemopericardium, or rapid accumulation of blood in the pericardial space, can have a traumatic or nontraumatic etiology. It is one of the most feared causes of tamponade because the semi-elastic pericardium cannot accommodate acute increases in pericardial fluid and clinical deterioration can be rapid. This diagnosis can be challenging to make because there may be little or no evidence during the initial evaluation (e.g., pericardial size might be normal on a chest radiograph).

Box 16-1

Causes of Pericardial Effusion

Connective Tissue Disease

Systemic lupus erythematosus

Scleroderma

Rheumatoid arthritis

Acute rheumatic fever

Metabolic Disorders

Myxedema

Uremia

Cholesterol pericarditis

Bleeding diatheses

Cardiac Disease

Acute myocardial infarction

Dissecting aortic aneurysm

Congestive heart failure

Closed-chest cardiopulmonary resuscitation

Penetrating

Major penetrating trauma

Intracardiac injections

Transthoracic and transvenous pacing wires

Pericardiocentesis

Cardiac catheterization

Central venous pressure catheter

Data from Guberman BA, Fowler NO, Engel PJ, et al. Cardiac tamponade in medical patients. Circulation. 1981;64:633; and Pories WJ, Caudiani VA. Cardiac tamponade. Surg Clin North Am. 1975;55:573.

Traumatic Hemopericardium

Penetrating Trauma: Penetrating cardiac trauma can cause acute hemopericardium by either external forces (e.g., a stab wound to the heart) or internal forces (e.g., iatrogenic injury during placement of a pacemaker). Cardiac perforation can lead to rapid clinical deterioration and PEA.

External cardiac puncture is associated with stab wounds or projectile injuries (e.g., gunshot wounds). Tamponade develops in 80% to 90% of patients with cardiac stab wounds as opposed to 20% of those with gunshot wounds.18,19 Stab wounds cause tamponade more frequently because if the pericardial injury is small, it can reseal and trap blood within the pericardial space.²⁰ On the other hand, a gunshot typically produces large pericardial wounds that allow continuous drainage into the pleural space.²¹ Clinical deterioration is usually secondary to hypovolemia.²¹ Any penetrating injury to the chest, back, or upper part of the abdomen may injure the pericardium and cause tamponade.

Internal penetrating trauma is typically caused by invasive diagnostic or therapeutic procedures. The procedures most often associated with this injury are pacemaker insertion and cardiac catheterization (angioplasty or valvuloplasty).22–24 Hemopericardium results from puncturing the cardiac chamber, a coronary artery, or a great vessel (e.g., the superior vena cava). Ironically, pericardiocentesis itself (treatment of a pericardial effusion) can cause hemopericardium if coronary vessels or the myocardium is injured during the procedure.^25,26

Internal jugular and subclavian venous catheters (e.g., central venous or hemodialysis catheters) are commonly inserted in the emergency department (ED). During such procedures, hemopericardium results from perforation of the superior vena cava, right atrium, or RV. Hemopericardium can occur immediately or can be delayed up to 2 days subsequent to erosion of the catheter through myocardial or vascular tissue.27,28 Although this complication seldom occurs, it should always be considered when a patient experiences sudden hemodynamic deterioration following an invasive procedure.

Blunt Trauma: Major blunt chest trauma can cause hemopericardium with or without obvious signs of injury.²⁹ Myocardial rupture can be uncontained or contained.^30,31 Patients with uncontained rupture do not typically survive long enough to reach the hospital.³² Contained rupture may be found soon after injury or may be a late finding (in some cases up to 12 days later).³³ Tamponade can also be caused by a deceleration mechanism of injury that induces either aortic or vena caval disruption.³⁴ In one case series the incidence of tamponade following deceleration injury was found to be 2.3% (1 in 43 patients).³⁵

Miscellaneous Trauma: Chest compressions during cardiopulmonary resuscitation (CPR) can also cause hemopericardium from broken ribs, bleeding intercostal vessels, or penetrating injury (e.g., intracardiac injection of medication, which is rarely performed today).³⁶ Hemopericardium following CPR has been described in case reports^37,38 but is unlikely to be significant, much less to cause tamponade.

Atraumatic Hemopericardium

Atraumatic hemopericardium is difficult to diagnose. Diagnosis is often delayed because it occurs spontaneously and the clinical findings can be less obvious than those of hemopericardium from traumatic causes. Maintain a high index of suspicion for this condition in patients with risk factors, such as recent myocardial infarction (MI). Common causes of atraumatic hemopericardium are discussed below.

Bleeding diathesis is an important cause of spontaneous hemopericardium and may be associated with the use of anticoagulants (reported incidence of 2.5% to 11%)²² or thrombolytic therapy (incidence <1%).³⁹ Patients who have undergone cardiac surgery are at increased risk because of the anticoagulative effects of the cardiopulmonary bypass machine and medications started postoperatively (e.g., clopidogrel, warfarin).⁴⁰ Fortunately, tamponade has a low incidence and is generally detected in the postoperative period before discharge.^41,42 This complication is usually prevented by the intraoperative placement of mediastinal or pericardial drains.^22,43

Hemopericardium can develop following MI. Early after a transmural MI (1 to 3 days), the necrotic myocardium causes inflammation of the overlying pericardium and then effusions can form. Late-developing effusions (weeks after an MI) are caused by an autoimmune pericarditis called Dressler’s syndrome.¹ Improved reperfusion techniques have reduced the incidence of post-MI pericarditis and effusion.⁴⁴

Ascending aortic dissection causes rapid and usually fatal hemopericardium. The dissection may expand in a retrograde fashion by extending to the base of the aorta and into the pericardial sac. Risk factors for aortic dissection include hypertension, atherosclerosis, vasculitis (e.g., giant cell arteritis, syphilis), collagen vascular disease (e.g., Marfan’s syndrome), and the use of sympathomimetics (e.g., cocaine).45–47

Ventricular free-wall rupture is a rapidly fatal cause of acute hemopericardium that can occur after MI. This complication is less common today than in the past (<1%)³⁹ secondary to improved revascularization techniques, better therapeutic medications, and faster intervention times (shorter door-to-balloon times) for coronary ischemia. Despite a reduction in its overall incidence, 7% of all deaths related to MI are caused by this complication.^48,49 Survival is possible with prompt recognition and treatment, but the prognosis is grim once tamponade occurs.^50,51

Nonhemorrhagic Effusions

Nonhemorrhagic pericardial effusions usually accumulate slower than acute hemopericardium does (over a period of weeks to months). Chronic fluid accumulation allows the pericardium to stretch circumferentially and accommodate up to 2000 mL of fluid without any hemodynamic compromise.⁵² Effusions that grow slowly allow the circulatory system to adapt to the intrapericardial pressure, thereby further maintaining hemodynamic stability. Thus, asymptomatic patients with moderate to large effusions may not need emergency pericardiocentesis, in contrast to patients with acute hemopericardium.^53,54

Nonhemorrhagic effusions have several causes (see Box 16-1), and the exact one may not be obvious during the initial evaluation without diagnostic pericardiocentesis. Common causes of nonhemorrhagic effusions are discussed in the following sections.

Idiopathic Effusions

Most idiopathic effusions are believed to be viral in origin and most commonly caused by infection with coxsackievirus, echovirus, or enterovirus. Idiopathic pericardial effusions may be asymptomatic or have an associated component of pericarditis (e.g., positional pain or diffuse ST-segment changes on the electrocardiogram [ECG]).⁵⁵ These effusions are often labeled “idiopathic” because the diagnosis cannot be made noninvasively (i.e., based on the history, physical examination, or serum testing) and the risk associated with diagnostic pericardiocentesis outweighs the risk of observation in asymptomatic adults who appear to be well.⁵⁶ Diagnostic pericardiocentesis may be recommended for idiopathic effusions that are persistent or symptomatic without a known cause.⁵⁷

Neoplastic Effusion

Tumors of the pericardium or myocardium may cause nonhemorrhagic effusions.54,58 Primary cardiac tumors are less common (0.001% to 0.003%) than metastases from another site (2% to 18%), but either may cause a malignant effusion.⁵⁹ Although no malignancy preferentially metastasizes to the heart, certain tumors commonly involve the heart when they metastasize; frequently implicated are lung cancer, breast cancer, mediastinal tumors, malignant melanoma, leukemia, and lymphoma.⁴⁶

Cardiac metastasis is usually a late finding in cancer; other foci are generally evident first.⁴⁷ The classic signs and symptoms of tamponade (e.g., chest pain and dyspnea) may not be obvious with malignant tamponade. When present, they may be mistakenly attributed to the underlying malignancy.⁴⁶ Thus, in the relevant clinical scenario, consider screening patients with malignancy for pericardial effusion (e.g., ultrasound) before the clinical findings of tamponade appear.

Congestive Heart Failure

Congestive heart failure (CHF) is a cause of pericardial effusion. Diagnosis may be difficult because of overlapping signs and symptoms with exacerbations of CHF (e.g., chest pain or dyspnea). Adding to the diagnostic complexity is that 12% to 20% of patients with CHF have a coexisting pericardial effusion.⁶⁰ Fortunately, treatment of CHF-associated pericardial effusion does not differ from that for an effusion from other causes: treat the underlying cause unless the patient has evidence of hemodynamic compromise.

Radiation

Pericardial effusions (secondary to radiation-induced pericarditis) can develop acutely during radiation therapy or nay be delayed for years. Risk factors include the radiation dose, duration of exposure, and age of the patient. Patients treated with radiation for Hodgkin’s disease have the highest association of radiation-induced pericarditis and subsequent effusions.²² These effusions can be serous, hemorrhagic, or fibrinous.⁵⁷

HIV-Associated Effusions

Human immunodeficiency virus (HIV) can cause nonhemorrhagic pericardial effusion and tamponade (see Review Box 16-1).^61,62 The incidence has been reported to be approximately 11% in patients with HIV infection or acquired immunodeficiency syndrome (AIDS), and 13% of cases are classified as moderate to severe. It is unclear whether antiretroviral therapy has affected these data.¹⁷

Renal Failure and Uremia

Pericardial effusion develops in approximately 15% to 20% of dialysis patients, and tamponade may eventually occur in as many as 35% of that group.66,67 Up to 7% of chronic dialysis patients have effusions with volumes of 1000 mL or greater.⁶⁸ In many cases, effusions secondary to renal failure can be managed solely with aggressive dialysis without pericardiocentesis. Any sign of hemodynamic compromise, however, warrants strong consideration of pericardiocentesis.

Hypothyroidism

Hypothyroid patients are at risk for pericardial effusions (up to 30%), but the fluid accumulates gradually, so tamponade develops in only a few patients.⁵⁴ If pericardial effusions are present, other areas of the body usually demonstrate serositis (e.g., pleural effusions). Treating the underlying hypothyroidism often reverses the effusion without the need for pericardiocentesis.

Special Considerations in Pericardial Disease

Pericardial tamponade is classically described as being secondary to circumferential effusion, which causes a generalized increase in pericardial pressure and compression of multiple cardiac chambers. Loculated effusions (caused by a local hematoma or an infectious process) or pericardial adhesions (from previous inflammation) can compress one or two cardiac chambers and thus reduce both cardiac filling and cardiac output.69,70

Constrictive pericarditis occurs following chronic pericardial inflammation, infection, or mediastinal irradiation. These processes cause scarring, fibrosis, or calcification, and the pericardium eventually becomes a nonelastic and “constrictive” sac around the heart. Myocardial relaxation and cardiac filling are impaired, and diastolic dysfunction ensues. Without echocardiography, constrictive pericarditis can be difficult to distinguish from pericardial tamponade.¹

Effusive-constrictive pericarditis is defined by the presence of both pericardial effusion and pericardial constriction. It may be quite difficult to differentiate between effusive-constrictive pericarditis and pericardial tamponade in stable patients because both are associated with effusions.⁷¹ Fortunately, distinguishing between these diagnoses is less important in hemodynamically unstable patients because they are treated identically (i.e., with pericardiocentesis).⁷²

Pneumopericardium is an interesting, though rare cause of cardiac tamponade. It is most commonly associated with pneumothorax caused by barotrauma (e.g., mechanical ventilation).⁷³ It also occurs spontaneously during acute asthma exacerbations,⁷⁴ and it can follow blunt chest injury.^75,76 Although typically benign, tension pneumopericardium has been reported as a cause of life-threatening tamponade after blunt^77,78 and penetrating chest trauma.^79,80

Diagnosing Cardiac Tamponade

Diagnosis of pericardial effusions requires integration of the patient’s history, findings on physical examination, and diagnostic testing. Unfortunately, even experienced clinicians may not initially consider pericardial effusion because the clinical findings are often vague and nonspecific. Nonspecific symptoms, such as chest pain and dyspnea, can be ascribed to more common conditions (e.g., CHF or pulmonary pathology), so the diagnosis might be delayed until diagnostic testing is performed (e.g., computed tomography [CT] of the chest for pulmonary embolism)⁸¹ or until hypotension develops and bedside ultrasound is performed.⁸²

Acute pericardial tamponade (e.g., secondary to blunt chest wall trauma) is usually challenging to diagnose because the findings on physical examination may resemble those of other life-threatening conditions (e.g., tension pneumothorax, hemothorax, hypovolemia, pulmonary edema, severe contusion of the RV, aortic dissection, or pulmonary embolism).⁶⁷ In hemodynamically unstable patients, diagnostic (e.g., bedside ultrasound) and therapeutic (e.g., pericardiocentesis) interventions must be performed even with a paucity of findings on physical examination because rapid clinical deterioration and cardiac arrest can occur before a definitive diagnosis can be made.

Once a pericardial effusion is suspected (or diagnosed), the next step is to determine its size and hemodynamic significance and presence of underlying or associated diseases.⁸³ Specific therapy will hinge on this information and is discussed in the following sections.

History: Patient Profile and Symptoms

The historical features of pericardial effusions are nonspecific and the diagnosis may be overlooked initially. However, an astute clinician might be suspicious based on comorbid conditions (e.g., warfarin therapy or a history of myxedema) and the time course of the symptoms (e.g., free-wall rupture several days after MI, dyspnea in a patient with uremic pericarditis). Box 16-2 lists important details to be ascertained from the history when pericardial effusion is suspected.⁸⁴

Box 16-2 Information to Obtain from Patients When Pericardial Effusion Is Suspected

Onset and Duration of Symptoms

Acute

Trauma

Recent cardiac surgery

Recent myocardial infarction

Acute aortic dissection

Recent diagnostic or therapeutic intervention (e.g., catheterization)

Recent upper thoracic vascular procedure (e.g., hemodialysis catheter, central line, peripherally inserted central catheter line, Mediport)

Recent placement of a pacemaker or automatic implantable cardioverter-defibrillator

Subacute/Chronic

Metabolic (e.g., uremia)

Endocrine (e.g., hypothyroidism)

Infectious

• Viral (e.g., human immunodeficiency virus)

• Bacterial (e.g., Staphylococcus)

• Fungal (e.g., Aspergillus)

Neoplastic

• Primary cardiac

• Metastatic

Autoimmune disorders (e.g., lupus)

Inflammatory

• Vasculitis

Medical/Surgical History

Autoimmune disorders

• Lupus

• Mixed connective tissue disease

• Vasculitis

Endocrine disease

• Hypothyroidism

• Ovarian hyperstimulation syndrome

Metabolic diseases

• End-stage renal disease

• Uremia

• Coagulopathies

Artificial cardiac valves

• Anticoagulation medications

• Risk for myocarditis

Cardiac disease

• Anticoagulation medications

• Pericarditis

• Aneurysm

Recent placement of a vascular catheter

Recent cardiac surgery

Recent cardiac intervention

Recent thoracic radiation

• Procainamide (drug-induced lupus)

Tuberculosis therapy

• Isoniazid (drug-induced lupus)

Common Symptoms

Altered mental status, confusion

Fatigue

Dizziness, lightheadedness

• Scapula (phrenic nerve irritation)

Physical Examination

Physical examination of patients with pericardial effusion (e.g., displaced point of maximal impulse, muffled heart sounds) lacks sensitivity and specificity. If the history suggests pericardial effusion, the physical examination should focus on determining the underlying cause (e.g., stigmata of hypothyroidism) to guide definitive diagnostic testing (e.g., echocardiography). Ironically, many pericardial effusions are not diagnosed from the history or findings on physical examination but are found incidentally during the evaluation for other diseases.

In 1935, Beck characterized the physical manifestations of tamponade with two triads—one for chronic and one for acute tamponade.⁸⁵ Beck’s “chronic” triad consists of increased central venous pressure (CVP) (i.e., distended neck veins), ascites, and a small, quiet heart. “Beck’s triad” is a classic description of acute cardiac compression, which includes increased CVP, decreased arterial pressure, and muffled heart sounds. Almost 90% of patients have one or more of these “acute” signs,⁸⁶ but only about 33% demonstrate the complete triad.^9,87 The utility of this triad is further limited because all three signs are usually observed shortly before cardiac arrest.

It would be clinically desirable to identify patients in early tamponade, before hemodynamic collapse. Unfortunately, findings on physical examination in early tamponade are nonspecific and may be indistinguishable from those of other critical diseases (e.g., septic shock, right heart failure).⁵⁷ Patients initially seen in late tamponade also have nonspecific findings. They may be agitated, panic-stricken, confused, uncooperative, restless, cyanotic, diaphoretic, acutely dyspneic, or hemodynamically unstable. Such patients should undergo a brief and focused physical examination because the time between initial evaluation and full arrest may be brief.

Some of the findings on physical examination associated with tamponade are described below. A more comprehensive list is presented in Box 16-3.

Box 16-3 Physical Examination Findings Suggestive of Pericardial Effusion or Tamponade

Vital Signs

Normal vital signs

Tachycardia (tamponade)

Hypotension (tamponade)

Narrow pulse pressure

Pulsus paradoxus

Fever (if the cause is infectious or neoplastic)

Appearance

Normal appearance

Anxiety

Sense of impending doom

Diaphoresis

Cold and clammy

Pallor

Altered mental status, confusion

Neck

Supraclavicular retractions

Distended neck veins (may be flat with hypotension)

Cardiovascular

Normal findings on examination

Tachycardia

Increased pain with a supine position, relieved by leaning forward

Muted, distant heart sounds

Pericardial friction rub (inflammatory pericarditis)

Displaced point of maximal impulse

Increased cardiac borders with percussion

Distended neck veins

Auscultatory dullness along the left scapular area

Pulmonary

Telegraphic speech

Respiratory distress

Supraclavicular retractions

Cough

Hoarseness

Clear breath sounds (may distinguish tamponade from congestive heart failure)

Dilated head and scalp veins

Peripheral edema

Anasarca

Vital Sign Abnormalities

The three stages occur sequentially and reflect the natural history of acute tamponade (Table 16-1).⁸⁸ The time course within each stage varies from patient to patient. Some patients are stable within a given stage for hours, whereas others proceed through all three stages and cardiac arrest within minutes.^9,88 Grade I tamponade is characterized by normal blood pressure and cardiac output with an increase in the heart rate and CVP (measured invasively with a central venous catheter). Grade II tamponade is defined by normal or slightly reduced blood pressure; CVP and the heart rate remain increased. Grade III tamponade is identified on the basis of Beck’s triad: hypotension, tachycardia, and elevated CVP.

TABLE 16-1

Shoemaker System of Grading Cardiac Tamponade

From Shoemaker WC, Carey SJ, Yao ST, et al. Hemodynamic monitoring for physiologic evaluation, diagnosis, and therapy of acute hemopericardial tamponade from penetrating wounds. J Trauma. 1973;13:36.

Nearly all patients with tamponade have sinus tachycardia, although its specificity is low.⁸⁹ The physiologic purpose of tachycardia is to maintain normal cardiac output despite reductions in stroke volume from worsening tamponade. Exceptions to the pairing of tachycardia with tamponade usually relate to the underlying cause of the effusion (e.g., myxedema) or the concomitant use of certain medications (e.g., β-blockers).

Adding to the diagnostic complexity, not all patients in tamponade have a reduction in blood pressure. In fact, Brown and coworkers ⁹⁰ described several tamponade patients with elevated blood pressure. These patients were previously hypertensive and paradoxically had reduced systolic blood pressure following pericardiocentesis.

Pulsus Paradoxus

PP is an exaggerated decrease in systolic blood pressure (>12 mm Hg) during inspiration secondary to reduced stroke volume (Fig. 16-4A).^30,91,92 Patients with moderate to severe tamponade typically demonstrate PP greater than 20 mm Hg.^9,86,93 Unfortunately, PP is not pathognomonic for tamponade. It is observed in other conditions, such as hypotension associated with labored breathing (secondary to extreme reductions in intrathoracic pressure [Fig. 16-4B]), severe emphysema, severe asthma, obesity, cardiac failure, constrictive pericarditis, pulmonary embolism, and cardiogenic shock.^9,86,93

Figure 16-4 Pulsus paradoxus. A, Top, The normal situation in which changes in intrathoracic pressure are transmitted to both the pericardial sac and the pulmonary veins. The effective filling gradient (EFG) changes only slightly during respiration. Bottom, Cardiac tamponade in which changes in intrathoracic pressure are transmitted to the pulmonary veins but not to the pericardial sac. The EFG falls during inspiration (Insp). LA, left atrium; LV, left ventricle; PC, pulmonary capillaries; PV, pulmonary veins. B, Normally, systolic blood pressure drops slightly during inspiration. To assess for pulsus paradoxus, have the patient breathe normally while lying at a 45-degree angle. Inflate the blood pressure cuff well above systolic pressure and slowly deflate it. When the pulse is first heard only during expiration, this is the upper value. Deflate the cuff until the pulse is heard during both inspiration and expiration; this is the lower value. A difference of more than 12 mm Hg between the two values indicates pulsus paradoxus. (A, Adapted from Sharp JT, Bunnell IL, Holand JF, et al. Hemodynamics during induced cardiac tamponade in man. Am J Med. 1960;25:640.)

The absence of PP does not rule out tamponade because it can occur with several conditions: atrial septal defects, aortic insufficiency, positive pressure ventilation, loculated pericardial effusions, and elevated left ventricular diastolic pressure (e.g., poor left ventricular compliance secondary to chronic hypertension).¹⁴ Finally, PP should be interpreted with caution in patients with traumatic tamponade because it can be unreliable.^94–96 In a study of 197 patients with traumatic tamponade, only 8.6% had PP.⁹⁷

Measuring PP is useful only occasionally because it is difficult, time-consuming, and not specific or sensitive for tamponade. Its description here is for historical value and for use in hemodynamically stable patients. When managing unstable patients, especially those in extremis, assessment for PP should not replace more definitive testing such as bedside ultrasound.

Neck Vein Distention and Elevated CVP

Neck vein distention (a surrogate for measuring CVP) occurs late in tamponade, when right-sided chambers (e.g., the RV) collapse. Neck vein distention may be obvious on examination (Fig. 16-5A), but visualization of such distention is less accurate than measuring CVP by central venous catheter or evaluation with ultrasound (Table 16-2). Patients with significant tamponade typically have a CVP of 12 cm H₂O or higher.⁹⁵ Finally, although initial CVP readings are useful and diagnostic when grossly elevated (e.g., 20 to 30 cm H₂O),^95,98 upward CVP trends can be a more sensitive diagnostic tool.⁹⁵

TABLE 16-2

Noninvasive Estimation of Right Atrial Pressure with Ultrasound

DIAMETER (cm) OF INFERIOR VENA CAVA	CHANGE IN DIAMETER WITH RESPIRATION	ESTIMATED RIGHT ATRIAL PRESSURE (mm Hg)
Normal (<2.1)	Decrease >50%	~3 (normal, 0-5)
Dilated (<2.1)	Decrease <50%	~8 (normal, 5-10)
Dilated (>2.1)	Decrease >50%	~8 (normal, 10-15)
Dilated (>2.1)	Decrease <50%	>15

Based on Rudski LG, Lai WW, Afilalo J, et al. Guidelines for the echocardiographic assessment of the right heart in adults: a report from the American Society of Echocardiography endorsed by the European Association of Echocardiography, a registered branch of the European Society of Cardiology, and the Canadian Society of Echocardiography. J Am Soc Echocardiogr. 2010;23:685.

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