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A 28-year-old man is brought to the emergency room following a motor vehicle accident where he was flown out of the car. The paramedics who were at the scene state that the patient was found on the side of the road unconscious after being thrown out of the car. His temperature is 37.5°C (99.5°F), pulse is 120/min, respirations are 20/min, and blood pressure is 80/40 mm Hg. Physical examination shows distended neck veins with muffled heart sounds. Breath sounds are normal with normal resonance upon percussion. An ultrasound was obtained and shows the following:
Which of the following is the most appropriate next step in management?
Content Reviewers:Rishi Desai, MD, MPH
The name “cardiac tamponade” can be broken down: “tamponade” refers to pressure which obstructs blood flow, and “cardiac” refers to the heart. So in cardiac tamponade there’s a buildup of fluid in the pericardium, and that fluid puts pressure on the outside of the heart. As a result, the heart is unable to pump normally and blood flow is obstructed.
Normally, the heart sits inside a two-layered pouch or cavity called the pericardium. The outer layer is the fibrous pericardium, which helps keep the heart in place within the chest cavity. The inner layer of the pouch is the serous pericardium, which includes the pericardial cavity; it’s filled with a small amount of fluid that lets the heart slip around as it beats. The cells of the serous pericardium secrete and reabsorb the fluid, so usually there’s no more than 50 milliliters of fluid in the pericardial cavity at any time—that’s about as much as would fit into a shot glass.
A pericardial effusion happens when this normally protective fluid begins to pool in the pericardial space. It can develop into cardiac tamponade depending on how much fluid there is and how quickly that fluid accumulates.
A rapid accumulation of fluid can occur as a result of trauma to the chest. For example, a stab wound can puncture a blood vessel and fill the pericardium with blood. Even blunt trauma like a steering wheel getting pushed into your chest during a car crash can lead to tamponade, because the force of the impact causes the rupture of lots of small blood vessels. Cardiac tamponade can also happen a few days after a myocardial infarction, because the weak, infarcted ventricular wall ruptures when it’s exposed to the high ventricular pressures. It’s a bit like how jeans might tear at the spot where the denim is worn away and already quite weak. A rare cause is heart surgery, where, once again, a weakened muscle can rupture and cause cardiac tamponade days after the operation. Yet another cause is aortic dissection, which is when blood pools in the actual wall of the aorta. If the aortic dissection ruptures through the wall of the aorta and through the fibrous pericardium, blood can spill right into the pericardial cavity, leading to cardiac tamponade. In these situations, even a small volume—as little as 150 ml!—can lead to tamponade, because the pericardium doesn’t have time to stretch and accommodate it.
Other causes of cardiac tamponade involve more long-term factors, rather than sudden trauma. In these cases, the fluid comes from a chronically inflamed serous pericardium that can’t resorb pericardial fluid as quickly as it builds up. Long-term causes of cardiac tamponade include cancers that have spread to the pericardium, often from the lung and the breast. Another cause is uremic pericarditis, where blood levels of urea, a nitrogen waste product, get really high, usually due to a kidney problem. The high levels of urea in the blood irritate the serous pericardium. More rarely, cardiac tamponade can happen due to hypothyroidism or because of chronic inflammation from a connective tissue disease. In these situations, when fluid accumulates gradually, the pericardium can hold as much as 1.5 L of fluid before tamponade sets in.
So, in cases of cardiac tamponade, fluid puts pressure on the heart itself, preventing it from fully stretching out or relaxing between contractions. This means that the cardiac chambers can’t fill with blood properly, causing a decrease in cardiac output or a lower amount of blood being squeezed out with each heartbeat, which leads to hypotension. Less blood leaving the heart also means less blood reaching the organs and tissues, and the heart tries to compensate for its low output by beating faster. When a person suffering from cardiac tamponade breathes in, the systolic blood pressure sometimes drops. Normally, inspiration creates a tiny bit of negative pressure which pulls blood into the heart, momentarily increasing systemic venous return. When that happens, the right heart volumes increases, and the right ventricle expands a bit into the pericardial space, so it doesn’t affect the left heart volume at all. During inspiration in someone with cardiac tamponade, the right ventricle can’t move into the pericardial space, so the extra volume pushes the interventricular septum leftwards. This leads to a reduction in left ventricular diastolic volume, a lower stroke volume, and a drop in systolic blood pressure during inspiration. A decrease in the systolic pressure of greater than 10 mmHg is called pulsus paradoxus, and it’s a classic sign of cardiac tamponade.