[Cardiac arrest caused by massive pulmonary embolism during treatment with tranexamic acid]. / Hjertestop forårsaget af massiv lungeemboli under behandling med tranexamsyre.

Pulmonary embolism (PE) as the direct cause of cardiac arrest is well known but probably under-diagnosed. Treatment of menorrhagia with antifibrinolytics is a well documented treatment modality and it is considered safe although thromboembolic complications have been reported. We describe a case of a 30-year-old otherwise healthy woman, who had been treated with antifibrinolytics for up to six months prior to the event, presenting with fatal acute, massive PE and cardiac arrest, which was treated with prompt resuscitation including thrombolysis with recombinant tissue plasminogen activator and subsequent return of spontaneous circulation.

Vasorelaxation in space.

During everyday life, gravity constantly stresses the cardiovascular system in upright humans by diminishing venous return. This decreases cardiac output and induces systemic vasoconstriction to prevent blood pressure from falling. We therefore tested the hypothesis that entering weightlessness leads to a prompt increase in cardiac output and to systemic vasodilatation and that these effects persist for at least a week of weightlessness in space. Cardiac output and mean arterial pressure were measured in 8 healthy humans during acute 20-s periods of weightlessness in parabolic airplane flights and on the seventh and eighth day of weightlessness in 4 astronauts in space. The seated 1-G position acted as reference. Entering weightlessness promptly increased cardiac output by 29+/-7%, from 6.6+/-0.7 to 8.4+/-0.9 L min(-1) (mean+/-SEM; P=0.003), whereas mean arterial pressure and heart rate were unaffected. Thus, systemic vascular resistance decreased by 24+/-4% (P=0.017). After a week of weightlessness in space, cardiac output was increased by 22+/-8% from 5.1+/-0.3 to 6.1+/-0.1 L min(-1) (P=0.021), with mean arterial pressure and heart rate being unchanged so that systemic vascular resistance was decreased by 14+/-9% (P=0.047). In conclusion, entering weightlessness promptly increases cardiac output and dilates the systemic circulation. This vasorelaxation persists for at least a week into spaceflight. Thus, it is probably healthy for the human cardiovascular system to fly in space.

Comparison of acute cardiovascular responses to water immersion and head-down tilt in humans.

The hypothesis was tested that acute water immersion to the neck (WI) compared with 6 degrees head-down tilt (HDT) induces a more pronounced distension of the heart and lower plasma levels of vasoconstrictor hormones. Ten healthy males underwent 30 min of HDT, WI, and a seated control (randomized). During WI, left atrial diameter and stroke volume increased to the same extent as during HDT. Cardiac output increased by 1 l/min more during WI than during HDT. (P < 0.05). Plasma atrial natriuretic peptide increased during WI (P < 0.05) but not during HDT, whereas plasma norepinephrine, vasopressin, and renin activity were suppressed similarly. Mean arterial pressure decreased by 9 mmHg (P < 0.05) during HDT and was unchanged during WI, and heart rate decreased more during HDT (P < 0.05). Arterial pulse pressure increased considerably more during HDT than during WI. In conclusion, the hypothesis was not confirmed because the cardiac atria were similarly distended by acute HDT and WI and the release of vasoconstrictor hormones were suppressed to the same extent.