J. R. Michael scite author profile

The goals of this study were to quantify the effects of epinephrine on myocardial and cerebral blood flow during conventional cardiopulmonary resuscitation (CPR) and CPR with simultaneous chest compression-ventilation and to test the hypothesis that epinephrine would improve myocardial and cerebral blood flow by preventing collapse of intrathoracic arteries and by vasoconstricting other vascular beds, thereby increasing perfusion pressures. Cerebral and myocardial blood flow were measured by the radiolabeled microsphere technique, which we have previously validated during CPR. We studied the effect of epinephrine on established arterial collapse during CPR with simultaneous chest compression-ventilation with the abdomen bound or unbound. Epinephrine reversed arterial collapse, thereby eliminating the systolic gradient between aortic and carotid pressures and increasing cerebral perfusion pressure and cerebral blood flow while decreasing blood flow to other cephalic tissues. Epinephrine produced higher cerebral and myocardial perfusion pressures during CPR with simultaneous chest compression-ventilation when the abdomen was unbound rather than bound because abdominal binding increased intracranial and venous pressures. In other experiments we compared the effect of epinephrine on blood flow during 1 hr of either conventional CPR or with simultaneous chest compression-ventilation with the abdomen unbound. Epinephrine infusion during conventional CPR produced an average cerebral blood flow of 15 ml/min-100 g (41 + 15% of control) and an average myocardial blood flow of 18 mI/min 100 g (15 ± 8% of control). In our previous studies, cerebral and myocardial blood flow were less than 3 ±+ 1 % of control during conventional CPR without epinephrine. Although flows during CPR with simultaneous chest compression-ventilation without epinephrine were initially higher than those during conventional CPR, arterial collapse developed after 20 min, limiting cerebral and myocardial blood flow. The use of epinephrine throughout 50 min of CPR with simultaneous chest compression-ventilation maintained cerebral blood flow at 22 + 2 ml/min 100 g (73 ± 25% control) and left ventricular blood flow at 38 ± 9 ml/min 100 g (28 ± 8% control). The improved blood flows with epinephrine correlated with improved electroencephalographic activity and restoration of spontaneous circulation. The mechanisms responsible for the increased brain and myocardial blood flow with epinephrine include the prevention of arterial collapse and the intense vasoconstriction of other vascular beds, which prevents the run off of blood into these tissues and preferentially increases cerebral and myocardial perfusion pressures. We conclude that epinephrine substantially improves cerebral and myocardial blood flow during both conventional CPR and CPR with simultaneous chest compression-ventilation and that the combined use of epinephrine and CPR with simultaneous chest compression-ventilation with the abdomen unbound maintains high levels of blood flow to the ...

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Age-related effects of compression rate and duration in cardiopulmonary resuscitation

Dean

Koehler

Schleien

et al. 1990

Journal of Applied Physiology

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The effects of various compression rate and duration combinations on chest geometry and cerebral perfusion pressure during cardiopulmonary resuscitation (CPR) were studied in immature swine. Pentobarbital-anesthetized 2- and 8-wk-old piglets received CPR after ventricular fibrillation. At compression rates of 40, 60, 80, 100, 120, and 150/min, duty cycle (compression duration/total cycle time) was increased from 10 to 80% by 10% increments. Mean aortic and sagittal sinus pressures, pulsatile displacement, and deformity of the anterior chest wall were measured. Increasing duty cycle increased cerebral perfusion pressure until chest relaxation time was compromised. Inadequate chest recoil, development of static chest deformation, and limitation of pulsatile chest wall movement occurred in both age groups when relaxation time was very short (150-200 ms in 2-wk-old piglets, 250-300 ms in 8-wk-old piglets). These changes in chest geometry correlated with deterioration of cerebral perfusion pressure only in 8-wk-old piglets. In the younger group, perfusion pressures plateaued but did not deteriorate. These data emphasize the importance of duty cycle in generating cerebral perfusion pressure and indicate that younger animals can tolerate high compression rates except at extremely long duty cycles.

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J. R. Michael

Mechanisms by which epinephrine augments cerebral and myocardial perfusion during cardiopulmonary resuscitation in dogs.

Age-related effects of compression rate and duration in cardiopulmonary resuscitation

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