A quantitative analysis of transcapillary refill in severe hemorrhagic hypotension in dogs.

In pressure-driven hemorrhage (PDH), where the rate of bleeding is a function of prevailing arterial pressure, survival time, arterial pressure, cardiac output, oxygen consumption, and base excess are functions of initial bleeding rate. The quantitative rate of transcapillary refill (TR) throughout PDH leading to death was determined in splenectomized dogs, through serial analysis of Cr51-tagged red cell dilution. Mild, moderate, and severe levels of PDH were produced by varying initial bleeding rate (10, 25, and 50 ml/min, respectively). The rate of TR is a function of the severity of PDH, but does not correlate with arterial pressure, cardiac output, or systemic resistance. The volume of transferred fluid represents an ever increasing fraction of total plasma volume, and accounts for more than 75% of plasma volume in preterminal stages of shock. TR sustains a relatively fixed level of plasma volume, equivalent to two-third of the initial plasma volume, irrespective of the rate of bleeding. Hypertonic NaCl (7.5%) enhances TR, while isotonic NaCl reverses it.

Physical and physiological characteristics of pressure-driven hemorrhage.

Research on hemorrhage has concentrated on its effects rather than the manner of occurrence. A new experimental method in which the rate of bleeding is a function of prevailing arterial pressure is proposed and described. The effects of standard crystalloid volume expansion and of small volume hypertonic treatment on this protocol are demonstrated. In pressure-driven hemorrhage, survival time and the decay of arterial pressure, cardiac output, oxygen consumption, and base excess are functions of the bleeding rate, but plasma proteins and hematocrits are independent. The decay of arterial pressure is also a complex function of blood volume deficit, but this relation is not dependent on the rate of blood removal. Volume expansion induces a recovery of circulatory function despite enhanced blood loss. A comparison between equiosmolar solutions of hypertonic sodium chloride and acetate shows that acetate produces a smaller pressor (hence less blood loss) but larger blood flow (hence higher O2 availability) effect. The possible importance of the isochloremic nature of the response to acetate is highlighted.