[Investigations concerning postural influences on blood and blood plasma (author's transl)]

The measurement of blood density and its meaning

Density is defined as mass per unit volume. The classical technique to measure the density of fluids consists of a determination of mass and volume. Blood density is proportional to hematocrit or, more exactly, to the total protein concentration of blood; only to a minor extent is blood density influenced by other plasma solutes. Since the introduction of the mechanical oscillator technique for the continuous recording of fluid density a sizeable amount of experience has accumulated. This review summarizes recent work performed with this technique. It appears that the scientific interest in a variable like blood density depends on the availability of a suitable and simple method. Until the oscillator technique was available the measurement of density was too complicated or too inaccurate for routine laboratory use. A further new technique permits us to determine fluid densities by measuring sound velocity transmission. The density dilution method can be used for the determination of distribution volumes, of flow through organs, and of the cardiac output. The influence of temperature and of certain artifacts like acceleration forces in the density measuring device have to be considered any may be used for additional diagnostic purposes like determination of erythrocyte sedimentation velocity. The new technique opens a reasonable simple way to study fluid shift between interstitial space and capillaries. The arterio-venous density gradient in an organ depends on the lymph production. The injection of a hypertonic solution leads to an osmotic fluid shift from the extravascular space towards the blood. This fluid shift can be recognized by a reduction of the blood density. A simple model for the description of this reaction is presented.

Effect of lower-body positive pressure on postural fluid shifts in men

To quantify the effect of 60 mm Hg lower-body positive pressure (LBPP) on orthostatic blood-volume shifts, the mass densities (+/- 0.1 g.1-1) of antecubital venous blood and plasma were measured in five men (27-42 years) during combined tilt table/antigravity suit inflation and deflation experiments. The densities of erythrocytes, whole-body blood, and of the shifted fluid were computed and the magnitude of fluid and protein shifts were calculated during head-up tilt (60 degrees) with and without application of LBPP. During 30-min head-up tilt with LBPP, blood density (BD) and plasma density (PD) increased by 1.6 +/- 0.3 g.1-1, and by 0.8 +/- 0.2 g.1-1 (+/- SD) (N = 9), respectively. In the subsequent period of tilt without LBPP, BD and PD increased further to + 3.6 +/- 0.9 g.1-1, and to + 2.0 +/- 0.7 g.1-1 (N = 7), compared to supine control. The density increases in both periods were significant (p less than 0.05). Erythrocyte density remained unaltered with changes in body position and pressure suit inflation/deflation. Calculated shifted-fluid densities (FD) during tilt with LBPP (1006.0 +/- 1.1 g.1-1, N = 9), and for subsequent tilt after deflation (1002.8 +/- 4.1 g.1-1, N = 7) were different from each other (p less than 0.03). The plasma volume decreased by 6.0 +/- 1.2% in the tilt-LBPP period, and by an additional 6.4 +/- 2.7% of the supine control level in the subsequent postdeflation tilt period. The corresponding blood volume changes were 3.7 +/- 0.7% (p less than 0.01), and 3.5 +/- 2.1% (p less than 0.05), respectively. Thus, about half of the postural hemo-concentration occurring during passive head-up tilt was prevented by application of 60 mm Hg LBPP.

Continuous measurement of plasma protein content in the alert rat during and after 3 to 5 minutes of moderate activity

A refractometric method was used for the continuous registration of plasma protein concentration in rats during and after 3 and 5 minutes of provoked activity. Simultaneous conductometric measurements of hematocrit (hct) showed that, although both invariably changing in the same direction, the relative change of protein concentration is always less than that of hct: plasma volume changes calculated from the former fall short of those calculated from hct by 34 +/- 23% during the hemoconcentrative period during activity and by 52 +/- 11% during the hemodilutory period after activity. The difference between these figures was significant, thus implying that fluid leaving the circulation during the filtration phase is less rich in protein than that entering it during the absorptive phase of microvascular adjustments. A kinetic analysis of the period after activity was made. The rate constants of fluid- and protein-flux were closely correlated. Both plasma volume and intravascular protein mass increased asymptotically to a new equilibrium 6% above control within 30 min after activity. It is suggested that the excess protein is mobilized from large parenchymatous organs, mainly the liver.