Influence of fibrinogen and haematocrit on erythrocyte sedimentation kinetics

This study investigates the influence of haematocrit, fibrinogen concentration and fibrinogen availability (amount of fibrinogen per red blood cell) on erythrocyte sedimentation. The Westergren technique was applied to blood samples from 36 subjects and to their blood manipulated to haematocrits of 10, 20, 30 and 40%. Readings were taken every 10 minutes for 300 minutes. Previous studies indicate that erythrocyte sedimentation occurs in three phases. In this study, we show that haematocrit has little influence on either the rate of fall of particles in the first phase (m1) or the duration of the first phase. This is also true for fibrinogen availability and for fibrinogen concentration at low haematocrits. At high haematocrits m1 increases with fibrinogen concentration. The rate of fall of rouleaux during phase 2 (m2) and ESR60 both decrease exponentially with haematocrit and increase linearly with fibrinogen concentration. While m2 is more closely correlated to fibrinogen availability than to fibrinogen concentration or to haematocrit, this is not the case for ESR60. Thus haematocrit, fibrinogen concentration and fibrinogen availability are more important to the velocity of sedimentation in the second phase than to the sedimenting velocity during phase 1 or to the duration of phase 1.     

The mechanism of blood cell sedimentation. XVIII. Sedimentation effect of fibrinogen plasminolysis products]

Various high molecular weight plasmin degradation products of fibrinogen were isolated by chromatographic procedures and investigated to what extent they influence the sedimentation rate of erythrocytes in heparinized serum. Among the early plasminolysis products Fragment X accelerated the sedimentation rate considerably although it was less effective than fibrinogen. Fragment Y showed a weaker but clearly demonstrable agglomerine activity. The late plasminolysis products D and E were ineffective, if applied alone and in concentrations equivalent to the fibrinogen content of plasma. However, they promoted the sedimentation effect of fibrinogen. If present in considerably higher concentrations are Fragments D and E, in absence of fibrinogen, also accelerated the sedimentation rate of erythrocytes significantly. A mixture of D and E was not more effective than the single compounds.     

Anomalies in sedimentation. IV. Decrease in sedimentation coefficients of chains at high fields

A theory is presented for the decrease of sedimentation coefficient at high centrifugal fields recently reported for samples of DNA by Rubenstein and Leighton and others. The theory uses the model of a chain of beads and springs to represent the molecule. Kirkwood's approximation is used for the sedimentation coefficient. The decrease in sedimentation coefficient with field comes about as a result of the uneven frictional forces in the chain, which on the average are less on segments near the center of the chain than on those near the ends. As a result the ends of the chain tend to drag behind the center, and the average intersegment distances are increased; consequently the hydrodynamic shielding of one segment by another is reduced, and the average friction is increased. The effect is thus characteristic of single molecules; intermolecular interaction is not involved. The sedimentation coefficient, S, varies as a power series in a parameter y that measures the distortion produced by the uneven friction: S = S⁰(1?D₂y² + D₄y⁴ ? ·). where S⁰ is the limiting value of S at zero centrifugal field and D₂ and D₄ are constants; y is proportional to the cen speed squared tunes the molecular weight squared divided by S⁰. It has been observed that the effects of centrifuge speed on S are negligible below certain critical values of the speed and molecular weight, but increase dramatically immediately above these values; this follows naturally from the high powers of the speed and molecular weight that appear in the above equation.     

Bacteroides intermedius binds fibrinogen.

The binding of Bacteroides intermedius VPI 8944 to human fibrinogen has been characterized. The binding is time dependent, at least partially reversible, saturable, and specific. On an average, a maximum of 3,500 fibrinogen molecules bind per bacterial cell, with a dissociation constant of 1.7 X 10(-11) M. These bacteria also exhibit a fibrinogenolytic activity which can be partially inhibited by protease inhibitors. Bacteria release fibrinogenolytic activity into the surrounding medium without loss of binding activity, but more pronounced fibrinogen breakdown occurs when 125I-labeled fibrinogen is associated with the bacteria, suggesting that fibrinogen is degraded at the cell surface. Fibrinogen binding by B. intermedius might represent a mechanism of bacterial tissue adherence.     

Inhibition of plasmin by fibrinogen.

The kinetics of inhibition of the amidolytic activity of plasmin on D-Val-L-Leu-L-Lys p-nitroanilide hydrochloride (S-2251) by fibrinogen and fibrin were determined. Reciprocal (1/v versus 1/[S]) plots of plasmin inhibition by 0.50 microM-fibrinogen showed a non-linear downward curve. The Hill coefficient (h) was 0.68, suggesting negative co-operativity. By contrast, fibrin produced a simple competitive inhibition of plasmin (Ki = 12 micrograms/ml). Addition of 0.1 mM-6-aminohexanoic acid shifted the non-linear curve obtained in the presence of fibrinogen to a straight line as for controls, indicating that 6-aminohexanoic acid abolishes the fibrinogen-induced inhibition. Transient exposure of the enzyme to pH 1.0 abrogates the ability of fibrinogen to inhibit plasmin activity. Acidification had no effect on the Vmax but increased the Km of plasmin. The present evidence for modulation of plasmin reveals a novel mechanism for control of fibrinolysis by fibrinogen, a component of the coagulation system and the precursor of the physiological substrate of plasmin.     

Interaction of fibrinogen with detergent.

Both cationic and anionic detergents were found to precipitate fibrinogen by forming fibrinogen-detergent complexes. These complexes were soluble in distilled water, but the aqueous solutions were very unstable and the complexes precipitated in the presence of salt. In the interaction of fibrinogen with the cationic detergent, stearyltrimethyl-ammonium chloride, approximately 160 molecules of detergent were found to bind to one molecule of fibrinogen. In distilled water, the fibrinogen-stearyltrimethylammonium complex (FG-STA(Cl)) remained soluble in the presence of thrombin [ED 3.4.21.5] although the same peptides were released as those released from fibrinogen. Precipitation of FG-STA(Cl) by salt was found to be closely related to adsorption of the anion of the salt by the complex. Futher addition of salt resulted in solubilization of the precipitate, and the solubilization was also due to further adsorption of the anion onto the precipitate.