Immunoglobulin G from single plasma donor in immune globulin intravenous causes false positive pyrogen test.

A sudden, unprecedented failure of USP rabbit pyrogen tests for multiple 10% IGIV-C lots prompted a thorough investigation of the root cause for this phenomenon. All microbe-related testing, including Limulus amebocyte lysate test for endotoxin, proved negative, and no deficiencies were discovered in manufacturing. Plasma pool composition analysis revealed that a single plasma donor ("Donor X″) was common to all pyrogenic IGIV-C lots and that as little as one unit of "Donor X″ plasma (in a pool of ∼4500 units) was sufficient to cause IGIV-C lot failure in the USP rabbit pyrogen test. Whole plasma and Protein A-purified IgG from "Donor X″ caused a temperature increase in rabbits; however, all IgG samples tested pyrogen-negative in two in vitro cell-based pyrogen tests. Flow cytometry showed that "Donor X″ IgG bound strongly to rabbit white blood cells (WBC) but minimally to human WBC. Exclusion of "Donor X″ plasma from manufacturing marked the end of IGIV-C lots registering positive in the USP rabbit pyrogen test. This failure of multiple 10% IGIV-C lots to pass the USP rabbit pyrogen test was demonstrated to be due to the highly unusual anti-rabbit-leukocyte specificity of IgG from a single donor.

Blood inhibitory capacity toward exogenous plasmin.

Stabilized, active plasmin is a novel thrombolytic for direct delivery to clots. Although it is known that protease inhibitors in plasma inhibit plasmin, the amount of plasmin that can be added to plasma/blood before free plasmin is observed is not clear. Determination of free plasmin activity in plasma using chromogenic substrates represents a challenge due to false-positive signals from plasmin entrapped by alpha2-macroglobulin. Size-exclusion chromatography was used to separate the plasmin-alpha2-macroglobulin complex from uninhibited, free plasmin. In this in-vitro study, exogenous plasmin is effectively inhibited up to 2.4 micromol/l after 5-min incubation with plasma at 37 degrees C. Initially, plasmin was consumed predominantly by alpha2-antiplasmin up to 1.2 micromol/l plasmin. Following exhaustion of alpha2-antiplasmin, plasmin was further consumed by alpha2-macroglobulin up to 2.4 micromol/l plasmin added to human plasma. Whole human blood was found to have an increased inhibitory capacity over that of plasma; free plasmin activity could be measured only above 3.8 micromol/l added plasmin. In conclusion, several mechanisms exist that control plasmin activity in human blood; in addition to alpha2-antiplasmin and alpha2-macroglobulin, blood cells contribute to the inhibition of exogenously administered plasmin. These in-vitro results indicate that doses of plasmin up to approximately 12 mg/kg in humans can be completely inactivated by blood.

Induction of lipolysis in vitro and loss of body fat in vivo by zinc-alpha2-glycoprotein.

Loss of adipose tissue in cancer cachexia has been associated with tumour production of a lipid-mobilizing factor (LMF) which has been shown to be homologous with the plasma protein zinc-alpha(2)-glycoprotein (ZAG). The aim of this study was to compare the ability of human ZAG with LMF to stimulate lipolysis in vitro and induce loss of body fat in vivo, and to determine the mechanisms involved. ZAG was purified from human plasma using a combination of Q Sepharose and Superdex 75 chromatography, and was shown to stimulate glycerol release from isolated murine epididymal adipocytes in a dose-dependent manner. The effect was enhanced by the cyclic AMP phosphodiesterase inhibitor Ro20-1724, and attenuated by freeze/thawing and the specific beta3-adrenoreceptor antagonist SR59230A. In vivo ZAG caused highly significant, time-dependent, decreases in body weight without a reduction in food and water intake. Body composition analysis showed that loss of body weight could be attributed entirely to the loss of body fat. Loss of adipose tissue may have been due to the lipolytic effect of ZAG coupled with an increase in energy expenditure, since there was a dose-dependent increase in expression of uncoupling protein-1 (UCP-1) in brown adipose tissue. These results suggest that ZAG may be effective in the treatment of obesity.

Locally delivered plasmin: why should it be superior to plasminogen activators for direct thrombolysis?

With advances in the field of thrombolytic therapy, whereby clots are routinely treated locally via a catheter, traditional systemic thrombolytics such as plasminogen activators might not be the best drugs for this task. Plasmin represents a new class of thrombolytic agents that exhibit direct fibrinolytic activity, without the need for either plasminogen or a plasminogen activator. In contrast to plasminogen activators, this independence from plasminogen allows plasmin to efficiently dissolve long, retracted blood clots that are inherently deficient in plasminogen. Preclinical safety studies in rabbits demonstrate that plasmin, in contrast to tissue-type plasminogen activator, does not cause re-bleeding from preformed hemostatic plugs. These results predict that plasmin will prove to be both superior to, and safer than, plasminogen activators in the dissolution of long, retracted blood clots in humans.

Membrane permeation characteristics of abacavir in human erythrocytes and human T-lymphoblastoid CD4+ CEM cells: comparison with (-)-carbovir.

Abacavir, (-)-(1S,4R)-4-[2-amino-6-(cyclopropylamino)-9H-purin-9-yl]-2-cyclopentene-1-methanol, is a novel purine carbocyclic nucleoside analogue that has been approved by the FDA for the treatment of HIV (as Ziagen trade mark [abacavir sulfate]). Chemically, abacavir and (-)-carbovir (CBV) differ only at the 6-position of the purine ring; abacavir contains a cyclopropylamino moiety in place of the 6-lactam functionality of CBV. Intracellularly both are ultimately metabolized to CBV triphosphate. We compared the membrane permeation characteristics of these two compounds at 20 degrees C in human erythrocytes and in human T-lymphoblastoid CD4+ CEM cells, using a "papaverine-stop" assay. In erythrocytes, abacavir influx was rapid, nonsaturable (rate constant=200 pmol/s/mM/microl cell water), and unaffected by inhibitors of nucleoside or nucleobase transport. CBV influx was slow, saturable, strongly inhibited by adenine or hypoxanthine, and occurred via both the nucleobase carrier (Vmax=0.67 pmol/s/microl cell water; Km=50 microM) and the nucleoside carrier (Vmax=0.47 pmol/s/microl cell water; Km=440 microM). Similar qualitative results were obtained with CD4+ CEM cells, although CBV influx rates were somewhat higher and abacavir influx rates lower, compared to the corresponding rates in erythrocytes. Equilibrium studies further revealed that both compounds are concentrated intracellularly, but nonmetabolically, in both cell types, apparently due to cytosolic protein binding (absent in erythrocyte ghosts). We conclude that, in both cell types, while CBV influx is slow and carrier-dependent, abacavir influx occurs rapidly by nonfacilitated diffusion. The membrane permeation characteristics of abacavir are consistent with its superior oral bioavailability and its impressive ability to penetrate the central nervous system.