Transgenic mice with tissue-specific expression of the human insulin gene in the beta cells of the pancreas do not produce insulin-specific antibodies when injected with human insulin. Tolerant transgenic mice injected with human or porcine insulin reflect the clinical situation. When injected with bovine insulin the transgenic mice produce antibodies. The potential immunogenicity of 12 recombinant human insulin analogues has been tested in this transgenic model. The analogues were designed either to prevent hexamer formation or to improve chemical stability or both. The analogues have amino acid substitutions or deletions at residue 8, 10 and 21 in the A-chain and residue 3, 9, 27 and 28 in the B-chain. The results show that substitution of single amino acids in the A-chain loop of human insulin for the corresponding amino acids in bovine insulin at residues A8 or A10 is sufficient to elicit an antibody response in responder mice. Only human insulin analogues with substitutions at residues 8 or 10 in the A-chain elicit antibody formation in the transgenic mice, whereas non-transgenic control groups respond to insulin and all analogues. Antibodies developed against the human insulin analogues are cross reactive with recombinant human insulin. Antibodies developed against an immunogenic analogue could therefore neutralize both the analogue and the native insulin and thereby aggravate the patient's condition. This transgenic mouse immunogenicity model should be useful as an in vivo model to map immunogenic areas of recombinant proteins.
Biosynthetic human growth hormone was injected subcutaneously in rats for 90 days and in cynomolgus monkeys for 30 days. The daily doses were 0.5, 3.3 and 25 IU kg-1 (rats) and 0.3 and 15 IU kg-1 (monkeys). The growth hormone was tolerated well in both rats and monkeys. No drug related deaths occurred and all animals appeared to be normal and also behaved normally throughout the dosing period. Increased body weight gain, increased food utilisation and increased organ weights were seen in the rats in the high and intermediate dose groups. The higher doses of human growth hormone (3.3 and 25 IU kg-1) caused a glandular hyperplasia of the mammary gland in male and female rats with evidence of secretory activity. In the female monkeys secretory activity was seen without any sign of mammary gland hyperplasia. Mucification of the vaginal epithelium and stress induced prostatitis was observed in the rats. Additional treatment related changes in the rats were an increased haematopoietic activity in the spleen and an increase in the amounts of calcium and phosphate excreted in urine. An increase in fasting plasma glucose levels was seen in the male monkeys on the high dose level. The changes observed during the treatment periods presumably represent exaggerated pharmacological effects of the growth hormone.
SummaryRecombinant human factor VII a (rFVIIa) is an activated coagulation factor for intravenous use as a haemostatic agent in haemophiliacs who generate antibodies against factor VIII or IX. Plasma kinetic studies are important for the understanding of the action of rFVIIa which is exerted in the vascular compartment of the body, more specifically on the vessel walls at the site of injury. In the present study, rats were dosed 100 or 500 μg/kg 125I-rFVIIa i. V., without any side effects being observed, and the plasma profile of rFVIIa was studied by 3 different assays that were shown to correlate well at early times post-dose: trichloroacetic acid (TCA)-precipitable drug-related radioactivity, rFVIIa antigen determination by ELISA technique, and the assay of clot activity which is the only clinically applicable assay. The plasma concentration curve could be resolved into 1-3 exponentials, depending on the FVIIa detection principle that was employed. Initially, there was a short (ca. 10 min) phase of increasing concentrations before the attainment of C max. This was followed by a plasma recovery (C max × plasma volume/dose) in the vicinity of one half of the administered dose. The initial volume of distribution (V 1) corresponded to the vascular compartment whereas the volume of distribution at steady state (V ss) was somewhat larger. Whole body clearance (CL-B) of rFVIIa was approx. 1 ml/min per kg, and mean residence time (MRT) and the half-life assumed to be associated with the loss of biological activity was approx. 1 h and 20-45 min, respectively. From these plasma data, rFVIIa appears to be a low clearance compound with limited tissue distribution and a short half-life. Tissue distribution studies showed that high 125I levels, assumed to be rFVIIa-related, included mineralised bone and well-perfused organs such as the liver which suggested that this organ was responsible for a major proportion of CL-B. Finally, mass balance studies showed that almost 90% of the administered radioactivity could be accounted for following an i. v. dose, predominantly as non drug-related radioactivity, even though a small amount of TCA-precipitable radioactivity was excreted via the biliary route. In conclusion, dose- or sex-dependent plasma kinetics and tissue distribution within a dose range of 100 to 500 μg/kg of rFVIIa was not observed. In the early and pharmacologically relevant phase after rFVIIa administration there appears to be good agreement between the various plasma assays employed in the study, indicating that the clot assay yields useful information in studies of rFVIIa plasma pharmacokinetics.
FFR-rFVIIa is an antithrombotic agent, which has also proven to have antirestenotic properties in animal models. FFR-rFVIIa is a modified recombinant FVIIa in which the catalytic site is irreversibly inactivated by a synthetic tripeptide covalently bound with the FVIIa molecule. The modified rFVIIa retains its tissue factor (TF) binding capacity but is otherwise enzymatically inactive. A double-blind, placebo-controlled, randomized dose escalation trial was conducted to investigate eight single i.v. doses of FFR-rFVIIa (0.01, 0.02, 0.05, 0.08, 0.12, 0.18, 0.27, or 0.40 mg/kg body weight) in healthy male volunteers (n = 62). Safety, pharmacokinetics, and pharmacodynamics of FFR-rFVIIa were assessed. Mean (SD)AUC0-infinity ranged from 0.35 (0.11) to 28.8 (3.5)microg.h/ml, and mean Cmax ranged from 0.078 (0.019) to 4.8 (0.7) microg/ml. The mean elimination half-life ranged from 3.8 to 5.8 hours. Mean AUC0-infinity increased with increasing dose levels. Cmax appeared to be proportional to the dose level, with the exception of the lowest dose level. A dose-dependent prolongation of the prothrombin time was found, demonstrating that FFR-rFVIIa inhibited coagulation via the TF-dependent pathway FFR-rFVIIa was generally well tolerated at all dose levels studied.
Based upon in vivo rat experiments it was recently suggested that interleukin 1 in the circulation may be implicated in the initial events of beta-cell destruction leading to insulin-dependent diabetes mellitus (IDDM) in humans. The aim of the present study was to estimate half-lives of distribution (T1/2 alpha) and elimination phases (T1/2 beta) of human recombinant interleukin 1 beta (rIL-1 beta), and its tissue distribution and cellular localization by means of mono-labelled, biologically active 125I-rIL-1 beta. After intravenous (i.v.) injection, 125I-rIL-1 beta was eliminated from the circulation with a T1/2 alpha of 2.9 min and a T1/2 beta of 41.1 min. The central and peripheral volume of distribution was 20.7 and 19.1 ml/rat, respectively, and the metabolic clearance rate was 16.9 ml/min/kg. The kidney and liver showed the highest accumulation of tracer, and autoradiography demonstrated that 125I-rIL-1 beta was localized to the proximal tubules in the kidney and to the hepatocytes in the liver. Furthermore, grains were localized to the islets of Langerhans in the pancreas. Tracer-bound proteins corresponding to intact 125I-rIL-1 beta were found in the circulation after i.v., intraperitoneal (i.p.) and subcutaneous (s.c.) injections, as demonstrated by high performance size exclusion chromatography, trichloracetic acid precipitation and SDS-PAGE until 5 h after tracer injection. Pre-treatment with 'cold' rIL-1 beta enhanced degradation of a subsequent injection of tracer. The route of administration was of importance for the biological effects of rIL-1 beta, as demonstrated by a reduced food intake, increased rectal temperature and blood glucose after s.c. injection of rIL-1 beta compared with i.p. The present demonstration of intact rIL-1 beta in the circulation and the islets of Langerhans supports the hypothesis that systemic IL-1 beta may be involved in the initial beta-cell destruction leading to IDDM in humans.
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