Monoclonal digoxin-specific antibodies induce dose- and affinity-dependent plasma digoxin redistribution in rats

Prediction of Drug Tissue to Plasma Concentration Ratios Using a Measured Volume of Distribution in Combination With Lipophilicity

One of the drug specific parameters needed in physiologically based pharmacokinetic (PBPK) models is the tissue to plasma drug concentration ratios (K(p) values). The aim of this study was to develop an empirical method for predicting K(p) values using a preclinically determined in vivo volume of distribution, in combination with descriptors for drug lipophilicity. Pharmacokinetic data in laboratory animals for a wide range of drug compounds were collected. Obtained correlations between K(p) values for muscle and other tissues, in a training set of 49 compounds, were used to predict K(p) values for a test set of 22 compounds, based on their volume of distribution and lipophilicity. Predicted K(p) values agreed well with experimentally determined values (n = 118), especially for noneliminating tissues (r(2) = 0.81) with 72% and 87% being within a factor +/-2 and +/-3, respectively. In conclusion, we present an empirical method based on a measured volume of distribution and a drug lipophilicity descriptor, which can be used to predict tissue K(p) values with reasonable accuracy.

Construction and functional evaluation of a single-chain antibody fragment that neutralizes toxin AahI from the venom of the scorpion Androctonus australis hector

9C2 is a murine monoclonal IgG that participates in the neutralization of Androctonus australis hector scorpion venom. It recognizes AahI and AahIII, two of the three main neurotoxins responsible for almost all the toxicity of the venom when injected into mammals. Using PCR we cloned the antibody variable region coding genes from 9C2 hybridoma cells and constructed a gene encoding a single-chain antibody variable fragment molecule (scFv). This scFv was produced in the periplasm of Escherichia coli in a soluble and functional form and purified in a single step using protein L-agarose beads yielding 1-2 mg.L(-1) of bacterial culture. scFv9C2 was predominantly monomeric but also tended to form dimeric and oligomeric structures, all capable of binding toxin AahI. The affinity of scFv and the parental mAb for toxin AahI and homologous toxin AahIII was of the same magnitude, in the nanomolar range. Similarly, purified forms of scFv9C2 completely inhibited the binding of toxin AahI to rat brain synaptosomes. Finally, scFv9C2 was efficient in protecting mice against the toxic effects of AahI after injection of the toxin and scFv to mice by the intracerebroventricular route in a molar ratio as low as 0.36 : 1. Thus, we produced a recombinant scFv that reproduces the recognition properties of the parent antibody and neutralizes the scorpion neurotoxin AahI, thereby opening new prospects for the treatment of envenomation.

Time- and dose-dependent digoxin redistribution by digoxin-specific antigen binding fragments in a rat model

To study the influence of the interval between digoxin intake and digoxin-specific antigen binding fragment (DSFab) administration, we developed a rat kinetic model. 3H-digoxin (0.77 nmol/kg) was injected by intravenous route and DSFab was injected at different times (12, 30 or 60 min) corresponding to different levels of 3H-digoxin distribution (50, 83 and 100%). The effect of increasing the molar DSFab/3H-digoxin ratio from 1 to 5 was also investigated. To evaluate DSFab effect on the 3H-digoxin pharmacokinetics, we also investigated the pharmacokinetics of the 125I-DSFab and DSFab-3H-digoxin complex. 3H-digoxin and DSFab-3H-digoxin complex pharmacokinetics showed that DSFab altered immunoreactive 3H-digoxin pharmacokinetics. In redistribution studies performed 12, 30 or 60 min after 3H-digoxin injection, DSFab bound immunoreactive 3H-digoxin including native 3H-digoxin and active metabolites of 3H-digoxin. This binding induced a redistribution process of immunoreactive 3H-digoxin in the DSFab distribution compartment and was evaluated by the redistribution fraction (F(R)). F(R) was 23% lower at 60 min than at 12 and 30 min, and by increasing the DSFab/3H-digoxin ratio from 1 to 5, F(R) increased by 60%. In conclusion, the longer the time interval between digoxin intake and DSFab administration, the lower the efficacy of the redistribution process. This effect could be reduced by increasing the DSFab dose.

Isolation and Characterization of Human Monoclonal Antibodies to Digoxin

Fab preparations of sheep polyclonal anti-digoxin Abs have proven useful for reversal of the toxic effects of digoxin overdoses in patients. Unfortunately, the use of foreign species proteins in humans is limited because of the potential for immunological responses that include hypersensitivity reactions and acute anaphylaxis. Immunization of recently developed transgenic mice, whose endogenous μ heavy and κ light chain Ig genes are inactivated and which carry human Ig gene segments, with a digoxin-protein conjugate has enabled us to generate and isolate eight hybridoma cell lines secreting human sequence anti-digoxin mAbs. Six of the mAbs have been partially characterized and shown to have high specificity and low nanomolar affinities for digoxin. In addition, detailed competition binding studies performed with three of these mAbs have shown them to have distinct differences in their digoxin binding, and that all three structural moieties of the drug, the primary digitoxose sugar, steroid, and five-member unsaturated lactone ring, contribute to Ab recognition.

Influence of various combinations of specific antibody dose and affinity on tissue imipramine redistribution

1. This study was designed to evaluate the distribution kinetics of imipramine (Imip) in the brain and the main peripheral organs (heart, kidney, liver and lung) of rats, and to establish the relationship between the redistribution of Imip from these tissues and the immunoreactive capacity (dose and affinity) of anti-TCA IgG. 2. [3H]-Imip (1 nmol kg(-1) body weight) was injected intravenously 6 min before the i.v. injection of antibodies. At this time, the concentrations of Imip and its main metabolites in plasma were determined. The radioactivity measured corresponded to 91.7% Imip, indicating that the pharmacokinetics reflected essentially Imip. Plasma and tissue Imip contents were measured over the interval 1 to 90 min in control and in treated rats. The antibodies used were a murine monoclonal IgG1 (Ka=3.8 10(7) M(-1)) at an IgG1/Imip molar ratio of 1000 (IgG1 1000), and a sheep polyclonal IgG (TAb, Ka=1.3 10(10) M(-1)) at IgG/ Imip molar ratios of 1, 10 and 100 (TAb1, TAb10 and TAb100). 3. The anti-TCA IgG increased the plasma [3H]-Imip concentrations: the AUC1-->60 min for [3H]-Imip were 4 (IgG1 1000), 9 (TAb1), 33.9 (TAb10) and 41.4 (TAb100) times higher in the treated groups than in the controls. The opposite effect occurred in the brain, heart and lungs, with large, rapid decreases in Imip. The increase in plasma Imip and the decrease in tissue Imip depended on the immunoreactive capacity (NKa) of the antibody, where N=molar concentration of IgG binding sites and Ka=IgG affinity constant. Maximal plasma and tissue redistribution occurred when NKa=33.8 x 10(4). 4. Imip redistribution can be controlled using various doses or affinities of specific antibodies, and the resulting rapid, extensive Imip redistribution from the main target organs could be very promising for TCA detoxification.

Anti-digoxin scFv fragments expressed in bacteria and in insect cells have different antigen binding properties

A gene encoding a single-chain antibody fragment directed against digoxin (named 1C10 scFv) was cloned in two expression systems. For this purpose, a new baculovirus transfer cassette fully compatible with the procaryotic pHEN vector was constructed. Baculovirus production led to higher yield than did Escherichia coli expression. The procaryotic fragment showed variations in the fine specificity profile but an affinity constant nearly identical to that of the 1C10 Fab, whereas the eucaryotic scFv fragment had a lower affinity with a specificity profile identical to original mAb. The half-lives of the digoxin:scFv complexes and the global specificity are compatible with therapeutic use of this antibody fragment.

Immunoreactivity of a new generation of horse F(ab')2 preparations against European viper venoms and the tetanus toxin

The immunoreactivity of the current and the new more purified, pasteurized preparations of horse F(ab')2 against the tetanus toxin and Vipera aspis venom was investigated with a biosensor based on technology using the optical phenomenon of surface plasmon resonance. Immunoreactivity data were compared with seroneutralization titres to investigate immunoreactivity-immunoprotection efficacy relationships. The association-dissociation rate and affinity constants of the current and the new tetanus toxin-specific F(ab')2 preparations were similar, at about 10(4) M-1 sec-1, 10(-4) sec-1 and 10(8) M-1, respectively. Similar values were found using a solid immunoradiometric assay. To assess the immunoreactivity of V. aspis venom-specific horse F(ab')2, the mol. wt and percentage of the antigenic fractions of V. aspis venom were determined. Western blotting of electrophoresis gels showed four antigenic fractions of V. aspis venom (mol. wts 17,500, 28,500, 32,000 and 60,000), which represented 6, 3.4, 17.7 and 5% of total venom, respectively. Association and dissociation rate constants were in the same range as those of the tetanus toxin-F(ab')2 interactions for each of the four antigenic fractions. Seroneutralization of both tetanus toxin and V. aspis by the corresponding specific F(ab')2 showed that the LD50 mg-1 protein was 1.76-fold and 1.51-fold higher with the new than with the current preparations, respectively. These improvements in efficacy were in close agreement with the higher immunoreactive fraction ratios, which were 2-fold and 1.8-fold higher with the new preparations. These results demonstrate that the removal of non-IgGT immunoglobulins and the pasteurization treatment have no overall influence on F(ab')2 affinity but improve the specific activity of these new antitoxin horse F(ab')2.

Facilitation of imipramine efflux from the brain by systemic specific antibodies

1. This study investigated the capacity of circulating anti-tricyclic antidepressant (TCA) IgG to increase the efflux of imipramine (Imip) from the rat brain. 2. A tracer amount of [3H]-Imip (40 pmol) was injected into the cerebral lateral ventricle and its efflux was determined in control rats and in rats given anti-TCA antibody. The monoclonal anti-TCA IgG1 was injected i.v. 48 h before Imip at 4 IgG:Imip molar ratios (10, 100, 1000 and 10,000). The [3H]-Imip in arterial and venous plasma was measured for up to 60 min, and in the brain and peripheral organs (heart, liver, lung, kidney) 5 and 60 min after Imip injection. 3. The arterial plasma concentration of Imip in control rats was significantly higher (26.7 +/- 2.1 pM) than the venous one (17.7 +/- 2.0 pM) at 5 min, indicating that Imip released from brain becomes distributed in peripheral tissues. These concentrations were not significantly different at 60 min suggesting that Imip was, at this time, redistributing from extravascular tissues to the blood. In rats given anti-TCA IgG, any Imip leaving the brain was immediately bound by the circulating antibody at 5 min. This greatly reduced the Imip in the heart (63.9%) and lung (61.3%) at the highest IgG:Imip ratio. The brain Imip was markedly lower at 60 min (31.5% with an IgG Imip ratio of 1000 and 57.5% at a ratio of 10,000). The two lowest IgG:Imip ratios had less effect on the plasma Imip because of the relative low affinity of the anti-TCA IgG (3.8 x 10(7) M-1). 4. These data indicate that the anti-TCA IgG facilitated the efflux of Imip from the brain, even though these antibodies cannot cross the blood-brain barrier. This may be an efficient system for increasing drug organ clearance, as more than half the Imip in the brain was actively removed by the antibody in 1 h.