Effect of Antivenom on Venom Pharmacokinetics in Experimentally Envenomed Rabbits: Toward an Optimization of Antivenom Therapy

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Vol. 281, Issue 1, 1-8, 1997

Effect of Antivenom on Venom Pharmacokinetics in Experimentally Envenomed Rabbits: Toward an Optimization of Antivenom Therapy

Gilles Rivière, Valérie Choumet, Françoise Audebert, Alain Sabouraud, Marcel Debray, Jean-Michel Scherrmann and Cassian Bon

Unité des Venins, Institut Pasteur, 25 rue du Dr Roux, 75724 Paris Cedex 15 (G.R., V.C., F.A., C.B.), Unité INSERM, Hôpital Fernand Widal, 200 rue du Faubourg Saint-Denis, 75010 Paris (A.S., J.M.S.), and Laboratoire de Biomathématiques, Université Paris 5, Faculté des Sciences Pharmaceutiques et Biologiques, 4 Avenue de l'Observatoire, 75006 Paris (M.D.), France

	Abstract

Top Abstract Introduction Methods Results Discussion References

Antivenomous immunotherapy is still used empirically. To improve the efficacy and safety of immunotherapy, we studied theeffects of administering antivenom antibodies (F(ab $'$ )₂) on thepharmacokinetics of the Vipera aspis venom in rabbits. Free venomlevels were measured by enzyme-linked immunosorbent assay andtotal concentrations were quantified by measuring the radioactivityof trichloroacetic acid-precipitable radioiodinated venom. Theintravenous infusion of 125 mg of antivenom 7 h after intramuscularinjection with 700 µg·kg¹ of V. aspis venom produced a redistribution of the venom antigensfrom the extravascular to the vascular space. Moreover, antivenomantibodies were able to neutralize the totality of venom antigensin the vascular space, because no free plasma venom was detectableby enzyme-linked immunosorbent assay within 15 min after antivenominjection. Similar effects were obtained after injection of 25mg of antivenom; however, the venom was only partially neutralizedwith lower doses (5 and 2.5 mg). We further established that intravenousinjection is the most efficient route for antivenom administration,and we examined the effects of early and late immunotherapy. Finally,the efficacy of Fab antibodies was compared with that of F(ab $'$ )₂;the plasma redistribution and the immunoneutralization of thevenom were lower than those induced after injection of the samedose of F(ab $'$ )₂. The difference between the effects of F(ab $'$ )₂and Fab could be explained by the differential pharmacokineticsof the two fragments.

	Introduction

Top Abstract Introduction Methods Results Discussion References

Snake bites represent a major medical problem, especially in subtropical countries where they still cause high rates of morbidityand mortality. The specific treatment of envenoming is the administrationof antivenoms, i.e., the injection of empirical amounts of antibodies,a part of which (about 20%) is directed against venom components.Although immunotherapy has proved its effectiveness in reducingmortality and morbidity of snake bites, it is also responsiblefor acute or delayed allergic reactions, the incidence of whichdepends mainly on the amount of heterologous antibodies injectedand on the purity of the antivenom. To improve the safety andefficacy of antivenoms, two approaches can be followed: 1) improvingthe antivenom preparation and processing and 2) optimizing theuse of antivenoms.

Acute side effects are mainly caused by immune sensitization to horse antibodies, which are widely used in human therapeutics.Some investigators have advocated antivenom produced in otheranimals, such as sheep (Sjostrom et al., 1994; Consroe et al.,1995) or hens (Carroll et al., 1992), although antibodies producedin this way were not shown to be less immunogenic than horse antibodies.Another approach to decreasing the side effects is to lower theamount of heterologous proteins injected by selecting those antibodiesthat specifically react with the venom, by use of immunopurification(Smith et al., 1992). The major drawback of this method is thehigh production cost. Other investigators have described the isolationof a fraction of immunoglobulins, called IgG_T, from the serumof hyperimmunized horses (Fernandes et al., 1991; Pépin et al.,1995). This fraction showed high protective ability but may bevery immunogenic because of a high level of glycosylation of theFc fragment (Sjostrom et al., 1994).

In parallel with the improvement of antivenom preparation, it would be useful to optimize their use during immunotherapy.At present, there is no definite protocol to guide cliniciansin the choice of an appropriate treatment of envenomings. To assessthe necessity of immunotherapy and to modify the dose of antivenom,the severity of the envenoming must be known as quickly as possible.Moreover, some parameters of antivenom administration, such asthe delay after snake bites, the route of injection and the typeof antibodies to be used (immunoglobulins or antigen-binding fragments)should be based on a clear understanding of the process of venomneutralization in the body. Such an understanding would lead toa precise definition of the antivenom quality and of the parametersof antivenom therapy applicable to different types of envenomings.

In France, the problem of envenoming is less acute than in subtropical countries, because only about 2,000 viper envenomingsoccur every year, with a mortality rate of about one to two deathsper year (Chippaux and Goyffon, 1989). An ELISA was set up todetermine venom concentrations in biological samples of patientsbitten by vipers to establish a correlation between venom plasmalevels and clinical symptoms (Audebert et al., 1992). This assaywas used to follow the disposition of Vipera aspis venom afterintravenous and intramuscular injections to rabbits (Audebertet al., 1994b). After intravenous injection, V. aspis venom wasshown to have a short distribution half-life (0.7 h) and a volumeof distribution 20-fold larger than that of the central compartment.After intramuscular injection, the venom followed a complex resorptionprocess, high concentrations being maintained in the blood formore than 3 days.

In the present work, we tested the effect of several doses of antivenom and of different routes of injection on the pharmacokineticsof venom. We also investigated the effect of early and delayedadministration of antivenom, as well as the relative efficacyof different fragments of immunoglobulins.

	Methods

Top Abstract Introduction Methods Results Discussion References

Detection of Free Venom in Plasma

Purification of reagents. Immunoglobulin fragments used for the ELISA determination were purified from IPSER Europe antivenom (Pasteur Mérieux Sérumset Vaccins). IPSER Europe antivenom consists of equine F(ab $'$ )₂fragments specifically directed against the venoms of V. aspis,Vipera berus and Vipera ammodytes. F(ab $'$ )₂ fragments were purifiedas described by Audebert et al. (1994a) and were labeled withperoxidase by glutaraldehyde coupling by a two-step procedure(Avraméas and Terninck, 1969, 1971).

ELISA. This test was based on the method described by Audebert et al. (1994b). Microplates (Nunc, Roskilde, Danemark) were coatedwith 100 µl per well of a solution of purified F(ab $'$ )₂ dilutedin 0.1 M sodium bicarbonate buffer, pH 9.5. After 2 h at 37°C,the plates were washed six times with a solution of phosphatebuffer saline, pH 7.4, containing 1 $per thousand$ Tween 20 (PBS-Tween). Theplates were blocked with PBS containing 3% of bovine serum albumin(PBS-BSA) during 1 h at 37°C. After washing, 100 µl samples wereadded in duplicate wells and the plates were incubated for 1 hat 37°C. The plates were washed six times with PBS-Tween and 100µl of venom-specific antibodies conjugated with peroxidase dilutedin PBS-BSA containing 1 $per thousand$ Tween 20 were added to each well. Theplates were incubated for 1 h at 37°C. After washing with PBS-Tween,100 µl of substrate medium [0.01 M phosphate sodium buffer, pH7.3, containing 2 mg·ml¹ of o-phenylenediamine dichloroamide (Sigma Chemical Co., St.Louis, MO) and 0.06% of H₂O₂] were distributed into each well.The colored reaction was stopped by adding to each well 50 µla solution of 2 N H₂SO₄ containing 0.5% of sodium sulfate. Opticaldensity was measured at 490 nm with a microplate reader MR 5000(Dynatech Laboratories, Denkendorf, Germany). Venom antigen plasmaconcentrations (ng·ml¹) were determined by comparison with a standard curve establishedwith crude V. aspis venom (Latoxan, Rosans, France) diluted innormal rabbit serum.

Iodination of Venom

Iodination was performed as described by Audebert et al., (1994b) with the iodogen method of Fraker and Speck (1978). Eppendorftubes (1.5 ml) were coated with 0.3 mg of iodogen (Pierce, Rockford,IL) diluted in 750 µl of chloroform. Three milligrams of venomdiluted in 300 µl of PBS were added to the radioactive iodine.After 6 min of incubation, free iodine was separated from radioactiveproteins by Sephadex G-15 gel filtration. As described by Audebertet al. (1994b), venom was separated in two fractions: HMWP, whichwere radiolabeled, and LMWP, which were not. Venom was reconstitutedby pooling HMWP and LMWP. Venom used in the pharmacokinetic experimentshad a specific activity of about 100 µCi·mg¹.

Detection of Total Venom

Total venom (free or immunoconjugated venom) was detected by determination of the TCA-precipitable ¹²⁵I-radiolabeled proteins contained in rabbit plasma. TCA precipitationswere performed as follows: 50 µl of plasma were loaded onto aGF/A filter (Whatman, Maidstone, England) and dried under a lamp.Two milliliters of 10% TCA were incubated with filters for 10min to precipitate native proteins on the filter. Two millilitersof absolute ethanol were used to dry the filters, and the radioactivityof the filters was counted using a multigamma counter 1261 (Pharmacia,Uppsala, Sweden).

Determination of Plasma Concentrations of F(ab $'$ )₂ and Fab

Plasma concentrations of fragments of immunoglobulins [F(ab $'$ )₂ or Fab] were measured by ELISA. Unlabeled and peroxidase-labeledrabbit antihorse immunoglobulin antibodies were obtained fromBiosys (Compiègne, France). Tests were performed as follows:microplates were coated with a solution of 2.5 µg·ml¹ of unlabeled antihorse immunoglobulin antibodies diluted in a0.1 M sodium bicarbonate buffer, pH 9.5 (100 µl per well). After2 h at 37°C, wells were saturated with 100 µl per well of PBScontaining 0.5% of gelatin. Samples and standards diluted in PBS-Tweencontaining 0.5% of gelatin were added in duplicates after 1 hat 37°C. After incubation at 37°C during 1 h, 100 µl per wellof peroxidase-labeled antihorse immunoglobulin antibodies dilutedin PBS-Tween-gelatin were added to each well. A color reactionwas performed as described above.

Lethality Assay

LD₅₀ values of cold and labeled venom were determined according to the WHO's method (1981). Male mice weighing 18 to 20 g(Charles River, St Aubin-lès-Elbeuf, France) were injected intravenouslyin the tail vein. Five doses of venom were injected (5, 7, 10,14 and 20 µg per mouse). Three mice were used per dose.

Preparation of Fab Fragments

Fab was produced by cleaving the commercial F(ab $'$ )₂ preparation with papain, according to the method of Parham (1986) withminor modifications. F(ab $'$ )₂ preparation was dialyzed against1 M Tris-HCl buffer, pH 7, containing 2 mM ethylenediaminetetraaceticacid. One milliliter of 1 M Tris-HCl buffer, pH 7.5, 1 ml of 20mM ethylenediaminetetraacetic acid, 1 ml of 0.1 M cysteine, 1ml of papain (10 mg, Boehringer, Mannheim, Germany) and 6 ml ofwater were added to the dialyzed preparation. This mixture wasincubated for 24 h at 37°C. Then, 1 ml of papain was added andthe mixture was again incubated for 24 h at 37°C. The reactionwas stopped by addition of iodoacetamide at 5 mM (final concentration).Undigested and digested fragments were separated by gel filtrationwith a Sephadex G-100 column equilibrated with 5 mM sodium phosphatebuffer, pH 8, containing 0.15 M NaCl.

Pharmacokinetic Experiments

New Zealand rabbits weighing 2.75 to 3 kg (CEGAV, St Mars-d'Egrenne, France) were placed in metabolism cages, which allowedthe collection of urines and feces. Food and water were providedad libitum. Experimental envenomings were performed by an intramuscularinjection in the leg of 700 µg·kg¹ of radioactive venom in a final volume of 500 µl. Blood was seriallycollected in heparinized tubes from the central artery of theears. Plasma was obtained by centrifugation at 1,500 × g for 15min. Antivenom antibodies diluted in 5 ml of 0.15 M NaCl wereinfused into the marginal vein of the ear for an 8-min periodby a syringe pump (Bioblock, Illkirch, France). Intramuscularimmunotherapy was performed by injecting immunoglobulin fragmentsin a final volume of 500 µl into the contralateral leg used forthe administration of the venom.

Pharmacokinetic parameters for the fragments of immunoglobulins were determined by the MKMODEL software (BioSoft, Cambridge,England). CL_T was determined as equal to D/AUC, Vd_ss as equalto (D·AUMC)/AUC² and MRT as equal to AUMC/AUC, where D was the dose injected,AUC was the area under the curve from injection to infinity andAUMC was the area under the mean curve; t_1/2 $alpha$ and t_1/2 $beta$ representedthe distribution and elimination half-lives.

The efficacy of immunotherapy was quantified by the following method: areas under the total and free venom curves (AUC_t andAUC_f, respectively) during 72 h after immunotherapy were calculatedusing the trapezoidal rule, the difference (AUC_d = AUC_t $-$ AUC_f)was then used to allow comparisons.

Statistics

All results are given as mean ± standard error of the mean. Their significance was analyzed by the two-tailed unpaired orpaired Student's t test; the level of significance was set atP < .05.

	Results

Top Abstract Introduction Methods Results Discussion References

Lethality assays. LD₅₀ values were determined with radioactive and native venoms; no difference in potency was observed between the preparations(LD₅₀ of 15 and 13.3 µg of venom per 18 to 20 g mouse, respectively),which showed that iodination of the venom did not modify its toxicity.

Pharmacokinetics of V. aspis venom after intramuscular injection. Six rabbits were injected intramuscularly with 700 µg·kg¹ of radiolabeled venom, and the time courses of venom concentrationsin plasma were followed by use of ELISA and radioactivity (fig.1A). The use of radiolabeled venom allowed the quantificationof total venom components in plasma, whereas ELISA detected freevenom that was not complexed by the antivenom antibodies. Levelsof radioactivity indicated a slightly, but significantly differenttime course of the venom from that measured by ELISA: the AUCswere 7,200 and 4,500 ng·h·ml¹·kg¹ for radioactivity and ELISA, respectively (P < .05).

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Fig. 1. Effect of different doses of antivenom on the plasma pharmacokinetics of the venom of V. aspis. Rabbits were envenomed with700 µg·kg¹ of radiolabeled venom. Seven hours after envenomations, theyreceived either none, 125, 25 or 5 mg (A, B, C and D respectively)of IPSER Europe antivenom (arrows). Concentrations of total venom( $bullet$ ) were measured with radioactivity, and free venom concentrations( $square$ ) were measured by ELISA. Values are the means ± S.E.M. of threeindependent experiments except for A (n = 6).

Influence of different doses of antivenom on the plasma pharmacokinetics of V. aspis venom. Four doses (125, 25, 5 and 2.5 mg of antivenom F(ab $'$ )₂ per rabbit) were tested in the case of an experimental envenoming with700 µg·kg¹ of radiolabeled venom, a dose of venom which led to plasma concentrationscorresponding to a severe envenoming in humans (Audebert et al.,1994a). Immunotherapy was performed 7 h after envenoming via theintravenous route.

After intravenous injection of 125 mg of antivenom (fig. 1B), the plasma levels of free venom antigens rapidly decreased andbecame undetectable for more than 80 h, whereas during the sametime the total venom concentration in plasma increased rapidly.The AUC_d was about 40,000 ng·h·ml¹, almost 3-fold higher than that measured in the absence of antivenom,and the maximal concentration of total venom was 800 ng·ml¹ (table 1).

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TABLE 1
Influence of different parameters on the efficiency of immunotherapy

A dose of 25 mg of antivenom neutralized the venom present in the blood, because free venom concentrations were undetectableduring 2 h after antivenom injection (fig. 1C). After this phaseof neutralization, low and nontoxic concentrations of free venomreappeared in the blood (about 10 ng·ml¹). The AUC_d and the maximum concentration of total venom werenot statistically different from the values obtained after injectionof 125 mg of antivenom.

Lower doses of antivenom (2.5 and 5 mg) did not completely neutralize V. aspis venom, because free venom concentrations couldstill be detected by ELISA immediately after antivenom infusion(fig. 1D and table 1). Furthermore, 30 h after immunotherapy,high and toxic concentrations of venom were found in rabbit plasma(between 50 and 80 ng·ml¹). AUC_d was significantly increased, in comparison with untreatedanimals, but was much lower than that measured for a dose of 125mg (table 1).

Two parameters were used to quantify the efficiency of immunotherapy: the extent of immunocomplexation of venom antigens bythe antivenom and the amount of venom attracted in the blood fromthe extravascular compartment, as indicated by AUC_f and AUC_d,respectively (fig. 2). The values of AUC_d reached a plateau whenmore than 25 mg of antivenom was injected via the intravenousroute, which showed that a maximum redistribution of venom tothe vascular compartment had been obtained. Immunocomplexationwas also complete above that dose. Thus, the dose of 25 mg ofantivenom injected intravenously 7 h after experimental envenomingappears to be the maximally effective dose in terms of immunocomplexationand redistribution of the venom, and the parameters obtained withthis experiment were used as a reference to compare differentprocedures of immunotherapy.

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Fig. 2. Influence of different doses of antivenom injected 7 h after envenomation on the AUC_d ( $square$ ) and the AUC_f between envenomationand 72 h later ( $bullet$ ). Values are the means ± S.E.M. of three independentexperiments. AUC_f and AUC_d were calculated as described under"Material and Methods."

Route of administration of antivenom. The efficiency of an intramuscular injection of 25 mg of antivenom to rabbits was compared with the intravenous route. Intramuscularinjection produced a delayed and partial neutralization of venom(fig. 3); moreover, the AUC_d and the maximal concentration oftotal venom were very low in comparison with the intravenous route(P < .05, table 1).

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Fig. 3. Effect of immunotherapy via the intramuscular route. Seven hours after experimental envenomation 25 mg of antivenom was injectedintramuscularly in rabbits (arrow). The time courses of free ( $square$ )and total ( $bullet$ ) venom concentrations were followed during 80 h.Values are the means ± S.E.M. of three independent experiments.

Effect of the delay between envenoming and immunotherapy. In a first experiment, 25 mg of antivenom were injected in rabbits 3 h after experimental envenoming. Immediately after infusion,a complete immunocomplexation was observed which lasted for 2h (fig. 4A). Low concentrations of free venom (5-10 ng·ml¹) could be detected after that period. The AUC_d and the maximalconcentration were not significantly different from those observedwith a delay of 7 h.

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Fig. 4. Effect of the delay between experimental envenomation and intravenous injection of antivenom.Twenty-five milligrams of antivenomwere injected 24 h (A) or 3 h (B) after experimental envenomation(arrows). Free venom concentrations ( $square$ ) and total venom concentrations( $bullet$ ) were observed until 100 h after envenomation. Values are themeans ± S.E.M. of three independent experiments.

When antivenom was injected 24 h after envenoming (fig. 4B), the venom was completely neutralized during 24 h after infusionof antivenom. The redistribution of venom from extravascular tovascular compartment was lower than that obtained with a delayof 7 h (table 1).

Effect of Fab fragments on the pharmacokinetics of the venom. Fab fragments were prepared from the antivenom by papain digestion, and 25 mg of Fab was injected via the intravenous route7 h after envenoming. The Fab did not neutralize the venom antigenscompletely, and the redistribution induced by immunoglobulin fragmentswas very low, as shown by the measurement of AUC_d and maximalconcentration of total venom (fig. 5 and table 1). Furthermore,17 h after immunotherapy, the blood of treated rabbits containedtoxic concentrations of uncomplexed venom (about 75 ng·ml¹).

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Fig. 5. Effect of an immunotherapy performed with Fab fragments. Twenty-five milligrams of Fab were injected intravenously (arrow)in rabbits 7 h after experimental envenomation with radiolabeledvenom. Free ( $square$ ) and total ( $bullet$ ) venom concentrations were observedduring 80 h. Values are the means ± S.E.M. of three independentexperiments.

Pharmacokinetics of F(ab $'$ )₂ and Fab. We studied the pharmacokinetics of F(ab $'$ )₂ and Fab fragments to understand their different effects on venom neutralizationand redistribution. F(ab $'$ )₂ or Fab (25 mg) were infused accordingto the same protocol used after experimental envenoming (fig.6). Distribution and elimination half-lives of Fab were similarto those published in the literature (Ohning et al., 1994).

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Fig. 6. Pharmacokinetics of F(ab $'$ )₂ and Fab fragments. Rabbits were injected intravenously with 25 mg of immunoglobulin fragmentsF(ab $'$ )₂ or Fab (A and B, respectively). Curves have been drawnwith pharmacokinetic parameters obtained after model-dependentanalysis. Experimental values are the means ± S.E.M. of threeindependent experiments.

In all rabbits and for both fragments, plasma concentrations of fragments of immunoglobulins versus time curves fitted a biexponentialequation (table 2). The half-lives of F(ab $'$ )₂ were significantlylonger than those observed for Fab. Similarly, total body clearanceof Fab was higher than that of the divalent fragments (P < .01).On the other hand, the volume of distribution of Fab was largerthan that of F(ab $'$ )₂ (Vd_ss = 138 ml·kg¹ for F(ab $'$ )₂ and 230 ml·kg¹ for Fab, respectively).

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TABLE 2
Pharmacokinetic parameters of F(ab $'$ )₂ and Fab determined after intravenous injection of 25 mg of fragments to 3 rabbits

In F(ab $'$ )₂ from IPSER Europe, Pépin et al. (1995)

obtained slightly different results from ours: the values of Vd_ss was 231ml·kg¹ and clearance was around 4 ml·kg¹·h¹. The authors did not describe pharmacokinetic parameters forFab, so that a total comparison of their results with ours couldnot be allowed.

	Discussion

Top Abstract Introduction Methods Results Discussion References

Although serotherapy was discovered a century ago, the mechanism by which antivenom antibodies neutralize venom proteins isstill poorly understood. We therefore examined the effect of aspecific antivenom on venom plasma pharmacokinetics after experimentalenvenoming by V. aspis venom in rabbits. The use of a ¹²⁵I-labeled venom allowed the quantification of total venom componentsin plasma, whereas only free venom antigens were determined byELISA.

We first compared pharmacokinetic parameters obtained after intramuscular injection of V. aspis venom by the two methods ofmeasuring plasma venom concentrations. Slightly different valuesof AUC and clearance were obtained for total and free venom. Nevertheless,the terminal half-lives (t_1/2 $beta$ ) and the mean residence times wereshown to be the same with the two methods (around 30 and 50 hfor t_1/2 $beta$ and mean residence time, respectively). A similar observationwas described in the pharmacokinetic analysis of activated humanprotein C (Ishii et al., 1995) in which three methods were usedto follow plasma levels of the protein: radioactivity, ELISA andamidolytic activity. In that case, the differences in kineticparameters obtained with the three methods were explained by theformation of large complexes of protein C with plasma proteins,still detectable by radioactivity but less antigenic and biologicallyinactive. In V. aspis venom, three hypotheses can be considered:a binding of venom proteins to plasma proteins which can maskantigenic determinants, a degradation of some venom proteins stilldetectable by radioactivity but less antigenic or alternativelya differential detection of some proteins by radioactivity andELISA. The two first hypotheses were tested by gel electrophoresisof radioactive venom samples under nondenaturing conditions. Radioactivitywas shown to be associated with unchanged venom proteins and wedid not observe any binding of venom proteins to plasma proteins(data not shown). Considering the third hypothesis, Audebert etal. (1994b) have shown that all the proteins of the venom arenot radiolabeled with the same specific radioactivity and thatthey do not respond to ELISA with the same intensity. Therefore,the different values of clearance and AUC may be explained becausevenom proteins were not quantified exactly in the same way byELISA and radioactivity. It is important, however, to recognizethat these differences have no consequence on the further interpretationof the results obtained in this study, because radioactivity andELISA data are considered independently to measure the extentof redistribution or immunoneutralization under different conditions.

After intravenous injection of a neutralizing dose of antivenom (125 mg of F(ab $'$ )₂, i.e., half a vial of IPSER Europe antivenomper rabbit) 7 h after venom injection, we observed a redistributionof venom antigens from the extravascular space into the centralcompartment as well as a complete immunocomplexation of venomantigens in the blood. The effect of antivenom therapy on venomlevels in plasma has already been investigated by several authorsin experimental models (Lwin et al., 1984; Labrousse et al., 1988;Theakston, 1989) who reported that the plasma levels of venomantigens determined by ELISA decreased after intravenous injectionof the antivenom. However, these studies incompletely describedthe mechanism of action of antivenom, because ELISA does not quantifythe antigens bound in vivo to the antibodies.

To minimize the risks caused by the injection of large quantities of heterologous proteins, we tested the effect of lowerdoses of antivenom to determine the minimal dose necessary totreat severe envenomings. Three doses (25, 5 and 2.5 mg) wereinjected intravenously to rabbits, 7 h after the injection ofvenom by the intramuscular route. The dose of 25 mg of antivenomwas shown to induce a redistribution of venom from the extravascularto the vascular space, but this effect was not statistically differentthan that obtained with 125 mg. Furthermore, all the antigenicsites of venom proteins were complexed by antivenom during 2 h,and subsequent concentrations of free venom did not reach thetoxic level defined by Audebert et al. (1994a), because concentrationsdid not exceed 20 ng·ml¹. The lower doses examined (5 and 2.5 mg of F(ab $'$ )₂ were inefficient,because toxic-free venom protein levels were detected by ELISAand only small quantities of venom were extracted from the extravascularspace.

The amount of antivenom administered by clinicians is mainly determined by the clinical features, the size of the snake aswell as the known efficacy of available antivenom (Chippaux andGoyffon, 1983). Clinical trials have been undertaken to reducethe dose of antivenom administered to envenomed patients (Jorgeet al., 1995; Theakston et al., 1992). ELISA quantification oflevels of venom antigens in the blood could allow clinicians toaccurately adapt the dose of antivenom to the gravity of the envenomingand to follow the efficacy of antivenom treatment and thus toquickly evaluate the necessity of further antivenom injections.

The route of administration of antivenom is still controversial. The intravenous route has been considered by many authorsto be the most efficient one, although it has not been systematicallycompared with the intramuscular route. Furthermore, in France,health regulations only allow intramuscular administration ofantivenom. We, therefore, compared the effects of intravenousand intramuscular injections of 25 mg of antivenom on the pharmacokineticsof the venom. We observed a lower redistribution of the venomproteins in the intramuscular route. In addition, the immunoneutralizationof antigenic sites was delayed and incomplete. This phenomenoncan be explained in the light of the results published by Pépinet al. (1995), who determined the pharmacokinetic parameters ofantivenom after an intramuscular injection to rabbits. The maximumblood concentration (C_max) of F(ab $'$ )₂ was reached only 48 h afterthe intramuscular injection of antivenom. Furthermore, the calculatedbioavailability of IPSER Europe antivenom was about 42%. Thesetwo observations explain that the maximum immunocomplexation ofvenom proteins was delayed and that the redistribution was lessefficient than with intravenous injection of antivenom, becauseless than half of the antibodies were able to reach the centralcompartment. The intravenous route is, therefore, the most efficientroute of injection of antivenom, allowing a quick immunocomplexation,as well as an intense redistribution of the venom antigens. Forthese reasons, the intravenous route should be recommended. However,in the rare cases where antivenom cannot be administered by theintravenous route, the intramuscular route, although much lessefficient, may still be used.

In the initial experiments, the administration of antivenom was performed after the absorption phase of venom proteins todetermine the extent of redistribution induced by the injectionof antibodies. However, the delays in arrival of envenomed patientsat the hospital are highly variable, ranging from 1 h after envenomingto several days. We therefore tested the effect of an early anda delayed intravenous administration of antivenom on the pharmacokineticsof V. aspis venom. We observed a maximal redistribution when antivenomwas injected 3 h after the envenoming. Furthermore, a completeimmunocomplexation of venom antigens lasted for 2 h, and onlyvery low concentrations of free venom were detected at later times.In conclusion, in V. aspis envenoming, when a dose of antivenomappropriate for the severity of envenoming was injected early,no reinjection of antivenom to rabbits was necessary. When antivenomwas injected later (24 h) after envenoming, it still efficientlymodified the pharmacokinetics of the venom. However the inducedredistribution was lower and immunocomplexation lasted longerthan in our standard conditions (25 mg of F(ab $'$ )₂ injected 7 hafter experimental envenoming). This may be explained by the factthat some venom has already been cleared from the blood circulationafter 24 h. Obviously, it is difficult to predict the clinicaleffect of an immunotherapy performed a long time after envenoming.Actually, the effect of a delayed administration of antivenomis still controversial in the literature. Karlson-Stiber and Persson(1994) have reported that immunotherapy was not efficacious forpatients envenomed by V. berus when injected more than 18 h afterenvenoming, although one case of severe coagulation disturbanceswas shown to normalize when the antivenom was injected 30 h afterthe bite. On the other hand, two studies have reported successfultreatment by immunotherapy 1 week after viper envenoming (DwivediShubha Sheshadri and D'Souza, 1989; Tiwari and Johnston, 1986).In conclusion, antivenom is more efficient when injected earlyafter the bite, but may still be effective even after a long delay.

Fab fragments have already been used for clinical therapy to treat intoxications by digitalis (Smith et al., 1976) and colchicine(Baud et al., 1995). Fab preparations have also been producedagainst desipramine (Brunn et al., 1992), phencyclidine (Valentineet al., 1994) and other compounds. Fab fragments are preferredover complete antibodies (IgG) or F(ab $'$ )₂ fragments because ofthe low incidence of adverse reactions which occur when they areinfused. Only 0.8% of treated patients with specific antidigoxinFab were shown to develop allergic reactions (Hickey et al., 1991),whereas 6 to 7% of envenomed patients showed adverse effects whentreated with specific antivenom F(ab $'$ )₂ (Smith et al., 1992).These differences may be explained by the fact that Fab are notassociated with type III hypersensitivity, do not bind complementor macrophages and are less immunogenic than intact IgG (Smithet al., 1979). Furthermore, they have a greater volume of distributionand a lower elimination half-life than IgG and F(ab $'$ )₂. However,the detoxification process is slightly different in digitalisor colchicine intoxication where the toxic agent penetrates intocells, from the case of envenoming by V. aspis, where, to ourknowledge, no intracellular toxicity has been shown for the componentsof this venom. We therefore digested IPSER Europe F(ab $'$ )₂ withpapain and injected 25 mg of Fab 7 h after experimental envenoming.In this case, we observed a very low redistribution of venom antigens,in comparison with the redistribution induced by F(ab $'$ )₂ in thesame conditions. This phenomenon has already been described byButler et al. (1977) in anti-digoxin Fab. Moreover, the concentrationof free venom reached a toxic level 17 h after the injection ofFab fragments. In agreement with our observations, Ohning et al.(1994) reported that the effect of anti-gastrin Fab decreased24 h after their injection. These results indicated that Fab haveto be injected as an infusion rather than an intravenous injection.

The differences observed between the effects of F(ab $'$ )₂ and Fab on the pharmacokinetics of the venom were clearly linked tothe pharmacokinetics of F(ab $'$ )₂ and Fab. Although F(ab $'$ )₂ remainedmainly in the vascular compartment, Fab was largely distributedin the extravascular compartment. This is probably why the latterwas less efficient in inducing a redistribution of venom antigensinto the circulation. In the same way, although Fab and F(ab $'$ )₂were shown to have similar affinity constants for antigens (approximately10¹⁰ M, data not shown), Fab has a much shorter half-life than F(ab $'$ )₂in the plasma and, therefore, loses its inhibitory effect rapidly,as evidenced by the reappearance of toxic venom concentrationsin the plasma of rabbits.

Fab fragments therefore appeared less efficient in treating envenoming than in treating digitalis or colchicine intoxications.This is consistent with the dissociation kinetics of the differenttoxins from receptors. In digitalis intoxication, digoxin wasshown to dissociate rapidly from its target with a dissociationhalf-life of 1 h, so that a rapid infusion of digoxin-specificFab is able to reverse the intoxication. In the case of colchicine,however, the dissociation half-life from tubulin is 20 h and requiresa longer infusion of Fab fragments. Similarly, in snake venom,Fab have to be frequently readministered or continuously infusedto maintain sufficient levels of antibodies for a period of timeat least equal to the half-life of the venom, which is 30 h bythe intramuscular route. The elimination route of venom-antibodycomplexes has not yet been identified clearly. Reticuloendothelialtissues might be involved in the catabolism of circulating F(ab $'$ )₂-venomcomplexes. Fab-venom complexes are larger than the complexes formedwith small molecules such as colchicine or phencyclidine: theirmolecular weight is higher than the glomerular filtration thresholdso that they cannot be cleared via the renal route. Further investigationsare in progress to clarify this important point.

In conclusion, this study of the in vivo neutralization of venom components by antivenom antibodies provides an experimentalbasis for the optimization of antivenom treatment in humans. Ithas to be completed by pharmacodynamic experiments to examinethe effect of antivenom therapy on the symptomatology of the envenoming.Interestingly, the present study performed in the case of a Europeanviper could be extended to envenomings by other poisonous animalsand their immunotherapeutic treatment by antivenoms.

	Footnotes

Accepted for publication December 9, 1996.

Received for publication July 8, 1996.

Send reprint requests to: Dr. Cassian Bon, Unité des Venins, Institut Pasteur, 25 rue du Dr Roux, 75724 Paris, France.

	Abbreviations

AUC, area under the curve; AUMC, area under the mean curve; BSA, bovine serum albumin; ELISA, enzyme-linked immunosorbent assay; HMWP, high molecular weight protein; LMWP, low molecular weight polypeptide; PBS, phosphate buffer saline; TCA, trichloroacetic acid; Vd_ss, volume of distribution at steady state.

	References

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