African polyvalent antivenom can maintain pharmacological stability and ability to neutralise murine venom lethality for decades post-expiry: evidence for increasing antivenom shelf life to aid in alleviating chronic shortages.

INTRODUCTION: Antivenom is a lifesaving medicine for treating snakebite envenoming, yet there has been a crisis in antivenom supply for many decades. Despite this, substantial quantities of antivenom stocks expire before use. This study has investigated whether expired antivenoms retain preclinical quality and efficacy, with the rationale that they could be used in emergency situations when in-date antivenom is unavailable. METHODS: Using WHO guidelines and industry test requirements, we examined the in vitro stability and murine in vivo efficacy of eight batches of the sub-Saharan African antivenom, South African Institute for Medical Research polyvalent, that had expired at various times over a period of 30 years. RESULTS: We demonstrate modest declines in immunochemical stability, with antivenoms older than 25 years having high levels of turbidity. In vitro preclinical analysis demonstrated all expired antivenoms retained immunological recognition of venom antigens and the ability to inhibit key toxin families. All expired antivenoms retained comparable in vivo preclinical efficacy in preventing the lethal effects of envenoming in mice versus three regionally and medically important venoms. CONCLUSIONS: This study provides strong rationale for stakeholders, including manufacturers, regulators and health authorities, to explore the use of expired antivenom more broadly, to aid in alleviating critical shortages in antivenom supply in the short term and the extension of antivenom shelf life in the longer term.

Analysis of commercially available snake antivenoms reveals high contents of endotoxins in some products.

As injectable therapeutics, snake antivenoms must meet specifications for endotoxin content. The Limulus amebocyte lysate (LAL) test was used to evaluate the endotoxin content in several commercially available antivenoms released for clinical use. It was found that some products have endotoxin concentrations higher than the accepted limit for these contaminants. These results emphasize the need to include endotoxin determination as part of the routine evaluation of antivenoms by manufacturers and regulatory agencies.

Clinical effects of immunization, bleeding, and albumin-based fluid therapy in horses used as immunoglobulin source to produce a polyspecific antivenom (Echitab-plus-ICP) towards venoms of African snakes.

During the production of snake antivenoms, the animals used as immunoglobulin source are subjected to processes that could deteriorate their physical condition. Therefore, these conditions must be carefully designed and validated. In this work, the immunization and bleeding protocols applied to horses used to produce the African polyspecific antivenom EchiTAb-plus-ICP were evaluated regarding their effects on the horses' health. The study focused on horses that had been previously immunized with venoms and then received periodic booster venom injections for antivenom production. It was found that the periodic immunization with 5 mg of a mixture of venoms of Bitis arietans, Echis ocellatus, Dendroaspis polylepis, and Naja nigricollis did not induce systemic signs of envenomation, and only caused mild swelling at the injection site, which did not evolve to abscesses, fistulas, or fibrosis. Three consecutive days of bleeding, collecting 6-8 L of blood per day, and self-transfusing the red blood cells (RBC) in the second and third days, did not induce evident cardiorespiratory alterations. However, this procedure caused significant reductions in RBC, hematocrit, hemoglobin, and total plasma protein values. Seven weeks after bleeding, these parameters were recovered, and horses were ready for the next immunization/bleeding cycle. The intravenous administration of equine albumin, at a dose of 2 g/kg body weight, increased the apparent plasma volume and the albumin concentration. However, this procedure induced early adverse reactions and transient alterations of the serum levels of the enzyme gamma-glutamyl transferase (GGT), thus suggesting some degree of hepatic injury. It was concluded that immunization and bleeding as described in this work do not cause significant clinical alterations in the horse's health, except for a transient drop in some hematological parameters. The albumin-based fluid therapy used does not hasten the recovery after bleeding but instead induces adverse events in the animals.

Assessing a 6-h endpoint observation time in the lethality neutralization assay used to evaluate the preclinical efficacy of snake antivenoms.

The lethality neutralization assay in mice is the gold standard for the evaluation of the preclinical efficacy and specification fulfillment of snake antivenoms. However, owing to the animal suffering involved, this assay is a candidate to be replaced by in vitro alternatives or, at least, improved by the reduction of the number of animals used per experiment, the introduction of analgesia, and the refinement of the test. Since these tests are usually run for 24 or 48 h, one possibility to refine it is to shorten the endpoint observation time of the assay and so limiting the duration of suffering. To assess the effect of this modification of the standard procedure on the analytical properties of the assay, we compared the median lethal dose (LD50) and median effective dose (ED50) values, estimated through observation times of 6, 24 and 48 h. We used African and Latin American snake venoms and several batches of two polyspecific antivenoms. A significant correlation was found between LD50 and ED50 values estimated at the three observation times. Although some LD50 and ED50 values were significantly different at these time points, results of 6 h were robust enough to be used in the characterization of new antivenoms, the verification of specification compliance, and the parallel comparison of formulations. Our observations support the modification of the standard procedures used for assessing neutralizing ability of antivenoms by carrying out the observations at 6 h instead of 24 or 48 h, with the consequent reduction in the suffering inflicted upon mice during these assays. However, the shortening of the observation time in the lethality tests must be validated for each venom and antivenom before its introduction in the routine procedures.

Influence of sexual dimorphism on venom composition in Bothrops asper and Crotalus simus (Serpentes: Viperidae) and its potential implications on the snake antivenom production.

This work is aimed to bring insights on the potential sexual dimorphism differences on the venom composition of Bothrops asper and Crotalus simus to expand the knowledge of the venom variability that might improve the antivenom design. Biological characterization of venoms of each sex in both species did not show significant qualitative differences. Considerations on the sexual venom variations in these species are not relevant for choosing the snake donors for venom production.

Intraspecific variability of the Central American rattlesnake (Crotalus simus) venom and its usefulness to obtain a representative standard venom.

Snake venoms are mixtures of proteins whose physicochemical features confer them toxicity and immunogenicity. Animals (e.g., horses or sheep) immunized with snake venoms produce antibodies towards the venom proteins. Since these antibodies can neutralize the venom toxicity, they have been used to formulate snake antivenoms. The efficacy of the antivenoms is widely accepted, and standard venoms are expected to be representative of the snake's population that inhabit in the region where the antivenom is intended to be used. The representativeness of a single venom collected from a Crotalus simus snake, and its usefulness as standard venom to produce an antivenom is evaluated. The use of an "average venom" might be as representative of the population intended to be used, as the standard venom composed by many venom samples. Variations in the relative abundance concentration of crotoxin in the C. simus leads to different clinical manifestations, as well as differences in the neutralization efficacy of the antivenoms. A monovalent anti-Cs antivenom was produced from a single venom C. simus specimen, and its efficacy in neutralizing the lethal activity of 30 C. simus snakes was tested. Despite the variations in the relative abundance content of crotoxin found in the proteomes, the monovalent anti-Cs antivenom was successful in neutralize the toxicity caused by the variations on the venom composition of three different snake population used. Interestingly, it seems that the sex is not a key factor in the lethality of the venoms tested. The concept of representative venom mixtures for immunization should be revised for the case of C. simus on the populations found in Costa Rica, since it might use as less as one representative individual whose venom covers the mainly toxic enzymes.

Development and characterization of two equine formulations towards SARS-CoV-2 proteins for the potential treatment of COVID-19.

In the current global emergency due to SARS-CoV-2 outbreak, passive immunotherapy emerges as a promising treatment for COVID-19. Among animal-derived products, equine formulations are still the cornerstone therapy for treating envenomations due to animal bites and stings. Therefore, drawing upon decades of experience in manufacturing snake antivenom, we developed and preclinically evaluated two anti-SARS-CoV-2 polyclonal equine formulations as potential alternative therapy for COVID-19. We immunized two groups of horses with either S1 (anti-S1) or a mixture of S1, N, and SEM mosaic (anti-Mix) viral recombinant proteins. Horses reached a maximum anti-viral antibody level at 7 weeks following priming, and showed no major adverse acute or chronic clinical alterations. Two whole-IgG formulations were prepared via hyperimmune plasma precipitation with caprylic acid and then formulated for parenteral use. Both preparations had similar physicochemical and microbiological quality and showed ELISA immunoreactivity towards S1 protein and the receptor binding domain (RBD). The anti-Mix formulation also presented immunoreactivity against N protein. Due to high anti-S1 and anti-RBD antibody content, final products exhibited high in vitro neutralizing capacity of SARS-CoV-2 infection, 80 times higher than a pool of human convalescent plasma. Pre-clinical quality profiles were similar among both products, but clinical efficacy and safety must be tested in clinical trials. The technological strategy we describe here can be adapted by other producers, particularly in low- and middle-income countries.

In vitro Characterization of Anti-SARS-CoV-2 Intravenous Immunoglobulins (IVIg) Produced From Plasma of Donors Immunized With the BNT162b2 Vaccine and Its Comparison With a Similar Formulation Produced From Plasma of COVID-19 Convalescent Donors.

Despite vaccines are the main strategy to control the ongoing global COVID-19 pandemic, their effectiveness could not be enough for individuals with immunosuppression. In these cases, as well as in patients with moderate/severe COVID-19, passive immunization with anti-SARS-CoV-2 immunoglobulins could be a therapeutic alternative. We used caprylic acid precipitation to prepare a pilot-scale batch of anti-SARS-CoV-2 intravenous immunoglobulins (IVIg) from plasma of donors immunized with the BNT162b2 (Pfizer-BioNTech) anti-COVID-19 vaccine (VP-IVIg) and compared their in vitro efficacy and safety with those of a similar formulation produced from plasma of COVID-19 convalescent donors (CP-IVIg). Both formulations showed immunological, physicochemical, biochemical, and microbiological characteristics that meet the specifications of IVIg formulations. Moreover, the concentration of anti-RBD and ACE2-RBD neutralizing antibodies was higher in VP-IVIg than in CP-IVIg. In concordance, plaque reduction neutralization tests showed inhibitory concentrations of 0.03-0.09 g/L in VP-IVIg and of 0.06-0.13 in CP-IVIg. Thus, VP-IVIg has in vitro efficacy and safety profiles that justify their evaluation as therapeutic alternative for clinical cases of COVID-19. Precipitation with caprylic acid could be a simple, feasible, and affordable alternative to produce formulations of anti-SARS-CoV-2 IVIg to be used therapeutically or prophylactically to confront the COVID-19 pandemic in middle and low-income countries.

Toxicological profile of medically relevant Crotalus species from Mexico and their neutralization by a Crotalus basiliscus/Bothrops asper antivenom.

Specimens of the Crotalus genus represent a potential snakebite problem in Mexico, and despite the great number of species of Crotalus present in this country, only a few of them are relevant from a medical point of view. Crotalus envenomed patients can present a range of signs and symptoms, depending on the species involved, and their treatment is indistinctly with either of the anti-viperid antivenoms available in the Mexican Public Health System. One of these antivenoms is produced by immunization of horses with a mixture of only two venoms: Crotalus basiliscus and Bothrops asper venoms. In light of the high variability found in Crotalus species venom composition, it is important to demonstrate the cross-neutralization of this antivenom against other Crotalus species. Therefore, in this work the toxic variability of eight medically important Crotalus venoms from Mexico and its neutralization by the Crotalus basiliscus/Bothrops asper antivenom were assessed. The present study evidenced the variability of toxic and enzymatic activities among the following Crotalus venoms: (1) Crotalus atrox, (2) Crotalus basiliscus, (3) Crotalus culminatus, (4) Crotalus simus, (5) Crotalus tzabcan, (6) Crotalus scutulatus salvini, (7) Crotalus scutulatus scutulatus-A, and (8) Crotalus scutulatus scutulatus-B. All venoms studied possess lethal and hemorrhagic activity on a murine model, although there are important variations among the species; in contrast, the PLA2 activity was similar for all venoms. Interestingly, only C. simus venom exhibited coagulant activity on human plasma under 100 µg. The antivenom neutralized the lethality and all the other assessed activities for all venoms tested. However, the dose required varied depending on the venom and the evaluated activity. Our preclinical data support the recommendation of using this antivenom to clinically manage Crotalus snakebites produced by the species assessed in this study. Nonetheless, only clinical trials could categorically validate these results.

Draft Genome Sequence of Bacillus thuringiensis Strain UNMSM10RA, Isolated from Potato Crop Soil in Peru.

The 5.5-Mb genome sequence of Bacillus thuringiensis strain UNMSM10RA, isolated from potato crop soil, is reported in this study. The strain UNMSM10RA contains 5,347 protein-coding sequences, 105 tRNA genes, 15 rRNA genes, and 5 noncoding RNA (ncRNA) genes, with an average G+C content of 35.1%.

In Vitro Tests for Assessing the Neutralizing Ability of Snake Antivenoms: Toward the 3Rs Principles.

There is an urgent need to strengthen the implementation of the 3Rs principle (Replacement, Reduction and Refinement) in the use of experimental animals in toxinological research and in the assessment of the neutralizing efficacy of snake antivenoms. This is a challenging task owing to the inherent complexity of snake venoms. The state of the art on this topic is hereby reviewed, with emphasis on the studies in which a correlation has been observed between in vivo toxicity tests and in vitro surrogate assays, particularly in the study of lethal activity of venoms and its neutralization. Correlations have been described with some venoms-antivenoms when using: (a) enzyme immunoassays, (b) hemagglutination, (c) enzyme assays (proteinase, phospholipase A2), (d) in vitro coagulant effect on plasma, (e) cell culture assays for cytotoxicity, (f) functional assays for assessing neurotoxicity in vitro, (g) use of hens' eggs, and (h) antivenomics. Additionally, the routine introduction of analgesia in these assays and the design of more 'humane' protocols for the lethality test are being pursued. It is expected that the next years will witness a growing awareness of the relevance of the 3Rs principles in antivenom testing, and that new in vitro alternatives and more 'humane' experimental designs will emerge in this field.

Efecto protector del Desmodium molliculum EAM (manayupa) en ratas con toxicidad hepática inducida por naproxeno / Protective effect of Desmodium molliculum EAM (manayupa) in rats with naproxen-induced liver toxicity

Objetivo. Verificar el efecto protector del extracto acuoso de hojas y tallos de Desmodium molliculum EAM (manayupa), en la toxicidad hepática inducida por el naproxeno en ratas Ratus novergicus variedad Wistar albino, hembras. Materiales y métodos. Estudio experimental. Se utilizaron 36 ratas hembras de 250 ± 10 g, divididas en seis grupos de seis: A (control -); B (control + naproxeno); patrón C (silimarina 100 mg / kg) y 3 experimental (EAM): D 80 mg/kg; E 160 mg/kg y F 240 mg/kg). Los grupos B, C, D, E, F recibieron por vía oral naproxeno 27,38 mg, los primeros cinco días y durante 14 días. El efecto protector hepático se determinó mediante el análisis bioquímico: GOT, GPT, GGT, proteínas totales, albúmina sérica, fosfatasa alcalina y creatinina. Resultados. Se encontró que el grupo B perdió peso (180,65 ± 6,5 g), bilirrubina total (0,76 ± 0,4) bilirrubina directa (1.7 ± 0,8), TGO (160 ± 10,4) y TGP (412 ± 20,4) alto, comparado con el grupo A, C, D, E y F. Conclusiones. El EAM tiene efecto protector sobre la toxicidad hepática inducida por naproxeno en ratas, evidenciado por los parámetros bioquímicos.

Objective. To verify the protective effect of the aqueous extract of leaves and stems of Desmodium molliculum EAM (manayupa), on the hepatic toxicity induced by Naproxen in rats Ratus novergicus albino Wistar variety, females. Materials and methods. 36 female rats of 250 ± 10 g were used, divided into six groups of six: A (Control -), B (Control + Naproxen), Pattern C (Silymarin 100 mg / kg) and 3 Experimental (EAM): D 80 mg / kg, E 160 mg / kg and F 240 mg / kg). Groups B, C, D, E, F orally received Naproxen 27.38 mg, the first five days and for 14 days. The hepatic protective effect was determined by the biochemical analysis: GOT, GPT, GGT, total proteins, serum albumin, alkaline phosphatase, creatinine. Results. group B was found to lose weight (180.65 ± 6.5 g), total bilirubin (0.76 ± 0.4) direct bilirubin (1.7 ± 0.8), TGO (160 ± 10.4) and TGP (412 ± 20.4) high, compared to group A, C, D, E and F. Conclusion. EAM has a protective effect on hepatic toxicity induced by naproxen in rats, evidenced by biochemical parameters.

Current technology for the industrial manufacture of snake antivenoms.

Snake antivenoms are formulations of animal immunoglobulins used in the treatment of snakebite envenomation. The general scheme for producing snake antivenoms has undergone few changes since its development more than a century ago; however, technological innovations have been introduced in the manufacturing process. These medicines must comply with identity, purity, safety and efficacy profiles, as requested by the current Good Manufacturing Practices (GMPs) applied to modern biopharmaceutical drugs. Industrial production of snake antivenoms comprises several stages, such as: 1) production of reference venom pools, 2) production of hyperimmune plasma, 3) purification of the antivenom immunoglobulins, 4) formulation of the antivenom, 5) stabilization of the formulation, and 6) quality control of in-process and final products. In this work, a general review of the existing technology used for the industrial manufacture of snake antivenoms is presented.

Contributions of the snake venoms of Bothrops asper, Crotalus simus and Lachesis stenophrys to the paraspecificity of the Central American polyspecific antivenom (PoliVal-ICP).

PoliVal-ICP antivenom is produced from plasma of horses immunized toward the venoms of Bothrops asper, Crotalus simus and Lachesis stenophrys. The antibody response induced by these venoms confers PoliVal-ICP the capacity to neutralize the venoms of the most important Central American viperids, including not only homologous venoms (i.e., venoms used as immunogen), but many heterologous venoms (i.e., venoms not used as immunogen). In this work, the individual contributions of homologous venoms to the paraspecificity of PoliVal-ICP were inferred from the capacity of experimental monospecific antivenoms toward venoms of B. asper (anti-Ba), C. simus (anti-Cs) and L. stenophrys (anti-Ls), and an experimental polyspecific antivenom (anti-Ba/Cs/Ls) to neutralize the lethality induced by different venoms in mice. It was found that all antivenoms neutralized their corresponding homologous venoms. Moreover, the anti-Ba antivenom cross-neutralized the venoms of Agkistrodon howardgloydi, Atropoides picadoi, Bothriechis lateralis, Bothriechis supraciliaris and Porthidium ophryomegas; the anti-Cs antivenom cross-neutralized the venoms of B. lateralis, B. supraciliaris, Cerrophidion sasai and Porthidium nasutum; and the anti-Ls antivenom cross-neutralized the venoms of B. lateralis, B. supraciliaris, C. sasai and Lachesis melanocephala. All venoms neutralized by any monospecific antivenom were also neutralized by the anti-Ba/Cs/Ls antivenom. Venoms of Atropoides mexicanus, Bothriechis nigroviridis and Bothriechis schlegelii were not neutralized by any experimental antivenom, thus explaining the limitations of PoliVal-ICP to neutralize these venoms. Consequently, an enlargement of the neutralization scope of PoliVal-ICP could be achieved by including these venoms in the group of those used as immunogens.

Preclinical Evaluation of the Efficacy of Antivenoms for Snakebite Envenoming: State-of-the-Art and Challenges Ahead.

Animal-derived antivenoms constitute the mainstay in the therapy of snakebite envenoming. The efficacy of antivenoms to neutralize toxicity of medically-relevant snake venoms has to be demonstrated through meticulous preclinical testing before their introduction into the clinical setting. The gold standard in the preclinical assessment and quality control of antivenoms is the neutralization of venom-induced lethality. In addition, depending on the pathophysiological profile of snake venoms, the neutralization of other toxic activities has to be evaluated, such as hemorrhagic, myotoxic, edema-forming, dermonecrotic, in vitro coagulant, and defibrinogenating effects. There is a need to develop laboratory assays to evaluate neutralization of other relevant venom activities. The concept of the 3Rs (Replacement, Reduction, and Refinement) in Toxinology is of utmost importance, and some advances have been performed in their implementation. A significant leap forward in the study of the immunological reactivity of antivenoms against venoms has been the development of "antivenomics", which brings the analytical power of mass spectrometry to the evaluation of antivenoms. International partnerships are required to assess the preclinical efficacy of antivenoms against snake venoms in different regions of the world in order to have a detailed knowledge on the neutralizing profile of these immunotherapeutics.

Effect of premedication with subcutaneous adrenaline on the pharmacokinetics and immunogenicity of equine whole IgG antivenom in a rabbit model.

Subcutaneous administration of a low dose of adrenaline is used to prevent the early adverse reactions (EARs) induced by snake antivenoms. We used a rabbit model to study the effect of premedication with adrenaline on the potential of antivenoms to exert therapeutic effects and to induce late adverse reactions. We found that premedication with adrenaline did not change the heart rate or blood pressure of normal rabbits, but reduced the rise in temperature in rabbits previously sensitized with antivenom. Pharmacokinetic studies suggest that premedication with adrenaline does not affect the ability of the antivenom to exert the initial control of envenomation nor the susceptibility of rabbits to develop recurrence of antigenemia and envenomation. Our results also indicate that it is unlikely that premedication with adrenaline decreases the incidence of late reactions induced by the antivenom administration, although it reduces the extent of early reactions.

Effect of geographical variation of Echis ocellatus, Naja nigricollis and Bitis arietans venoms on their neutralization by homologous and heterologous antivenoms.

Two antivenoms prepared by using Echis ocellatus, Bitis arietans and Naja nigricollis venoms from different locations in sub-Saharan Africa were compared for their neutralizing ability. Both antivenoms were similarly effective in the neutralization of the venoms of the three species from different locations. However in the case of E. ocellatus venom, antivenom prepared using venom from Nigerian specimens was more effective than antivenom prepared with venom from Cameroon specimens in the neutralization of coagulant activity.

Assessing endotoxins in equine-derived snake antivenoms: Comparison of the USP pyrogen test and the Limulus Amoebocyte Lysate assay (LAL).

Snake antivenoms are parenterally administered; therefore, endotoxin content must be strictly controlled. Following international indications to calculate endotoxin limits, it was determined that antivenom doses between 20 mL and 120 mL should not exceed 17.5 Endotoxin Units per milliliter (EU/mL) and 2.9 EU/mL, respectively. The rabbit pyrogen test (RPT) has been used to evaluate endotoxin contamination in antivenoms, but some laboratories have recently implemented the LAL assay. We compared the capability of both tests to evaluate endotoxin contamination in antivenoms, and we found that both methods can detect all endotoxin concentrations in the range of the antivenom specifications. The acceptance criteria of RPT and LAL must be harmonized by calculating the endotoxin limit as the quotient of the threshold pyrogenic dose and the therapeutic dose and the dose administered to rabbits as the quotient of the threshold pyrogenic dose and the endotoxin limit. Since endotoxins from Gram-negative bacteria exert different pyrogenicity, if contamination occurred, antivenom batches that induce pyrogenic reactions may be found in spite of passing LAL specifications. Although LAL assay can be used to assess endotoxin content throughout the antivenom manufacturing process, we recommend that the release of final products be based on the results of both methods.

The lethality test used for estimating the potency of antivenoms against Bothrops asper snake venom: pathophysiological mechanisms, prophylactic analgesia, and a surrogate in vitro assay.

The potency of antivenoms is assessed by analyzing the neutralization of venom-induced lethality, and is expressed as the Median Effective Dose (ED50). The present study was designed to investigate the pathophysiological mechanisms responsible for lethality induced by the venom of Bothrops asper, in the experimental conditions used for the evaluation of the neutralizing potency of antivenoms. Mice injected with 4 LD50s of venom by the intraperitoneal route died within ∼25 min with drastic alterations in the abdominal organs, characterized by hemorrhage, increment in plasma extravasation, and hemoconcentration, thus leading to hypovolemia and cardiovascular collapse. Snake venom metalloproteinases (SVMPs) play a predominat role in lethality, as judged by partial inhibition by the chelating agent CaNa2EDTA. When venom was mixed with antivenom, there was a venom/antivenom ratio at which hemorrhage was significantly reduced, but mice died at later time intervals with evident hemoconcentration, indicating that other components in addition to SVMPs also contribute to plasma extravasation and lethality. Pretreatment with the analgesic tramadol did not affect the outcome of the neutralization test, thus suggesting that prophylactic (precautionary) analgesia can be introduced in this assay. Neutralization of lethality in mice correlated with neutralization of in vitro coagulant activity in human plasma.

Preclinical assessment of a polyspecific antivenom against the venoms of Cerrophidion sasai, Porthidium nasutum and Porthidium ophryomegas: Insights from combined antivenomics and neutralization assays.

A polyspecific antivenom is used in Central America for the treatment of envenomings by viperid snakes. This antivenom is generated in horses hyperimmunized with a mixture of venoms from Bothrops asper, Crotalus simus and Lachesis stenophrys. The present study analyzed the ability of this antivenom to neutralize the venoms of three Central American viperid species of the 'Porthidium group', i.e. Porthidium nasutum, Porthidium ophryomegas and Cerrophidion sasai, formerly classified as Cerrophidion godmani. In addition, the immunorecognition of the components of these venoms was assessed by immunoaffinity antivenomics. The antivenom proved effective in neutralizing the lethal, hemorrhagic, myotoxic, phospholipase A(2) (PLA(2)) and proteinase activities of the three venoms, albeit exhibiting quantitative differences in the values of the Median Effective Doses (ED(50)). Excepting for certain low molecular mass bands corresponding to disintegrins, and some PLA(2)s and PI-metalloproteinases, Western blotting and immunoaffinity chromatography revealed immunorecognition of most Porthidium and Cerrophidion venom proteins. In agreement with in vivo neutralization assays, immobilized antivenom IgGs showed higher immunocapturing activity of toxins from both Porthidium taxa than from C. sasai. Overall our results demonstrate a significant paraspecific protection of the Costa Rican polyspecific antivenom against the three venoms sampled. They also stress the need to search for novel ways to enhance the immune response of horses against several weakly immunogenic venom components.