The Triterpenoid Betulin Protects against the Neuromuscular Effects of <i>Bothrops jararacussu</i> Snake Venom <i>In Vivo</i>

Ferraz, Miriéle Cristina; de Oliveira, Jhones Luiz; de Oliveira Junior, Joel Reis; Cogo, José Carlos; dos Santos, Márcio Galdino; Franco, Luiz Madaleno; Puebla, Pilar; Ferraz, Helena Onishi; Ferraz, Humberto Gomes; da Rocha, Marisa Maria Teixeira; Hyslop, Stephen; San Feliciano, Arturo; Oshima-Franco, Yoko

doi:https://doi.org/10.1155/2015/939523

Evidence-Based Complementary and Alternative Medicine

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Research Article | Open Access

Volume 2015 | Article ID 939523 | https://doi.org/10.1155/2015/939523

The Triterpenoid Betulin Protects against the Neuromuscular Effects of Bothrops jararacussu Snake Venom In Vivo

Miriéle Cristina Ferraz,¹Jhones Luiz de Oliveira,¹Joel Reis de Oliveira Junior,¹José Carlos Cogo,²Márcio Galdino dos Santos,³Luiz Madaleno Franco,⁴Pilar Puebla,⁵Helena Onishi Ferraz,⁶Humberto Gomes Ferraz,⁷Marisa Maria Teixeira da Rocha,⁸Stephen Hyslop,⁹and Arturo San Feliciano⁵ et al.

Academic Editor: Roman Huber

Received05 Jun 2015

Revised11 Sept 2015

Accepted15 Sept 2015

Published08 Nov 2015

Abstract

We confirmed the ability of the triterpenoid betulin to protect against neurotoxicity caused by Bothrops jararacussu snake venom in vitro in mouse isolated phrenic nerve-diaphragm (PND) preparations and examined its capability of in vivo protection using the rat external popliteal/sciatic nerve-tibialis anterior (EPSTA) preparation. Venom caused complete, irreversible blockade in PND (40 μg/mL), but only partial blockade (~30%) in EPSTA (3.6 mg/kg, i.m.) after 120 min. In PND, preincubation of venom with commercial bothropic antivenom (CBA) attenuated the venom-induced blockade, and, in EPSTA, CBA given i.v. 15 min after venom also attenuated the blockade (by ~70% in both preparations). Preincubation of venom with betulin (200 μg/mL) markedly attenuated the venom-induced blockade in PND; similarly, a single dose of betulin (20 mg, i.p., 15 min after venom) virtually abolished the venom-induced decrease in contractility. Plasma creatine kinase activity was significantly elevated 120 min after venom injection in the EPSTA but was attenuated by CBA and betulin. These results indicate that betulin given i.p. has a similar efficacy as CBA given i.v. in attenuating the neuromuscular effects of B. jararacussu venom in vivo and could be a useful complementary measure to antivenom therapy for treating snakebite.

1. Introduction

Snakebite is a worldwide health problem that results in at least 20,000 deaths each year [1]. Serum therapy is the primary treatment for systemic envenoming but its efficacy against local effects (pain, edema, hemorrhage, and necrosis) is limited [2]. Consequently, there has been increasing interest in the rapidly expanding field of “green medicine” that includes the study and use of plant products (extracts or isolated components) as complementary or ancillary measures to treat the local effects of snake venoms [3]. Appropriate exploitation of these plants can provide compounds for pharmacological analysis, whilst minimizing the destruction of natural resources, a critical aspect of sustainability [3].

Betulin is an important precursor biomolecule that can be converted to betulinic acid, a C-28 carboxylic derivative that is generally produced by plants in small amounts [4, 5]. However, numerous plants produce large amounts of betulin (Table 1) [6–28]. The clinical effects of betulin, mainly as an anticancer drug, have been pharmacologically less exploited than those of betulinic acid [29, 30]. However, a preliminary pharmacokinetic analysis of betulin found good bioavailability when administered intraperitoneally (i.p.) or subcutaneously (s.c.); there was also no subchronic toxicity in rats (injected i.p.) or dogs (injected s.c.) [9].

An ethnobotanical study previously identified Dipteryx alata Vogel as a plant with anti-snake venom properties [31], and Nazato et al. [32] subsequently confirmed this activity for a hydroalcoholic extract of D. alata bark. Puebla et al. [15] identified 18 compounds in D. alata, including betulin, previously isolated by Coelho Kaplan et al. [14]. Subsequent investigation showed that betulin attenuated the neurotoxicity and myotoxicity of Crotalus durissus terrificus (South American rattlesnake) and Bothrops jararacussu (jararacuçu) snake venoms in vitro, as assessed by twitch-tension recordings (neurotoxicity) and light microscopy (myotoxicity) [33].

Bothrops jararacussu venom causes irreversible paralysis in vitro [34] and myonecrosis at the bite site [35]. Based on previous findings with D. alata and betulin in phrenic nerve-diaphragm (PND) preparations in vitro [15, 32, 33], we speculated whether betulin could also attenuate the neuromuscular effects of snake venoms in a nerve-muscle preparation, the rat external popliteal/sciatic nerve-tibialis anterior muscle (EPSTA) preparation in situ, particularly when compared to the efficacy of commercial bothropic antivenom (CBA). Since the EPSTA is analyzed in situ whilst the rat is kept anesthetized throughout the experiment (120 min), this preparation may provide additional insights that are not immediately obtainable with PND preparations. Previous investigations have shown that the nerves supplying the EPSTA muscle are sensitive to a venom concentration of 40 μg/mL [36, 37], which was also used here. In this study, we therefore confirmed the effects of betulin in mouse PND and examined the neuromuscular alterations (changes in twitch-tension) and myotoxicity (assessed by creatine kinase release) caused by B. jararacussu venom in rat EPSTA; we also assessed the effect of betulin on the responses to venom in the latter preparation.

2. Material and Methods

2.1. Betulin and Its Dispersion

The triterpenoid betulin (Figure 1), found in plants such as D. alata Vogel [15, 33], was purchased from Sigma Chemical Co. (St. Louis, MO, USA) and used throughout this study.

For in vitro experiments, betulin (200 μg/mL) was dispersed in a maximum of 15 μL of polyethylene glycol 400 (PEG 400) prior to addition to the organ bath. The final concentration of PEG 400 (0.3%) in the organ bath did not change the basal responses of the preparation [38, 39]. For in vivo experiments, betulin (1–20 mg) was added to PEG 400 (15–300 μL). The dispersed betulin was placed in a glass beaker and the final volume was adjusted to 1 mL with sterile saline followed by gentle stirring. The osmotic pressure of each betulin solution was measured (in duplicate) using an osmometer (Fiske Associates, Norwood, MA, USA) in order to define the route of administration (intravenously (i.v.) or i.p.) (Table 2). PEG is on the Food and Drug Administration’s Generally-Recognized-As-Safe (GRAS) compound list for internal consumption [38, 40–42].

2.2. Venom and Antivenom

Bothrops jararacussu venom was collected manually from two adult specimens in the Serpentarium of the Center for Nature Studies at UNIVAP. The snakes were housed in open-air, concrete-walled pens and maintained under Environmental license SMA 15.380/2012 (São Paulo state environmental agency); they were fed Swiss white mice every two weeks. The venom was certified by Dr. José Carlos Cogo (UNIVAP), lyophilized, and stored at −20°C until used. Commercial bothropic antivenom (lot 091259/C, expiry date for human use: October 2011) produced by the Instituto Butantan (São Paulo, SP, Brazil) against a pool of Bothrops venoms (B. alternatus, B. jararaca, B. jararacussu, B. moojeni, and B. neuwiedi) [43] was kindly donated by the Escritório Regional de Saúde in Piracicaba, SP, Brazil.

2.3. Animals

Male Swiss white mice (26–32 g) and male Wistar rats (300–400 g) were purchased from Anilab (Animais de Laboratório, Paulínia, SP, Brazil). The animals were housed at °C on a 12 h light/dark cycle and had access to food and water ad libitum. This project was approved by the institutional Committee for Ethics in Animal Use of Vale do Paraiba University (protocol number A013/CEUA/2011), and the experiments were done within the ethical guidelines established by the Brazilian Society for Laboratory Animal Science (SBCAL).

2.4. Mouse PND Preparation

PND preparations [44] were obtained from mice anesthetized with halothane (Cristália, Itapira, SP, Brazil) and killed by exsanguination. The diaphragm was removed and mounted under a tension of 5 g/cm in a 5 mL organ bath containing aerated Tyrode solution (control) of the following composition (mM): NaCl, 137; KCl, 2.7; CaCl₂, 1.8; MgCl₂, 0.49; NaH₂PO₄, 0.42; NaHCO₃, 11.9; and glucose, 11.1. After equilibration with 95% O₂/5% CO₂ (v/v), the pH of this solution was 7.0. The preparations were stimulated indirectly with supramaximal stimuli (4x threshold, 0.06 Hz, 0.2 ms) delivered from a stimulator (model ESF-15D, Ribeirão Preto, SP, Brazil) to the nerve by bipolar electrodes. Isometric twitch-tension was recorded with a force-displacement transducer (cat. 7003, Ugo Basile, Varese, Italy) coupled to a two-channel Gemini flatbed physiograph device (cat. 7070, Ugo Basile) via a basic preamplifier (cat. 7080, Ugo Basile). Changes in twitch-tension were recorded as described by Farrapo et al. [45]. The preparations were allowed to stabilize for at least 20 min prior to application of the test agents (experiments described below).

Control experiments were done in which PND preparations were incubated with Tyrode solution alone () while the treatment groups included incubation with Tyrode solution containing betulin (200 μg/mL; ), CBA (8 μL/mL; ), or B. jararacussu venom (40 μg/mL; ). The venom and betulin concentrations were chosen based on previous work [33, 46], whereas the concentration of CBA was calculated based on the manufacturer’s information that 1 mL of antivenom neutralizes 5 mg of reference Bothrops jararaca venom. These same concentrations of betulin () and CBA () were used to test their neutralizing capacity against venom (40 μg/mL). For this, venom and the compound of interest were preincubated for 30 min at room temperature (~25°C) prior to screening for residual venom activity (neuromuscular blockade and/or myotoxicity) in PND preparations.

2.5. Rat EPSTA Preparation

This preparation was mounted essentially as described elsewhere [36, 37, 47]. Briefly, male Wistar rats were anesthetized with sodium pentobarbital (40 mg/kg, i.p.; Syntec do Brasil, Cotia, SP, Brazil) and additional doses were given as required during the experiment. The trachea was cannulated with a plastic endotracheal tube connected to a rodent ventilator (cat. 7025, Ugo Basile) and artificial ventilation was initiated at a flow of 1.2 mL/kg and respiratory rate of 70 inflations per minute. The left hind limb was immobilized and the popliteal/sciatic nerve tendon for insertion of the tibialis anterior muscle was freed and attached to a force-displacement transducer (cat. 7003, Ugo Basile) coupled to the recording device used in the PND experiments. The sciatic nerve in the popliteal space was stimulated indirectly with supramaximal stimuli (4x threshold, 0.5 Hz, 0.2 ms) delivered from a stimulator (model ESF-15D) to produce maximal twitches of the tibialis anterior muscle. The resting tension of the muscle was adjusted to 20 g to give the greatest evoked twitch-tension. The preparation was allowed to stabilize for at least 20 min before initiating the treatments. The experiments were run for 120 min after the addition of test agents.

Control experiments using this preparation included the injection of saline (120 μL, ) and PEG 400 intramuscularly (i.m.) in the left hind limb since saline and PEG 400 were the vehicles for venom and betulin administration, respectively. For experimental treatments, rats were injected with (1) venom (3.6 mg/kg, corresponding to 1.08 mg for a 300 g rat [36]) injected i.m. in 120 μL of saline (), (2) CBA (1.8 μL of CBA in 1 mL; this volume of CBA neutralized 9 μg of venom based on the neutralizing capacity indicated in Section 2.4); the i.v. infusion of antivenom (via a penile vein) was initiated 15 min after venom injection and was infused slowly over 30 min (), and (3) betulin (1 mL of a 20 mg/mL solution, referred to hereafter simply as 20 mg) administered i.p. 15 min after venom injection ().

2.6. Myotoxicity Assessed by Creatine Kinase (CK) Release

Since the EPSTA preparation did not lend itself to the simultaneous collection of blood samples for CK quantification, we undertook another series of experiments to assess the ability of CBA and betulin to attenuate venom-induced muscle damage (CK release). For this, four additional groups of rats (4 rats/group) were treated using protocols similar to those of the EPSTA experiments, except that the route of CBA administration was different (i.p. instead of i.v.), namely, (1) saline (negative control), (2) venom alone (positive control), (3) venom + betulin i.p. 15 min later, and (4) venom + CBA i.p. 15 min later. Since our aim in these experiments was to compare the efficacies of CBA and betulin in reducing venom-induced CK release and since betulin was already being given i.p., we chose to also inject CBA i.p. rather than i.v. in order to facilitate comparison with the protection by betulin, even though in clinical practice CBA is not generally administered i.p. After 2 h, blood samples (3–5 mL) were collected from anesthetized rats by cardiac puncture into heparinized tubes, centrifuged to obtain plasma, and stored for a maximum of 2 h at 4°C until CK quantification. CK activity (expressed in units/L, U/L) was assayed spectrophotometrically using a commercial kit (CK-NAC BIRG ref. 11.002.00, Biotécnica, Varginha, MG, Brazil). The reactions were run at 37°C and changes in absorbance at 340 nm were monitored with a Shimadzu multispec-1501 spectrophotometer. One unit of activity corresponded to the amount of enzyme that catalyzed 1 μmol of substrate at 25°C.

2.7. Statistical Analysis

Each protocol of the pharmacological assays was repeated at least four times and the results are shown as the mean ± SEM. The number of experiments () is indicated in the figure legends. All statistical comparisons (pharmacological assays and CK determinations) were done using Student’s -test with the confidence level set at 5% ().

3. Results

3.1. Betulin Solutions

Table 2 shows the osmolality of PEG 400, the vehicle for betulin dispersion, and betulin solutions. For intravenous injection, 1–3 mg of betulin dispersed in 15–45 μL of PEG 400 would appear to be good combinations since CBA alone had an osmolality of 421 mOsmol/kg. However, since for intravenous injection via a penile vein multiple administrations would be necessary to achieve a total amount of 20 mg of betulin, the intraperitoneal route of administration was selected for use in the in situ experiments; this route allowed a single injection of the total amount of betulin required (20 mg in 1 mL).

3.2. Contractile Responses in PND Preparations

Figure 2 shows the contractile responses of mouse PND preparations incubated with Tyrode solution (), CBA (8 μL/mL, ), and betulin (200 μg/mL, ) (panel A). Betulin alone caused marked facilitation (80% increase in twitch-tension after 10 min) compared to Tyrode solution and CBA, followed by a progressive decline until 40 min and subsequent stabilization of the tension at a level slightly but significantly above that of saline controls. Panel B shows the response to venom in the absence and presence of CBA and betulin. Venom alone (40 μg/mL) caused progressive, irreversible neuromuscular blockade that was virtually abolished by preincubating the venom with CBA. The preincubation of venom with betulin also markedly attenuated the venom-induced blockade, although it was difficult to compare the responses between the two groups because of the strong facilitation caused by betulin that may have masked the responses to venom (the curves for blockade by venom and venom + CBA were virtually parallel, with the latter simply being displaced in relation to the former because of the betulin-induced facilitation).

(a)

(b)

Figure 2

Contractile responses of mouse indirectly stimulated PND preparations incubated with Tyrode solution, CBA, and betulin (a) and B. jararacussu venom alone, venom + betulin, and venom + CBA (b). Note the facilitatory effect of betulin (alone and in the presence of venom). The points represent the mean ± SEM of the number of experiments () indicated in each panel. Note that in several cases the error bars are smaller than the symbol. compared to the Tyrode control (a) or venom alone (b). Note that, from 70 min onwards, the asterisks refer to the venom + betulin and venom + CBA curves.

3.3. Contractile Responses in EPSTA Preparations

The EPSTA preparation has an advantage over the PND preparation in that it is “mounted” in situ, with the anesthetized animal being kept alive throughout the experiment. This allows the administration of substances locally (i.m. injection), parenterally (i.p. injection), systemically (i.v. injection), or via a combination of these routes; these possibilities do not exist for PND preparations. However, use of the EPSTA preparation requires rigorous control of all variables, including the solutions to be injected, so as to avoid false positive or negative results. Figure 3 shows the twitch-tension records for indirectly stimulated EPSTA preparations treated with saline, PEG 400, and CBA, as described in Section 2.5; muscle contractility in the saline-, PEG 400- and CBA-treated preparations was unaltered at the end of the experiments, with twitch-tensions corresponding to % (), 98% (; only one experiment was done as screening), and % () of basal values (time zero), respectively. There were no significant changes in the contractile responses at the end of the incubations with each substance. Thus, any changes seen in subsequent treatments with other agents were not attributable to the effects of saline, PEG 400, or CBA.

(a)

(b)

(c)

Figure 3

Contractile responses of rat indirectly stimulated EPSTA preparations after treatment with saline (a), CBA (b), and PEG 400 (c). Saline and PEG 400 were injected i.m. in the left hind limb, whereas CBA was injected i.v. The recordings are representative of four experiments for the saline and CBA treatments; only one experiment was done with PEG 400 since we have shown elsewhere that this reagent is compatible with biological preparations [38]. Substances were injected at the arrow. Tension scale bar = 20 g/cm.

Figure 4 shows the contractile responses of EPSTA preparations to venom (3.6 mg/kg, ) injected i.m. in the left hind limb. There was progressive blockade from 10 min to 60 min after venom, when the contractile responses stabilized, followed by slight reversal. The maximal blockade at 60 min was %. At 120 min, the contractile responses were % of the saline (control) values, that is, significantly below the saline responses. In these protocols, CBA was administered i.v. because this is the route normally used for antivenom injection in the clinical setting and we wished to assess whether CBA given by this route could attenuate the venom-induced neuromuscular blockade. As shown here, CBA administered i.v. 15 min after venom injection significantly attenuated the venom-induced blockade from 50 min onwards. After 120 min, the contractile responses to venom + CBA were % of the control responses and significantly greater () than the responses to venom alone (Figure 4(a)). Betulin alone (20 mg in 1 mL of sterile saline) administered i.p. caused progressive muscle facilitation that reached % () at 120 min but was not significantly greater than that seen with saline alone. Betulin injected i.p. 15 min after venom significantly attenuated the venom-induced blockade from 40 min onwards so that, by 120 min after venom, the contractile responses were % () of control (saline) preparations (there was no significant difference between the two treatments at this point). Based on these findings alone, it is unclear whether betulin interacted directly with the venom to neutralize the venom-induced blockade or whether the attenuation of blockade was simply a consequence of the facilitatory effect of betulin on the muscle that masked the venom-induced blockade. However, the finding that the reversal of blockade seen with betulin was similar to that seen with CBA (no significant difference between them), which did not cause facilitation, strengthens the hypothesis of a direct interaction between betulin and venom components.

(a)

(b)

Figure 4

Contractile responses of indirectly stimulated EPSTA preparations treated with saline (i.m.), venom (3.6 mg/kg, i.m., in 120 μL), and venom + CBA (1.8 μL in 1 mL, i.v.) (a) or betulin (20 mg in 1 mL, i.p.) and venom + betulin (b). Note the parallelism between the responses to betulin alone and venom + betulin. The points represent the mean ± SEM of the number of experiments () indicated in each panel. compared to saline and compared to venom alone. CBA and betulin were administered at the arrows 15 min after the venom.

3.4. Myotoxicity Assessed by CK Release

The myotoxicity of the venom was assessed by quantifying the release of CK (Figure 5). Venom alone significantly increased CK release compared to treatment with saline. This increase was attenuated by CBA and, to a greater extent, by betulin administered 15 min after venom injection. There was no significant difference between the responses to venom + betulin and venom + CBA.

4. Discussion

Betulin, an ubiquitous triterpenoid that is found in numerous bushes and trees and that is easily isolated from the bark of birch trees, has more limited medicinal uses than its derivative betulinic acid [29]. To date, betulin has been shown to have anti-inflammatory [29], antiproliferative/antitumor [29, 48], and anti-snake venom [33] activities, the latter against the venoms of B. jararacussu and C. d. terrificus, two of the medically most important snake species in Brazil.

A major difficulty with betulin and other triterpenes is their poor solubility in polar and nonpolar solvents, which makes the use of solubilizing agents mandatory. Such solvents must be able to solubilize the drug at the desired concentration [49]. For this study, PEG 400 was used to disperse betulin for the experiments in vitro and in situ. We have previously shown that PEG 400 is compatible with use in vitro since a volume of 15 μL in an organ bath volume of 5 mL had no effect on the basal responses of PND preparations [38, 39].

The osmolality of normal serum ranges from 285 to 290 mOsmol/kg (or mOsmol/L) and is maintained by regulating renal water excretion, which in turn is modulated by the antidiuretic hormone vasopressin and development of the sensation of thirst to prevent excessive hypertonicity [50]. The osmolality of peripherally infused solutions was defined by the Infusion Nursing Society as 500 mOsm/L, the upper limit of peripheral vein tolerance, based on a study by Gazitua et al. [51]. However, Payne-James and Khawaja [52] suggested that osmolality should be kept below 1000 mOsmol/kg, although values of up to 1700 mOsmol/kg may be used in parenteral nutrition in conjunction with fine-bore polyurethane catheters [53]. Based on these data and as explained in Section 2.5, a single dose of betulin (20 mg) was used for the experiments in situ; since this solution had a higher osmotic pressure (Table 2) than blood, it was administered i.p. rather than i.v.

Ferraz et al. [33] considered betulin to be the best phytochemical among triterpenoids isolated from D. alata [15] based on its activity against the neurotoxicity and myotoxicity of B. jararacussu and C. d. terrificus venoms. As shown here, in preincubation protocols, betulin protected against the neuromuscular blockade caused by B. jararacussu venom to an extent similar to that seen with CBA after a 120 min incubation. The protective effect of betulin may be related to its intense facilitatory action that could increase the safety margin of the neuromuscular junction. Indeed, we have generally observed that plant products with a facilitatory action provide the best protection against neuromuscular damage caused by aggressive agents such as snake venoms [33, 54–56].

Antivenom therapy is the recognized standard treatment for envenoming following snakebite but may result in side effects such as anaphylactic shock, pyrogenic reaction, and serum sickness. The inefficacy of antivenoms against the local effects (severe pain, edema, hemorrhage, and necrosis) of envenoming may result in permanent venom-induced scarring and deformity as a consequence of extensive tissue damage [57, 58]. In this context, the efficacy of betulin observed in isolated nerve-muscle preparations [33] and confirmed here (Figure 2(b)) was similar to that of CBA. This finding suggested the need to assess this efficacy in a preparation in situ.

The rat EPSTA preparation provides a useful means of evaluating substances in real time since the anesthetized animal is kept alive during the experiment. Interventions in the popliteal nerve culminate in sciatic nerve responses. The popliteal fossa is where the sciatic nerve splits into its two major components, the tibial and common peroneal nerves that travel together within the same nerve sheath [59]. The response of the EPSTA preparation to B. jararacussu venom corroborated the paralysis first reported for this venom by Rodrigues-Simioni et al. [34], but at a different level. In mouse PND preparations, the blockade was complete and irreversible whereas, in rat EPSTA preparations, the blockade was partial (~30%) but sustained until the end of the experiment. The results obtained with the EPSTA preparation provide experimental evidence of neuromuscular blockade by B. jararacussu venom in vivo after local i.m. injection (the most common route of venom inoculation in Bothrops bites). The discrepancy between the extent of blockade seen in PND and that seen in EPSTA preparations could potentially reflect differences between the test species (mouse versus rat) and muscles used but is much more likely to be related to (1) the mode of venom application; that is, PND preparations were bathed in a solution of venom so that the whole tissue was in contact with venom whereas in EPSTA the muscle was injected locally with venom so that only part of the preparation was in contact with venom, and (2) the amount of venom used, which was much greater in EPSTA than in PND, for example, 1,224 μg (1.224 mg) injected in the EPSTA muscle of a 340 g rat compared to a total of 200 μg per PND preparation. The relative contribution of each of these factors to the responses observed here remains to be determined. In Bothrops snakebites, the local effects are progressive even after venom absorption [60]. This observation suggests that the neuromuscular blockade seen in EPSTA is not purely a myonecrotic event. In agreement with this conclusion, bothropstoxin-I, the main myotoxin from B. jararacussu venom, is known to act presynaptically [61].

Comparison of the effects of CBA and betulin indicated that the latter had a faster onset (10 min earlier) against venom-induced neuromuscular blockade than CBA, probably because of the large amount of betulin (20 mg) that was administered as a single injection i.p. compared to CBA which was injected slowly i.v. Overall, however, there was no significant difference between the recovery curves for the two treatments; that is, either treatment was as good as the other.

Myonecrosis at the bite site is an important local effect in Bothrops snakebites, primarily through the action of phospholipases [62] and snake venom metalloproteases (SVMPs) [63]. Histological analysis and CK determination are complementary parameters for assessing venom-induced tissue damage. Since Ferraz et al. [33] have already demonstrated the high potency of betulin against B. jararacussu and C. d. terrificus venoms using light microscopy, in this study we assessed myotoxicity based only on CK release as an indicator of cell damage [37]. The enzyme activity after 2 h (an interval sufficient for maximal CK release by B. jararacussu venom [64]) increased from U/L (saline control, ) to U/L (, ).

When rats were treated with CBA administered i.p., the venom myotoxicity was attenuated to U/L, whereas betulin reduced this myotoxicity to U/L, significantly less than venom alone, but still greater than the saline control. Statistical analysis showed the superiority of betulin compared to CBA. An important factor in the lower neutralization of CK release by CBA compared to betulin in these experiments may have been the route (i.p.) of CBA administration. In a comparative study on the influence of the route of CBA administration (i.p. versus i.m.), Agostini Utescher et al. [65] concluded that these two routes were much less efficacious than i.v. injection, in agreement with the official recommendation for use of the latter route in clinical envenomation [66]. Although not directly comparable, the findings with the two protocols tested here also point to better neutralization with i.v. administration since the attenuation of neuromuscular blockade by CBA given i.v. (Figure 4(a)) was better than that of myotoxicity (CK release) by CBA given i.m. (Figure 5); this conclusion generally agrees with i.v. administration being the clinically preferred route. Whereas antivenom neutralizes venom via antigen-antibody reactions, the mechanism by which betulin neutralizes B. jararacussu venom is unknown. Of various mechanisms postulated for plant-snake venom interactions, protein precipitation [67] appears unlikely since betulin has no toxic effects [9].

5. Conclusion

Based on the results described above, two major conclusions can be drawn. The first and more specific conclusion is that betulin injected i.p. can attenuate the neuromuscular effects of B. jararacussu venom by mechanisms that remain to be determined; this neutralizing capacity could be potentially useful for treating Bothrops bites in a veterinary setting and possibly also in humans, as a complementary measure to the use of antivenom. The second, more general conclusion is that the EPSTA preparation can be useful for studying the neuromuscular effects of Bothrops venoms and their neutralization by plant products. The principal advantage of this preparation over more commonly used nerve-muscle preparations such as the mouse PND is the maintenance of the normal physiological mechanisms of the muscle (because the preparation is in situ) that may have a role in modulating the responses to venom, thus providing a better simulation of what occurs following envenomation. This more realistic environment may allow better assessment of the efficacy of potential candidate molecules in neutralizing venom activity.

Conflict of Interests

The authors have no conflict of interests regarding the publication of this work.

Acknowledgments

The authors thank Gildo B. Leite and Dr. Lea Rodrigues-Simioni (Unicamp) for assistance with the EPSTA preparation, F. R. Quinelato, L. Q. Batista, and E. M. Carneiro (Unicamp) for help with the osmometer measurements, and A. D. Messias, S. M. M. Cattani, and E. A. R. Duek (PUC Sorocaba) for providing access to the spectrophotometer. This study was supported by Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP; Grant nos. 04/09705-8, 07/53883-6, 08/50669-6, 08/52643-4, and 08/11005-5), CAPES/Prosup, Probic/Uniso, Pibic/CNPq, and USAL (Grant no. 18KAC9/463AC01).

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Copyright © 2015 Miriéle Cristina Ferraz et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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