Abstract

Background

Spinal cord injury (SCI) is a leading cause of permanent disability in young adults [¹1 . Tator CH: Strategies for recovery and regeneration after brain and spinal cord injury. Inj Prev 2002, 8(Suppl 4):iv33-iv36.

2 . Rossignol S, Schwab M, Schwartz M, Fehlings MG: Spinal cord injury: time to move? J Neurosci 2007, 27(44):11782-11792.-³3 . Chiu WT, Lin HC, Lam C, Chu SF, Chiang YH, Tsai SH: Epidemiology of traumatic spinal cord injury: comparisons between developed and developing countries. Asia Pac J Public Health 2010, 22(1):9-18.]. At the time of trauma, the primary lesion usually leads to the disruption of axons, neurons and neuroglia cell bodies, resulting in nerve impulses interruption. Afterwards, the secondary neurode-generative events start and worsen the initial injury. Excessive accumulation of intracellular calcium is a common phenomenon after SCI and it is the most critical step in ionic dysregulation that generates axonal injury and eventual apoptosis or necrosis via an increase in cellular enzymes activation, mitochondrial damage, acidosis, and free radicals production [⁴4 . Isaac L, Pejic L: Secondary mechanisms of spinal cord injury.Surg Neurol 1995, 43(5):484-485.

5 . Amar AP, Levy ML: Pathogenesis and pharmacological strategies for mitigating secondary damage in acute spinal cord injury. Neurosurgery1999, 44(5):1027-1039.

6 . Lu J, Ashwell KW, Waite P: Advances in secondary spinal cord injury. Spine 2000, 25(14):1859-1866.

7 . Carlson GD, Gorden C: Current developments in spinal cord injury research. Spine J 2002, 2(2):116-128.

8 . Hall ED, Springer JE: Neuroprotection and acute spinal cord injury: a reappraisal. NeuroRx 2004, 1(1):80-100.-⁹9 . Liu WM, Wu JY, Li FC, Chen QX: Ion channel blockers and spinal cord injury. J Neurosci Res 2011, 89(6):791 -801.].

Calcium channel blockers (CCB) have shown great potential in reducing brain and spinal cord injury, by preventing the intense ion influx and, consequently, the secondary injury progression [¹⁰10 . Choi DW: Excitotoxicity cell death. J Neurobiol1992, 23(9):1261-1276.,¹¹11 . Lanz O, Bergman R, Shell L: Initial assessment of patients with spinal cord trauma. Vet Med 2000, 95:851 -853.]. A wide variety of natural CCB were identified in animal venoms containing neuroactive or neuroprotective peptides, including the conotoxins from Conus snails [¹²12 . Rajendra W, Armugam A, Jeyaseelan K: Neuroprotection and peptide toxins. Brain Res Brain Res Rev 2004, 45(2):125-141.]. Omega-conotoxin MVIIC (MVIIC) is a member of the CCB toxin family constituted by 26 aminoacids [¹³13 . Hillyard DR, Monje VD, Mintz IM, Bean BP, Nadasdi L, Ramachandran J, Miljanich G, Azimi-Zoonooz A, McIntosh JM, Cruz LJ, Imperial JS, Olivera BM: A new Conus peptide ligand for mammalian presynaptic Ca2+ channels. Neuron 1992, 9(1):69-77.]. It selectively inhibits the types N (Cav2.1), P, and Q (Cav2.2) voltage-dependent calcium channels (VDCC) that are essential in the release of neurotransmitters [¹⁴14 . Olivera BM, Miljanich G, Ramachandran J, Adams ME: Calcium channel diversity and neurotransmitter release: the omega-conotoxins and omega-agatoxins. Annu Rev Biochem 1994, 63:823-867.

15 . Uchitel OD: Toxins affecting calcium channels in neurons.Toxicon 1997, 35(8):1161 -1191.-¹⁶16 . Minami K, Raymond C, Martin-Moutot N, Ohtake A, Renterghem CV, Takahashi M, Seagar MJ, Mori Y, Sato K: Role of Thr11 in the binding of ω-conotoxin MVIIC to N-type Ca2+ channels. FEBS Lett2001,491 (1 -2):127-130.]. In recent years, studies on MVIIC effects have shown that it significantly reduces calcium influx through VDCC in several in vitromodels of ischemic brain and spinal injuries [¹⁵15 . Uchitel OD: Toxins affecting calcium channels in neurons.Toxicon 1997, 35(8):1161 -1191.,¹⁷17 . Liu H, Waards M, Scott VES, Gurnett CA, Lennon VA, Campbell KP: Identification of three subunits of the high affinity ω-conotoxin MVIIC-sensitive Ca2+ channel. J Biol Chem 1996, 271:13804-13810.

18 . McDonough SI, Boland LM, Mintz IM, Bean BP: Interactions among toxins that inhibit N-type and P-type calcium channels. J Gen Physiol2002, 119(4):313-328.

19 . Pinheiro ACN, Silva AJ, Prado MA, Cordeiro MN, Richardson M, Batista MC, de Castro Junior CJ, Massenssini AR, Guatimosim C, Romano-Silva MA, Kushmerick C, Gomez MV: Phoneutria spider toxins block ischemia-induced glutamate release, neuronal death, and loss of neurotransmission in hippocampus. Hippocampus2009,19(11):1123-1129.

20 . Wright CE, Angus JA: Effects of N-, P- and Q-type neuronal calcium channel antagonists on mammalian peripheral neurotransmission. Br J Pharmacol 1996, 119(1):49-56.-²¹21 . Imaizumi T, Kocsis JD, Waxman SG: The role of voltage-gated Ca++ channels in anoxic injury of spinal cord white matter. Brain Res1999, 817(1-2):84-92.]. Thus, these findings suggest a potential role of MVIIC in preventing secondary injuries after spinal trauma.

However, early clinical experience with MVIIC demonstrates that side effects may limit the usefulness of this class of drugs [²²22 . Bowersox SS, Gadbois T, Singh T, Pettus M, Wang YX, Luther RR: Selective N-type neuronal voltage-sensitive calcium channel blocker, SNX-111, produces spinal antinociception in rat models of acute, persistent, and neuropathic pain. J Pharmacol Exp Ther 1996, 279(3):1243-1249.,²³23 . Dalmolin GD, Silva CR, Rigo FK, Gomes GM, Cordeiro MN, Richardson M, Silva MA, Prado MA, Gomez MV, Ferreira J: Antinociceptive effect of Brazilian armed spider venom toxin Tx3-3 in animal models of neuropathic pain.Pain 2011, 152(10):2224-2332.]. Envenomation byConus toxins is characterized by various symptoms such as intense pain followed by shaking, generalized paresthesia, neuromus-cular paralysis and death caused by respiratory failure [²³23 . Dalmolin GD, Silva CR, Rigo FK, Gomes GM, Cordeiro MN, Richardson M, Silva MA, Prado MA, Gomez MV, Ferreira J: Antinociceptive effect of Brazilian armed spider venom toxin Tx3-3 in animal models of neuropathic pain.Pain 2011, 152(10):2224-2332.,²⁴24 . Watters MR, Stommel EW: Marine neurotoxins: envenomations and contact toxins. Curr Treat Options Neurol 2004, 6(2):115-123.]. No information about the pharmacokinetics and pharmacodynamic characteristics of MVIIC is available. To be possible to evaluate the effects of toxin on SCI, safety should be the overriding principle in the selection for the best dose. The present study was designed to determine, for the first time, the in vivo effects of MVIIC on blood profile and histopathological changes that it may provoke. In this experiment, MVIIC was intralesionally injected due to its peptide nature, so the toxin was directly administered in the central nervous system (CNS), and additionally this route enables local treatment, requiring a smaller amount of toxin with fewer side effects [²⁵25 . Snutch TP: Targeting chronic and neuropathic pain: the N-type calcium channel comes of age. NeuroRx 2005, 2(4):662-670.,²⁶26 . Takahashi Y, Tsuji O, Kumagai G, Hara CM, Okano HJ, Miyawaki A, Toyama Y, Okano H, Nakamura M: Comparative study of methods for administering neural stem/progenitor cells to treat spinal cord injury in mice. Cell Transplant 2011, 20(5):727-739.].

Methods

Experimental design

Thirty adult male Wistar rats weighting 400 to 450 g were randomly distributed into five groups. Rats were housed in a controlled environment and provided with commercial rodent food and water ad libitum. The Ethics Committee on Animal Experimentation of the Federal University of Minas Gerais (CETEA/UFMG) approved the present study under protocol n. 075/10. All animals experiments followed the recommendations of Guide for the Care and Use of Laboratory Animals of the US National Institute of Health.

Animals were premedicated with tramadol chloride (4 mg/kg, subcutaneously), and anesthesia was induced and maintained with isoflurane in a non-rebreathing circuit, through a facemask. The animals were positioned in a stereotaxic apparatus, received prophylactic antibiotic with cephalotin (60 mg/kg, subcutaneously) and then, prepared for asseptic surgery. An incision was made in the dorsal midline skin and subcutaneous tissues from T8 to L1, and the muscle and tissue overlying the spinal column were blunt-dissected away revealing the laminae. Using the spiny process of T13 as a landmark, laminectomy of T12 was performed with a pneumatic drill and the lamina was carefully removed to expose the spinal cord. Extradural compression of the spinal cord at the vertebral level of T12 was achieved as previously described [²⁷27 . Silva CMO, Melo EG, Almeida AERF, Gomez MG, Silva CHO, Rachid MA, Verçosa Júnior D, Vieira NT, França SA: Effect of prednisone on acute experimental spinal cord injury in rats. Arq Bras Med Vet Zootec2008, 60(3):641-650.

28 . Torres BBJ, Caldeira FMC, Gomes MG, Serakides R, Viott AM, Bertagnolli AC, Fukushima FB, Oliveira KM, Gomez MV, Melo EG: Effects of dantrolene on apoptosis and immunohistochemical expression of NeuN in the spinal cord after traumatic injury in rats. Int J Exp Pathol 2010, 91 (6):530-536.

29 . Torres BBJ, Silva CMO, Almeida ÁERF, Caldeira FMC, Gomes MG, Alves EGL, Silva SJ, Melo EG: Experimental model of acute spinal cord injury produced by modified steriotaxic equipment. Arq Bras Med Vet Zootec2010, 62(1):92-99.-³⁰30 . Torres BBJ, Serakides R, Caldeira F, Gomes M, Melo E: The ameliorating effect of dantrolene on the morphology of urinary bladder in spinal cord injured rats. Pathol Res Pract 2011, 207(12):775-779.] using a weight of 70 g/cm².Fiveminutes later, an intralesional injection was performed according to the experimental protocol. The incision was closed in two layers and the animals were allowed to recover from anesthesia in a warmed (37°C) box.

Post-operative care procedures involved manual expression of the bladder, three times a day, tramadol chloride (2 mg/kg, orally, every eight hours) for three days, and cephalexin (30 mg/kg, orally, twice a day) for five days.

Pharmacological treatment

Five minutes after the incision, 2 μL of treatment was administered into the injury center using a Hamilton microsyringe, as previously described [³¹31 . Kamada T, Koda M, Dezawa M, Anahara R, Toyama Y, Yoshinaga K, Hashimoto M, Koshizuta S, Nishio Y, Mannoji C, Okawa A, Yamazaki M: Transplantation of human bone marrow stromal cell-derived Schwann cells reduces cystic cavity and promotes functional recovery after contusion injury of adult rat spinal cord. Neuropathology 2011, 31(1):48-58.]. The animals were distributed into five groups, with six rats each, according to the treatment protocol: placebo treatment with sterile water (PLA), 15 pmol of MVIIC (G15), 30 pmol of MVIIC (G30), 60 pmol of MVIIC (G60), and 120 pmol of MVIIC (G120). Doses were based on studies describing that MVIIC doses of 3 pmol have analgesic effects by blocking the VDCC type P/Q, and those of 100 pmol had side effects [²³23 . Dalmolin GD, Silva CR, Rigo FK, Gomes GM, Cordeiro MN, Richardson M, Silva MA, Prado MA, Gomez MV, Ferreira J: Antinociceptive effect of Brazilian armed spider venom toxin Tx3-3 in animal models of neuropathic pain.Pain 2011, 152(10):2224-2332.,³²32 . Silva JF: Avaliação da atividade antinociceptiva espinhal da toxina Tx3-4 do veneno da aranha Phoneutria nigriventer em camundongos. Belo Horizonte: UFMG; 2009.].

For eight days, experiments focused on clinical observation. All animals were euthanized at Day 8 following SCI. Clinical and histopathological evaluations were carried out by investigators who did not take part into the research.

Clinical evaluation

For three days before SCI, animals were allowed to adapt to the open field arena - that had 90 cm in diameter and three inches high - for 15 minutes to clinical evaluation. After trauma, they were monitored for the presence of widespread tremor, walking in circle or muscle weakness, during the first five hours after the toxin administration and daily until euthanasia [³³33 . Malmberg AB, Yaksh TL: Voltage-sensitive calcium channels in spinal nociceptive processing: blockade of N- and P-Type channels inhibits formalin-induced nociception. J Neurosci1994,14(8):4882-4890.].

Blood collection

Blood samples were collected prior to experiment and eight days after treatment by caudal vein puncture in two types of tubes, with anticoagulant sodium fluoride in order to access hematologic profile, and without anticoagulant to collect serum and evaluate biochemical profiles, both analyzed immediately.

Hematological parameters

Hematological parameters including red blood cells (RBC), white blood cells (WBC) and hemoglobin concentration (Hb) were determined using Abacus Junior Vet electronic counter (Diatron Messtechnik GmbH, Austria). The RBC indices - namely mean corpuscular volume (MCV), mean corpuscular hemoglobin (MCH) and mean corpuscular hemoglobin concentration (MCHC) - were calculated using the RBC count, Hb and hematocrit (Ht) values. Blood smears were prepared on glass slides (26 χ 79 mm), fixed with May-Grunwald solution and stained with Giemsa in order to carry out differential counting of leukocytes and total number of platelets [³⁴34 . Thrall MA, Weiser G, Allison R, Campbell T: Veterinary Hematology and Clinical Chemistry. Baltimore: Lippincott Williams & Wilkins; 2004.]. Volume of packed RBC or Ht was determined using a micro-hematocrit centrifuge (Model Spin 1000®, Micro Spin, USA). The blood was centrifuged to obtain plasma and to determinate total protein by refractometry.

Biochemical parameters

Urea, creatinine, alanine aminotransferase (ALT) and as-partate aminotransferase (AST) were determined with the aid of commercial kits from Synermed® (Westfield, USA) and Cobas Mira Classic® chemical analyzer (Global Medical Instrumentations, USA).

Histological analysis of tissue injury

On Day 8 after surgery, the rats were deeply anesthetized with an overdose of sodium thiopental (100 mg/kg), intra-peritoneally. The animals were perfused with 300 mL of 0.9% sodium chloride saline followed by 300 mL of 10% phosphate-buffered formalin (pH 7.4). Following perfu-sion, the brain, heart, liver, kidney, lung, spleen, stomach, lumbar muscle, intestine, pancreas and adrenal were removed and placed overnight in 10% phosphate-buffered formalin. Twenty-four hours later, organ samples were dehydrated in a series of alcohol grades and embedded in paraffin wax. Briefly, 4-μm thick longitudinal sections were stained with routine hematoxylin-eosin (HE) for pathological studies.

Lesion areas were classified in nine grades, according to the histological pattern of intensity (mild, moderate, and severe) and extension (focal, multifocal, and diffuse) of the lesion (Table 1).

Statistical analysis

All collected data were analyzed using Prism 5® for Windows (GraphPad Software, La Jolla, USA) and were expressed as mean ± standard deviation (SD). Normal distributed data were subjected to analysis of variance (ANOVA), followed by t-paired test between times and Student-Newman-Keuls test between groups. Non-parametric parameters were subjected to Kruskall-Wallis test and Dunn's post hoc test (p < 0.05).

Results and discussion

In the current experiment, we studied the clinical, hematological, biochemical and tissue histopathological changes to investigate any toxic effects caused by MVIIC. These parameters help to identify possible changes caused by such toxins, the severity of the alterations and which doses can be clinically used in SCI.

Clinical evaluation

Although frequently reported, in the present study no dose provoked muscle weakness or paralysis as seen by Dalmolin et al. [²³23 . Dalmolin GD, Silva CR, Rigo FK, Gomes GM, Cordeiro MN, Richardson M, Silva MA, Prado MA, Gomez MV, Ferreira J: Antinociceptive effect of Brazilian armed spider venom toxin Tx3-3 in animal models of neuropathic pain.Pain 2011, 152(10):2224-2332.] at 100 or 300 pmol by intrathecal (IT) route or even shaking at 10 pmol by intracerebroven-tricular (IC) route. These differences may be attributable to the fact that it was impossible to evaluate variables such as hindlimb locomotor deficit, flaccid paralysis or decreased tail withdrawal response, describe by these authors, because they are similar to clinical signs of SCI. Besides, Malmberg and Yaksh [³³33 . Malmberg AB, Yaksh TL: Voltage-sensitive calcium channels in spinal nociceptive processing: blockade of N- and P-Type channels inhibits formalin-induced nociception. J Neurosci1994,14(8):4882-4890.] noticed that body shaking occurred 30 minutes after the injection and, at this time, the animal was recovering from anesthesia. Moreover, Dalmolin et al. [²³23 . Dalmolin GD, Silva CR, Rigo FK, Gomes GM, Cordeiro MN, Richardson M, Silva MA, Prado MA, Gomez MV, Ferreira J: Antinociceptive effect of Brazilian armed spider venom toxin Tx3-3 in animal models of neuropathic pain.Pain 2011, 152(10):2224-2332.] observed that IC route had more side effects than IT. This fact could be associated to the high density of P/Q-type expressed in nociceptive pathways at the supraspinal site, which emphasizes the powerful effect of MVIIC injected by IC route [³⁵35 . Hillman D, Chen S, Aung TT, Cherksey B, Sugimori M, Llinás RR: Localization of P-type calcium channels in the central nervous system.Proc Natl Acad Sci U S A 1991, 88(16):7076-7080.]. It also could be inferred that due to the IL injection into the spinal cord, we did not notice even body shaking as seen at 10 pmol by IC route.

Hematological parameters

In this experiment, an increase in RBC, Ht (Figure 1) and Hb (Figure 2) concentration in all groups may be due to the postoperative stress, restraint and anesthesia prior to euthanasia, leading to a splenic contraction and consequent erythrocyte release [³⁶36 . Weiss DJ, Wardrop JK: Schalm's Veterinary Hematology.Iowa: Blackwell Pub ishing; 2010.]. Furthermore, hemo-concentration is most likely a result of the liquid loss due to the weakened condition of rats in the postoperative period and reduced water consumption. Dehydration was not clinically observed, but water intake was reduced as suggested the levels of bottles. Moreover, in the dehydration process, total protein concentration is augmented [³⁷37 . Watson ADJ: Erythrocytosis and polycythemia. In Schalm's Veterinary Hematology. 5th edition. Edited by Feldman BF, Zinkl JG, Jain NC. Philadelphia: Lippincott Williams & Wilkins; 2000:200-204.]. Proteins have many functions in the organism and their levels helps in the diagnosis and prognosis of hydration status, inflammation, infection, nutritional status and changes in protein synthesis [³⁸38 . Santana AM, Fagliari JJ, Camargo CMS, Santana AE, Duarte JMB, Silva PRL: Serum protein concentrations of captive brown brocket deer(Mazama gouazoubira) determined by means of agarosis and sodium dodecyl sulphate-polyacrylamide (SDS-PAGE) gel electrophoresis.Arq Bras Med Vet Zootec 2008, 60(6):1560-1563.]. In this study, the absolute values of total protein showed no differences among times and groups (Additional file 1), suggesting that hematological changes are likely related to postoperative stress and euthanasia. Nevertheless, these parameters remained close to the reference values for the species [³⁹39 . Giknis MLA, Clifford CB: Clinical Laboratory Parameters for crl:WI (han). Massachusetts: Charles River Lab; 2008:1-17. http://www.criver.com/files/ pdfs/rms/wistarhan/rm_rm_r_wistar_han_clin_lab_parameters_08.aspx.
http://www.criver.com/files/ pdfs/rms/wi... ].

The values of MCV (Additional file 2), MCH (Additional file 3) and MCHC (Additional file 4) did not differ among times or groups, remaining within the physiologic patterns of species.

The increase of platelets (Figure 2) is a common finding in patients who underwent surgical intervention probably by tissue damage and inflammation. The relevance of this event is not clear yet [⁴⁰40 . Bunting RW, Doppelt SH, Lavine LS: Extreme thrombocytosis after orthopaedic surgery. J Bone Joint Surg 1991, 73-B:687-688.

41 . Valade N, Decailliot F, Rébufat Y, Heurtematte Y, Duvaldestin P, Stéphan F: Thrombocytosis after trauma: incidence, aetiology, and clinical significance. Br J Anaesth 2005, 94(1):18-23.-⁴²42 . Salim A, Hadjizacharia P, DuBose J, Kobayashi L, Inaba K, Chan LS, Marqulies DR: What is the significance of thrombocytosis in patients with trauma? J Trauma 2009, 66(5):1349-1354.]. Despite this fact, the parameters were within physiological standards for these animals (574-1253 χ 10³ cells/μL) [³⁹39 . Giknis MLA, Clifford CB: Clinical Laboratory Parameters for crl:WI (han). Massachusetts: Charles River Lab; 2008:1-17. http://www.criver.com/files/ pdfs/rms/wistarhan/rm_rm_r_wistar_han_clin_lab_parameters_08.aspx.
http://www.criver.com/files/ pdfs/rms/wi... ].

There are no reports of hematologic evaluation in animals that receive MVIIC, and this study shows that it does not cause anemia, hemolysis, vascular changes or interference in the hematologic response when applied by intralesional route.

There was a significant increase of the total leukocyte count in the PLA (7.680 ± 2.140 cells/μL) among the times of collection, not exceeding the maximum limits for the species (Figure 3) (p< 0.05). The leukocytosis can be attributed to stress induced by physical restraint at the time of euthanasia. In acute stress conditions, the release of endogenous glucocorticoids promotes increased blood and lymph circulation so leukocytes pass into the peripheral blood causing physiological leukocytosis [⁴³43 . Fukui Y, Sudo N, Yu XN, Nukina H, Sogawa H, Kubo C: The restraint stress-induced reduction in lymphocyte cell number in lymphoid organs correlates with the suppression of in vivo antibody production. J Neuroimmunol 1997, 79(2):211 -215.]. However, only the PLA group showed this significant leukocyte increase. Another possible explanation is that in animals with spinal cord trauma, there is great local inflammatory reaction in PLA group. In contrast, MVIIC groups did not show significant leukocyte augmentation and we can infer a possible anti-inflammatory effect, requiring further investigation.

There was no change in the absolute number of mono-cytes (Additional file 5), neutrophils (Additional file 6), and basophils (Additional file 7) among groups or times. Regarding the number of lymphocytes, it can be observed a significant increase (p < 0.05) in animals of PLA group (5.750 ± 1.250) eight days after the injury (Figure 3). Lymphocytes are the major circulating cells of rats, so the leucocytosis is probably due to lymphocytosis. Moreover, there was no difference among times and groups related to the absolute number of eosinophils, showing that MVIIC did not cause sensitization processes indicated by eosinophilia [⁴⁴44 . Jain NC: Essentials of Veterinary Hematology.Philadelphia: Lea & Febiger; 1993.].

As seen before, there was no toxic effect of treatment and, therefore, the toxin at the tested doses did not cause any hematological change. These results are unprecedented in the literature.

Biochemical parameters

Biochemical analysis is an important variable for evaluation in studies on toxins which reflects hepatic and renal function. Some enzymes such as AST and ALT are used to evaluate liver function, a key organ for drug metabolism. They reveal abnormalities, and deleterious effects of toxins may increase their levels, especially ALT, which is more specific for liver changes in rats [⁴⁵45 . Tennant BC, Center SA: Hepatic function. In Clinical Biochemistry of Domestic Animals. 6th edition. Edited by Kaneko JJ, Harvey JW, Bruss ML. San Diego: Academic Press; 2008:379-412.]. In our findings, there was no difference in the values of AST and ALT among time points (Figure 4), so there was no toxic effect on liver tissue, which was confirmed by liver histopathology. In addition to reflecting liver abnormalities, AST is used to assess myocardial infarction. Thus, according to our results, it can be stated that there was no significant cardiac muscle damage confirmed by heart histopathology.

Furthermore, renal excretion is a major route for drug elimination and their commitment may be evidenced by increases in serum creatinine and urea, indicators of glomerular filtration. Creatinine is considered a more reliable indicator that may be affected by the influence of extrarenal factors, and it is the final product of energy used by muscle tissue [⁴⁶46 . Magro MCS, Vattimo MFF: Evaluation of renal function: creatinine and other biomarkers. Rev BrasTer Int 2007, 19(2):182-185.]. Its concentration in blood depends on muscle injury, physical efforts and also meat intake in the case of carnivorous. It is filtered by the renal glomeruli, so renal glomerular lesions are verified by increased creatinine and urea [⁴⁶46 . Magro MCS, Vattimo MFF: Evaluation of renal function: creatinine and other biomarkers. Rev BrasTer Int 2007, 19(2):182-185.,⁴⁷47 Braun JP, Lefebvre HP: Kidney function and damage. InClinical Biochemistry of Domestic Animals. 6th edition. Edited by Kaneko JJ, Harvey JW, Bruss ML. San Diego: Academic Press; 2008:485-528.]. These values did not differ among groups and times (Figure 4). However, high levels of urea and creatinine in comparison with the physiological data set by Giknis and Clifford [³⁹39 . Giknis MLA, Clifford CB: Clinical Laboratory Parameters for crl:WI (han). Massachusetts: Charles River Lab; 2008:1-17. http://www.criver.com/files/ pdfs/rms/wistarhan/rm_rm_r_wistar_han_clin_lab_parameters_08.aspx.
http://www.criver.com/files/ pdfs/rms/wi... ] were noticed, both preoperatively and on the eighth day after trauma. Therefore, different standard physiological data from the literature were observed.

Histopathological evaluation

Histopathological studies revealed no significant abnormalities in tissue of brain, lung, heart, liver, adrenal, muscle, pancreas, spleen, and stomach in all groups.

In our study kidney tissues showed degenerative changes, especially when treated with 120-pmol doses of MVIIC, including degeneration in the Bowman's space, glomerular and tubular epithelial cells with deposition of eosinophilic material (amyloid) inside renal tubules, atrophy and glomerular sclerosis [⁴⁸48 . Di Bartola SP, Tarr MJ, Webb DM, Giger U: Familial renal amyloidosis in Chinese Shar-Pei dogs. J Am Vet Med Assoc 1990, 197(4):483-487.]. The 120-pmol dose significantly differed from others groups (p < 0.05) (Figures 5 and 6). This type of injury may lead to renal failure and have been observed in animals after spinal trauma following spider or scorpion envenom-ation [⁴⁹49 . Wall BM, Huch KM, Mangold TA, Steere EL, Cooke R: Risk factors for development of proteinuria in chronic spinal cord injury. Am J Kidney Dis 1999, 33(5):899-903.

50 . Tambourgi DV, Petricevich VL, Magnoli FC, Assaf SL, Jancar S, Dias Da Silva W: Endotoxemic-like shock induced by Loxosceles spider venoms: pathological changes and putative cytokine mediators. Toxicon1998, 36(2):391 -403.-⁵¹51 . Dehghani R, Khamechian T, Rafiezadeh MTZ, Nasajizavareh M: Histopathological assessment of Hemiscorpius lepturus venom effects on rats. Iran J Leg Med 2004, 10:202-206.]. It seems that in addition to amyloidosis caused by SCI, the 120-pmol dose intensified the kidney injury, even without increased levels of urea and cre-atinine, since it occurs when over 75% of renal function is lost [⁴⁷47 Braun JP, Lefebvre HP: Kidney function and damage. InClinical Biochemistry of Domestic Animals. 6th edition. Edited by Kaneko JJ, Harvey JW, Bruss ML. San Diego: Academic Press; 2008:485-528.]. Although there is no record of systemic effects of MVIIC, the highest dose increased renal changes, possibly by a direct glomerulopathy to renal tubule, or indirect, inflammatory response, as seen with others drugs [⁵²52 . Hill GS: Drug-associated glomerulopathies. Toxic Pathol1986,14(1):37-44.].

Conclusion

Our results suggest that MVIIC at 15, 30 and 60 pmol are safe to be used via intralesional route after spinal cord injury. The 120-pmol dose of MVIIC was detrimental to renal tissue, but it was not enough to change the renal function. More studies are necessary to investigate other routes of MVIIC administration and its possible side effects.

Additional files

Additional file 1: Effects of different doses of MVIIC on total protein levels. After spinalcord injury, controls were injected with sterile water (PLA) and other groups received different doses of MVIIC (15, 30, 60 and 120 pmol). Values represent the means ± SD of six animals at each time.

Additional file 2: Effects of different doses of MVIIC on median corpuscular volume. After spinalcord injury, controls were injected with sterile water (PLA) and other groups received different doses of MVIIC (15, 30, 60 and 120 pmol). Values represent the means ± SD of six animals at each time.

Additional file 3: Effects of different doses of MVIIC on median corpuscular hemoglobin. After spinalcord injury, controls were injected with sterile water (PLA) and other groups received different doses of MVIIC (15, 30, 60 and 120 pmol). Values represent the means ± SD of six animals at each time.

Additional file 4: Effects of different doses of MVIIC on mean corpuscular hemoglobin concentration. After spinal cord injury, controls were injected with sterile water (PLA) and other groups received different doses of MVIIC (15, 30, 60 and 120 pmol). Values represent the means ± SD of six animals at each time.

Additional file 5: Effects of different doses of MVIIC on monocyte levels.After spinalcord injury, controls were injected with sterile water (PLA) and other groups received different doses of MVIIC (15, 30, 60 and 120 pmol). Values represent the means ± SD of six animals at each time.

Additional file 6: Effects of different doses of MVIIC on neutrophil levels.After spinalcord injury, controls were injected with sterile water (PLA) and other groups received different doses of MVIIC (15, 30, 60 and 120 pmol). Values represent the means ± SD of six animals at each time.

Additional file 7: Effects of different doses of MVIIC on basophil levels.After spinalcord injury, controls were injected with sterile water (PLA) and other groups received different doses of MVIIC (15, 30, 60 and 120 pmol). Values represent the means ± SD of six animals at each time.

Abbreviations

SCI: Spinalcord injury; MVIIC: ω-conotoxin MVIIC; CCB: Calcium channe blockers; VDCC: Voltage-dependent calcium channels; PLA: Placebo; G15: 15 pmolof MVIIC; G30: 30 pmolof MVIIC; G60: 60 pmolof MVIIC; G120: 120 pmolof MVIIC; RBC: Red blood cells; WBC: White blood cells; Hb: Hemoglobin; MCV: Mean corpuscular volume; MCH: Mean corpuscular hemoglobin; MCHC: Mean corpuscular hemoglobin concentration; HT: Hematocrit; ALT: Alanine aminotransferase; AST: Aspartate aminotransferase; HE: Hematoxylin-eosin; SD: Standard deviation.

Acknowledgments

We gratefully acknowledge the support from the State ofMinas Gerais Research Foundation (FAPEMIG) and the National Council for Scientific and Technological Development (CNPq) for supporting the project, the Coordination for the Improvement of Higher Education Personnel(CAPES) for granting a scholarship and Cristália Lab for providing the medications. All these organizations did not have access to the research and had no role in data collection, analysis, interpretation, writing or decision to publish. None of the authors was paid.

References

Publication Dates

History