Additionally, only few
scientific probes are available for investigation of intracellular and molecular events of the envenoming in this specie. Thus, an animal model that would allow the investigation of these events is highly advantageous. The subcutaneous implantation Cyclopamine purchase of sponges have been used in several studies, because it is a model that resembles a cell culture in vivo by inducing an amplified inflammatory foreign body reaction that progresses to the formation of a highly vascular granulation tissue in which various components of subcutaneous tissue can be analyzed by biochemical, functional and histological parameters ( Campos et al., 2008 and Parrilha et al., 2011). Previously, we have investigated the effects of Bothrops venom on blood flow of the fibrovascular tissue induced by synthetic matrix implanted subcutaneously
in mice ( Vieira et al., 1992). We reasoned that this model could be used to study the actions of Loxosceles venom in mice thus, providing a new tool to investigate not only the inflammatory effects of the venom, but also the mechanisms of the injury. In this study, we set up a methodology based on subcutaneous implantation of sponge matrix to evaluate the inflammation pattern (neutrophil and macrophage infiltration, vasodilatation, hyperhaemia, edema and hemorrhage) check details induced by Loxosceles venom in mice. The venom was extracted from the venom glands of adult animals by maceration and centrifugation according to Silvestre et al. (2005), and frozen at −80 °C Y-27632 2HCl until use. Thirty two 6–8 weeks old male Swiss mice were housed individually and provided with chow pellets and water ad
libitum. The light/dark cycle was 12:12 h with lights on at 7:00 a.m. and lights off at 7:00 p.m. Housing, anesthesia, and postoperative care concurred with the guidelines established by our local Institutional Animal Welfare Committee. The present study was approved by the Ethics Committee in Animal Experimentation (CETEA) of Universidade Federal de Minas Gerais (UFMG) process number 229/09 approved in June 9, 2010. Discs of Polyether–polyurethane sponge (Vitafoam Ltd., Manchester, UK), 6 mm thick, and 11 mm diameter (Fig. 1A) were soaked overnight in 70% v/v ethanol and boiled in distilled water for 15 min before implantation. Animals were anesthetized with xilasin/ketamin (1 mg/kg, Syntec of Brazil), the dorsal fur was shaved and the skin antissepsy was made with 70% ethanol. The sponge discs were aseptically implanted into a subcutaneous pouch, through a 1 cm long dorsal mid-line incision. Post-operatively, animals were monitored for any sign of infection at the operative site, discomfort or distress. Fourteen days post implantation, animals were separated into two groups: (1) control group – sixteen mice that injected with 30 μL of saline intra-implant; (2) treated group – sixteen mice injected with 0.