, 1991). However, still there were some limitations with the encapsulated Rh and TS due to the product inhibition by the formed sulfite. This approach was further improved by the application of organic thiosulfonates with find more superior SCN formation efficacy and superior cell penetration capability to that of the inorganic TS (Petrikovics et al., 1994). When butane thiosulfate was administered with encapsulated Rh in combination with SN, a prophylactic antidotal protection

of 14× LD50 was achieved (Petrikovics et al., 1995). Sulfur donors with higher lipophilicity can penetrate cell membranes and reach the mitochondrial Rh, and are expected to be efficient even without external Rh administration. Various synthetic and naturally occurring organo-sulfur molecules were tested in vitro and in vivo and compared check details to the inorganic TS ( Baskin et al., 1999, Frankenberg, 1980 and Iciek, 2001). Several garlic originated

organo-sulfur molecules were evaluated as SDs and CN acceptors ( Ashani et al., 2006, Block, 1985 and Iciek et al., 2005). Although great progress was achieved in the field, especially in the prophylactic treatment of cyanide intoxication, there are still numerous factors that could be improved, including the need to identify further, possibly more effective organo-sulfur molecules and the need of an intramuscular preparation for therapeutic treatment. Latter is important since the presently used antidotes are all intravenous preparations, which in the case of a mass casualty scenario are difficult to administer in time due to the large number of people involved. An intramuscular preparation would be easier and quicker to administer or even self-administer which in turn would be more favorable in such a situation. One of the main drawbacks of the organo-sulfur almost donors is their very low water solubility, which hinders their application in liquid dosage forms.

To overcome this issue, an appropriate solubility enhancing method or solvent system has to be developed that is capable of dissolving the compounds at therapeutically relevant concentrations. In the case of parenterals this poses extra difficulties as the available excipients for solubilizing lipophilic molecules is limited and their applicable concentration range is also restricted (Liu, 2008 and Strickley, 2004). Present study focused on the in vitro efficacy characterization of methyl propyl trisulfide (MPTS), an SD molecule that to our present knowledge has never been used in combating cyanide intoxication, and on its in vivo antidotal efficacy determined on a therapeutic mice model. Furthermore, since the identified SD is a highly lipophilic molecule it was the aim of the study to design a solvent system that is capable of dissolving the drug candidate in therapeutically effective doses.