Antimicrobial peptides (AMPs) are found in almost all organisms as part of the immune system. Despite sequence variability, they are usually positively charged and fold in an amphipathic structure upon interaction with biologic membranes. Esculentin-1b is an interesting 46-mer peptide isolated from the skin of Rana esculenta, which shows an outstanding antimicrobial activity. Experimental studies revealed that the N-terminal (1-18) fragment is responsible for the activity of the whole peptide, with a negligible toxicity towards eukaryotic cells, thus representing an excellent canditate for future applications. It is expected, like most of the known AMPs, to target the bacterial plasma-membrane but its 3D-structure and detailed mode of action are still unknown. Before an in-depth investigation on peptide/membranes interactions could be undertaken, it is necessary to characterize its folding propensity in solution, in order to understand what is intrinsically due to the peptide sequence and what is actually driven by the membrane interaction. In this scenario, the present study represents the first structural investigation on Esculentin-1b(1-18). Liquid state NMR was employed to determine the peptide structure, moving from water to increasing amounts of trifluorethanol. NMR parameters have been used as restraints during structure determination through a simulated annealing procedure. The results showed that Esculentin-1b(1-18) has a clear tendency to fold in a helical conformation with increasing the environment hydrophobicity, confirming circular dichroism data. Interestingly, the helix is formed only for residues ranging from 3 to 11, while it appears to be unstructured in the rest of the peptide. Nevertheless, the whole conformation was found to be amphipathic with a 3-mer hydrophobic cluster right in the middle of the unstructured segment, which might act as an anchoring tail upon membrane binding.