Extracellular proteic plaques found in the brains of patients affected by Alzheimer’s disease contain fibrils composed of bamyloid (Ab) peptides. These range in length from 39 to 43 amino acids, the most abundant form being Ab-(1–42). Although there is evidence of the presence of aggregates inside affected neurons in other neurodegenerative diseases, in the Current views of the role of b-amyloid (Ab) peptide fibrils range from regarding them as the cause of Alzheimer’s pathology to having a protective function. In the last few years, it has also been suggested that soluble oligomers might be the most important toxic species. In all cases, the study of the conformational properties of Ab peptides in soluble form constitutes a basic approach to the design of molecules with “antiamyloid” activity. We have experimentally investigated the conformational path that can lead the Ab-(1–42) peptide from the native state, which is represented by an a helix embedded in the membrane, to the final state in the amyloid fibrils, which is characterized by bsheet structures. The conformational steps were monitored by using CD and NMR spectroscopy in media of varying polarities. This was achieved by changing the composition of water and hexafluoroisopropanol (HFIP). In the presence of HFIP, b conformations can be observed in solutions that have very high water content (up to 99% water ; v/v). These can be turned back to a helices simply by adding the appropriate amount of HFIP. The transition of Ab-(1–42) from a to b conformations occurs when the amount of water is higher than 80% (v/v). The NMR structure solved in HFIP/H2O with high water content showed that, on going from very apolar to polar environments, the long N-terminal helix is essentially retained, whereas the shorter C-terminal helix is lost. The complete conformational path was investigated in detail with the aid of molecular-dynamics simulations in explicit solvent, which led to the localization of residues that might seed b conformations. The structures obtained might help to find regions that are more affected by environmental conditions in vivo. This could in turn aid the design of molecules able to inhibit fibril deposition or revert oligomerization processes.