In this work the results of the production and characterization of new organic electroluminescent devices (OLEDs) are presented and discussed. The work can be ideally divided in three parts. The first is composed by the OLEDs that use the distyrilbenzene (DSBs) compounds as electroluminescent layer. The DSBs are systems used in supramolecular Chemistry as bridges for load transfer. This is the first time that they are used in small molecule OLEDs. The second part deals with OLEDs based on dipyridamole (2; 6-bis(diethanolamino) - 4; 8 - dipiperidinopyrimido (5; 4-d)pyrimidine) (DIP) molecule, which is a very well known anti-platelet drug thoroughly used in the treatment of hearth diseases that for possessing an intense fluorescence woke up our curiosity in order to investigate the possibility of its use as electroluminescent layer. The use of DIP as electroluminescent layer resulted in a particular OLED with the highest luminance of the investigated devices, about 1500 cd/m2. Finally, the third part involves OLEDs that use calixarenes molecules [Al . 1]3+ and [Zn . 1] 2+ (1 = 8- oxyquinolinecalix[4]arene) as electroluminescent and electron transporting layer. In this work were studied two calixarenes systems: the first system is coordinated with aluminum (calix[Al]3+) and the second one is coordinated with zinc (calix[Zn]2+). The first one presented an interesting cooperation property among the central calix ring and the quinolina group coordinated with the Al metal. Using this synergic mechanism we were able to produce a tunable OLED, which electroluminescent emission varies continuously from 510 nm to 446 nm as a function of the applied bias voltage. All the organic compounds used in this work were analyzed from a thermal point of view through a Differential Scanning Calorimetry (DSC), in order to determine their transition glass temperature (Tg). By using electrochemistry measurements it was possible to establish a systematic and simple experimental procedure to determine the HOMO (highest occupied molecular orbital) energy levels of the organic materials studied in the form of films. Finally, through the electrical characterization it was possible to determine the type of carrier injection that governs the fabricated devices as well as the model that controls the carrier transport inside the OLEDs.