Lactone and carboxylate forms of potent antitumor agents, camptothecins (CPTs) have been studied by Raman, Fourier-transform Raman (FT-Raman) and surface-enhanced Raman scattering (SERS) spectroscopy. Similarity of the Raman spectra of CPTs with corresponding FT-Raman spectra in the near-infrared allowed the latter to be compared with their SERS counterparts in order to analyse the interaction of the drugs with silver colloids. Different types of silver colloids (reduced with sodium borohydride or sodium citrate, with or without activation by anions) have been evaluated. Citrate-reduced colloid, activated with chloride anions (CAS) has been found to be the best compromise for SERS studies of both forms of CPTs. We suggest that in general CPTs are adsorbed on CAS via the nitrogen in ring B and are more inclined to a flat orientation than to a perpendicular one. However, probable interactions of substitution groups and/or of the COO- groups of hydrolysed CPTs with the CAS surface introduce some particularities in the adsorption patterns. As a result, SERS spectra are highly sensitive to hydrolysis and substitutions at distant rings of CPT and uniquely characteristic of each of the CPT derivatives. The pronounced hydrolysis-induced changes, similar in the Raman and SERS spectra of CPTs, involve similar vibrations in the spectra of different CPTs. Vibrational assignments, proposed for the main Raman and SERS bands of CPT and its derivatives (21-lactam-S-CPT, 10,11-(methylenedioxy)-CPT, CPT-11, SN-38 and topotecan) indicate that most of the bands which decreased upon lactone hydrolysis are those preferentially related to stretching modes of the quinoline rings A and B, and the bands which increased are those of the ring D stretching modes. Our data make the spectroscopic approach very promising for the further investigations of the molecular mechanisms of biological activity of CPTs.