The matrix-assisted laser desorption/ionization in-source decay (MALDI-ISD) of peptides and glycans was studied using an oxidizing chemical, 5-nitrosalicylic acid (5-NSA) as the matrix. The use of 5-NSA for the MALDI-ISD of peptides and glycans promoted fragmentation pathways involving “hydrogen-deficient” radical precursors. Hydrogen abstraction from peptides resulted in the production of a “hydrogen-deficient” peptide radical that contained a radical site on the amide nitrogen in the peptide backbone with subsequent radical-induced cleavage at the C_α–C bonds. Cleavage at the C_α–C bond leads to the production of an a^•/x fragment pair and the radical a^• ions then undergo further hydrogen abstraction to form a ions after C_α–C bond cleavage. Since the Pro residue does not contain a nitrogen-centered radical site, C_α–C bond cleavage does not occur at this site. Alternatively, the specific cleavage of CO−N bonds leads to a b^•/y fragment pair at Xxx−Pro which occurs via hydrogen abstraction from the C_α−H in the Pro residue. In contrast, “hydrogen-deficient” glycan radicals were generated by hydrogen abstraction from hydroxyl groups in glycans. Both glycosidic and cross-ring cleavages occurred as the result of the degradation of “hydrogen-deficient” glycan radicals. Cross-ring cleavage ions are potentially useful in linkage analysis, one of the most critical steps in the characterization of glycans. Moreover, isobaric glycans could be distinguished by structure specific ISD ions, and the molar ratio of glycan isomers in a mixture can be estimated from their fragment ions abundance ratios. MALDI-ISD with 5-NSA could be a useful method for the sequencing of peptides including the location of post-translational modifications, identification and semi-quantitative analysis of mixtures of glycan isomers.