Solid-state NMR has been demonstrated as a powerful technique in the investigation of detailed molecular information and chemical identification. Thus, it is widely used in biomineralization studies of samples such as bone, enamel, dentin, and cartilage. In this work, we focus on the identification of the structure and composition of the teeth of Alopias superciliosus, a thresher shark, using various solid-state NMR strategies. The Alopias superciliosus teeth samples came in several rows with distinguishable size and morphology, and these dental series comprise teeth that evolved from nascent to mature in embryotic development. Samples of separate rows and sizes were characterized individually for their chemical compositions. The aim of this work is to identify chemical species and their role in the growth of shark’s teeth. With the help of model compounds, hydroxyapatite (Ca10(PO4)6(OH)2, HAp), fluorohydroxyapatite (Ca10(PO4)6(OH)2-xFx, FHAp), and CaF2 were identified in the 1D and 2D solid-state NMR spectra of the teeth samples. These data can provide essential information for a better understanding of the biomineralization of vertebrate teeth at the molecular level. Chapter 1 and 2 provide the background knowledge of this work. In Chapter 3, a complete layout of the chemicals used for solid-state NMR measurement is provided. Synthetic model compounds such as FHAp are characterized with the listed instruments. In Chapter 4, the solid-state NMR spectra of the teeth samples are assigned by 2D HETCOR and the spatial relationships among biominerals species are clarified. Analyses of cross polarization kinetics and peak deconvolution reveal the variation trend of the chemical species of shark teeth at different growth stages. The CaF2-like species, identified in the teeth samples by solid-state NMR but not XRD, is thought to reside in the amorphous phase that constitutes a large portion in teeth at early growth stage. The different amount of hydroxyapatite, fluorapatite, and fluorohydroxyapatite in nascent and mature teeth shed light on the mineralization kinetics and the mechanism of shark teeth development.