A new Raman spectroscopic technique has been refined to more efficiently previous termdetermine the crystallinitynext term indeces of previous termbiogenicnext term apatites. We investigate the possible relationships between the structure (previous termcrystallinity)next term and geochemistry (rare earth element (REE), δ18O) of previous termbiogenicnext term apatites. A selection of phosphatic remains dated from present to about 510 Ma (Late Cambrian), for most of which either the oxygen isotope compositions or REE patterns are available, has been characterized for previous termcrystallinitynext term using Raman spectroscopy. We define a new previous termcrystallinitynext term index (CIRaman) from the ratio of the full width at half maximum (FWHM) of the intense peak of the PO4 symmetric stretching mode in the sample and a reference magmatic apatite. In order to compare our previous termcrystallinitynext term index with CI previous termusednext term in previously published studies, we also analyzed part of our sample set with FT-IR spectroscopy and X-ray diffractometry. A detailed study of natural samples demonstrates that previous termcrystallinitynext term index is a poor criterion for determining if a sample has been altered since deposition. This result is based on three major observations: (1) independently of the CIRaman, the original geochemical signatures of the previous termbiogenicnext term apatites previous termcannext term be preserved over a long period, (2) strong geochemical perturbations (lowering of δ18O values and of La/Sm ratios) may occur without detectable recrystallization, and (3) previous termalterationnext term by heating, marked by the transformation of organic matter into graphite, produces REE fractionations and limited oxygen isotope exchange with crustal aqueous fluids.