Recent studies showed that presence of fluoride (F) in hydroxyapatite enhanced bone formation. There have been no previous reports on calcium phosphate cements (CPC) capable of forming fluorapatite (FA) as a product. Objective: To study the properties of FA-forming CPC. Materials and Methods: Various amounts of NaF powder was added to a conventional CPC powder consisting of equimolar amounts of tetracalcium phosphate (median size 17 µm) and dicalcium phosphate anhydrous (1.2 µm) to obtain F/Ca ratios of 0, 0.05, 0.10, 0.20 (stoichiometric ratio for FA) and 0.40. Samples for setting time (Gilmore needle method) and diametral tensile strength (DTS) measurements were prepared by mixing the cement powder with 0.5M phosphate (pH 5.6) solution at P/L=2.5. Porosity was determined from the dry weight of the set specimen. Results: The setting times (mean±standard deviation; n=4) of the FA-CPCs with F/Ca ratios of 0, 0.05, 0.10, 0.20 and 0.40 were (13.8±2.5, 8.3±1.3, 8.3±1.7, 8.8±1.0, and 31.5±2.4) min, respectively. The DTS were (8.4±1.1, 4.5±0.4, 2.0±0.1, 1.3±1.4, and 0.13±0.01) MPa, respectively. The porosities were (35.5±1.8, 36.6±2.0, 38.0±1.5, 42.4±1.0, and 49.7±0.9) vol%, respectively. Total F contents were (0, 0.71±0.02, 1.28±0.04, 1.97±0.04, and 3.82±0.10) mass%, respectively. Conclusions: FA can be formed as a product of CPC. ANOVA of the results showed significant (p<0.05) differences among the groups. The amounts of F incorporated into the CPC product increased with F/Ca ratio in the cement powder. F incorporation led to decreases in the setting time (except F/Ca ratio of 0.4) and DTS, but increases in the porosity (except F/Ca ratio of 0.05 and 0.10) and crystallinity of the apatitic product. Supported by NIDCR grant DE11789, ADAHF, Nihon University and NIST.