563, 605 cm−1[34] and two slight sh

563, 605 cm−1[34] and two slight shoulders at 958 and 1105 cm−1are observed. At 1655 cm−1, a band characteristic of (Amide I:C O) function appears at the expense of the disappearance ofthe band at 1568 cm−1. Furthermore, the bands correspondingto (Amide:  N H) chemical bond at 645 and 620 cm−1disap-pear, ditto to the band at 522 cm−1characteristic of the symmetricSi O Si stretching bond.The bands characteristics of P O bonds of hydroxyapatite for2CH-1BG scaffolds are more intense and are characteristics of abetter crystallization. This confirms the hypothesis of the resultsobtained by XRD.These results confirm the bioactive character of scaffolds. ICP-OES analyses were performed to measure the ionic exchangesbetween scaffolds and SBF and to understand the mechanism ofbioactivity.After immersion in the SBF solution, SEM micrographs (Fig. 8) donot reveal the layer of hydroxyapatite. However, modifications ofsurfaces are observed. They present a creamy aspect after immer-sion. The glass grains, present on the surface, have disappeared. Thecoated glass grains are more visible because the chitosan matrix istorn by location. The hydroxyapatite, detected by XRD and FTIR, isnot observed. It may be that it has formed inside the material underthe chitosan matrix.The chemical elements Si, Ca and P have been carefully selectedfor quantitative analyses by ICP-OES. This physical method presentsa high sensitivity and allows having the kinetic of bioactivity.Indeed, silicon is an indicator of the dissolution of bioactive glasswhile calcium and phosphorus help to understand the formationof calcium phosphate [35,36]. These chemical elements were mea-sured in the SBF solution at different periods (2, 4, 8 and 16 h and1, 2, 7, 15 and 30 days)