When femtosecond laser pulses are focused into water, an impulsive force is generated that propagates from the laser focal point in a micron-sized space. This femtosecond laser-induced optical breakdown has been widely used as a promising technique for detaching and manipulating individual adherent cells, and insertion of nanoparticles and bio-molecules into cells. In early studies on the femtosecond laser application, most researchers have focused only on the induced physical behaviors, but rarely on chemical aspect of the behaviors such as generation of transient chemical species by the irradiation. The investigation of the chemical reactions on femtosecond laser-induced multiphoton absorption in solution is indispensable to confirm that these physical behaviors are realized without any chemical changes. In this work, gold and silver nanoparticle fabrication is chosen as a probe in order to confirm the generation of transient species such as ions and radicals by intense femtosecond laser irradiation, since the resultant metal nanoparticles shows these characteristic extinction spectra due to their surface plasmon. These nanoparticles are prepared by the multiphoton reduction of HAuCl4 and AgNO3 in the presence/absence of polyvinylpyrrolidone (PVP) and/or 1-propanol, and the formation of colloid formation is confirmed by the change in the extinction spectra. The laser energy dependence of gold nanoparticle formation strongly supports the reduction of HAuCl4 through 2-photon absorption of AuCl4-. On the other hand, for silver nanoparticle formation, the increase in the Δextinction is observed only in the presence of PVP, which indicates that the colloid formation is achieved through the 2-photon absorption of PVP. While, even in the absence of PVP, a little extinction change is observable. This result suggests that silver ions are reduced by hydroxyl and/or hydrogen radicals due to 4-photon absorption of water, that is due to femtosecond laser-induced optical breakdown. Thus, we successfully demonstrate multiphoton absorption of AuCl4-, PVP and H2O by femtosecond laser irradiation as a primary mechanism of gold and silver nanoparticle fabrication. Furthermore, we have succeeded in nanoparticle fabrication by laser ablation of nanoparticles formed by the reduction, and also succeeded in controlling the mean size and the size distribution by optimizing various kinds of experimental conditions. These successes will give us a novel guideline for the studies on femtosecond laser-induced phenomena.