In this thesis, femtosecond laser pulses, intrinsically with wide bandwidth and high peak power simultaneously, are utilized in frequency domain photon migration (FDPM) spectroscopy. First, the modulation frequency limit arising from traditional cw-modulated lasers in FDPM systems is break out by using the higher-order modulations of mode-locked laser pulses. Second, the restrictions on the operation wavelength in a single light source are utilized by a photonic crystal fiber (PCF) wavelength converter, where the excitation 1030 nm pulses are efficiently transformed toward the shorter and longer wavelength regimes via various fiber-nonlinear effects. The FDPM spectroscopy with GHz modulation bandwidth and a wide wavelength tunability in the 700 nm to 1030 nm were also demonstrated in the thesis. Finally, we also proposed and demonstrated a preliminary result that the SNR can be enhanced by increasing the pulse width through fiber dispersion. in biological tissue or sample.