Optical coherence tomography (OCT) is one of the widely used biomedical imaging techniques, which can provide two-dimensional cross-section images for many clinical applications. An OCT system is based on an optical interferometer. The longitudinal resolution depends on the bandwidth of the light source used in the OCT system. Use of a broadband light source can lead to the longitudinal resolution down to a few microns. The scanning speed of OCT system is another advantageous issue for its application. The development of the technique of spectral–domain OCT improves significantly the OCT scanning speed. In this dissertation, we first propose a software dispersion compensation method to eliminate the dispersion mismatch in an OCT system. By combining the multiple scans, dispersion mismatch can be dynamically adjusted for different applications. Second, we demonstrate a method for improving the OCT resolution. The resolution enhancement originates from the superposition of several longitudinal scans with different phase modulation speeds. Third, a high-resolution spectral-domain OCT system is demonstrated. In the spectral-domain OCT system, the resolution is improved by using a broadband light source generate from the nonlinear optics effects in a high numerical-aperture fiber. By fast sweeping the spectrum, a fast-scanning and high-resolution OCT system can be achieved. Next, the hemoglobin oxygen saturation level is measured by a spectroscopic spectral-domain OCT system. Hemoglobin oxygen saturation level can be obtained by comparing the A-mode scan profiles between the wavelength ranges shorter and longer than 800 nm. This technique has the potential for high-resolution in vivo haemoglobin oxygen saturation level monitoring.