The present work experimentally studied several relevant dynamic characteristics of gas-liquid intermittent flow through a horizontal pipe. All tests were performed in a test section formed by 50.8 mm internal diameter pipe using air and water as working fluids. The tests covered a region where the flow undergoes a complex transition from elongated bubble flow regime, characterized by long gas bubbles located near the top of the pipe, to the slug flow regime, characterized by a large amount of dispersed gas bubbles in the liquid slug and elongated bubbles with distorted shapes and fronts displaced from the top of the pipe. In this region there is a notable lack of experimental techniques capable of extracting quantitative information of the characteristic dynamic phenomena involved. A set of infrared optical switches was employed to obtain statistical information on liquid piston lengths and frequency, as well as the elongated bubble lengths. An extensive comparison of the data obtained with works available in the literature was performed, validating the experimental results and the technique employed. Also, a high frame rate camera with back illumination was employed to capture images of the nose and tail of gas bubbles. An innovative procedure for image processing was developed, allowing for the extraction of original quantitative information on the complex shapes of the bubble and its relationship with flow variables. Relevant information such as the lowering of the bubble nose as a result of competing gravitational and inertial forces could be verified and confirmed quantitatively seemingly for the first time.