Vital fluorescent dyes (FITC-albumin, Texas Red-albumin, and acridine orange) were used together with a confocal laser scanning optical microscope (CLSM) to display and analyze formation, movement, and fusion of vesicles during the phagocytosis of Paramecium primaurelia, in the x-y-z-t space. By immobilizing living cells pulsed with a food vacuole marker at successive times after chasing in unlabeled medium, the intracellular movement of food vacuoles from their formation at the cytostome to their egestion at the cytoproct was visualized, and food vacuoles were selected in a specific digestion stage. Small pinocytic vesicles are shown to evaginate from the vacuoles and move in the cytoplasm. These vesicles are transported toward the cytopharynx where they enlarge the membrane of the nascent food vacuoles or fuse with stage II food vacuoles, when the vacuoles of stage II increase their size, changing from an acidic to an alkaline status. A multimodal analysis of confocal fluorescence images and the false-color technique were used to visualize vesicle movement vs. time. Starting from three images of the same cell at succeeding time points, a composite image was generated by associating with each originally acquired image a different color corresponding to each sampling point in time. The composite image shows that vesicles move away from the food vacuole in a scattered manner exhibiting changes in direction.