The most commonly used stationary/mobile phase solvent systems in counter-current chromatography (CCC) are organic-water systems. However, we employed surfactant-modified solvent systems in CCC separations. In the first part of this thesis, an n-hexane/surfactant -containing water solvent system was developed to separate a steroid sample. Retention times of steroids increased slightly by increasing the sodium 1-heptanesulfonate (SHS) concentration below the critical micellar concentration. However, the retention times increased drastically while the SHS concentrations were above the CMC. Aromatic hydrocarbons were not retained by the stationary phase no matter what the surfactant concentrations were. The retention times of esters, however, were only slightly affected by the surfactant addition even above the CMC. The micellar solvent systems provide an alternative way for hydrophobic sample separations in CCC In the second part, a protein mixture consisting of myoglobin, cytochrome c, and lysozyme was separated by CCC using a two-phase aqueous/AOT reverse micelle-containing organic solvent system. Separations were manipulated mainly by pH gradients and incorporating an ionic strength gradient along with the pH gradient. The recovery of cytochrome c and lysozyme reached 90% and 82%. Furthermore, concentration or enrichment of these two proteins was achieved from a large-volume sample load. This technique can potentially be employed in the recovery and enrichment of proteins from large-volume aqueous solutions. In the third part, size separation of silver nanoparticles was investigated in CCC based on a continuous extraction process. The aqueous nanoparticles were readily transferred to the organic phase (toluene/hexane = 1:1, v/v) together with the phase transfer catalyst, tetraoctylammonium bromide (TOAB), owing to the ion-pair adduct formation between silver nanoparticle anions and tetraoctylammonium cations. Smaller nanoparticles were found to be more readily transferred to the organic phase compared to larger nanoparticles. It appeared that a concentration of 0.02 mM TOAB was adequate to achieve optimum separation and recovery for the aqueous Ag nanoparticle sample. Samples of 15.8 ± 5.3 nm were separated; the distributions of four fractions collected were 13.7 ± 1.9, 14.1 ± 3.5, 19.2 ± 4.3, and 22.2 ± 4.9 nm. Compared with the stepwise extraction performed in this study, the step-gradient extractions using CCC provided much better size discrimination. In the last part of this thesis, the dispersion behavior of solutes was investigated in a rotating flowing coiled tube. Silver nanoparticles, bovine serum albumin, lysozyme, ascorbic acid, tartrazine, and potassium iodide samples were eluted in a coiled tube of counter-current chromatography (CCC) apparatus with a single phase. Apparent convection peaks of low-diffusivity solutes appeared in the static CCC tube, while Gaussian-like peaks showed up for the high-diffusivity solutes. When the rotation speed of the CCC apparatus was elevated, all solute peak widths became smaller, and the convection peaks of silver nanoparticles and BSA were minimized and formed Gaussian-like peaks. We studied the effect of rotating to the theoretical plate of the signals. The same reasoning could also be used to rationalize other special band shapes encountered in two-phase CCC separations