Cell adhesion is crucial to cell behaviors including survival, growth and differentiation. Self-assembled monolayers (SAMs) provide a convenient and versatile means of modifying surface properties to study how environmental cues affect the cell adhesion process. Serial ζ-potential surfaces can be realized by introducing various ratios of oppositely charged functional groups on a gold surface. Static cell density, morphology and proliferation for NIH3T3 fibroblasts and HEK293T epithelial cells on these serial surfaces have been investigated. These two kinds of cells showed the same tendency in cell densities but different morphological responses to the ζ-potential value. Quartz crystal microbalance with dissipation monitoring (QCM-D) has advantages for examining real-time viscoelastic changes on surfaces. This surface-sensitive technique can be applied in cell adhesion studies to investigate the cell-surface interactions. Combining an optical microscope with the QCM-D system, in situ and real-time cell morphology and corresponding viscoelastic changes can be obtained. In this work, cell-surface, extracellular matrix (ECM)-surface and cell-ECM interaction for NIH3T3 and HEK293T cells on these serial ζ-potential surfaces were examined. The effect of ζ-potential on focal adhesion was also characterized by immunostaining. For NIH3T3 cells, the morphological results indicated that cells were prone to spread on surfaces of more positive potential, while more negative potentials led to more cell movement on the surface. When cells adhered on more positive charge surfaces, soft and elastic cell bodies with less ECM layer on the surfaces can be sensed by QCM-D. Cells adhere to the surface and spread more quickly owing to electrostatic attraction. The shift in resonant frequency and energy dissipation of the quartz substrate can be described using a film resonance model, and a single-phase adhesion process was observed. On the other hand, for surfaces of more negative potential, round cells were observed and behave similar to coupled oscillators on the QCM-D sensor. Furthermore, three phases were observed during the cell adhesion process. Initially, round cells interact with the surface weakly with a point contact due to the repulsive interaction between negatively charged cell membranes and the surface. For higher magnitude of surface charge, more rigid ECM was deposited on the surfaces in the second phase. Finally, cells then adhered on the surface through the ECM layer. In other words, the mechanism of cell adhesion changed from an electrostatic cell-surface interaction to a cell-ECM-surface composite. For HEK293T cells, cells were also prone to spread and form more focal adhesion sites on surfaces with more positive charge (more NH2 groups) but aggregated and remained highly mobile on surfaces with more negative charge (more COOH groups). On NH2-rich surfaces, cells underwent three-phase kinetics during the adhesion process. Initially, for attractive interaction between NH2 groups and cell membrane, cells adhered and spread quickly on the NH2-rich surfaces with less ECM sensed. The epithelial cells then shrank their filopodia in the second phase to normalize their size. In the final phase, cells underwent ECM remodeling and formed matured ECM. On COOH-rich surfaces, four phases were identified during the cell adhesion process. Initially, due to electrostatic repulsion between the negatively charged cell membrane and surfaces, direct cell adhesion and spreading were restricted. However, ECM was quickly deposited. In the second phase, cells adhered on and interacted with the surface through the ECM layer. In the third phase, cells underwent ECM remodeling, and additional ECM was deposited on the surfaces. Finally, instead of cell-surface interactions, the cells aggregated to form cell-cell junctions. From the dynamic observation, it has been known that these charged surfaces had electrostatic influence on adhesion mechanism of HEK293T epithelial and NIH3T3 fibroblast cells. However, the ECM-associated adhesion mechanisms were still not clear. Cell secreted matrices (CSM), where extracellular matrix proteins (ECM) deposited by monolayer cells, can help us to understand cell-ECM interactions and find the cues of the cell fate on material surfaces. The composition and the morphology of CSM were examined to investigate the effect of surface charge on epithelial and fibroblast cells adhering on these SAM-modified surfaces. After incubation, cells were removed and time-of-flight secondary ion mass spectrometry (ToF-SIMS) was used to generate spectra for each CSM surfaces. Principle component analysis (PCA) was used to extract the extract the trend of similarly between CSM and referential ECM proteins. Immuno-stained cellular images visualize ECM secreting activities and the same staining method was also applied on decellularized CSM sample to verify ToF-SIMS results. For epithelial cells, surface charge has minor effect in morphology and CSM composition in adhesion phase. Although CSM compositions were similar in proliferation phase, the discontinuity of CSM allowed the surface charge affect the cells adhere as monolayer on NH2 surface while aggregate on COOH surface. For fibroblast cells, surface charge affect cells distribute ECM proteins more localized around nuclei on NH2 surface and uniformly on COOH surfaces in adhesion and proliferation phase. In adhesion phase, higher laminin loading was found in CSM composition on COOH surface than on NH2 surface to alleviate effect of surface charge. However, CSM compositions were surface independent after addition incubation time.