Stem cell research is one of the most fascinating areas of contemporary biology as stem cells are capable of dividing and self-renewing for long periods and have potential to give rise to any type of somatic cells. These unique properties allow us to generate specialized adult human cells for drug screening, as well as for replacing damaged tissue in cell therapy. However, either to produce a great deal of stem cells undifferentiated or to direct their differentiation into a specific cell lineage with high efficiency is still a challenge. Stem cell differentiation is influenced by a complex system, including ECM composition, medium additives (proteins or small molecules) and mechanical factors in the environment, etc. During the differentiation process, cell morphology is monitored on daily basis and gene/protein expression is checked at selected time points to certify the status of the progeny. It is useful if scientists can have thorough learning on the cell culture environment of differentiation process and, further, have control to make it favorable for the desired induction lineage. In this dissertation, the purpose is to develop three sensors, glucose, pH and oxygen sensors, for continuously monitoring the changes in the culture medium during stem cell differentiation process. The glucose, pH, and oxygen sensors have been made and are all nonenzymatic electrochemical sensors. The sensing materials of the glucose, pH and oxygen sensors are nanostructured Pt-Ir, IrO2-x, and nanostructured Pt, respectively. The sensitivities of the glucose, pH and oxygen sensors are 9.7 uA/cm2-mM, 68.5 mV/pH and 28.7 uA/cm2-1% oxygen tension, respectively. This dissertation explains the mechanism, the fabrication method and the characteristics of the three sensors’ functionality in each chapter.