Various modern technologies facilitate chemical analysis. They often enable automation and miniaturization of conventional chemical assays. We have developed two analytical methods which address some of the persisting challenges of analytical chemistry. In the first study, we constructed a system incorporating a robotic arm and electronic control units to pre-treat and deliver samples for mass spectrometric analysis. It identifies the sample, adds a reagent, incubates the reactants, and transfers the reaction mixture to the ion source of an ion-trap mass spectrometer. The whole analysis sequence has been programmed in C language. In order to enable precise control of movements of the robotic arm, the momentary position of the arm was verified based on the signals received from a number of sensors. We applied this automated device in the monitoring of glutathione oxidation in real time. The device has been made of low-cost materials. Hence, it can readily be replicated. In the second study, we developed an analytical method that takes advantage of the fusion of aqueous droplets in a non-polar (oil) matrix to trigger chemical reactions. Microliter or sub-microliter droplets are pipetted nearby into the oil, and they spontaneously fuse initiating the reaction. Optical detection of the reaction product is conducted using the smartphone built-in camera. Using LED light source, colorimetric, spectrophotometric and fluorimetric detection was possible. Chemiluminescence detection was achieved in the absence of light source. The LODs obtained with colorimetric, fluorimetric and chemiluminescence detection are 1.19 mM (potassium permanganate), 1.37 μM (fluorescein), and 112 nM (sodium hypochlorite), respectively. The proposed method enables analysis of low-volume samples a low cost. It can be applied to chemical reactions which generate chromophoric, fluorogenic or chemiluminescent products or intermediates. To conclude, using a range of widely available inexpensive electronic modules, and other pieces of equipment, it is possible to develop automated and miniaturized analytical assays with mass spectrometric or optical detection.