Fast and accurate prediction of certain properties from a given structure, as well as pinpointing key factors influencing particular properties, is crucial for the targeted design of new compounds with desired properties or crystal phase compositions. In the current work, a total of 2,419,200 Gaussian-type structure descriptors (GTSDs) were utilized as a bridge to establish artificial neural network (ANN) potential models between 1400 titanium dioxide (TiO2) structures and their corresponding system energies and band gaps. After training, the ANN showed high accuracy in predicting energy, with Rtrain of 0.985, Rtest of 0.967, and RMSE of 0.0489. However, for the band gap values with intense data fluctuation, the Rtrain, Rtest, and RMSE changed to 0.864, 0.832, and 0.1304, respectively, indicating that the ANN's predictive ability for drastically changing data is limited. Compared with ab initio calculations, using ANN model can increase the calculation speed by 4–6 orders of magnitude. Furthermore, we identified the most significant features affecting the system energy and band gap values as the shape and distortion of [TiOx] polyhedra through the random forest model. Our work aims to provide a new toolkit and research ideas for accelerating the development of new materials.