3D printing technique shows great promises for fabricating customized structural scaffolds for tissue regeneration. Using hydrogel as bioink for cell printing provides a biological platform for basic research and potential medical treatment. In this study, the waterborne dispersions of poly(ε-caprolactone) (PCL)-based biodegradable polyurethane (PU) nanoparticles were prepared. The sol-gel transition of the PU dispersions affected by temperature or electrolytes was examined by dynamic light scattering (DLS), small angle X-ray scattering (SAXS), X-ray diffraction (XRD), and rheology. The dispersion of PU nanoparticles with 20 mol% poly (L-lactide) (PLLA) diol or poly (D,L-lactide) (PDLLA) diol and 80 mol% PCL diol in soft segement composition could form compact packing structure at temperatures ≥37°C. The dispersion of PU with PLLA-PCL soft segment was more responsive to the temperature increase, while that with PDLLA-PCL soft segment was more responsive to the added electrolytes. With thermally-responsive properties, both PU dispersions could gel in 3 min with the gel modulus increased to about 6-8 kPa after 30 min. PU hydrogels were preheated and blended with cells, and the mixture was later printed at 37°C. The hybrid hydrogel of PU and soy protein isolate (PU/SPI hybrid) was further developed to enhance the structural integrity of the cell-laden constructs during deposition. The viscosity of the PU/SPI hybrid was lower than that of PU gel, but could undergo rapid gelation at 37°C with modulus increased to 130 Pa in 1 min. Moreover, the PU/SPI hybrid gel may be directly mixed with cells at room temperature and subsequently printed at 37°C without preheating. Cells cultured in the PU/SPI hybrid gel for 48 h proliferated faster than those in PU gel. The hybrid gel made of thermoresponsive PU and SPI may be a new type of bioink for 3D biopriniting applications.