Understanding the rheological properties of the continental lower crust (CLC), particularly its response to water, is vital for comprehending various geodynamic processes within the Earth. In this study, two groups of clinopyroxene–plagioclase aggregates, which serve as representative samples of the CLC, were hot pressed in a Paterson gas-medium apparatus with “as is” and additional water. Subsequently, deformation tests were conducted on the hot-pressed samples in the same apparatus, under a confining pressure of 300 MPa, temperature of 1,173–1,423 K, and strain rates of 6 × 10−6 to 2 × 10−4 s−1. Mechanical data revealed that axial stresses between 15–464 MPa and total accumulated finite strain values between 12%–20%. The resulting mechanical data were analyzed and fitted to a flow law, yielding a stress exponent (n) of 3.6±0.6 and activation energy (Q) of 504±85 kJ/mol for the “as is” samples, and n = 3.7±1.4 and Q = 347±48 kJ/mol for water-added samples. Microstructural observations revealed that the deformed samples exhibited a shapepreferred orientation (SPO) and crystallographic preferred orientation (CPO) with subgrain boundaries in coarse-grained domains (constituting ~80 vol%), indicating that the primary deformation mechanism is dislocation creep. Additionally, the presence of melt, neoformed phases (olivine + orthopyroxene) and abundant fine-grained particles (