The high spatial resolution and motion sensitivity of optical-based shear wave detection have made it an attractive technique in biomechanics studies with potential for improving the capabilities of ultrasound-based shear wave elasticity imaging. In this research, a laser speckle contrast shear wave imaging system was developed. The estimation of shear wave speed is based on the detection of the local blurring of the optical speckle pattern resulting from the mechanical disturbances induced by shear wave propagation. In two-dimensional (2D) imaging, the developed system can estimate the shear wave speed with an error of less than 6% on homogeneous phantoms with shear moduli ranging from 1.52 kPa to 7.99 kPa. The standard deviation of shear modulus estimation was less than 0.07 kPa and motion sensitivity of better than 0.6 µm/ms was demonstrated. In three-dimensional (3D) imaging, two system setups were devised. The first setup performed plane-by-plane 2D reconstruction of the shear wave speed maps at different positions by linearly translating the sample. The second setup, on the other hand, performed tomographic reconstruction of the shear wave wavefront by rotating the ultrasound transducer used for the induction of shear waves. The second setup has the advantage of multi-directional shear wave speed estimation in the radial direction. Thus, it can be beneficial for evaluating the elasticity of an anisotropic sample. The systems exhibit submillimeter spatial resolution in all three dimensions. Due to the limited depth-of-field and motion sensitivity (in the presence of static scatterers), the effective imaging depth along optical axis (Y direction) is approximately 6.25 mm. The applicability of the developed systems for in vitro mechanobiology study with 3D cancer cell culture systems is also explored. The shear wave speed measured for the cell culture sample was found to be strongly correlated with the extracellular matrix fiber density in two types of cell culture system (r=0.832 with P<0.001, and r=0.642 with P=0.024 for cell culture systems containing 4 mg/ml Matrigel with 1 mg/ml and 2 mg/ml collagen type I hydrogel, respectively). Cell migration along the stiffness gradient in the cell culture system as well as an association between cell proliferation and the stiffness of the local extracellular matrix was also observed. As the elasticity measurements can be performed without the need of exogenous probes, the developed system can be used to assist the study on how the microenvironmental stiffness interacts with cancer cell behaviors without possible adverse effects of the exogenous particles. In addition, providing information on the dynamics of the cell microenvironmental stiffness in a scale closer to the in vivo scenario may increase the understanding of the mechanism of the complex matrix remodeling occurs during cancer progression, which may lead to the improvements in cancer treatment strategies.