We present TIPSy-GAN, a new approach to improve the accuracy and stability in unsupervised adversarial 2D to 3D human pose estimation. In our work we demonstrate that the human kinematic skeleton should not be assumed as one spatially codependent structure. In fact, we believe when a full 2D pose is provided during training, there is an inherent bias learned where the 3D coordinate of a keypoint is spatially codependent on the 2D locations of all other keypoints. To investigate our theory we follow previous adversarial approaches but train two generators on spatially independent parts of the kinematic skeleton, the torso and the legs. We find that improving the 2D reprojection self-consistency cycle is key to lowering the evaluation error and therefore introduce new consistency constraints during training. A TIPSy is produced model via knowledge distillation from these generators which can predict the 3D coordinates for the entire 2D pose with improved results. Furthermore, we address the question left unanswered in prior work detailing how long to train for a truly unsupervised scenario. We show that two independent generators training adversarially has improved stability than that of a solo generator which will collapse due to the adversarial network becoming unstable. TIPSy decreases the average error by 18% when compared to that of a baseline solo generator. TIPSy improves upon other unsupervised approaches while also performing strongly against supervised and weakly-supervised approaches during evaluation on both the Human3.6M and MPI-INF-3DHP dataset.