We propose to map focal motor to bilateral tonic-clonic seizures (FMBSs), which are the most dangerous epileptic seizures. These seizures increase the risk of sudden unexpected death in epilepsy (SUDEP) and lead to fractures and dislocations due to violent falls. SUDEP is the most common cause of death in patients with epilepsy. We propose that the canonical circuit published in Kandel's Principles of Neural Science (2013), which posits that focal seizures engage diencephalic thalamocortical circuits, which leads to secondarily generalized tonic-clonic seizures is too simplistic. It is not consistent with known neuroanatomy of the motor cortex, and modulation of seizures by subcortical structures. We propose that FMBSs originating in the frontal cortex spread through the striatum to the globus pallidus, substantia nigra and thalamus via the indirect pathway, in addition to spreading directly to the thalamus .. We test this hypothesis in three aims. Aim 1: to map FMBS spread at the mesoscale and compare it to anatomical connections of the seizure focus in TRAP mice using tissue clearing and 3D imaging combined with tract tracing and electrophysiological techniques). Aim 2 to map FMBS spread at the microscopic scale through the cortex and direct and indirect basal ganglia circuits in TRAP mice using immunohistochemistry. In aim 3, we will study dopamine type 2 receptor modulation of seizures at the mesoscale and microcircuit levels using a combination of techniques. We incorporated tools and techniques developed by the BRAIN initiative in our laboratory to move seizure circuit mapping research forward. We have used TRAP mice, the CLARITY technique, high resolution, high-throughput imaging, and 3D reconstruction of images to visualize activated neuronal pathways. We have constructed a highly collaborative team with expertise in anatomy, electrophysiology and computer science of imaging, which allows us to generate and analyze large volumes of data and build on each other's creativity. We have acquired sufficient equipment to perform these studies. These studies will generate new targets for the modulation of seizures by deep brain stimulation. Currently, this method is used for anterior thalamic stimulation and responsive neurostimulation, but in the future, multiple subcortical structures could sites for neuromodulation. Receptors and ion channels known to modulate basal ganglia circuits may emerge as novel targets for anticonvulsant development. If our studies confirm seizure passage through the striatum, then ii would be important to understand the underlying cellular mechanisms.