ABSTRACT Roughly 10% of births in the United States are premature and typically involve a stay in the Neonatal Intensive Care Unit (NICU), where infants endure painful procedures and periods of separation from their primary caregiver. Premature births often occur in low socioeconomic status (SES) families. The NICU experience has lasting effects on the brain and behavior, including increasing the risk of later developing substance use disorder (SUD). This R34 will support the design of a better rat model of the NICU to begin to delineate mechanisms by which this early adverse experience affects motivated behavior and the medial prefrontal cortex (mPFC), a key node in the reward network that is affected by other early stressors. Manipulations of early pain are typically used to model the NICU, but here we will include other aspects of the NICU experience by combining early pain with socioenvironmental factors associated with premature birth: resource scarcity and separation from the primary caregiver. A feature of the planned activities is a focus on translation: testing developmentally appropriate motivated behaviors that occur cross-species, leveraging human imaging data to inform rat imaging studies, and utilizing an external advisory committee to get input from a range of experts, including those who study prenatal stress and early pain in humans. Aim 1 will first engage our advisory committee to optimize our proposed design of the NICU model. Then, using a longitudinal design, we will determine the effects of early pain vs. the NICU model (combined pain, low resources, and separation) vs. control conditions in male and female rats on social behavior across development: juvenile play and social motivation in adolescents and adults. Given many people begin experimenting with drugs by first using cannabis in adolescence, we will next develop an adolescent tetrahydrocannabinol (THC) gummy self-administration procedure and begin to test if early pain and/or the NICU model increases adolescent cannabis motivation compared to controls. Aim 2 will investigate how the NICU model affects the cortical structure. We will leverage existing human neuroimaging data sets by assessing how relevant variables (preterm birth, low SES) affect human cortical structure to guide our rat imaging study design. Next, rat diffusion tensor imaging and 3D structural MRI will be used to assess changes in cortical structure in juvenile, adolescent, and adult males and females following early pain, the NICU model, or control rearing in a longitudinal design. Finally, we will engage in a hypothesis-generating activity by assessing DNA methylation in the mPFC in adolescent rats following our early manipulations using cutting-edge long-read native DNA sequencing for simultaneous profiling of 5mC, 5hmC, and 6mA in the same sample. This will reveal putative mechanisms by which the NICU experience can have lasting consequences on mPFC development to be tested in a subsequent R01. ...