10-year update to the combined 16-month nuclear medicine and diagnostic radiology residency: The NuRad pathway.

BACKGROUND: The decline in nuclear medicine (NM) residencies in the United States has led to a shortage of NM physicians. To help address this, a 16-month NM pathway for diagnostic radiology (DR) residents was developed in 2010. At the University of Arkansas for Medical Sciences, we matched our first resident into the NuRad (NM + DR) pathway in 2013. Despite our success, we remain one of only five programs in the United States that offers a combined training pathway through the National Resident Matching Program. OBJECTIVES: Review our 10-year experience with the NuRad pathway at UAMS and highlight the key components and significance of the 16-month NM pathway. METHODS: Retrospective review of NRMP applicants to the DR and NuRad pathway from 2013 and 2023 at UAMS. Literature and website review of the educational structure of the 16-month NM pathway. RESULTS: We have seen significant increase in the number of applicants to the NuRad pathway at UAMS over the last 10 years with 184 applicants for 1 position in 2023, up from 18 applicants in 2013. Furthermore, we have seen an increase in the USMLE step scores for applicants during this time. CONCLUSIONS: There is a growing need for NM trained physicians in the United States. Over the last 10 years, we have seen increasing interest in the NM 16-month pathway as a part of DR residency. A wider implementation of this combined training pathway is needed, if we are to realize its full potential.

Mother's physical activity during pregnancy and newborn's brain cortical development.

Background: Physical activity is known to improve mental health, and is regarded as safe and desirable for uncomplicated pregnancy. In this novel study, we aim to evaluate whether there are associations between maternal physical activity during pregnancy and neonatal brain cortical development. Methods: Forty-four mother/newborn dyads were included in this longitudinal study. Healthy pregnant women were recruited and their physical activity throughout pregnancy were documented using accelerometers worn for 3-7 days for each of the 6 time points at 4-10, ∼12, ∼18, ∼24, ∼30, and ∼36 weeks of pregnancy. Average daily total steps and daily total activity count as well as daily minutes spent in sedentary/light/moderate/vigorous activity modes were extracted from the accelerometers for each time point. At ∼2 weeks of postnatal age, their newborns underwent an MRI examination of the brain without sedation, and 3D T1-weighted brain structural images were post-processed by the iBEAT2.0 software utilizing advanced deep learning approaches. Cortical surface maps were reconstructed from the segmented brain images and parcellated to 34 regions in each brain hemisphere, and mean cortical thickness for each region was computed for partial correlation analyses with physical activity measures, with appropriate multiple comparison corrections and potential confounders controlled. Results: At 4-10 weeks of pregnancy, mother's daily total activity count positively correlated (FDR corrected P ≤ 0.05) with newborn's cortical thickness in the left caudal middle frontal gyrus (rho = 0.48, P = 0.04), right medial orbital frontal gyrus (rho = 0.48, P = 0.04), and right transverse temporal gyrus (rho = 0.48, P = 0.04); mother's daily time in moderate activity mode positively correlated with newborn's cortical thickness in the right transverse temporal gyrus (rho = 0.53, P = 0.03). At ∼24 weeks of pregnancy, mother's daily total activity count positively correlated (FDR corrected P ≤ 0.05) with newborn's cortical thickness in the left (rho = 0.56, P = 0.02) and right isthmus cingulate gyrus (rho = 0.50, P = 0.05). Conclusion: We identified significant relationships between physical activity in healthy pregnant women during the 1st and 2nd trimester and brain cortical development in newborns. Higher maternal physical activity level is associated with greater neonatal brain cortical thickness, presumably indicating better cortical development.