Coccidioidomycosis, also known as Valley Fever (VF) is caused by the fungus Coccidioides. Pigtail macaques (PTMs) bred at the Washington National Primate Research Center (WaNPRC) in Mesa, AZ are naturally infected with Coccidioides and are similar to humans in their physiology, symptoms, and immune responses. Populations with a weakened immune system, notably older individuals, are at risk for severe complications from infection. Additionally, there is evidence that males have a higher incidence of VF than females in endemic areas. I characterized the immune responses in a PTM model across age and sex to better understand how VF affects the immune response of these populations. Forty-two PTMs (2.25-19.24 years, 3.66-18.29 kg, 37 female, 5 male) at the WaNPRC were sampled for blood. The frequencies of immune cell subsets in whole blood were characterized by flow cytometry and compared for significant differences based on age and sex. I analyzed sex-based differences with Brown-Forsythe and Welch ANOVA t-tests and found no statistically significant differences. For age-based differences, we used a simple linear regression to analyze differences by age in immune cell subsets. We found that old PTMs (10.07-19.24 years) have higher activation of CD8+ T cells, myeloid dendritic cells, intermediate monocytes, and higher frequency of γΔ T cells and CD4+ γΔ T cells than young PTMs (2.25-9.69 years). Young PTMs have a higher frequency of CD45+ granulocytes, PD-1 High CD8+ T cells, plasmacytoid dendritic cells, and NK cells. By correlating older PTMs with higher immune cell activation, and younger PTMs with higher immune cell frequency, we have a better understanding of how a vaccine or treatment could be developed to support older individuals, who are at greater risk of severe infection.

Vaccines have successfully reduced global infectious disease burden, but there is room to improve vaccination technologies. Because many pathogens infect at mucosal sites, a goal of new vaccines is to promote strong mucosal and systemic antibody and T-cell responses. Integrated fiber microneedle devices (iFMN) are a novel oral vaccination method that may achieve this goal. These devices are patches with a polymer backfill matrix and multiple >1 mm pyramidal needles that penetrate immune cell-rich mucosal tissue in the mouth, inducing immune responses at draining lymph nodes. To test the hypothesis that priming with iFMN delivery of a DNA vaccine increases mucosal and systemic antibody responses after systemic booster immunization with the same vaccine, male rhesus macaques (n=6) were primed with an iFMN delivery of a DNA vaccine encoding Influenza A Virus (IAV) Nucleoprotein (NP) at weeks (0) and (6). The macaques then received a single boost of the same NP DNA vaccine at week (12) using the proven delivery modality of Gene Gun epidermal delivery (GG). Mucosal secretions (including bronchoalveolar lavage, saliva, and nasal/tracheal swabs) and serum were collected 2-4 weeks before and after each immunization. I conducted enzyme-linked immunosorbent assays (ELISAs) to quantify antigen-specific IgG and IgA binding antibody at each timepoint. To characterize the priming effect of iFMN oral delivery on systemic and mucosal antibody responses, I compared these animals’ responses to macaques (n=8) previously immunized with a single GG dose of the same NP DNA vaccine. The iFMN-primed animals had robust post-GG boost NP-specific IgG responses in serum but these responses were not significantly higher than for macaques boosted solely with GG DNA. These results demonstrate that iFMN delivery did not effectively prime for robust systemic and mucosal antibody responses. Additional experiments will be done to confirm these findings.

Flying insect robots (FIRs), owing to their minuscule weight and size, offer unparalleled advantages in terms of material cost and scalability. However, their size introduces control hurdles, notably high-speed dynamics, restricted power, and payload capacities. While there have been notable advancements in developing lightweight sensors, often drawing inspiration from biological systems, the challenge remains in executing controlled flight without external feedback. We introduce Tiny Sense, a novel avionics system tailored for FIRs, encompassing an integrated sensor package — an inertial measurement unit, a pressure sensor, and an optical flow sensor. Coupled with a Kalman Filter (KF), this system weighs a mere 78.4 mg, drawing 15 mW of power. This is lighter and more power-efficient than previous sensor suites of the same capabilities. Our system uses a global-shutter camera as an optical flow sensor to collect pixel intensities for accurate optical flow calculations at 100 Hz. We collected raw data from the Tiny Sense by attaching it to a Crazyflie quadcopter and tested the KF by comparing its results to the measurements from the Crazyflie. We will continue to integrate the Tiny Sense with sub-gram FIRs and are currently working on mounting it to a 74-mg RoboFly. Our sensor suite allows even smaller FIRs to be able to achieve autonomous control.