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1. Toward Wearable MagnetoCardioGraphy (MCG) for Cognitive Workload Monitoring: Advancements in Sensor and Study Design

   https://doi.org/10.3390/s25154806  

   Kaiss, Ali; Yang, Jingzhen; Kiourti, Asimina (August 2025, Sensors)

   Despite cognitive workload (CW) being a critical metric in several applications, no technology exists to seamlessly and reliably quantify CW. Previously, we demonstrated the feasibility of a wearable MagnetoCardioGraphy (MCG) sensor to classify high vs. low CW based on MCG-derived heart rate variability (mHRV). However, our sensor was unable to address certain critical operational requirements, resulting in noisy signals, often to the point of being unusable. In addition, test conditions for the participants were not decoupled from motion (i.e., physical activity (PA)), raising questions as to whether the noted changes in mHRV were attributed to CW, PA, or both. This study reports software and hardware advancements to optimize the MCG data quality, and investigates whether changes in CW (in the absence of PA) can be reliably detected. Performance is validated for healthy adults (n = 10) performing three types of CW tasks (one for low CW and two for high CW to eliminate the memory effect). Results demonstrate the ability to retrieve MCG R-peaks throughout the recordings, as well as the ability to differentiate high vs. low CW in all cases, confirming that CW does modulate the mHRV. A paired Bonferroni t-test with significance α=0.01 confirms the hypothesis that an increase in CW decreases mHRV. Our findings lay the groundwork toward a seamless, practical, and low-cost sensor for monitoring CW. 

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2. Decoupling Cognitive Workload and Physical Motion Effects on Heart Rate Variability Using a Wearable Magnetocardiography Sensor

   Kaiss, Ali; Yang, Jingzhen; Kiourti, Asimina (May 2025, International Applied Computational Electromagnetics Society (ACES) Symposium)

   We have recently demonstrated a wearable MagnetoCardioGraphy (MCG) sensor capable of classifying high vs. low cognitive work, i.e., the amount of mental effort a person is exerting when performing a task during a given period of time. However, a major limitation of our previous work was the requirement to eliminate any type of motion for the participants. Here, we explore the effect of motion by employing three (3) different experimental setups, each with a different amount of physical motion and cognitive load exerted. To better understand the effect of motion, an inertial measurement unit (IMU) and a breathing rate sensor are employed in addition to the MCG sensor. Our results show that heart rate variability (HRV), demonstrated through the mean difference in duration between consecutive heartbeats, is at its highest when neither cognitive workload nor motion are exerted. HRV drops when the subject involves cognitive workload and motion. Our results pave the way for additional research in the field, with an utmost goal of catering to specific clinical applications. 

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3. Despite high objective numeracy, lower numeric confidence relates to worse financial and medical outcomes

   https://doi.org/10.1073/pnas.1903126116  

   Peters, Ellen; Tompkins, Mary Kate; Knoll, Melissa A.; Ardoin, Stacy P.; Shoots-Reinhard, Brittany; Meara, Alexa Simon (September 2019, Proceedings of the National Academy of Sciences)

   null (Ed.)

   People often laugh about being “no good at math.” Unrecognized, however, is that about one-third of American adults are likely too innumerate to operate effectively in financial and health environments. Two numeric competencies conceivably matter—objective numeracy (ability to “run the numbers” correctly; like literacy but with numbers) and numeric self-efficacy (confidence that provides engagement and persistence in numeric tasks). We reasoned, however, that attaining objective numeracy’s benefits should depend on numeric confidence. Specifically, among the more objectively numerate, having more numeric confidence (vs. less) should lead to better outcomes because they persist in numeric tasks and have the skills to support numeric success. Among the less objectively numerate, however, having more (vs. less) numeric confidence should hurt outcomes, as they also persist, but make unrecognized mistakes. Two studies were designed to test the generalizability of this hypothesized interaction. We report secondary analysis of financial outcomes in a diverse US dataset and primary analysis of disease activity among systemic lupus erythematosus patients. In both domains, best outcomes appeared to require numeric calculation skills and the persistence of numeric confidence. “Mismatched” individuals (high ability/low confidence or low ability/high confidence) experienced the worst outcomes. For example, among the most numerate patients, only 7% of the more numerically confident had predicted disease activity indicative of needing further treatment compared with 31% of high-numeracy/low-confidence patients and 44% of low-numeracy/high-confidence patients. Our work underscores that having 1 of these competencies (objective numeracy or numeric self-efficacy) does not guarantee superior outcomes. 

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4. Can early weaning calves of first-calf heifers improve long-term herd and financial performance in a vertically-integrated beef production system? A case-study application using system dynamics.

   https://doi.org/https://doi.org/10.15232/aas.2021-02235  

   Taylor, J.K. (March 2022, Applied animal science)

   Objectives: The objectives were to (a) evaluate whether marginal reproductive gains from early weaning (EW) calves of first-calf replacement heifers extend throughout the animal’s productive life and (b) compare via cost–benefit analysis EW with conventional weaning (CW) practices on a vertically integrated ranch in Florida, USA. Materials and Methods: A system dynamics model was developed to evaluate CW versus EW of calves from replacement heifers that calve in the first 21 or 42 d of the calving season. A combination of sensitivity analyses and deterministic management tests (EW vs. CW and 21- vs. 42-d calving seasons) were simulated and compared across a range of 18 production and financial metrics, including net present value, over the useful life of one generation of replacement heifers. We hypothesized that EW calves from replacement heifers would improve reproductive performance, resulting in greater total calves produced and, therefore, improved cow-calf and whole-system profitability. Results and Discussion: The 42-d calving criteria for EW created significant production and financial gains and outperformed the 21-d calving criteria. Counterintuitively, these gains did not arise in the cow-calf or feedyard segments (which saw financial declines) but in the stocker segment due to more efficient livestock gains facilitated by lower weaning weights of incoming calves. Sensitivity analyses corroborated these trade-offs. Feedyard sale price (i.e., value received for finished cattle) was the most influential factor influencing whole-system profitability. Implications and Applications: Trade-offs and incentives between enterprises may provide misleading feedback and mask changes that improve the system as a whole (e.g., EW reduced calf weaning weights and reinforced the reproductive performance pressure on management; gains at the stocker segment may mask EW benefits at the cow-calf level, making the cow-calf enterprise more reliant on short-term adjustments, a behavior known as “shifting the burden”). 

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5. Can Wearable Sensors Provide Accurate and Reliable 3D Tibiofemoral Angle Estimates during Dynamic Actions?

   https://doi.org/10.3390/s23146627  

   Ajdaroski, Mirel; Esquivel, Amanda (July 2023, Sensors)

   The ability to accurately measure tibiofemoral angles during various dynamic activities is of clinical interest. The purpose of this study was to determine if inertial measurement units (IMUs) can provide accurate and reliable angle estimates during dynamic actions. A tuned quaternion conversion (TQC) method tuned to dynamics actions was used to calculate Euler angles based on IMU data, and these calculated angles were compared to a motion capture system (our “gold” standard) and a commercially available sensor fusion algorithm. Nine healthy athletes were instrumented with APDM Opal IMUs and asked to perform nine dynamic actions; five participants were used in training the parameters of the TQC method, with the remaining four being used to test validity. Accuracy was based on the root mean square error (RMSE) and reliability was based on the Bland–Altman limits of agreement (LoA). Improvement across all three orthogonal angles was observed as the TQC method was able to more accurately (lower RMSE) and more reliably (smaller LoA) estimate an angle than the commercially available algorithm. No significant difference was observed between the TQC method and the motion capture system in any of the three angles (p < 0.05). It may be feasible to use this method to track tibiofemoral angles with higher accuracy and reliability than the commercially available sensor fusion algorithm. 

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