Linear angular momentum multiplexing-conceptualization and experimental evaluation with antenna arrays

Linear Angular Momentum Multiplexing is a new method for providing highly spectrally efficient short range communication between a transmitter and receiver, where one may move at speed transverse to the propagation. Such applications include rail, vehicle and hyperloop transport systems communicating with fixed infrastructure on the ground. This paper describes how the scientific concept of linear angular momentum multiplexing evolves from orbital angular momentum multiplexing. The essential parameters for implementing this concept are: a long array at least at one of the ends of the link; antenna element radiation characteristics; and the array element spacing relative to the propagation distance. These parameters are also backed by short range measurements carried out at 2.4GHz used to model the Rice fading channel and determine resilience to multipath fading

Linear Angular Momentum Multiplexing – Conceptualisation and Experimental Evaluation with Antenna Arrays

Linear Angular Momentum Multiplexing is a new method for providing highly spectrally efficient short range communication between a transmitter and receiver, where one may move at speed transverse to the propagation. Such applications include rail, vehicle and hyperloop transport systems communicating with fixed infrastructure on the ground. This paper describes how the scientific concept of linear angular momentum multiplexing evolves from orbital angular momentum multiplexing. The essential parameters for implementing this concept are: a long array at least at one of the ends of the link; antenna element radiation characteristics; and the array element spacing relative to the propagation distance. These parameters are also backed by short range measurements carried out at 2.4GHz used to model the Rice fading channel and determine resilience to multipath fading

A TSHr-LH/CGr Chimera that Measures Functional TSAb in Graves' Disease.

Context: Stimulating thyrotropin receptor (TSHr) autoantibodies (TSAb) are the cause of hyperthyroidism in Graves' disease. In a patient's serum, TSAb can coexist with antagonist TSHr autoantibodies that block TSAb stimulatory activity (TSBAb); both can vary in amount and time. Objective: The objective of the study was to create a functional assay that detects only TSAb, thus having an increased accuracy for diagnosing Graves' disease. Design: A TSHr chimera (Mc4) that retains an agonist-sensitive TSAb epitope but replaces a TSBAb epitope was stably transfected in cells to establish the Mc4 assay. Setting: The study was conducted at the Chieti University (Outpatient Endocrine Clinic) and the University of Pisa (the Department of Endocrinology). Patients: The assay was validated using sera from 170 individuals with Graves' disease, Hashimoto's thyroiditis, and nonautoimmune hyperthyroidism and normal subjects from Chieti University. A second blinded study evaluated sera from 175 patients with autoimmune thyroid disease (mainly Graves' disease) from the University of Pisa. Interventions: Interventions included the assessment of patients' sera using human wild-type TSHr (WT-TSHr), Mc4 chimera, and binding (TRAb) assays. Main Outcome Measures: The Mc4 assay has the best accuracy for diagnosing Graves' disease. Results: The Mc4 assay has a better diagnostic accuracy than WT-TSHr and second-generation TRAb assays. Indeed, the sensitivity of the WT-TSHr, TRAb, and Mc4 assays was 97.3, 86.5, and 100%, respectively, whereas the specificity was 93.1, 97, and 98.5%, respectively. Conclusion: The Mc4 assay is a functional assay with improved sensitivity and specificity for the detection of TSAb and is clinically useful in diagnosing Graves' disease

A TSHR-LH/CGR Chimera that Measures Functional Thyroid-Stimulating Autoantibodies (TSAb) Can Predict Remission or Recurrence in Graves' Patients Undergoing Antithyroid Drug (ATD) Treatment.

Context: A functional thyroid-stimulating autoantibodies (TSAb) assay using a thyroid-stimulating hormone receptor chimera (Mc4) appears to be clinically more useful than the commonly used assay, a binding assay that measures all the antibodies binding to the thyroid-stimulating hormone receptor without functional discrimination, in diagnosing patient with Graves' disease (GD). Objective: The objective of the study was to investigate whether an Mc4 assay can predict relapse/remission of hyperthyroidism after antithyroid drug (ATD) treatment in patients with GD. Design: An Mc4 assay was used to prospectively track TSAb activity in GD patients treated with ATD over a 5-yr period. Setting and Patients: GD patients from the Chieti University participated in this study. Interventions: Interventions included the assessment of patients' sera using the Mc4 assay, the Mc4-derivative assay (Thyretain), and a human monoclonal thyroid-stimulating hormone receptor antibody, M22 assay. Main Outcome Measures: The Mc4 assay, a sensitive index of remission and recurrence, was used in this study. Results: The TSAb levels significantly decreased only in the remitting group as evidenced by Mc4 assay values at the end of ATD (0.96 ± 1.47, 10.9 ± 26.6. and 24.7 ± 37.5 arbitrary units for the remitting, relapsing, and unsuspended therapy groups, respectively). Additional prognostic help was obtained by thyroid volume measurements at the end of treatment. Although not statistically significant, the Mc4 assay has a trend toward improved positive predictive value (95.4 vs. 84.2 or 87.5%), specificity (96.4 vs. 86.4 and 90.9%), and accuracy (87.3 vs. 83.3 and 80.9%) comparing the Mc4, Thyretain, and M22 assays, respectively. Thyretain has a trend toward improved negative predictive value (82.6 vs. 81.8 and 76.9%) and sensitivity (80 vs. 77.8 and 70%) comparing Thyretain, Mc4, and M22 assays, respectively. Conclusion: The Mc4 assay is a clinically useful index of remission and relapse in patients with GD. Larger studies are required to confirm these findings