Analyzing the effects of polymeric dielectric materials on micro capacitive pressure sensors: A model incorporating displacement-dependent porosity.

Recently, the extensive utilization of porous polymeric materials to amplify the sensitivity of capacitive devices is noticeable. The absence of an effective mathematical model for studying these devices has spurred the development of a comprehensive mathematical model in the current work. This model is formulated to analyze the static and dynamic behavior of systems incorporating a porous polymer dielectric material within the gap between flexible and fixed microplates. The derived nonlinear governing equations encompass the effects of electrostatic force, von-Karman nonlinear strains, and displacement-dependent porosity. Employing spatial decomposition, the resulting nonlinear algebraic equations and ordinary differential equations are leveraged to study the static and transient dynamic behavior, as well as the frequency response of the sensor using a learning approach. Two scenarios are investigated to assess the impact of various geometrical and physical parameters on sensor sensitivity one with a polymeric material and another without, each with distinct parameter values. The results reveal that the inclusion of a polymeric dielectric material increases electrostatic force but concurrently elevates the equivalent stiffness of the structure. The effectiveness of using a polymeric dielectric material is contingent upon the specific geometrical and physical properties of the sensor. Moreover, the obtained results in simplified cases are compared to existing numerical and experimental data, demonstrating a high degree of agreement. This work significantly contributes to advancing the understanding of sensors incorporating porous polymer dielectric materials and underscores their potential for enhanced sensitivity across diverse applications.

Structural Insight into Privileged Heterocycles as Anti-Trypanosoma cruzi and brucei Agents.

Trypanosomiasis is caused by parasitic protozoan trypanosomes in vertebrates. T. cruzi and T. brucei are causative agents of Chagas disease (CD) and Human African Trypanosomiasis (HAT), respectively. These life-threatening diseases are a serious threat to public health, with considerable incidence in sub-Saharan African and continental Latin America countries. Although WHO validated mitigated number of HAT cases in Togo (June 2020) and Cote d'Ivoire (December 2020), serious efforts need to be performed for the elimination of the disease. Antigenic variation of trypanosomal parasites provides a major bottleneck for developing effective vaccines. In the absence of human vaccines or chemoprophylaxis, the control of trypanosomatid infections may be envisaged through the eradication of vectors, management of animal reservoirs, and chemotherapy. A small number of chemical agents are currently available for antitrypanosomal treatments, and most of them are associated with toxicity, lack of efficacy, and non-oral route of administration. Given the restricted applicability of current medications, numerous efforts have been made for the synthesis and biological evaluation of heterocyclic scaffolds as antitrypanosomal candidates. In light of the above considerations, we were prompted to describe chemical diversity within privileged 5- membered heterocycles (imidazoles, thiazoles, triazoles and tetrazoles) as antitrypanosomal agents. The main purpose of the study was to throw light on the structure-activity relationship (SAR) of the relevant structures. To capture the recent structural diversity within reported cases, small molecules that belonged to the recent 7-year period (2015-2021) have been discussed. The available medications have also been briefly reviewed.

Thermo-vibrational analyses of skin tissue subjected to laser heating source in thermal therapy.

Laser-induced thermal therapy, due to its applications in various clinical treatments, has become an efficient alternative, especially for skin ablation. In this work, the two-dimensional thermomechanical response of skin tissue subjected to different types of thermal loading is investigated. Considering the thermoelastic coupling term, the two-dimensional differential equation of heat conduction in the skin tissue based on the Cattaneo-Vernotte heat conduction law is presented. The two-dimensional differential equation of the tissue displacement coupled with the two-dimensional hyperbolic heat conduction equation in the tissue is solved simultaneously to analyze the thermal and mechanical response of the skin tissue. The existence of mixed complicated boundary conditions makes the problem so complex and intricate. The Galerkin-based reduced-order model has been utilized to solve the two-sided coupled differential equations of vibration and heat transfer in the tissue with accompanying complicated boundary conditions. The effect of various types of heating sources such as thermal shock, single and repetitive pulses, repeating sequence stairs, ramp-type, and harmonic-type heating, on the thermomechanical response of the tissue is investigated. The temperature distribution in the tissue along depth and radial direction is also presented. The transient temperature and displacement response of tissue considering different relaxation times are studied, and the results are discussed in detail.

Green synthesis of nonprecious metal-doped copper hydroxide nanoparticles for construction of a dopamine sensor.

Background: Copper oxide nanoparticles doped with nonprecious metal species (Ni and Mn) were synthesized. Method: A glassy carbon electrode (GCE) was modified by drop-casting of nanostructure suspensions, constructing Ni:Cu(OH)2/GCE, Mn:Cu(OH)2/GCE and Cu(OH)2/GCE. Results: The voltammetric oxidation of dopamine (DA) by the constructed electrodes confirmed that the electrocatalytic oxidation of DA is a reversible, pH-dependent, diffusion-controlled process; the best response was obtained by Mn:Cu(OH)2/GCE. A sensitive calibration graph (0.664 µA/µM) was produced for DA in the concentration range of 0.3-10.0 µM, with a detection limit of 79 nM using Mn:Cu(OH)2/GCE. Conclusion: The Mn:Cu(OH)2/GCE possessed an accurate response toward DA with an acceptable selectivity, stability and antifouling effect, revealing the applicability of the Mn:Cu(OH)2/GCE for DA analysis in biological samples.