Towards skin-acetone monitors with selective sensitivity: Dynamics of PANI-CA films

Annerino, Anthony; Faltas, Michael; Srinivasan, Manoj; Gouma, Pelagia‐Irene

doi:10.1371/journal.pone.0267311

Cited by 4 publications

(3 citation statements)

References 35 publications

(31 reference statements)

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“…In conclusion, we have shown that energy cost scales non-linearly with joint torque and predicts bilateral limb force sharing and the same exponent is applicable to muscle force sharing. Such metabolic cost models, when generalized to each joint or muscle, may be used in whole body biomechanical simulations for predictions of movement behavior as well as potentially for real-time metabolic monitoring [47, 48].…”

Section: Discussionmentioning

confidence: 99%

Metabolic cost for isometric force scales nonlinearly and predicts how humans distribute forces across limbs

Muralidhar,

Marin,

Melick

et al. 2023

Preprint

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Muscles consume metabolic energy for force production and movement. A mathematical model of metabolic energy cost will be useful in predicting instantaneous costs during human exercise and in computing effort-minimizing movements via simulations. Previous in vivo data-derived models usually assumed either zero or linearly increasing cost with force, but a nonlinear relation could have significant metabolic or behavioural implications. Here, we show that metabolic cost scales nonlinearly with joint torque with an exponent of about 1.64, using calorimetric measurements of isometric squats. We then demonstrate that this metabolic nonlinearity is reflected in human behaviour: minimizing this nonlinear cost predicts how humans share forces between limbs in additional experiments involving arms and legs. This shows the utility of the nonlinear energy cost in predictive models and its generalizability across limbs. Finally, we show mathematical evidence that the same nonlinear metabolic objective may underlie force sharing at the muscle level.

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Section: Discussionmentioning

confidence: 99%

Metabolic cost for isometric force scales nonlinearly and predicts how humans distribute forces across limbs

Muralidhar,

Marin,

Melick

et al. 2023

Preprint

Self Cite

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“…Based on the host response of a subject-in this case the gases emitted from cells in the case of infection by a virus-a novel sensor system/breath tester for COVID-19 which produced a breath print for the infection by "smelling" a single exhaled breath was also demonstrated [6]. At the same time, there are chemo-mechanical actuators and resistors for sensing gases emitted from skin cells [7]. These breakthroughs have opened the way to explore fundamentally novel approaches to safeguard the environment, protect public health and individual well-being through the processing of living sensor systems that detect pathogens rapidly, as described next.…”

Section: How To Design Living Cell Sensorsmentioning

confidence: 99%

How to Build Live-Cell Sensor Microdevices

Gouma

2023

Sensors

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There is a lot of discussion on how viruses (such as influenza and SARS-CoV-2) are transmitted in air, potentially from aerosols and respiratory droplets, and thus it is important to monitor the environment for the presence of an active pathogen. Currently, the presence of viruses is being determined using primarily nucleic acid-based detection methods, such as reverse transcription- polymerase chain reaction (RT-PCR) tests. Antigen tests have also been developed for this purpose. However, most nucleic acid and antigen methods fail to discriminate between a viable and a non-viable virus. Therefore, we present an alternative, innovative, and disruptive approach involving a live-cell sensor microdevice that captures the viruses (and bacteria) from the air, becomes infected by them, and emits signals for an early warning of the presence of pathogens. This perspective outlines the processes and components required for living sensors to monitor the presence of pathogens in built environments and highlights the opportunity to use immune sentinels in the cells of normal human skin to produce monitors for indoor air pollutants.

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“…A good sensor exhibits key factors that contribute to its performance, including sensitivity, specificity, resolution, repeatability, and response time [4][5][6]. P-TENG technology, with its compatibility with numerous piezoelectric and triboelectric materials, enables the development of tailored sensors that embody these characteristics [7].…”

Section: Introductionmentioning

confidence: 99%

Chemical Sensor Based on Piezoelectric/Triboelectric Nanogenerators: A Review of the Modular Design Strategy

et al. 2023

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Piezoelectric and triboelectric nanogenerators (P-TENGs) have emerged as promising technologies for converting mechanical energy into electrical energy, with potential applications in self-powered wearable and environmental monitoring devices. Modular design in P-TENGs, characterized by the flexible assembly and customization of device components, enables the development of sustainable and versatile chemical sensors. In this review, we focus on the role of modularity in P-TENG-based chemical sensing, discussing how it enhances design flexibility, sensing versatility, scalability, and integration with other technologies. We explore the various strategies for functionalizing P-TENGs with specific recognition elements, facilitating selective and sensitive detection of target chemicals such as gases, biochemicals, or biomolecules. Furthermore, we examine the integration of modular P-TENGs with energy storage devices, signal conditioning circuits, and wireless communication modules, highlighting the potential for creating advanced, self-powered sensing systems. Finally, we address the challenges and future directions in the development of modular P-TENG-based chemical sensors (PCS and TCS), emphasizing the importance of improving selectivity, stability, and reproducibility for practical applications.

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Towards skin-acetone monitors with selective sensitivity: Dynamics of PANI-CA films

Cited by 4 publications

References 35 publications

Metabolic cost for isometric force scales nonlinearly and predicts how humans distribute forces across limbs

Metabolic cost for isometric force scales nonlinearly and predicts how humans distribute forces across limbs

How to Build Live-Cell Sensor Microdevices

Chemical Sensor Based on Piezoelectric/Triboelectric Nanogenerators: A Review of the Modular Design Strategy

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