A Potentiostatic/Galvanostatic Study and Theoretical Description of Polypyrrole Film Electrodes: A Model of the Intracellular Matrix of Ectothermic Muscle Cells

Beaumont, Samuel; Otero, Toribio F.

doi:10.1002/celc.201700915

Cited by 14 publications

(23 citation statements)

References 66 publications

(90 reference statements)

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“… Evolution of the specific reversible charge consumed during the reversible oxidation/reduction of a pPy/Pt in different concentrations of NaCl aqueous solutions at room temperature submitted to: a) potential cycles between −0.35 and 0.25 V at a scan rate of 90 mV s −1 Reproduced with permission . Copyright 2017, Elsevier, and b) potential square waves of ±0.1 V kept for 6 s each Reproduced with permission . Copyright 2018, IOP Science.…”

Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

“…During the reversible oxidation/reduction of the polymer film, under constant extension of the reaction by consumption of constant anodic and cathodic charges using consecutive square current waves (constant anodic and constant cathodic currents each applied for the same constant time), the material anodic and cathodic potentials evolve at decreasing values under rising temperatures, or under rising electrolyte concentrations,, and at increasing values under increasing driving currents. Higher available energy (whatever the origin) requires the consumption of lower electrochemical energy during the reaction (Equation 5) to attain the same reaction extension.…”

Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

“…d) Evolution of the specific reaction energy consumed when the film is submitted to the above‐described potential sweeps (reproduced with permission . Copyright 2017, Elsevier), e) potential square waves (reproduced with permission . Copyright 2017, Wiley) and f) current square waves at different cell temperatures, submerged in a 0.1 M NaCl aqueous solution.…”

Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

“…Using basic electrochemical, polymeric and mechanical principles a theoretical description of sensing and tactile artificial muscles (artificial proprioception) has been attained ,,,,. The way is open for a theoretical (physical‐chemical) description of bioreplicating chemical‐driven properties and functions.…”

Section: Technological Outlooksmentioning

confidence: 99%

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The Energy Consumed by Electrochemical Molecular Machines as Self‐Sensor of the Reaction Conditions: Origin of Sensing Nervous Pulses and Asymmetry in Biological Functions

Otero

Beaumont

2018

ChemElectroChem

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For reactions involving molecular machines (artificial or biochemical), the evolution of the reaction energy, or that of any of its components, adapts to and senses the working thermal, chemical, or mechanical conditions. Here, the state of the art and the attained sensing equations of the oxidation/reduction of conducting polymers seen as replicating materials and reactions of the intracellular matrix of functional cells (molecular machines, ions and water) are reviewed. The adapting reaction energy in actuating muscles and other organs can originate the nervous pulses translating its quantitative energetic information (thermal, fatigue state and mechanical) to the brain. Besides, reversible oxidation/reduction charges originate a great asymmetry of the consumed reaction energies, which could explain why evolution has selected and improved the most efficient of the two reactions to drive full asymmetric biological functions such as muscle contraction or the flow of nervous signals. The material reaction drives volume variations and energetic adaptation, two simultaneous functions that have allowed the development of artificial sensing‐muscles postulated to replicate some primitive artificial proprioception.

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Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

Section: Quantitative Formulation For Electrochemical Reactionsmentioning

confidence: 99%

Section: Technological Outlooksmentioning

confidence: 99%

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The Energy Consumed by Electrochemical Molecular Machines as Self‐Sensor of the Reaction Conditions: Origin of Sensing Nervous Pulses and Asymmetry in Biological Functions

Otero

Beaumont

2018

ChemElectroChem

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Exploring Brain Information Storage/Reading for Neuronal Connectivity Using Macromolecular Electrochemical Sensing Motors

Otero

2021

Advanced Intelligent Systems

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Dense electroactive gels of conducting polymers, carbon nanotubes, or graphenes, constituted by multisensing macromolecular electrochemical motors, are presented herein as model materials to get a physicochemical characterization of the opening/closing cycles of ion protein channels in neurons. The conformational contracted energetic states of these macromolecular motors store both long‐term and short‐term information packages. Under a potential cycle, the energy of each ionic pulse generated during the channel opening reads the stored information, which is restored during the channel conformational closing. Simultaneously the motor actuation senses the working physical and chemical energetic conditions, transferring to the ionic pulse energy those sensing information packages. A quantitative description of the stored and read information packages is attained from basic electrochemical, mechanical, and polymeric concepts. Translated to ion channel proteins in brain dendrites, it can describe brain information storage mechanisms and the energetic information packages read and carried through each ionic pulse to the action potential. An unexplored way is opened to try to understand and describe how the different brain parts can use this information to originate brain functions. In parallel, the construction of new electrochemical devices and computers replicating biological functions will provide feedback quantitative information to decipher brain functions.

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Reaction Induced Conformational Change in Polyindole: Polyindole/PVA Film as Biomimetic Sensors of Temperature and Electrical Energetic Conditions

Rajan,

Shabeeba,

Sidheekha

et al. 2023

Chemistry An Asian Journal

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The influence of surrounding temperature and electrical energetic condition on the conformational movements (cooperative actuation) of polyindole is verified using a polyindole‐coated polyvinyl alcohol (PIN/PVA) film. Chronopotentiometric studies reveals that the consumed electrical energy during the reaction varies linearly with the change in working temperature. The influence of temperature on the reversible conformational movements of the polymer chain is related to the charge consumed during the reaction. The logarithmic dependence of reversible redox charge obtained from coulovoltammogram with inverse of temperature further proved the temperature sensing characteristics and the influence of temperature on the cooperative actuation of the PIN/PVA film. The conformational relaxation increases as the temperature increases through hosting higher number of counter anions with the solvent molecule. The extension of the redox reaction or charge consumption was found to decrease as the scan rate increases. The double logarithmic relation between the consumed redox charge and the scan rate has proved that the electrical energetic condition can influence the conformational movement or the extension of the redox reaction in a reversible manner. The results suggest that the PIN/PVA film can act as a biomimetic macro molecular sensor of working temperature and electrical energetic condition as biological muscles do.

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A Potentiostatic/Galvanostatic Study and Theoretical Description of Polypyrrole Film Electrodes: A Model of the Intracellular Matrix of Ectothermic Muscle Cells

Cited by 14 publications

References 66 publications

The Energy Consumed by Electrochemical Molecular Machines as Self‐Sensor of the Reaction Conditions: Origin of Sensing Nervous Pulses and Asymmetry in Biological Functions

The Energy Consumed by Electrochemical Molecular Machines as Self‐Sensor of the Reaction Conditions: Origin of Sensing Nervous Pulses and Asymmetry in Biological Functions

Exploring Brain Information Storage/Reading for Neuronal Connectivity Using Macromolecular Electrochemical Sensing Motors

Reaction Induced Conformational Change in Polyindole: Polyindole/PVA Film as Biomimetic Sensors of Temperature and Electrical Energetic Conditions

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