Electron Equivalents Research Articles

A novel pulse-modulated closed-loop artificial pancreas based on intravenous administration of insulin and glucagon

Current attempts to implement and apply automated control systems for the management of glucose homeostasis in individuals with diabetes are partly successful. In most semi and closed loop control systems to mimic the action of a normal pancreas in diabetes patients, insulin is administered subcutaneously. However, the parameters for insulin diffusion and transport time constants are relatively large and have wide individual variations. Therefore, deviation from a normal meal can result in suboptimal euglycemic control. Stable and reliable closed loop feedback control using continuous glucose monitoring under these conditions is difficult and needs regular interventions from the user. This article describes the translation of the endocrine physiology of a normal pancreas to an electronic equivalent. With this translation, the complex effects of a direct intravenous pulsatile method of insulin and glucagon administration can be simulated in accordance with physiological observations in a healthy subject and has been built with standard electronic components. This device is applicable for any individual and under any condition to automatically maintain the desired optimal euglycemic condition. The insulin and glucagon response control is presented in the same physiological pulsatile manner as is observed in healthy individuals.

Cysteine-Facilitated Cr(VI) reduction by Fe(II/III)-bearing phyllosilicates: Enhancement from In-Situ Fe(II) generation

Structural Fe in phyllosilicates represents a crucial and potentially renewable reservoir of electron equivalents for contaminants reduction in aquatic and soil systems. However, it remains unclear how in-situ modification of Fe redox states within Fe-bearing phyllosilicates, induced by electron shuttles such as naturally occurring organics, influences the fate of contaminants. Herein, this study investigated the processes and mechanism of Cr(VI) reduction on two typical Fe(II/III)-bearing phyllosilicates, biotite and chlorite, in the presence of cysteine (Cys) at circumneutral pH. The experimental results demonstrated that Cys markedly enhanced the rate and extent of Cr(VI) reduction by biotite/chlorite, likely because of the formation of Cr(V)-organic complexes and consequent electron transfer from Cys to Cr(V). The concomitant production of non-structural Fe(II) (including aqueous Fe(II), surface bound Fe(II), and Cys-Fe(II) complex) cascaded transferring electrons from Cys to surface Fe(III), which further contributed to Cr(VI) reduction. Notably, structural Fe(II) in phyllosilicates also facilitated Cr(VI) reduction by mediating electron transfer from Cys to structural Fe(III) and then to edge-sorbed Cr(VI). 57Fe Mössbauer analysis revealed that cis-coordinated Fe(II) in biotite and chlorite exhibits higher reductivity compared to trans-coordinated Fe(II). The Cr end-products were insoluble Cr(III)-organic complex and sub-nanometer Cr2O3/Cr(OH)3, associated with residual minerals as micro-aggregates. These findings highlight the significance of in-situ produced Fe(II) from Fe(II/III)-bearing phyllosilicates in the cycling of redox-sensitive contaminants in the environment.

The concept and necessity of ‘control’ in the use of emerging technologies in commercial transactions

Abstract An understanding of the concept of ‘control’ is essential to understand recent developments in commercial law. This article charts the history of ‘control’, the need for this concept in contemporary commercial law, why ‘control’ is not the electronic equivalent of ‘possession’, and the necessary recent and future developments of this concept.

Design and Implementation of High QoS 3D-NoC using Modified Double Particle Swarm Optimization on FPGA

One technique to overcome the exponential growth bottleneck is to increase the number of cores on a processor, although having too many cores might cause issues including chip overheating and communication blockage. The problem of the communication bottleneck on the chip is presently effectively resolved by networks-on-chip (NoC). A 3D stack of chips is now possible, thanks to recent developments in IC manufacturing techniques, enabling to reduce of chip area while increasing chip throughput and reducing power consumption. The automated process associated with mapping applications to form three-dimensional NoC architectures is a significant new path in 3D NoC research. This work proposes a 3D NoC partitioning approach that can identify the 3D NoC region that has to be mapped. A double particle swarm optimization (DPSO) inspired algorithmic technique, which may combine the characteristics having neighbourhood search and genetic architectures, also addresses the challenge of a particle swarm algorithm descending into local optimal solutions. Experimental evidence supports the claim that this hybrid optimization algorithm based on Double Particle Swarm Optimisation outperforms the conventional heuristic technique in terms of output rate and loss in energy. The findings demonstrate that in a network of the same size, the newly introduced router delivers the lowest loss on the longest path. Three factors, namely energy, latency or delay, and throughput, are compared between the suggested 3D mesh ONoC and its 2D version. When comparing power consumption between 3D ONoC and its electronic and 2D equivalents, which both have 512 IP cores, it may save roughly 79.9% of the energy used by the electronic counterpart and 24.3% of the energy used by the latter. The network efficiency of the 3D mesh ONoC is simulated by DPSO in a variety of configurations. The outcomes also demonstrate an increase in performance over the 2D ONoC. As a flexible communication solution, Network-On-Chips (NoCs) have been frequently employed in the development of multiprocessor system-on-chips (MPSoCs). By outsourcing their communication activities, NoCs permit on-chip Intellectual Property (IP) cores to communicate with one another and function at a better level. The important components in assigning application duties, distributing the work to the IPs, and coordinating communication among them are mapping and scheduling methods. This study aims to present an entirely advanced form of research in the area of 3D NoC mapping and scheduling applications, grouping the results according to various parameters and offering several suggestions for further research.

Electro-polarization of the sludge with dynamic magnetic field enhanced the interspecies electron transfer in ZVI-added anaerobic digesters

Zero-valent iron (ZVI) has been widely reported to strengthen anaerobic digestion; however, ZVI passivation prevents its continuous function. In this study, a dynamic magnetic field (DMF) was imposed on a ZVI-added anaerobic digester treating food waste to promote microbial interspecies electron transfer to enhance methane production. Results showed that methane production with DMF was 15.3% higher than that without DMF. Meanwhile, the Fe(II) concentration from ZVI increased by 39.46% with DMF, but the electron equivalent was far less than the increased methane production even if all electrons from the ZVI were used for hydrogenotrophic methanogenesis. In agreement, the relative abundances of hydrogenotrophic methanogens were less changed after DMF. Notably, an induced electric current ranging from −0.017–0.021 μA was detected with DMF. With the DMF-induced current as electrical stimulation, the sludge conductivity and capacitance increased by 242% and 18%, respectively. In-situ electrochemical tests on the functional groups of the sludge showed that the protein-like substances were polarized by the induced electromotive force to enhance the proton-coupled electron transfer in the sludge. Together with the enriched electrotrophic methanogens, the enhanced microbial interspecies electron exchange was the main reason for the improved performance of anaerobic digestion with DMF.

Vestibular prosthesis: from basic research to clinics.

Balance disorders are highly prevalent worldwide, causing substantial disability with high personal and socioeconomic impact. The prognosis in many of these patients is poor, and rehabilitation programs provide little help in many cases. This medical problem can be addressed using microelectronics by combining the highly successful cochlear implant experience to produce a vestibular prosthesis, using the technical advances in micro gyroscopes and micro accelerometers, which are the electronic equivalents of the semicircular canals (SCC) and the otolithic organs. Reaching this technological milestone fostered the possibility of using these electronic devices to substitute the vestibular function, mainly for visual stability and posture, in case of damage to the vestibular endorgans. The development of implantable and non-implantable devices showed diverse outcomes when considering the integrity of the vestibular pathways, the device parameters (current intensity, impedance, and waveform), and the targeted physiological function (balance and gaze). In this review, we will examine the development and testing of various prototypes of the vestibular implant (VI). The insight raised by examining the state-of-the-art vestibular prosthesis will facilitate the development of new device-development strategies and discuss the feasibility of complex combinations of implantable devices for disorders that directly affect balance and motor performance.

Hydrogen recovery cascade from pretreated rice straw and its fermentative residuals using step-up potential-based sulfate reducing bacteria-bioelectrochemical system

Despite the availability of well-proven biohydrogen production technology, the uncapping of the biological theoretical hydrogen yield is still a challenge. This study explores the stimulation of step-up applied potential for hydrogen production in a sulfate-reducing bacteria-based bioelectrochemical system (SRB-BES), a sustainable and promising technology for organic waste recycling with resource recovery. This research focused on the application of a low applied potential to recover H2 from pretreated rice straw and its residual fermentative by-products. An applied potential of −40 mV could proficiently recover 1.5 times higher hydrogen from pretreated rice straw by completely inhibiting methanogens. The residual fermentative byproducts obtained at the first stage were further used in extra H2 recovery at a step-up applied potential of −150 mV, −300 mV, and −450 mV. The H2 recovery from fermentative residuals shows maxima at −300 mV. The acetic acid and iso-butyric acid production of 52.89 ± 15.67 and 56.93 ± 11.81 mM at −300 mV and −450 mV respectively contribute majorly to volatile fatty acids (VFAs). The more electronic equivalents of 2024.34 (mM) in R-450mV in comparison to 1850.803 (mM) in R-40mV (effluent recovered from AD-MEC) indicate the involvement of the higher applied potential in chain elongation of VFAs. So, optimization of step-up potential could lead to the bioelectrochemical synthesis of the desired fatty acids through chain elongation deserving various applications with hydrogen recovery. The gaseous data obtained were verified by Richard, Logistic, and modified Gompertz kinetic models to check H2 prediction validity using cumulative H2 production. This study demonstrated the technical foundation with a novel approach to maximize hydrogen recovery from the fermentation residuals by step-up applied potential.

Kinetics of Hydroxyl Radical Production from Oxygenation of Reduced Iron Minerals and Their Reactivity with Trichloroethene: Effects of Iron Amounts, Iron Species, and Sulfate Reducing Bacteria.

Reactive oxygen species generated during the oxygenation of different ferrous species have been documented at groundwater field sites, but their effect on pollutant destruction remains an open question. To address this knowledge gap, a kinetic model was developed to probe mechanisms of •OH production and reactivity with trichloroethene (TCE) and competing species in the presence of reduced iron minerals (RIM) and oxygen in batch experiments. RIM slurries were formed by combining different amounts of Fe(II) and sulfide (with Fe(II):S ratios from 1:1 to 50:1) or Fe(II) and sulfate with sulfate reducing bacteria (SRB) added. Extents of TCE oxidation and •OH production were both greater with RIM prepared under more reducing conditions (more added Fe(II)) and then amended with O2. Kinetic rate constants from modeling indicate that •OH production from free Fe(II) dominates •OH production from solid Fe(II) and that TCE competes for •OH with Fe(II) and organic matter (OM). Competition with OM only occurs in experiments with SRB, which include cells and their exudates. Experimental results indicate that cells and/or exudates also provide electron equivalents to reform Fe(II) from oxidized RIM. Our work provides new insights into mechanisms and environmental significance of TCE oxidation by •OH produced from oxygenation of RIM. However, further work is necessary to confirm the relative importance of reaction pathways identified here and to probe potentially unaccounted for mechanisms that affect abiotic TCE oxidation in natural systems.

Formate-induced CO tolerance and methanogenesis inhibition in fermentation of syngas and plant biomass for carboxylate production

BackgroundProduction of monocarboxylates using microbial communities is highly dependent on local and degradable biomass feedstocks. Syngas or different mixtures of H2, CO, and CO2 can be sourced from biomass gasification, excess renewable electricity, industrial off-gases, and carbon capture plants and co-fed to a fermenter to alleviate dependence on local biomass. To understand the effects of adding these gases during anaerobic fermentation of plant biomass, a series of batch experiments was carried out with different syngas compositions and corn silage (pH 6.0, 32 °C).ResultsCo-fermentation of syngas with corn silage increased the overall carboxylate yield per gram of volatile solids (VS) by up to 29% (0.47 ± 0.07 g gVS−1; in comparison to 0.37 ± 0.02 g gVS−1 with a N2/CO2 headspace), despite slowing down biomass degradation. Ethylene and CO exerted a synergistic effect in preventing methanogenesis, leading to net carbon fixation. Less than 12% of the electrons were misrouted to CH4 when either 15 kPa CO or 5 kPa CO + 1.5 kPa ethylene was used. CO increased the selectivity to acetate and propionate, which accounted for 85% (electron equivalents) of all products at 49 kPa CO, by favoring lactic acid bacteria and actinobacteria over n-butyrate and n-caproate producers. Inhibition of n-butyrate and n-caproate production by CO happened even when an inoculum preacclimatized to syngas and lactate was used. Intriguingly, the effect of CO on n-butyrate and n-caproate production was reversed when formate was present in the broth.ConclusionsThe concept of co-fermenting syngas and plant biomass shows promise in three aspects: by making anaerobic fermentation a carbon-fixing process, by increasing the yields of short-chain carboxylates (propionate and acetate), and by minimizing electron losses to CH4. Moreover, a model was proposed for how formate can alleviate CO inhibition in certain acidogenic bacteria. Testing the fermentation of syngas and plant biomass in a continuous process could potentially improve selectivity to n-butyrate and n-caproate by enriching chain-elongating bacteria adapted to CO and complex biomass.

Highly Efficient Utilization of Ferrate(VI) Oxidation Capacity Initiated by Mn(II) for Contaminant Oxidation: Role of Manganese Species.

Manganese ion [Mn(II)] is a background constituent existing in natural waters. Herein, it was found that only 59% of bisphenol A (BPA), 47% of bisphenol F (BPF), 65% of acetaminophen (AAP), and 49% of 4-tert-butylphenol (4-tBP) were oxidized by 20 μM of Fe(VI), while 97% of BPA, 95% of BPF, 96% of AAP, and 94% of 4-tBP could be oxidized by the Fe(VI)/Mn(II) system [20 μM Fe(VI)/20 μM Mn(II)] at pH 7.0. Further investigations showed that bisphenol S (BPS) was highly reactive with reactive iron species (RFeS) but was sluggish with reactive manganese species (RMnS). By using BPS and methyl phenyl sulfoxide (PMSO) as the probe compounds, it was found that reactive iron species contributed primarily for BPA oxidation at low Mn(II)/Fe(VI) molar ratios (below 0.1), while reactive manganese species [Mn(VII)/Mn(III)] contributed increasingly for BPA oxidation with the elevation of the Mn(II)/Fe(VI) molar ratio (from 0.1 to 3.0). In the interaction of Mn(II) and Fe(VI), the transfer of oxidation capacity from Fe(VI) to Mn(III), including the formation of Mn(VII) and the inhibition of Fe(VI) self-decay, improved the amount of electron equivalents per Fe(VI) for BPA oxidation. UV-vis spectra and dominant transformation product analysis further revealed the evolution of iron and manganese species at different Mn(II)/Fe(VI) molar ratios.

Caffeine as an energy storage material for next-generation lithium batteries

Organic compounds are attracting attention as potential candidates for next-generation energy storage materials for rechargeable batteries. The utilization of redox centers in naturally occurring and human-edible organic compounds has excellent potential for designing sustainable and safe energy storage materials. However, an in-depth understanding of the energy storage mechanism is an essential prerequisite for its use and optimization as an electrode material. In this study, we applied caffeine as an electrode material in lithium batteries and revealed the energy storage mechanism for the first time. Two equivalents of electrons and lithium-ions participate in redox reactions during the charge-discharge process, providing a reversible capacity of 265 mAh g−1 in a voltage window of 1.5–4.3 V. Furthermore, it was discovered that a new redox reaction site can be controlled through molecular tuning by halogenation, and the newly created redox site shows that oxidation voltage increases in proportion to the electronegativity of halogen elements in the order of I, Br, Cl, and F. These results demonstrate the applicability of nature-derived organic materials as energy storage materials and a feasible strategy to design tunable redox-active sites and their redox potential through molecular-scale engineering.

ВОВЛЕЧЕННОСТЬ ОРГАНИЗАТОРОВ ЗДРАВООХРАНЕНИЯ В ПРОЦЕСС ЦИФРОВИЗАЦИИ ЗДРАВООХРАНЕНИЯ

Significance. The traditional healthcare system is losing its relevance. Digital transformation of healthcare dictates new conditions to medical organizations, imposing new requirements on healthcare administrators. The purpose of the study is to analyze the attitude of heads of medical organizations in the Arkhangelsk region towards the digital model of healthcare organization. Material and methods. A sociological survey was conducted among heads of the state medical organizations in the Arkhangelsk region. The survey was conducted in the period from March 2021 to August 2022. Representatives of 46 medical organizations took part in the survey including 28 urban and 18 rural organizations. The total number of the respondents added up to 181. A semi-structured questionnaire was used as a research tool, the design was a cross-sectional study. Results. The conducted study shows that 82.3% of the healthcare administrators consider informatization of medical organizations to be successful and show a high level of confidence (95.6%) in information retrieved from medical information systems. In urban areas, the respondents noted a higher level of workplace automation (78.0%), greater need for a personal computer in everyday work (94,9%) and higher frequency of its use (96.6%), and the highest proportion of connection to the medical information system of all departments of a medical organization (94.1%). Healthcare administrators are unanimously positive about replacing the paper medical history/ outpatient records with an electronic equivalent. The main problems related to automation of a medical organization are as follows: insufficient financing of informatization in a medical organization (50.8%), requirements to duplicate electronic information in paper form (48.1%), lack of clear requirements for the implemented information systems (22.7%). Conclusion. The study of attitude of the heads of medical organizations in the Arkhangelsk region towards the digital model of healthcare organizational showed a greater readiness of urban organizations for a standard information interaction in healthcare in the region. To ensure successful work with the medical information systems, healthcare administrators need a supervised on-the-job training by a more experienced colleague. The prospects of digital transformation of healthcare for an individual medical organization are overwhelmingly defined by the electronic document flow between medical organizations.

Electronic equivalent of a pump-modulated erbium-doped fiber laser

We built the electronic equivalent circuit based on the model of a pump-modulated erbium-doped fiber laser. The model equations have two state variables, optical field intensity x and population inversion y, and a harmonic modulation applied to the pump parameter. In addition, the model contains two nonlinear terms, xy and ey. The exponential nonlinearity is implemented electronically using a power series expansion. The circuit dynamics is investigated using bifurcation, Lyapunov spectrum, and phase space analyses. Similar to the fiber laser, the equivalent electronic circuit exhibits very rich dynamics, exhibiting chaos and multiple coexisting periodic orbits. The existence of a saddle–node fixed point is demonstrated.

Microbial succession in a marine sediment: Inferring interspecific microbial interactions with marine cable bacteria.

Cable bacteria are long, filamentous, multicellular bacteria that grow in marine sediments and couple sulfide oxidation to oxygen reduction over centimetre-scale distances via long-distance electron transport. Cable bacteria can strongly modify biogeochemical cycling and may affect microbial community networks. Here we examine interspecific interactions with marine cable bacteria (Ca. Electrothrix) by monitoring the succession of 16S rRNA amplicons (DNA and RNA) and cell abundance across depth and time, contrasting sediments with and without cable bacteria growth. In the oxic zone, cable bacteria activity was positively associated with abundant predatory bacteria (Bdellovibrionota, Myxococcota, Bradymonadales), indicating putative predation on cathodic cells. At suboxic depths, cable bacteria activity was positively associated with sulfate-reducing and magnetotactic bacteria, consistent with cable bacteria functioning as ecosystem engineers that modify their local biogeochemical environment, benefitting certain microbes. Cable bacteria activity was negatively associated with chemoautotrophic sulfur-oxidizing Gammaproteobacteria (Thiogranum, Sedimenticola) at oxic depths, suggesting competition, and positively correlated with these taxa at suboxic depths, suggesting syntrophy and/or facilitation. These observations are consistent with chemoautotrophic sulfur oxidizers benefitting from an oxidizing potential imparted by cable bacteria at suboxic depths, possibly by using cable bacteria as acceptors for electrons or electron equivalents, but by an as yet enigmatic mechanism.

Инвестиции в Интернете: дистанционные сделки с электронными эквивалентами обязательств и требований

Introduction: to date, transactions with complex new investment objects are investigated, including utilitarian digital rights, digital financial assets, and digital currency. In this regard, the author sets a goal: to analyze and investigate the features of remote investment transactions made by individuals (private investors) on the Internet. Methods: the methodological framework for the study was the methods of scientific cognition, among which the main ones are the methods of systematicity, analysis and comparative law. Results: the specifics of the circumstances justified by the fact that the category “electronic equivalents of obligations and requirements” should be fixed as the key concept that should be included in the title of the Federal Law “On Digital Financial Assets” instead of the word formation “digital financial assets”. Conclusions: based on the analysis of the legislation, it is necessary to simplify and modernize the structure of interaction between a private investor, an information system operator, an investment recipient and eliminate unnecessary irrational stages of their interaction using digital computer technologies of a smart contract. Based on the results of the study, the author offers recommendations for the development of standard smart contracts.

The enhancement on biohydrogen production by the driving forces from extracellular iron oxide respiration

Biohydrogen productions from xylose and glucose under dark condition were enhanced by the presence of natural Fe3O4. The electron equivalent of H2 fractions accounted for 4.55 % and 5.69 % of the total given xylose and glucose in the experiments without Fe3O4, and that were correspondingly increased to 5.14 % and 6.50 % in the experiments with 100 mg/L of Fe3O4, respectively. Moreover, Fe3O4 increased the total intracellular NAD(H) concentrations by 8.84 % and 8.37 %, and boosted the ratios of NADH/NAD+ by 8.33 % and 17.72 % in xylose and glucose fermentation, respectively, comparing to the corresponding control experiments. The formation of electron couples of Fe(III)/Fe(II) during the iron oxide respiration and more generation of active extracellular polymeric substances components were determined as the important reasons for the improved biohydrogen production performance. Thus, a promotion mechanism of the internal “driving forces” from extracellular iron oxide respiration on the biohydrogen production was proposed.

The noninvasive monitoring of the redox status of photosynthetic electron transport chains in Hibiscus rosa-sinensis and Tradescantia leaves

We present an approach to the noninvasive determination of the electron capacity of the intersystem pool of electron carriers in chloroplasts in situ. As apt experimental models, we used the leaves of Hibiscus rosa-sinensis and Tradescantia species. Electron paramagnetic resonance and optical response of P700 (the primary electron donor in Photosystem I) were applied to measuring electron transport in chloroplasts. Electron capacities of the intersystem electron transport chain (ETC) were determined from redox transients of P700 upon chromatic transitions (white light → far-red light). During the induction period, we observed the nonmonotonic changes in the number of electron equivalents in the intersystem ETC per P700 (parameter Q). In Hibiscus rosa-sinensis, the light-induced rise of Q from ≈2.5 (in the dark) to Q ≈ 12 was followed by its decrease to Q ≈ 6. The data obtained are discussed in the context of pH-dependent regulation of electron transport in chloroplasts, which provides the well-balanced operation of the intersystem ETC. The decay of Q is explained by the attenuation of Photosystem II activity due to the lumen acidification and the acceleration of plastoquinol re-oxidation as a result of the Calvin-Benson cycle activation. Our computer model of electron and proton transport coupled to ATP synthesis in chloroplasts was used to analyze the up and down feedbacks responsible for pH-dependent regulation of electron transport in chloroplasts. The procedures introduced here may be important for subsequent works aimed at defining the plastoquinone participation in regulation of photosynthetic processes in chloroplasts in situ.

Equivalent Electronic Circuit of a System of Oscillators Connected with Periodically Variable Stiffness

In this paper, we have shown an electronic circuit equivalence of a mechanical system consisting of two oscillators coupled with each other. The mechanical design has the effects of the magnetic spring force resistance force, and the spring constant of the system is periodically varying. We have shown that the system’s state variables, such as the displacements and the velocities, under the effects of different forces, lead to some nonlinear behaviors, like a transition from the fixed point attractors to the chaotic attractors through the periodic and quasi-periodic oscillations. We have verified those numerically obtained phenomena using the analog electronic circuit of this mechanical system.

The emergence of valency in colloidal crystals through electron equivalents.

Colloidal crystal engineering of complex, low-symmetry architectures is challenging when isotropic building blocks are assembled. Here we describe an approach to generating such structures based upon programmable atom equivalents (nanoparticles functionalized with many DNA strands) and mobile electron equivalents (small particles functionalized with a low number of DNA strands complementary to the programmable atom equivalents). Under appropriate conditions, the spatial distribution of the electron equivalents breaks the symmetry of isotropic programmable atom equivalents, akin to the anisotropic distribution of valence electrons or coordination sites around a metal atom, leading to a set of well-defined coordination geometries and access to three new low-symmetry crystalline phases. All three phases represent the first examples of colloidal crystals, with two of them having elemental analogues (body-centred tetragonal and high-pressure gallium), while the third (triple double-gyroid structure) has no known natural equivalent. This approach enables the creation of complex, low-symmetry colloidal crystals that might find use in various technologies.

Neuromorphic Dynamics of Chua Corsage Memristor

Neuromorphic computing can solve computationally hard problems with energy efficiencies unattainable for von Neumann architectures. A locally-active memristor, which possesses the capability to amplify infinitesimal fluctuations in energy and can be used to generate neuromorphic behaviors, is a natural candidate for constructing an electronic equivalent of biological neurons. This paper identifies some unknown neuromorphic dynamics of the Chua corsage memristor (CCM), and shows that the CCM, when biased at the edge of chaos domain, can exhibit rich dynamics of biological neurons. Using Chua’s theories of local activity and edge of chaos, we demonstrate that under the destabilizing of the input voltage and the circuit parameters (inductance or capacitance), two CCM-based circuits can produce thirteen types of neuromorphic behaviors either on, or near the edge of chaos domain via supercritical or subcritical Hopf bifurcation. In addition, we give the conditions to test the edge of chaos of the CCM and the CCM-based circuit only by using the poles and the zero of their admittance functions.