Your search keyword '"Biocybernetics"' showing total 652 results

1. Novel Square Error Minimization-Based Multilevel Thresholding Method for COVID-19 X-Ray Image Analysis Using Fast Cuckoo Search.

Author

Naik, Manoj Kumar, Swain, Monorama, Panda, Rutuparna, and Abraham, Ajith

Subjects

*X-ray imaging, *THRESHOLDING algorithms, *IMAGE analysis, *COVID-19, *COVID-19 pandemic, *CUCKOOS, *WASTE minimization

Abstract

Coronavirus outbreaks in 2019 (COVID-19) have been a huge disaster in the fields of health, economics, education, and tourism in the last two years. For diagnosis, a quick interpretation of the COVID-19 chest X-ray image is required. There is also a strong need to find an efficient multiclass segmentation technique for the analysis of COVID-19 X-ray images. Most of the threshold selection techniques are entropy-based. Nevertheless, these techniques suffer from their dependencies on the spatial distribution of grey values. To tackle these issues, a novel non-entropic threshold selection method is proposed, which is the primary key contribution having found a new source of information to the biomedical image processing field. The firsthand Square Error (SE)-based objective function is suggested. The second key contribution is the new optimizer called Fast Cuckoo Search (FCS), which is useful and brings novel ideas into the subject, used to optimize the suggested objective functions for computing the optimal thresholds. To ensure a faster convergence with a quality optimal solution, we include extra exploitation together with a chance factor. The FCS is validated using the well-known classical and CEC 2014 benchmark test functions, which shows a significant improvement over its predecessors—Adaptive Cuckoo Search (ACS) and other state-of-the-art optimizers. Further, the SE minimization-based optimal multilevel thresholding method using the FCS, coined as SE-FCS, is proposed. To experiment, images are considered from the Kaggle Radiography database. We have compared its performances with Tsallis, Kapur's, and Masi entropy-based techniques using well-known segmentation metrics and achieved a performance increase of 2.95%, 5.51% and 10.50%, respectively. The proposed method shows superiority using Friedman's mean rank statistical test and ranked first. [ABSTRACT FROM AUTHOR]

Published

2024

2. Dynamic symmetrization in a memristive HR neuron

Author

Keyu Huang, Chunbiao Li, Yongxin Li, Tengfei Lei, and Haiyan Fu

Subjects

biocybernetics, bioelectric phenomena, chaos, chaos generators, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Abstract The significance of neuronal discharge symmetry lies in its reflection of the stability and orderliness within the neuron's activity. This symmetry is correlated with various issues, including the biophysical properties within neurons, network structures, and synaptic transmission. Memristors are highly analogous to neuronal synapses due to their unique memory properties, allowing them to emulate biological neural synapses. In this work, a memristor is employed into the Hindmarsh‐Rose (HR) neuron as a synapse for the construction of a memristive HR neuron. Accompanied with the introducing of the absolute value and signum function, the derived neurons exhibit complex coexisting symmetric firing patterns. The phenomenon of symmetric firing can effectively simulate the depolarization and hyperpolarization processes of neurons, providing a new approach to study the diversity of the brain.

Published

2024

3. Dynamic symmetrization in a memristive HR neuron.

Author

Huang, Keyu, Li, Chunbiao, Li, Yongxin, Lei, Tengfei, and Fu, Haiyan

Subjects

*NEURONS, *ABSOLUTE value, *MEMRISTORS

Abstract

The significance of neuronal discharge symmetry lies in its reflection of the stability and orderliness within the neuron's activity. This symmetry is correlated with various issues, including the biophysical properties within neurons, network structures, and synaptic transmission. Memristors are highly analogous to neuronal synapses due to their unique memory properties, allowing them to emulate biological neural synapses. In this work, a memristor is employed into the Hindmarsh‐Rose (HR) neuron as a synapse for the construction of a memristive HR neuron. Accompanied with the introducing of the absolute value and signum function, the derived neurons exhibit complex coexisting symmetric firing patterns. The phenomenon of symmetric firing can effectively simulate the depolarization and hyperpolarization processes of neurons, providing a new approach to study the diversity of the brain. [ABSTRACT FROM AUTHOR]

Published

2024

4. Predicative Computing Structures and Hybrid Automates in Modeling Invasive Processes and Epidemic COVID Waves.

Author

Perevaryukha, A. Yu.

Subjects

*COVID-19 pandemic, *KILLER cells, *SARS-CoV-2, *PREDATION, *CYTOTOXIC T cells, *STRUCTURAL dynamics, *DIFFERENTIAL equations

Abstract

Rapid processes in the area of cell biophysics, invasions, or epidemiology are distinguished by the variety of their variants; therefore, they require original methods of mathematical description for long-term prediction of the state of biophysical systems. Without building predictions of the dynamics of biophysical interaction, it is impossible to improve the technology of industrial exploitation of natural objects. Classical models based on systems of differential equations do not describe the dynamics of real processes that are observed during aggressive invasions of alien species. Known models of "predator/prey" systems assumed the cyclical dynamics of two rival species, but in reality, the oscillatory solution of the model's equations is only a mathematical hypothesis. In real biosystems, the variants for the development of scenarios after the introduction of an aggressive predator or parasite are more complicated. Dynamics during invasions becomes extreme. In laboratory experiments with ciliates, instead of asynchronous oscillations with the prey, the infused predator after a rapid outbreak completely destroyed the entire population of prey. Processes with abrupt metamorphoses are extremely relevant, for example, the development of an immune response during the presentation of antigens of new strains of coronavirus and the activation of specific T-lymphocytes of immune memory killer cells to destroy infected cells. Modeling of extreme development in our works is based on the aspects of eventfulness and variability of choice during abrupt changes in the stages of the process under study, for example, adaptation of a parasite against a breeding invader, which is an important way to combat invasions. For rapidly changing biophysical processes, we proposed to expand the models in differential equations with the components of eventfulness, delay, trigger switching, and the logic of switching stages of development. Previously, we proposed an original formalization of the event hierarchy for continuous-discrete time in a hybrid model. In the article, we will present a method for including predicates in the model, i.e., logical functions that allow us to calculate the sequence of changes in the behavior of the invasive process. Our predictive logic approach is important for computational modeling with transformations in dangerous and fast invasive processes and waves of the COVID-19 epidemic based on a comparative analysis of scenarios. Based on the predicative choice of the behavior of a hybrid automaton defined for a set of right-hand sides of systems of differential equations, we also formalize the decision-making logic in scenarios with a controlled impact on biosystems. Post-COVID immunodeficiency is the most complex legacy of the pandemic. [ABSTRACT FROM AUTHOR]

Published

2023

5. Adequacy of Interpretation of Monitoring Data on Biophysical Processes in Terms of the Theory of Bifurcations and Chaotic Dynamics.

Author

Trofimova, I. V., Perevaryukha, A. Y., and Manvelova, A. B.

Subjects

*DISCRETE systems, *ELECTRONIC data processing, *DYNAMICAL systems, *MISSING data (Statistics), *CHARACTERISTIC functions, *CURVES, *BIFURCATION theory, *LIMIT cycles

Abstract

The problem of confirming the correspondence of the dynamics of biophysical processes arising from the incomplete and noisy data obtained during monitoring of the state of bioresources or statistics gathering in a series of laboratory experiments to three behavioral modes of paths of discrete dynamic systems (equilibrium, limiting cycle, or chaos) is considered. It is shown using the examples of real monitoring data and results of laboratory experiments that the data-approximation technique yields a dependence function, which excludes the observed qualitative development of the population process. Attempts to plot regression lines based on the monitoring data for dissipative paths do not yield the necessary information. Known models of biophysics with qualitative changes in the behavior are considered that use characteristics of the reproductive function that cannot be interpreted in terms of the environmental role. The Schwartz derivative depends on the third derivative of the second iteration of the function at the moment of stationary-point stability loss. Criteria for discrete dynamic systems are proposed that can be used to analyze the results of computational simulation from the point of view of biophysical adequacy of occurring nonlinear effects. It is suggested that the rate of population change in the model has a range of negative values and the population reproduction curve has at least two nontrivial stationary points. Consideration of the effect of an aggregated group, arising during invasions, in the action models facilitates an essential interpretation of the behavior of the model path. It is proposed to delimit the nonlinear effects arising in discrete iterative models. In the case of an invasive species that has penetrated into the ecosystem and caused the depletion of its vital resources, a rapid transition to collapse of the new population is possible. Our approach with two-attractor models makes it possible to predict the state of a critically low population of an aggressive intruder. [ABSTRACT FROM AUTHOR]

Published

2022

6. Computational Modeling of the Nonlinear Metabolism Rate as a Trigger Mechanism of Extreme Dynamics of Invasion Processes.

Author

Mikhailov, V. V., Perevaryukha, A. Y., and Trofimova, I. V.

Subjects

*METABOLIC models, *DIFFERENTIAL forms, *POPULATION dynamics, *DIFFERENTIAL equations, *MATHEMATICAL analysis, *MICROBIAL metabolism, *BIOLOGICAL extinction

Abstract

Formalization in the form of systems of differential equations to describe sharp changes in the development of invasion processes remains an important and urgent problem for mathematical biophysics and bioinformatics. The spread of aggressive biological organisms is accompanied by the rapid phenomena of explosive increase in the dynamics of the population of these dangerous foreign species. Hardly predictable population outbreaks of small insects may continue until the total destruction of forests on large areas. This phenomenon of imbalance affects the entire environment and biochemical processes in the trophic chain of the biosystem. After a rapid uncontrolled (by natural physical factors and a biotic environment) outbreak, degradation of ecosystems and extinction of the invasive species may occur. The fundamental problem of controlling new aggressive species is very important for practical problems of the optimal use of bioresources. The generality of some situations requires special mathematical analysis, which can be constructed by analogy with physical processes with sharp transient regimes. Parametric changes and bifurcations cannot explain the change in behavior, because these reproductive characteristics of aggressive species in a specific biophysical environment are stable during evolutionary adaptation and change only gradually. The simulation of changes in the development rate of individuals in a competitive environment is considered as a hidden factor affecting the realization of critical effects in the dynamics of the population of species with a pronounced staging of ontogenesis. A hybrid model is constructed based on the system of equations describing actual changes in the metabolism rate in ontogenesis, which is applicable to populations in different states of the invasion process. [ABSTRACT FROM AUTHOR]

Published

2022

7. Conclusion: Life-on-Demand

Author

Fletcher, Amy Lynn and Fletcher, Amy Lynn

Published

2020

8. Matters of Life and Death in the Anthropocene

Author

Fletcher, Amy Lynn and Fletcher, Amy Lynn

Published

2020

9. Biocybernetic model for the diagnosis and treatment of chronic pain : An approximation from cognitive neurosciences and the theory of complexity

Author

Hormazabal, Fernando, Lavanderos, Leonardo, and Malpartida, Alejandro

Published

2021

10. Modeling of a Crisis in the Biophysical Process by the Method of Predicative Hybrid Structures.

Author

Perevaryukha, A. Y.

Subjects

*LOTKA-Volterra equations, *DIFFERENTIAL equations, *DECISION making, *PHASE transitions, *CRISES, *CRUSTACEA

Abstract

Crisis processes of biosystems often develop according to scenarios of rapid collapse, which cannot be predicted by statistical methods. This paper develops a method for constructing hybrid computational models using event-hierarchy representation for biophysical processes. System events calculated by the algorithm change the order of calculation of equations according to a given set of rules. The rules of physically conditioned redefinition of the right-hand sides of differential equations are used. The predicates employ the calculations of a group of accompanying characteristics, which are an integral part of the controlled biophysical dynamics. The model is investigated by presenting a computational scenario with a set of parameters, initial values, and an algorithm for making decisions about changing the impact for discrete time. Using computational experiments, a real outcome scenario for a situation that leads to the collapse of a biophysical system at a controlled level of exposure is described. The scenario sets the logic for making control decisions to change the level of external pressure on the natural environment. It is shown as a result of modeling that the transition of the process to an oscillatory mode leads to the choice of a risky control mode. It has been established that the dynamics of many real water populations has a point of threshold reduction in the efficiency of replenishment of stocks. The model scenario uses transformations of the phase portrait of iterations, which, in the presence of disconnected boundaries of the areas of attraction of alternative attractors and a strange chaotic repeller, lead to the uncertainty effects arising due to chaotic modes in a deterministic model. The properties of the described model scenario with a chaotic regime of dynamics are confirmed by the example of the catch of oceanic species of crustaceans. [ABSTRACT FROM AUTHOR]

Published

2022

11. Dynamic Light Control Using Bionic Dielectric Elastomer Iris Actuators.

Author

Martin, Sina, Bruns, Arne, and Franke, Jörg

Subjects

*IRIS (Eye), *ACTUATORS, *BIONICS, *ELASTOMERS, *LUMINOUS flux, *ELECTROMECHANICAL effects, *DAYLIGHT, *RADIO jets (Astrophysics)

Abstract

Apertures are used in optical systems to limit the luminous flux. In the human eye the iris serves this purpose but can be damaged requiring an implant, which to date is static, limiting the optical performance. The authors thus report the development of a prototype demonstrating the feasibility of a flexible dynamic iris implant manufactured with an automated manufacturing technique. The presented actuators are printed via aerosol jet printing allowing a high reliability in produced electrode quality. Through optimization of the actuator design for maximum contraction they demonstrate a pupil area reduction of 13.40% or 6.94% reduction of pupil diameter, respectively. Thereby the prototype demonstrates an illuminance reduction of 18.25% in the central visual axis. Furthermore, they present a first iteration of a bionic closed‐loop control mimicking the human iris reflex thus laying the foundation for a self‐controlled iris implant. [ABSTRACT FROM AUTHOR]

Published

2022

12. Beyond the Microbiome: Germ-ganism? An Integrative Idea for Microbial Existence, Organization, Growth, Pathogenicity, and Therapeutics.

Author

Kambouris, Manousos E., Goudoudaki, Stavroula, Kritikou, Stavroula, Milioni, Aphroditi, Karamperis, Kariofyllis, Giavasis, Ioannis, Patrinos, George P., Velegraki, Aristea, and Manoussopoulos, Yiannis

Subjects

*MICROBIAL virulence, *THERAPEUTICS, *COVID-19 pandemic, *TWENTY-first century, *BIOSECURITY, *ECOSYSTEMS

Abstract

The advances made by microbiome research call for new vocabulary and expansion of our thinking in microbiology. For example, the life-forms presenting in both unicellular and multicellular formats invite us to rethink microbial existence, organization, growth, pathogenicity, and therapeutics in the 21st century. A view of such populations as parts of single organisms with a loose, distributed multicellular organization, introduced here as a germ-ganism, rather than communities, might open up interesting prospects for diagnostics and therapeutics innovation. This study tested and further contextualized the concept of germ-ganism using solid cultures of bacteria and fungi. Based on our findings and the literature reviewed herein, we propose that germ-ganism has synergy with a systems medicine approach by broadening host-environment interactions from cells and microorganisms to a scale of biological ecosystems. Germ-ganism also brings about the possibility of studying the multilevel impacts of novel therapeutic agents within and across networks of microbial ecosystems. The germ-ganism would lend itself, in the long term, to a veritable biocybernetics system, while in the mid-term, we anticipate it will contribute to new diagnostics and therapeutics. Biosecurity applications would be immensely affected by germ-ganism. Industrial applications of germ-ganism are of interest as a more sustainable alternative to costly solutions such as tampered strains/microorganisms. In conclusion, germ-ganism is informed by lessons from microbiome research and invites rethinking microbial existence, organization, and growth as an organism. Germ-ganism has vast ramifications for understanding pathogenicity, and clinical, biosecurity, and biotechnology applications in the current historical moment of the COVID-19 pandemic and beyond. [ABSTRACT FROM AUTHOR]

Published

2022

13. ZNACZENIE BIOCYBERNETYKI W NAUCZANIU INŻYNIERII BIOMEDYCZNEJ NA PODSTAWIE OPINII STUDENTÓW.

Author

TADEUSIEWICZ, RYSZARD

Abstract

Teaching Biomedical Engineering now takes place in most technical schools and in some universities. Each of them uses its own curricula, tailored to the goals of education and the qualifications of their staff. This diversity concerns, among other things, the lecture on the subject of biocybernetics. At the birth of the Biomedical Engineering studies (which was launched at the AGH University of Science and Technology a year earlier than in all other Polish universities), the biocybernetics lecture was the first one that the students listened to. Following the example of AGH, other universities also introduced this lecture. Later, however, many universities gave up teaching this subject, and Act 2.0 changed the name of the scientific discipline for many years called "Biocybernetics and Biomedical Engineering" to "Biomedical Engineering", limiting the chances of obtaining degrees in biocybernetics. Nevertheless, at AGH UST, this subject is still taught at the beginning of the Biomedical Engineering course. In the academic year 2021/22, a survey was conducted among the students; having had one semester of lectures, they answered the question: "How will the knowledge of biocybernetics help me in the profession of a biomedical engineering specialist?" This article presents the results of this survey and encourages you to think about it. [ABSTRACT FROM AUTHOR]

Published

2022

14. Exploring the biocybernetic loop : classifying psychophysiological responses to cultural artefacts using physiological computing

Author

Karran, Alexander John, Fairclough, Stephen H., and Fergus, Paul

Subjects

500, Psychology. Psychophysiology, Biocybernetics, Machine Learning, Classification, Real-time

Abstract

The aim of this research project was to provide a bio-sensing component for a real-time adaptive technology in the context of cultural heritage. The proposed system was designed to infer the interest or intention of the user and to augment elements of the cultural heritage experience interactively through implicit interaction. Implicit interaction in this context is the process whereby the system observes the user while they interact with artefacts; recording psychophysiological responses to cultural heritage artefacts or materials and acting upon these responses to drive adaptations in content in real-time. Real-time biocybernetic control is the central component of physiological computing wherein physiological data are converted into a control input for a technological system. At its core the bio-sensing component is a biocybernetic control loop that utilises an inference of user interest as its primary driver. A biocybernetic loop is composed of four main stages: inference, classification, adaptation and interaction. The programme of research described in this thesis is concerned primarily with exploration of the inference and classification elements of the biocybernetic loop but also encompasses an element of adaptation and interaction. These elements are explored first through literature review and discussion (presented in chapters 1-5) and then through experimental studies (presented in chapters 7-11).

Published

2014

15. Pupil detection schemes in human eye: a review.

Author

Min-Allah, Nasro, Jan, Farmanullah, and Alrashed, Saleh

Subjects

*HOUGH transforms, *EYEBROWS, *CATARACT, *IRIS recognition, *VISIBLE spectra, *OPTICAL reflection, *EYE tracking, *INTRAOCULAR lenses

Abstract

Pupil detection in a human eyeimage or video plays a key role in many applications such as eye-tracking, diabetic retinopathy screening, smart homes, iris recognition, etc. Literature reveals pupil detection faces many complications including light reflections, cataract disease, pupil constriction/dilation moments, contact lenses, eyebrows, eyelashes, hair strips, and closed eye. To cope with these challenges, research community has been struggling to devise resilient pupil localization schemes for the image/video data collected using the near-infrared (NIR) or visible spectrum (VS) illumination. This study presents a critical review of numerous pupil detection schemes taken from standard sources. This review includes pupil localization schemes based on machine learning, histogram/thresholding, Integro-differential operator (IDO), Hough transform and among others. The probable pros and cons of each scheme are highlighted. Finally, this study offers recommendations for designing a robust pupil detection system. As scope of pupil detection is very broader, therefore this review would be a great source of information for the relevant research community. [ABSTRACT FROM AUTHOR]

Published

2021

16. Design method for a bionic wrist based on tensegrity structures

Author

Jianwei Sun, Xuemin Cao, and Guangsheng Song

Subjects

biocybernetics, muscle, bone, physiological models, gait analysis, medical robotics, artificial limbs, biomechanics, motion control, design method, bionic wrist, tensegrity structure, traditional bionic upper limb structure design, motion pair, mechanical structure, high deformability, strong self-adaptability, multidirectional impact, biological characteristics, upper limbs, human body, upper limb wrist joints, related bones, mechanical model, two-bar tensile properties, movement characteristics, human muscles, optimised bionic upper limb wrist tensioning robot, bionic tensile wrist, human wrist, adaptive motion characteristics, Biotechnology, TP248.13-248.65, Biochemistry, QD415-436

Abstract

The traditional bionic upper limb structure design is limited by the motion pair and cannot guarantee the flexibility of the mechanical structure. The tensegrity structure has the characteristics of high deformability, strong self-adaptability, and resistance to multi-directional impact. According to the biological characteristics of the upper limbs of the human body, an anatomical study is performed on the upper limb wrist joints that achieve adduction/abduction, flexion/extension, to obtain the relationship between the movements of the related bones and muscles, and to simplify the shape and structure of the wrist. Equivalent mapping of a mechanical model based on two-bar tensile properties. Through the contraction and stretching of the spring, the movement characteristics of the human muscles are realised, and the optimised bionic upper limb wrist tensioning robot without motion pair is further obtained. Adams simulation is used to verify that the bionic tensile wrist can simulate the change movement of the human wrist. The experimental platform was built and a physical prototype was made and the prototype was tested. The results show that the bionic tensile wrist can realise the adaptive motion characteristics of the human wrist well and stably, which proves the validity and feasibility of this design method.

Published

2020

17. A distributed cognitive approach in cybernetic modelling of human vision in a robotic swarm.

Author

Podpora, Michal, Kawala-Sterniuk, Aleksandra, Kovalchuk, Viktoria, Bialic, Grzegorz, and Piekielny, Pawel

Subjects

*AGGREGATION (Robotics), *COMPUTER vision, *IMAGE analysis, *IMAGE processing, *MOBILE robots, *CYBERNETICS, *TEXT recognition

Abstract

Objectives: In this paper a novel approach regarding image analysis in Machine Vision applications was proposed. Methods: The presented concept consists of two issues: (1) shifting some of the complex image processing and understanding algorithms from a mobile robot to distributed computer, and (2) designing the cognitive system (in a distributed computer) in such a way, that it would be common for numerous robots. The authors of this work focused on image processing, and they propose to accelerate vision understanding by using Cooperative Vision (CoV), i.e., to get video input from cooperating robots and process it in a centralized system. Results: To verify the purposefulness of such approach, a comparative study is currently being conducted, involving a classical single-camera Computer Vision (CV) mobile robot and two (or more) single-camera CV robots cooperating in CoV mode. Conclusions: The CoV system is being designed and implemented so that the algorithm would be able to utilize multiple video sources for recognition of objects on the very same scene. [ABSTRACT FROM AUTHOR]

Published

2020

18. Modeling the Scenarios of Collapse of the Commercial Aquatic Populations off the Coast of Canada and Alaska*.

Author

Perevaryukha, A. Yu.

Subjects

*FISHERIES, *ATLANTIC cod, *FISH populations, *STATISTICS, *AQUATIC invertebrates

Abstract

Special situations, which are difficult to predict and to model by traditional methods, develop rapidly in population processes. A sudden collapse of commercial fish stocks, in addition to outbreaks of forest pests, are among the most economically significant nonlinear phenomena in ecosystems. According to systems analysis of statistical data on the dynamics of catches, the transitional stages of rapid degradation in completely different species of fish and aquatic invertebrates occur in a similar way. The most representative stages of the development of fish resources collapse have been distinguished. Restoration of the already critically depleted aquatic bioresources occurs at different rates. Based on the method of dynamically redefinable hybrid computational structure, we considered situations of collapse that occurred with crab off the coast of Alaska and northern cod off the coast of Canadian provinces of Newfoundland and Labrador. The resulting computational scenarios for collapse manifestation consist of three stages, all the way up to the degradation of bioresources. Bifurcations are implemented purposefully and follow the logic of the process. The modeling method is generalized for cases with stationary food resources and with oscillatory dynamics of food organisms. [ABSTRACT FROM AUTHOR]

Published

2020

19. МОДЕЛИРОВАНИЕ СЦЕНАРИЯ КОЛЛАПСОВ ПРОМЫСЛОВЫХ ПОПУЛЯЦИЙ У БЕРЕГОВ КАНАДЫ И АЛЯСКИ

Author

ПЕРЕВАРЮХА, А. Ю.

Abstract

Copyright of Cybernetics & Systems Analysis / Kibernetiki i Sistemnyj Analiz is the property of V.M. Glushkov Institute of Cybernetics of NAS of Ukraine and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2020

20. A cybernetic theory for EEG biofeedback

Author

Patterson, Kip Errett

Published

2017

21. Investigation of reciprocating friction characteristics between different bionic surfaces of prosthesis materials and skin

Author

Quanping Feng, Wei Li, Xidong Liu, Wei Ji, and Zhongrong Zhou

Subjects

friction, silicone rubber, prosthetics, elastomers, surface energy, biocybernetics, surface texture, adhesion, biomedical materials, friction characteristics, skin, tree frog, gecko feet, energy dissipation, reciprocating friction, silicone rubber substrate, friction energy, bionic prosthetic socket surface design, prosthetic substrates, quadrangular prism texture, bionic textures, microstructure, thermoplastic polyurethane elastomer, comprehensive weight rating method, Biotechnology, TP248.13-248.65, Biochemistry, QD415-436

Abstract

In this study, three types of bionic texture surfaces were designed, based on the microstructure of tree frog and gecko feet, for two typical prosthetic substrates: silicone rubber and thermoplastic polyurethane elastomer (TPU). The surface energy of all bionic texture surfaces, and the relative displacement and energy dissipation of the reciprocating friction between these bionic surfaces and skin, were investigated. The results revealed that the bionic texture of the prosthetic socket surface had an obvious influence on the surface characteristics and reciprocating characteristics of friction with the skin. According to the comprehensive weight rating method, the optimal bionic textures for the silicone rubber substrate were a regular hexagonal prism and a quadrangular prism; for the TPU substrate, only the regular quadrangular prism texture was optimal. These textures can effectively increase the surface energy of the surface of the prosthetic socket, thereby increasing its adhesion to skin and reducing the dissipation of friction energy when it interacts with the stump. This bionic prosthetic socket surface design helps improve the adaptation between the prosthetic socket and the stump.

Published

2019

22. Quantitative modeling of mathematical relationships in money, spending and the real economy : An evolutionary learning ethical view

Author

Masudul Alam Choudhury and M. Ishaq Bhatti

Published

2016

23. Linking Stress, Catecholamine Autotoxicity, and Allostatic Load with Neurodegenerative Diseases: A Focused Review in Memory of Richard Kvetnansky.

Author

Goldstein, David S. and Kopin, Irwin J.

Subjects

*NEURODEGENERATION, *CATECHOLAMINES, *CELLULAR aging, *PHYSIOLOGICAL stress

Abstract

In this Focused Review, we provide an update about evolving concepts that may link chronic stress and catecholamine autotoxicity with neurodegenerative diseases such as Parkinson's disease. Richard Kvetnansky's contributions to the field of stress and catecholamine systems inspired some of the ideas presented here. We propose that coordination of catecholaminergic systems mediates adjustments maintaining health and that senescence-related disintegration of these systems leads to disorders of regulation and to neurodegenerative diseases such as Parkinson's disease. Chronically repeated episodes of stress-related catecholamine release and reuptake, with attendant increases in formation of the toxic dopamine metabolite 3,4-dihydroxyphenylacetaldehyde, might accelerate this process. [ABSTRACT FROM AUTHOR]

Published

2018

24. The interspecies educator's cybernetic world

Author

Affifi, Ramsey

Published

2014

25. Formation of Hybrid Computational Structure for the Analysis of Critical Control Scenarios in Biocybernetics

Author

A. Y. Perevaryukha

Subjects

Computer science, Structure (category theory), Control engineering, Control (linguistics), Biocybernetics

Abstract

We have considered methods of computational modeling of rapid processes in ecosystems and events of changes with extreme amplitude of abundance. For biocybernetics, the phenomena of degradation of the commercial population in the form of a sudden collapse for specialists and an explosive increase in the number of a new species after invasion — outbreaks are of the type predicted with difficulties. We have developed and ecologically substantiated a method for modeling a group of rapid phenomena, including the calculation of threshold states and transient modes. Algorithmically implemented computational structure, which describes spontaneous modes of rapid transformations in ecodynamics based on the internal properties of biosystems. New model is based on the formalization of threshold effects in regulation of reproduction, included as additional functionals in the basic hybrid structure for research in scenario experiments. Computational scenario is obtained for a generalized description of the extreme population process. We have considered the situation of the collapse of the commercial population with a quota-regulated harvest on the example of the king crab Paralithodes camtschaticus near the coast of Alaska. In the simulation scenario of the crab collapse, we took into account the logic of expert management of the level of exploitation of biological resources. The resulting control scenarios using the iterative model use bifurcations and the loss of the invariance property by the attractor. Modeling with the expert logic of fishery management revealed the characteristic signs of the dynamics of crab collapse and predicted important stages in the process of degradation of exploited biological resources.

Published

2021

26. Homeostatic systems, biocybernetics, and autonomic neuroscience.

Author

Goldstein, David S. and Kopin, Irwin J.

Subjects

*TREATMENT of neurodegeneration, *PHYSIOLOGICAL control systems, *HOMEOSTASIS, *NEUROSCIENCES, *NEUROPHYSIOLOGY, *AUTONOMIC nervous system

Abstract

In this review we describe a series of major concepts introduced during the past 150 years that have contributed to our current understanding about how physiological processes required for well-being and survival are regulated. One can theorize that hierarchical networks involving input-output relationships continuously orchestrate and learn adaptive patterns of observable behaviors, cognition, memory, mood, and autonomic systems. Taken together, these networks function as “good regulators” determining levels of internal variables and act as if there were homeostatic comparators (“homeostats”). The consequences of models with vs. without homeostats remain the same in terms of allostatic load and the eventual switch from stabilizing negative feedback loops to destabilizing, pathogenic positive feedback loops. Understanding this switch seems important for comprehending senescence-related, neurodegenerative disorders that involve the autonomic nervous system. Our general proposal is that disintegration of homeostatic systems causes disorders of regulation in degenerative diseases and that medical cybernetics can inspire and rationalize new approaches to treatment and prevention. [ABSTRACT FROM AUTHOR]

Published

2017

27. Measurement error analysis of binocular stereo vision: effective guidelines for bionic eyes.

Author

Wang, Qingbin, Yin, Yingjie, Zou, Wei, and Xu, De

Abstract

The depth measurement error of bionic eyes consisting of two active cameras is derived by considering the eyes' rotation angle errors and image feature extraction errors. The effect factors of the depth measurement are obtained from the calculation formula of depth error. Based on the analysis of these effect factors, some effective guidelines for bionic eyes are proposed to reduce the measurement errors. The guidelines suggest keeping long baseline, observing the target as nearly as possible, controlling two active cameras with the same angular velocity and keeping the target on Zw axis if possible. The simulation experiments and practical experiments in bionic eyes platform validate the effectiveness of the proposed guidelines. [ABSTRACT FROM AUTHOR]

Published

2017

28. Control of age-structured population dynamics with intraspecific competition in context of bioreactors.

Author

Kurth, Anna-Carina and Sawodny, Oliver

Subjects

*POPULATION dynamics, *SEWAGE disposal plants, *BIOREACTORS, *DISTRIBUTED parameter systems, *COMPETITION (Biology), *DIFFERENTIAL equations

Abstract

Bioreactors are used for commercial manufacturing of products or as a simplified representation of wastewater treatment plants. If it is taken into account that individual organisms from the population in the bioreactor behave differently, an additional structure such as age can be added to the population. This leads to a nonlinear, hyperbolic, integro-partial differential equation (IPDE) with non-local integral boundary conditions (BC) in the modeling. The steady-states of this system can be uniquely determined by a substitution due to the non-local BC. Using the asymptotic properties of the system, the IPDE is split into finite-dimensional dynamics and infinite dimensional internal dynamics. The internal dynamics are globally exponentially stable. Therefore, a feedforward control based on the finite dimensional dynamics is designed, augmented with a feedback control to compensate for the remaining influence of the internal dynamics on the output. Finally, the control concept is supplemented by an observer. Global exponential attractiveness of certain reference trajectories is proven. The overall control concept is validated experimentally with a bioreactor. A system parameter is identified and it is shown that by applying the control concept, the biomass can track various reference trajectories with small errors. [ABSTRACT FROM AUTHOR]

Published

2023

29. The fractional Fourier transform as a biomedical signal and image processing tool: A review

Author

Alejandro Gómez-Echavarría, Catalina Tobón, and Juan P. Ugarte

Subjects

Computer science, 0206 medical engineering, Biomedical Engineering, Biomedical signal, Image processing, 02 engineering and technology, computer.software_genre, 020601 biomedical engineering, Fractional Fourier transform, Field (computer science), Time–frequency analysis, 0202 electrical engineering, electronic engineering, information engineering, 020201 artificial intelligence & image processing, Detection theory, Data mining, computer, Biocybernetics

Abstract

This work presents a literature review of the fractional Fourier transform (FrFT) investigations and applications in the biomedical field. The FrFT is a time-frequency analysis tool that has been used for signal and image processing due to its capability in capturing the non-stationary characteristics of real signals. Most biomedical signals are an example of such non-stationarity. Thus, the FrFT-based solutions can be formulated, aiming to enhance the health technology. As the literature review indicates, common applications of the FrFT involves signal detection, filtering and features extraction. Establishing adequate solutions for these tasks requires a proper fractional order estimation and implementing the suitable numeric approach for the discrete FrFT calculation. Since most of the reports barely describe the methodology on this regard, it is important that future works include detailed information about the implementation criteria of the FrFT. Although the applications in biomedical sciences are not yet among the most frequent FrFT fields of action, the growing interest of the scientific community in the FrFT, supports its practical usefulness for developing new biomedical tools. © 2020 Nalecz Institute of Biocybernetics and Biomedical Engineering of the Polish Academy of Sciences

Published

2020

30. On the prediction of premature births in Hispanic labour patients using uterine contractions, heart beat signals and prediction machines.

Author

Nsugbe E, Reyes-Lagos JJ, Adams D, and Samuel OW

Abstract

Preterm birth is a global epidemic affecting millions of mothers across different ethnicities. The cause of the condition remains unknown but has recognised health-based implications, in addition to financial and economic ones. Machine Learning methods have enabled researchers to combine datasets using uterine contraction signals with various forms of prediction machines to improve awareness of the likelihood of premature births. This work investigates the feasibility of enhancing these prediction methods using physiological signals including uterine contractions, and foetal and maternal heart rate signals, for a population of south American women in active labour. As part of this work, the use of the Linear Series Decomposition Learner (LSDL) was seen to lead to an improvement in the prediction accuracies of all models, which included supervised and unsupervised learning models. The results from the supervised learning models showed high prediction metrics upon the physiological signals being pre-processed by the LSDL for all variations of the physiological signals. The unsupervised learning models showed good metrics for the partitioning of Preterm/Term labour patients from their uterine contraction signals but produced a comparatively lower set of results for the various kinds of heart rate signals investigated., Competing Interests: The authors declare no conflict of interest., (© 2023 The Authors. Healthcare Technology Letters published by John Wiley & Sons Ltd on behalf of The Institution of Engineering and Technology.)

Published

2023

31. A biocybernetic method to learn hand grasping posture

Author

Rezzoug, N. and Gorce, P.

Published

2003

32. The decomposition method for solving first order partial differential equations

Author

Khelifa, S. and Cherruault, Y.

Published

2002

33. A Methodology for Vertical Translation Between Molecular and Organismal Level in Biological Feedback Loops

Author

Johannes W Dietrich

Subjects

Physics, Causality (physics), Nonlinear system, Quadratic equation, Systems biology, Exponent, Feedback loop, Biological system, Integer (computer science), Biocybernetics

Abstract

Feedback loops are among the primary network motifs in living organisms, ensuring survival via homeostatic control of key metabolites and physical properties. However, from a scientific perspective, their characterization is unsatisfactory since the usual modelling methodology is incompatible with the physiological and biochemical basis of metabolic networks. Therefore, any “vertical translation”, i.e. the study of the correspondence between molecular and organismal levels of causality, is difficult and in most cases impossible.As a viable solution, we demonstrate an alternative modelling platform for biological feedback loops that is based on key biochemical principles, including mass action law, enzyme kinetics, binding of mediators to transporters and receptors, and basic pharmacological properties. Subsequently, we show how this framework can be used for translating from molecular to systems-level behaviour.Basic elements of the proposed modelling platform include Michaelis-Menten kinetics defining nonlinear dependence of the output y(t) on an input signal x(t) with the Hill-Langmuir equation y(t) = G * x(t)n / (D + x(t)n), non-competitive inhibition for linking stimulatory and inhibitory inputs with y(t) = G + x1(t) / ((D + x1(t) * (1 + x2(t) / KI)) and processing structures for distribution and elimination.Depending on the structure of the feedback loop, its equifinal (steady-state) behaviour can be solved in form of polynomials, with a quadratic equation for the simplest case with one feedback loop and a Hill exponent of 1, and higher-grade polynomials for additional feedback loops and/or integer Hill exponents > 1. As a companion to the analytical solution, a flexible class library (CyberUnits) facilitates computer simulations for studying the transitional behaviour of the feedback loop.Unlike other modelling strategies in biocybernetics and systems biology, this platform allows for straightforward translation from the statistical properties of single molecules on a “microscopic” level to the behaviour of the whole feedback loop on an organismal “macroscopic” level. An example is the Michaelis constant D, which is equivalent to (k–1 + k2) / k1, where k1, k–1 and k2 denote the rate constants for the association and dissociation of the enzyme-substrate or receptor-hormone complex, respectively. From the perspective of a single molecule the rate constants represent the probability (per unit time) that the corresponding reaction will happen in the subsequent time interval. Therefore 1/k represents the mean lifetime of the complex. Very similar considerations apply to the other described constants of the feedback loop.In summary, this modelling technique renders the translation from a molecular level to a systems perspective possible. In addition to providing new insights into the physiology of biological feedback loops, it may be a valuable tool for multiple disciplines of biomedical research, including drug design, molecular genetics and investigations on the effects of endocrine disruptors.

Published

2021

34. Frank H. George Research Award winning paper Cancer self‐remission and tumour instability – a cybernetic analysis Towards a fresh paradigm for cancer treatment

Author

Dutta Majumder, D. and Roy, Prasun Kumar

Published

2000

35. A neural network for modeling the process of transcriptional control in eukaryotic cells

Author

Saci, Emilie A. and Cherruault, Yves

Published

1999

36. Control of the first‐line human defence system An autocatalytic model

Author

Kochel, Bonawentura

Published

1999

37. An approximation method for the optimization of continuous functions of n variables by densifying their domains

Author

Mora, Gaspar and Cherruault, Yves

Published

1999

38. The theoretic calculation time associated to &agr;‐dense curves

Author

Mora, Gaspar and Cherruault, Yves

Published

1998

39. Biocybernetics and Biosemiosis.

Author

Johnson, Donald

Subjects

*PHYSIOLOGICAL control systems, *COMPUTER storage devices, *COMPUTER software, *INFORMATION science, *DNA analysis, *RNA analysis

Published

2013

40. Biocybernetics: fitting the oxyhaemoglobin dissociation curve

Author

Engel, Alejandro B., Massad, Eduardo, and Pulino, Petronio

Published

1996

41. Philosophical aspects of biological information, in the course of organic regeneration

Author

Szkutnik, Dariusz Adam

Subjects

thermodynamics, embryology, biocybernetics, matter, information, energy

Abstract

The fundamental element of developmental processes is the category of information, which gives the dynamic character to the existence of an organic whole. The manifestations of its causal action were noticed already in antiquity by Aristotle, while observing the development of organisms. Today, it manifests itself clearly in the field of experimental research on organic regeneration. Still, however, information as a causal developmental parameter requires an unequivocal definition in the context of its “controlling action” in relation to matter and energy.

Published

2021

42. Inside and Outside the Zone of Proximal Development: An Ecofunctional Reading of Vygotsky.

Abstract

The Zone of Proximal Development (ZPD) has drawn attention from psychologists and educators and has oriented their research, diagnosis, and educational work toward new grounds. We hold that, rather than a term to be added to conventional psychology and pedagogy, the ZPD provides us with an instrument whose use will inevitably lead to a reappraisal and renewal of theory. We suggest that this concept also operated as a Zone of Proximal Development in its own right for Vygotsky's theoretical thought. He focused his endeavors on the areas of conflict where his contemporaries ran into difficulties by exploring three theoretical frontiers: “1. The evolutionary and historical frontier (change and evolution of the child and individual, of the species, of cultures). 2. The identity frontier (the view of the functional system as shared, of functions as socially distributed). 3. The ecological frontier between the internal and external, the mental and the material, the organism and the medium.” A large part of the literature on Vygotsky and the research carried out on the basis of his ideas have developed his proposals with regard to the first two frontiers. Although the third frontier has received scant attention, it is in our opinion essential to a full understanding of Vygotsky's thought, especially the concept of ZPD. [ABSTRACT FROM AUTHOR]

Published

2007

43. Quantitative modeling of mathematical relationships in money, spending and the real economy.

Author

Choudhury, Masudul Alam and Bhatti, M. Ishaq

Subjects

*BANKING industry, *ECONOMIC development, *FISCAL policy, *ECONOMIC research, *ECONOMICS

Abstract

Purpose – The purpose of this paper is to bring out the topic of ethics and economics in reference to the nature of complementarities that can exist between monetary and fiscal activities. The connector in such complementarities is the unity of knowledge that can be generated in the inter-causal relations between monetary and fiscal activities. Design/methodology/approach – The methodology adopted is of measuring out by quantitative modeling how well there exists complementary relations or otherwise between the Central Bank and commercial bank in order to mathematically explain the role of participatory learning behavior using money, debt, and spending variables. Findings – The argument placed takes the conceptual form of result to show that there would be a prolonged extension of the non-inflationary and technological induction of economic growth in a regime of complementing money and fiscal policies. Originality/value – The role of the quantity of money in a non-inflationary economic growth is set against the background of the tripartite inter-causal relationships between the Central Bank, the commercial bank, and the real economy. Analytical methods used bring out the role of knowledge in the inter-causal relations termed as circular causation for the attainment of social well-being in response to a stable and advancing economy with the ethicality of unity of knowledge. [ABSTRACT FROM AUTHOR]

Published

2016

44. Package Optimization of the Cilium-Type MEMS Bionic Vector Hydrophone.

Author

Liu Linxian, Zhang Wendong, Zhang Guojun, and Xue Chenyang

Abstract

We optimize the package of the cilium-type MEMS bionic vector hydrophone introduced by Chenyang and Wendong in 2007, which has the disadvantages of a low receiving sensitivity, narrow frequency band, and fluctuating frequency response curve. Initially, a full parametric analysis of frequency response and sensitivity with different material sound transparent cap were made. Then, we propose and realize an umbrella-type packaged structure with high receiving sensitivity and wide frequency band. The theoretical analysis and simulation analysis are conducted by ANSYS software and LMS virtual. Lab acoustic software. Finally, to verify the practicability of the package, the umbrella-type packaged hydrophone calibration was carried out in the National Defense Underwater Acoustics Calibration Laboratory of China. The test results show that the performance of umbrella-type hydrophone has been greatly improved compared with the previous packaged hydrophone: exhibiting a receiving sensitivity of -178 dB (increasing by 20 dB, 0-dB reference 1 V/μPa), the frequency response ranging from 20 Hz to 2 kHz (broaden one times), the fluctuation of frequency response curve within ±2 dB, and a good dipole directivity. [ABSTRACT FROM PUBLISHER]

Published

2014

45. Different Approaches to Solving the Problem of Reconstructing the Distance Matrix Between DNA Chains

Author

Elena Melnikova, Boris Melnikov, and Marina Trenina

Subjects

Matrix (mathematics), Distance matrix, Basis (linear algebra), Computer science, Metric (mathematics), Branch and bound method, Development (differential geometry), Algorithm, Comparative evaluation, Biocybernetics

Abstract

In this paper, we consider one of the tasks of biocybernetics, i.e. the problem of reconstructing the distance matrix between DNA sequences. In this problem, not all the elements of the matrix under consideration are known at the input of the algorithm (usually 50% or less elements). The basis for the development of the algorithm for reconstructing such a matrix is the method of comparative evaluation of the algorithms for calculating distances between DNA sequences developed and investigated by us earlier. In this analysis, the badness of each of the triangles of the matrix determined by us was applied.

Published

2020

46. An Introduction to Neuroergonomics: From Brains at Work to Human-Swarm Teaming

Author

Hussein A. Abbass

Subjects

Cognitive science, Engineering, Work (electrical), business.industry, Neuroergonomics, Swarm behaviour, business, Working environment, Augmented cognition, Work environment, Biocybernetics

Abstract

The field of Neuroergonomics sits at the interface between humans’ brains and humans’ working environment with an aim to improve the work humans do. In this chapter, I will review the scientific journey that led to the birth of Neuroergonomics. The journey starts from the Biocybernetics and Brain–Computer Interfaces projects in 1960s, followed by work on adaptive aiding in 1970s, and all the way to early 2000s with work on Augmented Cognition and Neuroergonomics. An extension to Neuroergonomics gave birth to Cognitive-Cyber Symbiosis, whereby Neuroergonomics is augmented with artificial intelligence agents that act as relationship managers between the human brain and the information-centric work environment. Some challenges facing these fields today are then discussed using a human-swarm teaming lens.

Published

2020

47. Evolution of cybernetics: philosophical and methodological analysis

Author

Vladimir Lepskiy

Subjects

Cognitive science, 0209 industrial biotechnology, medicine.medical_specialty, Engineering cybernetics, Conceptualization, Computer science, media_common.quotation_subject, Rationality, 02 engineering and technology, Medical cybernetics, Theoretical Computer Science, 020901 industrial engineering & automation, Control and Systems Engineering, Originality, Sociocybernetics, 0202 electrical engineering, electronic engineering, information engineering, Computer Science (miscellaneous), medicine, Cybernetics, 020201 artificial intelligence & image processing, Engineering (miscellaneous), Social Sciences (miscellaneous), media_common, Biocybernetics

Abstract

Purpose The aim of this paper is to elaborate the connection between the evolution of cybernetics and the development of scientific rationality (classical, non-classical, post-non-classical) and to emphasize the relevance of the formation of post-non-classical cybernetics for self-developing reflexive-active environment (the third-order cybernetics). Design/methodology/approach This paper includes interdisciplinary analysis of the evolution of cybernetics and possible directions of its development. Findings A connection between the types of scientific rationality (classical, non-classical and post-non-classical) and the stages of the development cybernetics is presented. Classical rationality is first-order cybernetics dealing with observed systems (an external observer). Non-classical rationality is second-order cybernetics dealing with observing systems (built-in observer). Post-non-classical rationality is third-order cybernetics dealing with the self-developing reflexive-active environment (distributed observer). Research limitations/implications This is an initial theoretical conceptualization, which needs a broader assessment and case studies. Practical implications This proposed direction for the analysis of cybernetics opens new approaches to social control on the basis of the subject-focused models and integration of traditional cybernetic tools. Social implications Third-order cybernetics will promote the development of civil society. Direct democracy receives new tools for development. Originality/value The value of this research is in the interdisciplinary analysis of the cybernetics evolution and in new possible directions for its development.

Published

2018

48. Philosophy of gustatory perception strategy for hand gesture recognition.

Author

Kashef, Nermeen El, Hassan, Yasser Fouad, Mahar, Khaled, and Fahmy, Mustafa H.

Subjects

*HAND signals, *SENSES, *ARTIFICIAL intelligence, *PHYSIOLOGICAL control systems, *BLOOD sugar monitoring, *GENETIC algorithms

Abstract

Purpose - Nature is the single and most complex system that has been always studied, and no one can compete Mother Nature, but we can learn from her, by many new methodologies through biology. The paper aims to discuss this issue. Design/methodology/approach - In this paper, being inspired by the mechanism through which our Mother Nature handling human taste, a proposed model for clustering and classification hand gesture is introduced based on human taste controlling strategy. Findings - The model can extract information from measurement data and handling it as the structure of tongue and the nervous systems of human taste recognition. Originality/value - The efficiency of proposed model is demonstrated experimentally on classifying the sign language data set; in the high recognition accuracy obtained for numbers of ASL was 95.52 percent. [ABSTRACT FROM AUTHOR]

Published

2015

49. Optimal vaccination policy and cost analysis for epidemic control in resource-limited settings.

Author

Yang, Kuan, Wang, Ermei, Zhou, Yinggao, and Zhou, Kai

Subjects

*OPTIMAL control theory, *LAGRANGE multiplier, *COST analysis, *PHYSIOLOGICAL control systems, *PREVENTION of epidemics, *MATHEMATICAL models

Abstract

Purpose - The purpose of this paper is to use analytical method and optimization tools to suggest time-optimal vaccination program for a basic SIR epidemic model with mass action contact rate when supply is limited. Design/methodology/approach - The Lagrange Multiplier Method and Pontryagin's Maximum Principle are used to explore optimal control strategy and obtain analytical solution for the control system to minimize the total cost of disease with boundary constraint. The numerical simulation is done with Matlab using the sequential linear programming method to illustrate the impact of parameters. Findings - The result highlighted that the optimal control strategy is Bang-Bang control - to vaccinate with maximal effort until either all of the resources are used up or epidemic is over, and the optimal strategies and total cost of vaccination are usually dependent on whether there is any constraint of resource, however, the optimal strategy is independent on the relative cost of vaccination when the supply is limited. Practical implications - The research indicate a practical view that the enhancement of daily vaccination rate is critical to make effective initiatives to prevent epidemic from out breaking and reduce the costs of control. Originality/value - The analysis of the time-optimal application of outbreak control is of clear practical value and the introducing of resource constraint in epidemic control is of realistic sense, these are beneficial for epidemiologists and public health officials. [ABSTRACT FROM AUTHOR]

Published

2015

50. The Role of Technology and Engineering Models in Transforming Healthcare.

Author

Pavel, Misha, Jimison, H. B., Wactlar, H. D., Hayes, T. L., Barkis, W., Skapik, J., and Kaye, J.

Abstract

The healthcare system is in crisis due to challenges including escalating costs, the inconsistent provision of care, an aging population, and high burden of chronic disease related to health behaviors. Mitigating this crisis will require a major transformation of healthcare to be proactive, preventive, patient-centered, and evidence-based with a focus on improving quality-of-life. Information technology, networking, and biomedical engineering are likely to be essential in making this transformation possible with the help of advances, such as sensor technology, mobile computing, machine learning, etc. This paper has three themes: 1) motivation for a transformation of healthcare; 2) description of how information technology and engineering can support this transformation with the help of computational models; and 3) a technical overview of several research areas that illustrate the need for mathematical modeling approaches, ranging from sparse sampling to behavioral phenotyping and early detection. A key tenet of this paper concerns complementing prior work on patient-specific modeling and simulation by modeling neuropsychological, behavioral, and social phenomena. The resulting models, in combination with frequent or continuous measurements, are likely to be key components of health interventions to enhance health and wellbeing and the provision of healthcare. [ABSTRACT FROM PUBLISHER]

Published

2013