The Human Organism as an Integrated Interaction Network: Recent Conceptual and Methodological Challenges

Lehnertz, Klaus; Bröhl, Timo; Rings, Thorsten

doi:10.3389/fphys.2020.598694

Cited by 20 publications

(18 citation statements)

References 203 publications

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“…The proposed approach to estimate MIR in the presence of short and possibly noisy point process data is recommended for applications in the field of Network Physiology, where the estimation of organ system interactions is typically challenged by the inherently complex nature of human physiological signals (Lehnertz et al, 2020). In our work, where complex point process interactions between the heartbeat timings and the arrival times of the sphygmic wave on the body periphery have been analyzed, we detected significant coupling between the two processes in all subjects and experimental conditions.…”

Section: Discussionmentioning

confidence: 99%

Measuring the Rate of Information Exchange in Point-Process Data With Application to Cardiovascular Variability

Mijatovic

Pernice

Perinelli

et al. 2022

Front. Netw. Physiol.

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The amount of information exchanged per unit of time between two dynamic processes is an important concept for the analysis of complex systems. Theoretical formulations and data-efficient estimators have been recently introduced for this quantity, known as the mutual information rate (MIR), allowing its continuous-time computation for event-based data sets measured as realizations of coupled point processes. This work presents the implementation of MIR for point process applications in Network Physiology and cardiovascular variability, which typically feature short and noisy experimental time series. We assess the bias of MIR estimated for uncoupled point processes in the frame of surrogate data, and we compensate it by introducing a corrected MIR (cMIR) measure designed to return zero values when the two processes do not exchange information. The method is first tested extensively in synthetic point processes including a physiologically-based model of the heartbeat dynamics and the blood pressure propagation times, where we show the ability of cMIR to compensate the negative bias of MIR and return statistically significant values even for weakly coupled processes. The method is then assessed in real point-process data measured from healthy subjects during different physiological conditions, showing that cMIR between heartbeat and pressure propagation times increases significantly during postural stress, though not during mental stress. These results document that cMIR reflects physiological mechanisms of cardiovascular variability related to the joint neural autonomic modulation of heart rate and arterial compliance.

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Section: Discussionmentioning

confidence: 99%

Measuring the Rate of Information Exchange in Point-Process Data With Application to Cardiovascular Variability

Mijatovic

Pernice

Perinelli

et al. 2022

Front. Netw. Physiol.

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“…The higher-level external environment provides the necessary information to the lower levels that constrain their emergent possibilities, and thereby all them to "do the work" required to maintain life and health. The latter is particularly evident from network physiology research (36,54,55). For completeness the figure integrates the network relationships between the layers, as well as the main HPA-axis regulatory pathways.…”

Section: Top-down Causation In Complex Adaptive Systemsmentioning

confidence: 98%

“…Importantly, while we understand HPA axis regulation and while we have a fairly detailed understanding of its regulatory pathways, it remains yet unclear how the underlying various low-level physiological networks work in detail, and how they interact with each other (54). However, while these "microscopic" physiological details are missing, they are not always necessary to appreciate their observable "macroscopic" consequences (36).…”

Section: Inflammatory Regulationmentioning

confidence: 99%

Health and Disease Are Dynamic Complex-Adaptive States Implications for Practice and Research

Sturmberg

2021

Front. Psychiatry

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Interoception, the ability to convey one's overall physiological state, allows people to describe their health along an experiential continuum, from excellent, very good, good, fair to poor. Each health state reflects a distinct pattern of one's overall function. This assay provides a new frame of understanding health and disease as complex-adaptive system states of the person as-a-whole. It firstly describes how complex patterns can emerge from simple equations. It then discusses how clinical medicine in certain domains has started to explore the pattern characteristics resulting in the heterogeneity of disease, and how this better understanding has improved patient management. The experiential state of health can be surprising to the observer—some are in good health with disabling disease, others are in poor health without the evidence of any. The main part of the assay describes the underlying complexity principles that contribute to health, and synthesizes available evidence from various research perspectives to support the philosophic/theoretical proposition of the complex-adaptive nature of health. It shows how health states arise from complex-adaptive system dynamics amongst the variables of a hierarchically layered system comprising the domains of a person's macro-level external environment to his nano-level biological blueprint. The final part suggests that the frame of health as a dynamic complex-adaptive state defines a new paradigm, and outlines ways of translating these expanded understandings to clinical practice, future research, and health system design.

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“…By understanding the bigger picture, it allows, on the one hand, the detection of potential drug targets, while at the same time offering the possibility of a systems approach to diagnosis and therapy ( 21 , 27 , 31 , 32 ). Furthermore, under the framework of the recently emerging field of network physiology, network approaches have proven valuable to describe the structural organization and functional interrelations between different physiological and organ systems on the whole-organism level ( 18 , 22 , 33 – 35 ). Noteworthy, in the last decade perhaps the most remarkable breakthroughs of complex network analysis were achieved in neuronal physiology, where these approaches are used to quantify the brain’s functional and anatomical organization and have reached the maturity to be translated into clinical practice ( 36 – 39 ).…”

Section: Introductionmentioning

confidence: 99%

From Isles of Königsberg to Islets of Langerhans: Examining the Function of the Endocrine Pancreas Through Network Science

Stožer

Šterk²,

Leitgeb³

et al. 2022

Front. Endocrinol.

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Islets of Langerhans are multicellular microorgans located in the pancreas that play a central role in whole-body energy homeostasis. Through secretion of insulin and other hormones they regulate postprandial storage and interprandial usage of energy-rich nutrients. In these clusters of hormone-secreting endocrine cells, intricate cell-cell communication is essential for proper function. Electrical coupling between the insulin-secreting beta cells through gap junctions composed of connexin36 is particularly important, as it provides the required, most important, basis for coordinated responses of the beta cell population. The increasing evidence that gap-junctional communication and its modulation are vital to well-regulated secretion of insulin has stimulated immense interest in how subpopulations of heterogeneous beta cells are functionally arranged throughout the islets and how they mediate intercellular signals. In the last decade, several novel techniques have been proposed to assess cooperation between cells in islets, including the prosperous combination of multicellular imaging and network science. In the present contribution, we review recent advances related to the application of complex network approaches to uncover the functional connectivity patterns among cells within the islets. We first provide an accessible introduction to the basic principles of network theory, enumerating the measures characterizing the intercellular interactions and quantifying the functional integration and segregation of a multicellular system. Then we describe methodological approaches to construct functional beta cell networks, point out possible pitfalls, and specify the functional implications of beta cell network examinations. We continue by highlighting the recent findings obtained through advanced multicellular imaging techniques supported by network-based analyses, giving special emphasis to the current developments in both mouse and human islets, as well as outlining challenges offered by the multilayer network formalism in exploring the collective activity of islet cell populations. Finally, we emphasize that the combination of these imaging techniques and network-based analyses does not only represent an innovative concept that can be used to describe and interpret the physiology of islets, but also provides fertile ground for delineating normal from pathological function and for quantifying the changes in islet communication networks associated with the development of diabetes mellitus.

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The Human Organism as an Integrated Interaction Network: Recent Conceptual and Methodological Challenges

Cited by 20 publications

References 203 publications

Measuring the Rate of Information Exchange in Point-Process Data With Application to Cardiovascular Variability

Measuring the Rate of Information Exchange in Point-Process Data With Application to Cardiovascular Variability

Health and Disease Are Dynamic Complex-Adaptive States Implications for Practice and Research

From Isles of Königsberg to Islets of Langerhans: Examining the Function of the Endocrine Pancreas Through Network Science

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