Organ System Network Disruption Is Associated With Poor Prognosis in Patients With Chronic Liver Failure

Tan, Yen Yi; Montagnese, Sara; Mani, Ali R.

doi:10.3389/fphys.2020.00983

Cited by 15 publications

(19 citation statements)

References 83 publications

(97 reference statements)

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“…Their results showed that in a cohort of critically ill patients, survivors consistently exhibited a higher number of edges and clusters compared to non-survivors in their organ connectivity network structures (Asada et al, 2016). In a recent report, we used a similar approach and showed that functional connectivity of organ systems is significantly disrupted in patients with cirrhosis who did not survive during 12-month follow up (Tan et al, 2020). However, the methodology of these studies is based on correlation analysis of a population of patients and cannot be used for mapping the network connectivity at the level of individual patients.…”

Section: Introductionmentioning

confidence: 92%

“…Seven standard clinical variables representing unique physiological functions or clinical feature were collected (serum albumin, ALB; total bilirubin, Bil; prothrombin time, PT; serum creatinine, Cr; ammonia, NH 4 ; serum sodium, Na; and hepatic encephalopathy, HE) based on a previous study (Tan et al, 2020). HE was classified as unimpaired, minimal and overt HE according to Montagnese et al (Montagnese et al, 2004;Vilstrup et al, 2014).…”

Section: Clinical Laboratory Variablesmentioning

confidence: 99%

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Prognosis and Survival Modelling in Cirrhosis Using Parenclitic Networks

Zhang

Oyelade

Moore

et al. 2022

Front. Netw. Physiol.

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Background: Liver cirrhosis involves multiple organ systems and has a high mortality. A network approach to complex diseases often reveals the collective system behaviours and intrinsic interactions between organ systems. However, mapping the functional connectivity for each individual patient has been challenging due to the lack of suitable analytical methods for assessment of physiological networks. In the present study we applied a parenclitic approach to assess the physiological network of each individual patient from routine clinical/laboratory data available. We aimed to assess the value of the parenclitic networks to predict survival in patients with cirrhosis.Methods: Parenclitic approach creates a network from the perspective of an individual subject in a population. In this study such an approach was used to measure the deviation of each individual patient from the existing network of physiological interactions in a reference population of patients with cirrhosis. 106 patients with cirrhosis were retrospectively enrolled and followed up for 12 months. Network construction and analysis were performed using data from seven clinical/laboratory variables (serum albumin, bilirubin, creatinine, ammonia, sodium, prothrombin time and hepatic encephalopathy) for calculation of parenclitic deviations. Cox regression was used for survival analysis.Result: Initial network analysis indicated that correlation between five clinical/laboratory variables can distinguish between survivors and non-survivors in this cohort. Parenclitic deviations along albumin-bilirubin (Hazard ratio = 1.063, p < 0.05) and albumin-prothrombin time (Hazard ratio = 1.138, p < 0.05) predicted 12-month survival independent of model for end-stage liver disease (MELD). Combination of MELD with the parenclitic measures could predict survival better than MELD alone.Conclusion: The parenclitic network approach can predict survival of patients with cirrhosis and provides pathophysiologic insight on network disruption in chronic liver disease.

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Section: Introductionmentioning

confidence: 92%

Section: Clinical Laboratory Variablesmentioning

confidence: 99%

Prognosis and Survival Modelling in Cirrhosis Using Parenclitic Networks

Zhang

Oyelade

Moore

et al. 2022

Front. Netw. Physiol.

Self Cite

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“…Alteration in the interactions within a layer will not only change the dynamics of that layer but also those of interacting layers, and thereby shift the integrated function of the system-as-a-whole ( 39 , 40 ). Physiological network properties have pragmatic clinical implications as exemplified in patients with liver failure ( 41 ) or severe critical illness ( 42 )—the breakdown/loss of network interconnection between the layers of system organization is associated with poor outcomes.…”

Section: Health Patterns—the Outcome Of Complex-adaptive Dynamicsmentioning

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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“…In recent years, the Network Physiology framework has been utilized in various fields of basic Physiology and Clinical Medicine, including multiple organ failure and sepsis in critically ill patients (Asada et al, 2016;Moorman et al, 2016), neonatal intensive care (Lavanga et al, 2020;Lucchini et al, 2020), liver disease (Tan et al, 2020), epilepsy and neurological disorders (Lin et al, 2020), diabetes and obesity (Podobnik et al, 2020;Prats-Puig et al, 2020), cancer (Liu et al, 2020), or psychiatry (Bolton et al, 2020), and has the potential for broad applications in the field of Exercise Physiology and Sports Medicine to uncover how the key physiological systems interact pairwise, that is, which links are the major mediators in a given network and how these links adjust their strength with accumulation of fatigue, after a training intervention, or in response to a certain pathological condition (e.g., musculoskeletal injury and neurodegenerative disease).…”

Section: Introductionmentioning

confidence: 99%

Network Physiology of Exercise: Vision and Perspectives

et al. 2020

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The basic theoretical assumptions of Exercise Physiology and its research directions, strongly influenced by reductionism, may hamper the full potential of basic science investigations, and various practical applications to sports performance and exercise as medicine. The aim of this perspective and programmatic article is to: (i) revise the current paradigm of Exercise Physiology and related research on the basis of principles and empirical findings in the new emerging field of Network Physiology and Complex Systems Science; (ii) initiate a new area in Exercise and Sport Science, Network Physiology of Exercise (NPE), with focus on basic laws of interactions and principles of coordination and integration among diverse physiological systems across spatio-temporal scales (from the sub-cellular level to the entire organism), to understand how physiological states and functions emerge, and to improve the efficacy of exercise in health and sport performance; and (iii) to create a forum for developing new research methodologies applicable to the new NPE field, to infer and quantify nonlinear dynamic forms of coupling among diverse systems and establish basic principles of coordination and network organization of physiological systems. Here, we present a programmatic approach for future research directions and potential practical applications. By focusing on research efforts to improve the knowledge about nested dynamics of vertical network interactions, and particularly, the horizontal integration of key organ systems during exercise, NPE may enrich Basic Physiology and diverse fields like Exercise and Sports Physiology, Sports Medicine, Sports Rehabilitation, Sport Science or Training Science and improve the understanding of diverse exercise-related phenomena such as sports performance, fatigue, overtraining, or sport injuries.

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Organ System Network Disruption Is Associated With Poor Prognosis in Patients With Chronic Liver Failure

Cited by 15 publications

References 83 publications

Prognosis and Survival Modelling in Cirrhosis Using Parenclitic Networks

Prognosis and Survival Modelling in Cirrhosis Using Parenclitic Networks

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

Network Physiology of Exercise: Vision and Perspectives

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