Allostatic load as a complex clinical construct: A case‐based computational modeling approach

Buckwalter, J. Galen; Castellani, Brian; McEwen, Bruce S.; Karlamangla, Arun S.; Rizzo, Albert; John, Bruce; O’Donnell, Kyle L.; Seeman, Teresa E.

doi:10.1002/cplx.21743

Cited by 32 publications

(40 citation statements)

References 54 publications

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“…Second, selected parameters reflect those for which information could be collected within the logistical and financial constraints of the MIDUS project itself. Selection of subscale components was confirmed by results of factor analyses (Buckwalter et al, in preparation). Measures of (1) cardiovascular functioning included resting systolic blood pressure, pulse pressure, and resting pulse rate.…”

Section: Methodsmentioning

confidence: 84%

Social status and biological dysregulation: The “status syndrome” and allostatic load

Seeman

Merkin

Karlamangla

et al. 2014

Social Science & Medicine

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Data from a national sample of 1255 adults who were part of the MIDUS (Mid-life in the U.S.) follow-up study and agreed to participate in a clinic-based in-depth assessment of their health status were used to test the hypothesis that, quite part from income or educational status, perceptions of lower achieved rank relative to others and of relative inequality in key life domains would be associated with greater evidence of biological health risks (i.e., higher allostatic load). Results indicate that over a variety of status indices (including, for example, the person’s sense of control, placement in the community rank hierarchy, perception of inequality in the workplace) a syndrome of perceived relative deprivation is associated with higher levels of biological dysregulation. The evidence is interpreted in light of the well-established associations between lower socio-economic status and various clinically identified health morbidities. The present evidence serves, in effect, both as a part of the explanation of how socio-economic disparities produce downstream morbidity, and as an early warning system regarding the ultimate health effects of currently increasing status inequalities.

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Section: Methodsmentioning

confidence: 84%

Social status and biological dysregulation: The “status syndrome” and allostatic load

Seeman

Merkin

Karlamangla

et al. 2014

Social Science & Medicine

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“…As a second example, in a recent study we conducted on the negative impact of stress, we treated allostatic load as our primary case [1]. We did this by conceptualizing it as a complex clinical construct, comprised of a large number of interdependent biological subsystems, which are represented by an even larger number of interconnected biomarkers.…”

Section: Stepmentioning

confidence: 99%

“…Hence, we come to the purpose of the current study: we seek to formalize our case-based density approach, as employed through the SAC Toolkit, in application to several of our recent health studies, including a study on allostatic load [1], public health [6], and international health [18], along with a forthcoming study on depression and wellbeing [19]. While the last three studies are all longitudinal, the first is discrete; nonetheless, we will refer to it here, as it was crucial to developing several of our steps.…”

Section: Introductionmentioning

confidence: 99%

Cases, clusters, densities: Modeling the nonlinear dynamics of complex health trajectories

Castellani¹,

Rajaram²,

Gunn

et al. 2015

Complexity

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In the health informatics era, modeling longitudinal data remains problematic. The issue is method: health data are highly nonlinear and dynamic, multilevel and multidimensional, comprised of multiple major/minor trends, and causally complex -making curve fitting, modeling and prediction difficult. The current study is fourth in a series exploring a case-based density (CBD) approach for modeling complex trajectories; which has the following advantages: it can (1) convert databases into sets of cases (k dimensional vectors) based on a set of bio-social variables, called traces; (2) compute the trajectory (velocity vector) for each case, based on (3) key traces from the k dimensional profile; (4) construct a theoretical map to explain these traces; (5) use vector quantization (i.e., k-means, topographical neural nets) to longitudinally cluster case trajectories into major/minor trends; (6) employ genetic algorithms and ordinary differential equations to create a microscopic (vector field) model (the inverse problem) of these trajectories; (7) look for complex steady-state behaviors (e.g., spiraling sources, etc) in the microscopic model; (8) draw from thermodynamics, synergetics and transport theory to translate the vector field (microscopic model) into the linear movement of macroscopic densities; (9) use the macroscopic model to simulate known and novel case-based scenarios (the forward problem); and (10) construct multiple accounts of the data by linking the theoretical map and k dimensional profile with the macroscopic, microscopic and cluster models. Given the utility of this approach, our purpose here is to organize our method (as applied to recent research) so it can be employed by others.

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“…Emergency evacuations of hospitals after hurricane Katharina and Sandy, and the May 22, 2011 tornado in Joplin illustrate the urgent need for modeling the adaptive capacity of hospitals during an extended loss of infrastructure [1]. Presidential Policy Directive 21 [2] and the U.S. Department of Homeland Security National Infrastructure Protection Plan (NIPP) [3] call for increasing resilience of the nation's critical infrastructure.The resilience is the ability to withstand, adapt to, and rapidly recover from a disruptive change [4][5][6][7][8][9]. Complex systems researchers use a holistic interdisciplinary approach to predict emergent behaviors in systems under large stress with the intent to better manage them.…”

mentioning

confidence: 99%

“…The resilience is the ability to withstand, adapt to, and rapidly recover from a disruptive change [4][5][6][7][8][9]. Complex systems researchers use a holistic interdisciplinary approach to predict emergent behaviors in systems under large stress with the intent to better manage them.…”

mentioning

confidence: 99%

System under large stress: Prediction and management of catastrophic failures

Hübler

2016

Complexity

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T he tensile strength of a chain is determined by its weakest link. Does this idea apply to more complex systems too? For instance, does the weakest thread of a spider web initiate cascading failure, when a strong wind gust is stretching the web to its limit? What happens to a computer when both the supply voltage and the ambient temperature are more than 20% outside its normal range of operations?Climate change, an increasingly more densely populated world and the rapid change of technology seem to put more systems under large stress. Engineering sustainable systems with a more favorable response to large stress appears to be an urgent societal need. Emergency evacuations of hospitals after hurricane Katharina and Sandy, and the May 22, 2011 tornado in Joplin illustrate the urgent need for modeling the adaptive capacity of hospitals during an extended loss of infrastructure [1]. Presidential Policy Directive 21 [2] and the U.S. Department of Homeland Security National Infrastructure Protection Plan (NIPP) [3] call for increasing resilience of the nation's critical infrastructure.The resilience is the ability to withstand, adapt to, and rapidly recover from a disruptive change [4][5][6][7][8][9]. Complex systems researchers use a holistic interdisciplinary approach to predict emergent behaviors in systems under large stress with the intent to better manage them. The long term goal is to engineer and design sustainable systems with more favorable behaviors under large stress. Typically the following 5-step approach is used: (1) First one uses cloud data, knowledge field experts and practitioners to construct a flow chart with many components. One keeps track of all relationships including nonlinearities. Figure 1 shows a schematic of a partial flow chart for a university. (2) Linear response theory is used to verify the response to small stress. The linearized model is considered complicated due to its many components, but is not called complex. (3) Agent based models on super computers such as the UIUC Blue Water system and NCSA's computer clusters are used to simulate the flow chart dynamics under large stress. (4) Key concepts of complex systems theory are used to describe the computed response to large stress. For instance the theory of catastrophes (including the failure of the weakest link and nonlinear resonances), deterministic chaos, synchronization, fractals, genetic algorithm, self-organized criticality, cellular automata, neural nets, rare events, and multiscale networks help to choose reproducible meaningful observables to analyze the resulting large data sets and to discover relationships between the control parameters and the observables.

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Allostatic load as a complex clinical construct: A case‐based computational modeling approach

Cited by 32 publications

References 54 publications

Social status and biological dysregulation: The “status syndrome” and allostatic load

Social status and biological dysregulation: The “status syndrome” and allostatic load

Cases, clusters, densities: Modeling the nonlinear dynamics of complex health trajectories

System under large stress: Prediction and management of catastrophic failures

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