SAPHIR - a multi-scale, multi-resolution modeling environment targeting blood pressure regulation and fluid homeostasis

Thomas, Sophie; Abdulhay, Enas; Baconnier, Pierre; Fontecave, Julie; Françoise, Jean–Pierre; Guillaud, François; Hannaert, Patrick; Hernández, Alfredo; Rolle, Virginie Le; Tahi, Fariza; Zehraoui, Farida

doi:10.1109/iembs.2007.4353884

Cited by 11 publications

(11 citation statements)

References 22 publications

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“…This would allow the model predictions to be directly compared to clinical studies such as INDANA [90]. To this end, refinements are being incorporated into the original Guyton model [32] as part of the SAPHIR project [13], such as a detailed model of the RAAS [34]. The culmination of these efforts will result in a richly-detailed and more accurate model of renal autoregulation being incorporated into the Guyton model, providing a platform for pharmacological predictions that may assist in the diagnosis and treatment of hypertension [77].…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, since one of the main limitations of the early Guyton models is the low-resolution description of most of their constituting modules, a framework was built to allow replacement of the original sub-modules by new versions at a higher temporal or spatial resolution [32]; e. g., a pulsatile heart was introduced to treat systolic and diastolic blood pressures instead of only mean blood pressure [33], and a detailed model of the renin-angiotensin-aldosterone system (RAAS) has also been integrated [34]. That work was also linked to efforts in the European VPH via two Exemplar Projects, one of which used our modular reimplementation of the Guyton model as the basic set of “bricks” for a collaborative core-modeling environment for multi-organ physiology modeling [13], [14], and the other uses the Guyton model as a demonstrator for the tagging of parameters and variables with a set of reference ontologies common to databases of high-throughput genomic and proteomic data [35]. Collaborators in the Physiome/VPH community have also carried out XML markup of the individual modules of the Guyton model in CellML (http://models.cellml.org/workspace/guyton_2008), thus providing precious documentation of its structure and content.…”

Section: Introductionmentioning

confidence: 99%

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Virtual Patients and Sensitivity Analysis of the Guyton Model of Blood Pressure Regulation: Towards Individualized Models of Whole-Body Physiology

et al. 2012

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Mathematical models that integrate multi-scale physiological data can offer insight into physiological and pathophysiological function, and may eventually assist in individualized predictive medicine. We present a methodology for performing systematic analyses of multi-parameter interactions in such complex, multi-scale models. Human physiology models are often based on or inspired by Arthur Guyton's whole-body circulatory regulation model. Despite the significance of this model, it has not been the subject of a systematic and comprehensive sensitivity study. Therefore, we use this model as a case study for our methodology. Our analysis of the Guyton model reveals how the multitude of model parameters combine to affect the model dynamics, and how interesting combinations of parameters may be identified. It also includes a “virtual population” from which “virtual individuals” can be chosen, on the basis of exhibiting conditions similar to those of a real-world patient. This lays the groundwork for using the Guyton model for in silico exploration of pathophysiological states and treatment strategies. The results presented here illustrate several potential uses for the entire dataset of sensitivity results and the “virtual individuals” that we have generated, which are included in the supplementary material. More generally, the presented methodology is applicable to modern, more complex multi-scale physiological models.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Virtual Patients and Sensitivity Analysis of the Guyton Model of Blood Pressure Regulation: Towards Individualized Models of Whole-Body Physiology

et al. 2012

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“…?/ M2SL (Multi-formalism Multi-resolution Simulation Library; Hernandez et al 2009), ultimately producing a validated C ? ?/M2SL version of GCM (Thomas et al 2007;Thomas et al 2008;Hernandez et al 2009). On the basis of a careful analysis of the relevant literature, we have constructed the present model of the RAS, keeping the description of aldosterone-related processes as in native GCM.…”

Section: Methods and Toolsmentioning

confidence: 99%

“…IUPS Physiome Project, QHP/QCP Quantitative Human/ Circulatory Physiology, european VPH Virtual Physiological Human). In this line of view, our collaborative initiative, SAPHIR project, develops an integrated and progressively refined description of the cardiovascular, renal and respiratory human physiology (Thomas et al 2007). In order to address blood pressure homeostasis and hypertensive pathology, we have based our model on the influential ''large circulatory model'' by Guyton and coworkers (Guyton et al 1972; see Abram et al 2007; Montani and Van Vliet 2009a, b;Osborn et al 2009a, b).…”

Section: Introductionmentioning

confidence: 98%

A Computational Model of the Circulating Renin-Angiotensin System and Blood Pressure Regulation

Guillaud

Hannaert

2010

Acta Biotheor

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(1) model BP, PRA and [Ang II] are within reported ranges, and respond physiologically to sodium intake; (2) short-term Ang II infusion induces reported rise in BP and PRA. The modeled circulating RAS, in interaction with an integrated CVR, exhibits a realistic response to BP control maneuvers. This construction will allow for modelling hypertensive and CVR patients, including salt-sensitivity, polymorphisms, and pharmacotherapeutics.

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“…The SAPHIR (a Systems Approach for Physiological Integration of Renal, Cardiac, and Respiratory function) is the best example of a multiorgan model. 78 This is a model of body fluid homeostasis and blood pressure regulation and has been reviewed by Thomas. 79 Karaaslan et al 80 developed an integrated cardiovascular/renal model with emphasis on the role of renal sympathetic nerve activity.…”

Section: Computational Approachesmentioning

confidence: 99%

Systems biology of kidney diseases

Chuang

Ma’ayan

et al. 2012

Kidney International

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Kidney diseases manifest in progressive loss of renal function, which ultimately leads to complete kidney failure. The mechanisms underlying the origins and progression of kidney diseases are not fully understood. Multiple factors involved in the pathogenesis of kidney diseases have made the traditional candidate gene approach of limited value toward full understanding of the molecular mechanisms of these diseases. A systems biology approach that integrates computational modeling with large-scale data gathering of the molecular changes could be useful in identifying the multiple interacting genes and their products that drive kidney diseases. Advances in biotechnology now make it possible to gather large data sets to characterize the role of the genome, epigenome, transcriptome, proteome, and metabolome in kidney diseases. When combined with computational analyses, these experimental approaches will provide a comprehensive understanding of the underlying biological processes. Multiscale analysis that connects the molecular interactions and cell biology of different kidney cells to renal physiology and pathology can be utilized to identify modules of biological and clinical importance that are perturbed in disease processes. This integration of experimental approaches and computational modeling is expected to generate new knowledge that can help to identify marker sets to guide the diagnosis, monitor disease progression, and identify new therapeutic targets.

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SAPHIR - a multi-scale, multi-resolution modeling environment targeting blood pressure regulation and fluid homeostasis

Cited by 11 publications

References 22 publications

Virtual Patients and Sensitivity Analysis of the Guyton Model of Blood Pressure Regulation: Towards Individualized Models of Whole-Body Physiology

Virtual Patients and Sensitivity Analysis of the Guyton Model of Blood Pressure Regulation: Towards Individualized Models of Whole-Body Physiology

A Computational Model of the Circulating Renin-Angiotensin System and Blood Pressure Regulation

Systems biology of kidney diseases

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