Model‐Based Interspecies Scaling of Glucose Homeostasis

Alskär, Oskar; Karlsson, Mats O.; Kjellsson, Maria C.

doi:10.1002/psp4.12247

Cited by 17 publications

(25 citation statements)

References 31 publications

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“…In the introduction, we mentioned the now classical nonlinear mixed effects models describing plasma levels of glucose and insulin (Silber et al 2007; Silber et al 2010; Jauslin et al 2007). These models have since these early publications been used to scale data between pre-clinical data from animals to clinical human data for glucose and insulin concentrations (Alskär et al 2017), and to describe cross-talk with more long-term processes, such as disease development in mice (Choy et al 2016) and dynamics of HbA1c (Kjellsson et al 2013; Møller et al 2013). Glucose homeostasis-centered models, focusing on the glucose-insulin interplay, lie at the heart of mathematical models developed for type 1 diabetes, e.g.…”

Section: Discussionmentioning

confidence: 99%

An organ-based multi-level model for glucose homeostasis: organ distributions, timing, and impact of blood flow

Herrgårdh

Nyman

et al. 2020

Preprint

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Glucose homeostasis is the tight control of glucose in the blood. This complex control is important and not yet sufficiently understood, due to its malfunction in serious diseases like diabetes. Due to the involvement of numerous organs and sub-systems, each with their own intra-cellular control, we have developed a multi-level mathematical model, for glucose homeostasis, which integrates a variety of data. Over the last 10 years, this model has been used to insert new insights from the intra-cellular level into the larger whole-body perspective. However, the original cell-organ-body translation has during these years never been updated, despite several critical shortcomings, which also have not been resolved by other modelling efforts. For this reason, we here present an updated multi-level model. This model provides a more accurate sub-division of how much glucose is being taken up by the different organs. Unlike the original model, we now also account for the different dynamics seen in the different organs. The new model also incorporates the central impact of blood flow on insulin-stimulated glucose uptake. Each new improvement is clear upon visual inspection, and they are also supported by statistical tests. The final multi-level model describes >300 data points in >40 time-series and dose-response curves, resulting from a large variety of perturbations, describing both intra-cellular processes, organ fluxes, and whole-body meal responses. We hope that this model will serve as an improved basis for future data integration, useful for research and drug developments within diabetes.

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Section: Discussionmentioning

confidence: 99%

An organ-based multi-level model for glucose homeostasis: organ distributions, timing, and impact of blood flow

Herrgårdh

Nyman

et al. 2020

Preprint

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“…Simple models were used for insulin secretion and its increase after glucose ingestion; in the model on intravenous glucose data, first-phase insulin secretion was represented only in healthy subjects and omitted in T2D patients. Extensions of these models included the description of circadian rhythms [based on 24-h glucose and insulin profiles, (Jauslin et al, 2011)], glucagon kinetics and glucose production dependence from glucose, insulin and glucagon [using meal tests with glucagon measurement, (Schneck et al, 2013)], gastric emptying and glucose absorption [using paracetamol, (Alskär et al, 2016)], and scaling factors to account for interspecies differences (Alskär et al, 2017). These models employ empirical descriptions of their components (e.g., insulin secretion), sufficient to predict the available data adequately.…”

Section: Glucose Homeostasismentioning

confidence: 99%

Mathematical Modeling for the Physiological and Clinical Investigation of Glucose Homeostasis and Diabetes

et al. 2020

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Mathematical modeling in the field of glucose metabolism has a longstanding tradition. The use of models is motivated by several reasons. Models have been used for calculating parameters of physiological interest from experimental data indirectly, to provide an unambiguous quantitative representation of pathophysiological mechanisms, to determine indices of clinical usefulness from simple experimental tests. With the growing societal impact of type 2 diabetes, which involves the disturbance of the glucose homeostasis system, development and use of models in this area have increased. Following the approaches of physiological and clinical investigation, the focus of the models has spanned from representations of whole body processes to those of cells, i.e., from in vivo to in vitro research. Model-based approaches for linking in vivo to in vitro research have been proposed, as well as multiscale models merging the two areas. The success and impact of models has been variable. Two kinds of models have received remarkable interest: those widely used in clinical applications, e.g., for the assessment of insulin sensitivity and β-cell function and some models representing specific aspects of the glucose homeostasis system, which have become iconic for their efficacy in describing clearly and compactly key physiological processes, such as insulin secretion from the pancreatic β cells. Models are inevitably simplified and approximate representations of a physiological system. Key to their success is an appropriate balance between adherence to reality, comprehensibility, interpretative value and practical usefulness. This has been achieved with a variety of approaches. Although many models concerning the glucose homeostasis system have been proposed, research in this area still needs to address numerous issues and tackle new opportunities. The mathematical representation of the glucose homeostasis processes is only partial, also because some mechanisms are still only partially understood. For in vitro research, mathematical models still need to develop their potential. This review illustrates the problems, approaches and contribution of mathematical modeling to the physiological and clinical investigation of glucose homeostasis and diabetes, focusing on the most relevant and stimulating models.

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“…20 An integrated glucose-insulin model, as first introduced by Silber, 38 was modified to incorporate a glucose dependent MK-2640 clearance mechanism and used to describe the minipig and dog PKPD data and allometrically scaled to man. 27,28,39 This glucose-dependent clearance mechanism was assumed to be a linear change in systemic clearance between low and high glucose concentrations. Both minipig and dog models predicted a ~ 30% lower MK-2640 clearance at hyperglycemia (300 mg/dL) compared with euglycemia (75 mg/dL).…”

Section: Human Dose Predictions For Mk-2640 In Healthy and T1dm Subjectsmentioning

confidence: 99%

A Model‐Informed Drug Discovery and Development Strategy for the Novel Glucose‐Responsive Insulin MK‐2640 Enabled Rapid Decision Making

Visser

Kandala

Fancourt

et al. 2020

Clin Pharma and Therapeutics

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A model-informed drug discovery and development strategy played a key role in the novel glucose-responsive insulin MK-2640's early clinical development strategy and supported a novel clinical trial paradigm to assess glucose responsiveness. The development and application of in silico modeling approaches by leveraging substantial published clinical insulin pharmacokinetic-pharmacodynamic (PKPD) data and emerging preclinical and clinical data enabled rapid quantitative decision making. Learnings can be applied to define PKPD properties of novel insulins that could become therapeutically meaningful for diabetic patients.

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Model‐Based Interspecies Scaling of Glucose Homeostasis

Cited by 17 publications

References 31 publications

An organ-based multi-level model for glucose homeostasis: organ distributions, timing, and impact of blood flow

An organ-based multi-level model for glucose homeostasis: organ distributions, timing, and impact of blood flow

Mathematical Modeling for the Physiological and Clinical Investigation of Glucose Homeostasis and Diabetes

A Model‐Informed Drug Discovery and Development Strategy for the Novel Glucose‐Responsive Insulin MK‐2640 Enabled Rapid Decision Making

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