Authors: Picchini, Umberto¹; Ditlevsen, Susanne²; Gaetano, Andrea³

Source: Journal of Mathematical Biology, Volume 53, Number 5, November 2006 , pp. 771-796(26)

Publisher: Springer

Abstract:

The Euglycemic Hyperinsulinemic Clamp (EHC) is the most widely used experimental procedure for the determination of insulin sensitivity. In the present study, 16 subjects with BMI between 18.5 and 63.6 kg/m² have been studied with a long-duration (5 hours) EHC. In order to explain the oscillations of glycemia occurring in response to the hyperinsulinization and to the continuous glucose infusion at varying speeds, we first hypothesized a system of ordinary differential equations (ODEs), with limited success. We then extended the model and represented the experiment using a system of stochastic differential equations (SDEs). The latter allow for distinction between (i) random variation imputable to observation error and (ii) system noise (intrinsic variability of the metabolic system), due to a variety of influences which change over time. The stochastic model of the EHC was fitted to data and the system noise was estimated by means of a (simulated) maximum likelihood procedure, for a series of different hypothetical measurement error values. We showed that, for the whole range of reasonable measurement error values: (i) the system noise estimates are non-negligible; and (ii) these estimates are robust to changes in the likely value of the measurement error. Explicit expression of system noise is physiologically relevant in this case, since glucose uptake rate is known to be affected by a host of additive influences, usually neglected when modeling metabolism. While in some of the studied subjects system noise appeared to only marginally affect the dynamics, in others the system appeared to be driven more by the erratic oscillations in tissue glucose transport rather than by the overall glucose-insulin control system. It is possible that the quantitative relevance of the unexpressed effects (system noise) should be considered in other physiological situations, represented so far only with deterministic models.

Keywords: Mathematical models; Dynamical systems; Diffusion processes; Glucose; Insulin; Parameter estimation; Monte Carlo methods; Simulated maximum likelihood

Document Type: Research article

DOI: 10.1007/s00285-006-0032-z

Affiliations: 1: Email: umberto.picchini@biomatematica.it 2: Email: sudi@pubhealth.ku.dk 3: Email: andrea.degaetano@biomatematica.it

Share this item with others: These icons link to social bookmarking sites where readers can share and discover new web pages.

• Website © 2009 Ingenta. Article copyright remains with the publisher, society or author(s) as specified within the article.
• Terms and Conditions
• Privacy Policy
• Information for advertisers

Click here for Page Help

Browse

Search

Electronic content Journal or book title

 

• Search History
  • Ti: Steroid ho... (tka)
    (2,397 hits)
  • Ti: LAYING HEN... (tka)
    (659 hits)
  • Ti: Clopidogre... (tka)
    (1,069 hits)
  • Ti: cerebral e... (tka)
    (669 hits)
  • Ti: aeromedica... (tka)
    (22 hits)
  • Ti: Brittle as... (tka)
    (7 hits)
  • Current search history
  • Saved searches
  • Search alerts

Shopping cart

Tools

• Print
• Article access options
• Export
  • EndNote
  • BibT_EX
• Linking
  • IngentaConnect
  • OpenURL
  • DOI
• Alerting Options
  • Receive New Issue Alert
  • Latest TOC RSS Feed
  • Recent Issues RSS Feed
• Bookmark
  • Marked List
  • Add to Marked List
  • Social Bookmarking Links

Sign in

Text size: A | A | A | A