Mitochondrial Oxidation and Insulin Resistance in Burn Patients Treated With Fenofibrate

Last updated: December 10, 2012
Sponsor: The University of Texas Medical Branch, Galveston
Overall Status: Trial Not Available

Phase

2/3

Condition

Diabetes And Hypertension

Diabetes (Pediatric)

Hormone Deficiencies

Treatment

N/A

Clinical Study ID

NCT00732485
07-389
SHC 08-GAL-006
  • Ages 7-20
  • All Genders

Study Summary

Major burn injury causes significant insulin resistance on glucose and protein metabolism that persists for up to 6 months after the acute injury

This project proposes to answer the following questions:

  1. Will fenofibrate given to burn patients with insulin resistance restore their insulin sensitivity?

  2. What is the relationship between mitochondrial dysfunction in muscle tissue as the causative mechanism of burn related insulin resistance?

  3. To what extent will the restored insulin sensitivity affect glucose and protein metabolism in muscle, regenerating wounds and the liver, i.e. ameliorate burn related hyperglycemia and protein catabolism?

Eligibility Criteria

Inclusion

Inclusion Criteria:

  • Patients > 7 years old with burns covering 40% or more of body surface who areadmitted to the Shriners Hospital for Children, Galveston, Texas

Exclusion

Exclusion Criteria:

  • Abnormal liver and kidney function,

  • Pregnancy,

  • Diabetes mellitus,

Study Design

Study Start date:
August 01, 2008
Estimated Completion Date:
December 31, 2013

Study Description

The following specific hypotheses will be investigated:

  1. Following severe burn injury in human patients the mitochondrial fat oxidation capacity is decreased in muscle. This is associated with a corresponding progression in the severity of the resistance to the action of insulin on glucose disposal and protein synthesis and breakdown in muscle, regenerating wound and liver.

  2. Fatty acids, or their active intracellular products (e.g., DAG, acyl-CoenzymeA (Co-A), or acylcarnitine), are the direct inhibitors of insulin action, rather than tissue triglycerides (TG) itself. In other words, impaired mitochondrial fatty acid oxidation is the mechanism that causes altered lipid metabolism that ultimately contributes to insulin resistance.

  3. Accumulation of active fatty acid products, such as DAG, acyl-CoA, or acylcarnitine esters in muscle cells is due to the rate of uptake of plasma free fatty acid (FFA) exceeding the rate of oxidation within muscle due principally to a reduced capacity of mitochondria to oxidize fatty acids.

  4. Decreased insulin sensitivity in muscle is related to impaired insulin signaling. This will be reflected by increased activity of protein kinase C (PKC). Because PKC is thought to exert its regulatory effect primarily on either tyrosine kinase activity on the insulin receptor or downstream kinase insulin receptor substrate (IRS) phosphorylation, these elements of the insulin signaling cascade will be decreased. In turn, elements of insulin signaling related to the response of muscle glucose (PI3 kinase) and protein (P70S6k) metabolism will be reduced. We propose that increased tissue PKC activity will be associated with increased tissue concentration of DAG, acyl-CoA, or acylcarnitine.

  5. Treatment of patients with the peroxisome proliferator-activated receptor (PPAR) alpha agonist fenofibrate will improve mitochondrial capacity to oxidize fatty acids.

  6. Insulin sensitivity in muscle, skin and liver in terms of both glucose and protein metabolism will be improved by fenofibrate treatment.

Connect with a study center

  • Shriners Hospital for Children

    Galveston, Texas 77550
    United States

    Site Not Available

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