Insulin Resistance Clinical Trial
Official title:
Phase 2 Trial to Examine the Metabolic Effects of Fenofibrate in Burned Patients
Insulin resistance and hyperglycemia contribute to negative outcomes in burned patients. We
will assess insulin sensitivity in traditional terms of glucose metabolism, and with regard
to the responsiveness of both muscle and liver protein metabolism, in severely burned
patients. Plasma free fatty acid (FFA) and tissue TG levels will be manipulated via
inhibition of peripheral lipolysis with nicotinic acid or activation of plasma lipoprotein
lipase activity with heparin, stimulation of tissue fatty acid oxidation and thus reduction
of tissue TG with the peroxisome proliferate-activated receptor (PPAR) alpha agonist
fenofibrate. Methodological approaches will include stable isotope tracer techniques to
quantify kinetic responses of protein, glucose and lipid metabolism in vivo, quantification
of intracellular stores of TG and glycogen by means of magnetic resonance spectroscopy
(MRS), as well as quantitative analysis of tissue levels of active products of fatty acids,
key intermediates of the insulin signaling pathway, glycogen, the enzyme activities of
citrate synthase and glycogen synthase and the activity of the muscle mitochondria. These
studies will clarify the physiological and clinical significance of the alterations of
tissue lipid metabolism that occur after burn injury, thereby forming the basis for new
therapeutic approaches not only in this specific clinical condition but in other clinical
circumstances in which hepatic and/or muscle TG is elevated.
We will investigate the general hypothesis that the accumulation of intracellular TG in
liver and muscle either directly causes insulin resistance in those tissues or serves as an
indictor of the intracellular accumulation of active fatty acid products, such as fatty acyl
CoA and diacylglycerol, which in turn disrupt insulin action.
The following specific hypotheses will be investigated:
1. Intracellular TG is elevated in both muscle and liver in severely burned patients. The
reduction of the fat in the liver and the insulin resistance will improve clinical
outcomes, glucose and protein metabolism.
2. The insulin signaling pathway, as reflected by phosphoinositol-3-kinase (PI3K) and PKC
activity, is impaired in tissues with elevated TG.
3. Fatty acids, or their active intracellular products, are the direct inhibitors of
insulin action, rather than the tissue TG itself.
We will study patients with severe burns, defined as 2nd or 3rd degree burn covering >40% of
total body surface area (TBSA). We propose to study burned children from Shriners Burns
Hospital. The Shriners census is such that approximately 50 children with severe burns are
treated every year. We will study patients immediately prior to their third surgical
procedure, approximately 12-15 days after injury. One half of the patients will be given
fenofibrate (5 mg/kg/day) daily delivered through feeding tube from the time of consent
following admission until 12-14 days post-burn. This length of time after injury will ensure
that untreated patients will have a large accumulation of hepatic TG. Because the "control"
group of patients will have elevated liver TGs, the "experimental" group will have their
hepatic TGs lowered by fenofibrate. By studying the patients the day before the operations,
it will be possible to remove the staples used in skin grafting without risk of loss of
adhesion of the graph, thereby ensuring safety in the MRS. Femoral line inserted for the
surgery can also be utilized, and all patient generally receive a full transfusion during
surgeries, minimizing any study related blood loss. In addition to the liver, we will study
the muscle in burn patients. Patients will be studied during brief fasted state. The will be
fasted four hours prior to the study and then through out the study. Their TPN will be
immediately reconnected following the study. The surgical team at the Shrine places 3Fr, 8
cm polyethylene catheters (Cook, Inc., Bloomington, IN) into the femoral vein and femoral
artery under local anesthesia the day before surgery. Both femoral catheters will be used
for blood sampling, while the femoral arterial catheter will also used for indocyanine green
infusion for the determination of leg blood flow. Systemic concentration of indocyanine
green will be measured from a central vein, as standard procedure has a multi-lumen
subclavian line in all patients. Patency of all catheters is maintained by saline infusion.
Patients will be infused with stable (non-radioactive) isotope tracers of glucose,
phenylalanine and palmitate for up to 8 hours. After 4 hours, without interruption of the
tracer infusion, an infusion of insulin will be started and maintained at the rate of 1.5
mU/kg•min for the final 4 h. Blood glucose concentrations will be measured throughout the
insulin infusion and glucose infused as necessary to maintain the basal plasma glucose
concentration.
A biopsy of the quadriceps will be obtained with a Bergstrom needle at the beginning of the
study, 4 h (immediately before the insulin infusion) and at the end of the 4 h insulin
infusion. We will use the A-V balance technique to address the relation between tissue fatty
acid and TG metabolism and the insulin responsiveness of glucose uptake and myofibrillar and
mitochondrial protein synthesis and net protein balance.
b. Subjects Patients are admitted to the burn unit within 48 h of injury. Fluid
resuscitation is provided as previously described (94). Within 48 h of admission, the burn
wound is excised and subsequently grafted by autograft or cadaveric allograft. Patients
typically return to the operating room for reharvesting of donor sites every five to seven
days. The experiments proposed here will be performed the day prior to the third surgery at
day 12-15, as femoral catheters are normally inserted at the time for access during surgery.
Enteral feeding with Vivonex TEN (Sandoz Nutrition Corp, Minneapolis, MN) is started within
24h of admission and continued until the patient is capable of food by mouth. All patients
will be eligible for the study unless one of the exclusion criterion listed below apply.
c. Procedures From day 1 to day 22 patients will be maintained on enteral feeding of a high
carbohydrate/amino acid mixture (Vivonex, Novartis, Minneapolis, MN). Vivonex contains 300
kcal/serving in the following caloric breakdown: 82.3% carbohydrate, 15% protein, 2.7% fat
(linoleic acid). Patients will be given 25 kcal/kg of Vivonex plus an additional 45 kcal/kg
for each percentage point of total body surface area burned. One half of the patients will
be given fenofibrate (5 mg/kg/day - maximum daily dose) from the time of the first tracer
study until the time of the second tracer study.
The tracer study subjects can commence once catheters in the femoral artery and vein have
been placed by the surgical team, if necessary, since the majority of patients wil have
pre-existing lines placed for clinical reasons. The catheters will be used for sampling and
in a peripheral vein for infusing, as in our previous studies (e.g., 4). Enteral
administration of a mixture of carbohydrate and amino acids (Vivonex) will be stopped four
hours prior to the study, and will be started immediately following the study.
On the day after the tracer infusion the amount of liver and muscle TG and liver glycogen
will be determined by MRS. After metal staples are removed, patients will be transported to
the clinical MRS facilities at UTMB Dept. of Radiology, where measurements will be performed
(see below for details), After obtaining baseline samples, tracer infusions will be started
as described in Figure 2. Half the patients with high tissue TG will be given nicotinic acid
(500 mg orally) at the start of period 2 to lower FFA levels acutely. In the group given
fenofibrate (200 mg/d) or propranolol 0.5mg/kg every 6 hours to lower FFA, half will be
infused with heparin (0.5 U/kg•min, 2.8 U/ kg prime IV) at a dose sufficient to activate
lipoprotein lipase, thereby elevating plasma FFA, while not affecting blood coagulation.
After baseline blood samples from the femoral artery, femoral vein, and peripheral vein are
collected, an 8 hour continuous infusion of primed-constant infusions of 6,6-d2-glucose
(0.08 mg/kg•min, prime = 6.8 mg/kg) and d5-phenylalanine (0.20 µmol/kg•min, prime = 8.0
µmol/kg) will be given in order to quantify hepatic glucose production and protein synthetic
rates, respectively. In addition, 2 hours into the protocol, U-13C16-palmitate (0.16 µmol/kg
per minute) will be started with NaH13CO3 prime (150 µmol/kg) in order to quantify hepatic
fatty acid uptake and oxidation. These tracer infusions will also be maintained throughout
the 8 hour tracer study. Blood samples (2- 12 ml) will be taken from the artery, femoral
vein and peripheral vein simultaneously at 120, 180, 210, 225 and 240 minutes (see Appendix
2 for full timeline). Muscle tissue biopsies will be obtained at the start of period 1, and
at 4 hours of period 1 to measure protein kinetics and also determine biochemical
parameters. Then, period 2 will start. At the start of period 2, a primed, constant infusion
of 15N-phenylalanine will be started and maintained throughout period 2. The different
tracer of phenylalanine will be used to quantify the plasma protein synthetic rates using
the same tracer protocol as in period 1. We have previously shown that the two phenylalanine
tracers yield the same results (70). The tracer technique will enable us to measure the
primary endpoints of insulin responsiveness of the liver, i.e., endogenous glucose
production and synthetic rates of albumin and fibrinogen. At 4 hours, hyperinsulinemia will
be initiated by the infusion of insulin at the rate of 1.5 mu/kg•min, which will result in
circulating levels of approximately 200 uU/ml (5). This rate of infusion was based on our
previous experience with insulin infusion in burned patients (e.g., 1-5). We anticipate a
considerable variation in the baseline insulin concentrations, such that if a low rate of
infusion were to be used, the resulting "hyperinsulinemia" in some patients would likely be
below the baseline concentration in others. Consequently, we have chosen a rate of infusion
that will result in a clear-cut difference between the baseline and "hyperinsulinemic"
values. Further, although during the insulin infusion we anticipate that insulin
concentrations will also be variable, our endpoints will be assessed in terms of the
magnitude of change from the baseline value in each subject. This statistical approach
should minimize concern regarding subject variability. The dosage was selected because we
have previously shown that protein metabolism is responsive to this rate of infusion (5),
but that it is below the maximally-effective dose (4). Blood glucose concentration will be
monitored throughout the second period, and glucose will be infused (if necessary) to
maintain glucose concentrations at the baseline level. Since the baseline concentrations of
glucose will vary, this means that during hyperinsulinemia the glucose concentrations will
likely differ between subjects, but we have selected this approach because in this way only
the insulin concentration will differ between periods 1 and 2, thereby simplifying
interpretation of the changes in substrate and protein kinetics from period 1 to 2. The
sampling schedule will be the same as in period 1, including the timing of the biopsy (i.e.,
at 4 h of period 2).
Leg blood flow will be measured by indocyanine green infusion, ad described previously (14).
Whole-body indirect calorimetry will be performed to quantify whole-body carbohydrate and
fat oxidation.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double-Blind, Primary Purpose: Treatment
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