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V.
ANABOLIC STRATEGY
(The Rationale for the use of
Anabolic Hormones)
The
successful correction of lean mass loss and prevention of a
severe protein deficiency in the presence of catabolic
illness requires an increase in overall anabolism.
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ROLE
OF ANABOLIC HORMONES
- attenuate
the catabolic stimulus during stress
- to
more rapidly restore lean mass loss
- to
restore normal nutrient partitioning such that
protein consumed is not converted to energy
and weight gained is not fat mass
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Even
in the recovery phase, endogenous anabolic activity remains
depressed. This is the case in elderly patients, those with
chronic illness, or patients with involuntary weight loss.
Adequacy of substrate (1.5 g/kg/d protein) may not be
sufficient to jump-start restoration of lean body mass.
However, the machinery is capable of a very rapid rate of
protein synthesis that is not age-dependent if stimulated by
anabolic agents.
Body
composition studies during correction of protein energy
malnutrition (PEM) have demonstrated that a significant
portion of weight gain after unintentional weight loss from
catabolic disease represents the addition of body fat and
extracellular fluid, not added protein mass. Inadequate
anabolic stimulation is the cause.
The
action of all anabolic agents
currently in clinical use is twofold. First, amino acids are
driven into the protein synthesis channel in the cell thru
action of cell surface receptors in lean mass. The metabolic
pathways used by anabolic agents to achieve protein
synthesis may be different, but the outcome is increased
lean mass. The second action is anticatabolic. All anabolic
agents appear to decrease protein degradation, possibly by
blocking cell cortisol receptors.
In
the absence of a sufficient anabolic activity, the
energy-requiring protein synthesis pathway is underused and
excess energy is stored as fat.
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Actions
of Anabolic Hormones
- Anticatabolic
by decreasing loss of amino acids from the
protein synthesis pathway
- Anabolic
by increasing the rate of protein synthesis
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*
Anabolic
hormones are being used with increasing frequency in
populations with lean mass loss or existing PEM, along
with optimal nutrition and the added anabolic stimulus of
resistance exercise.
Activity
of Anabolic Hormones
SPECIFIC
ANABOLIC HORMONES
A
number of approaches to increasing anabolic activity are
currently available. Several have been shown to be
efficacious for increasing protein synthesis during both
the stress and recovery phases of burn injury. The most
promising agents are discussed here.
HGH
is normally produced by the pituitary gland (0.8 mg/d) and
is a potent endogenous anabolic hormone. It is found in
highest concentrations in childhood during the growth spurt
and gradually decreases with age or chronic illness. HGH
binds to specific cell receptors leading to a host of
metabolic effects, some due to direct hormone activity on
tissues, especially in the liver. Other effects are due to
the release of insulin-like growth factor-1, which has
potent wound-healing effects.
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Metabolic
Effects of HGH
- Increase
nitrogen retention, protein synthesis
- Increased
cell amino acid influx, decreased efflux
- Decreased
urea formation
- Increased
IGF-levels
- Increased
fat oxidation, decreased catabolism
- Increased
metabolic rate (10%)
- Insulin
resistance, hyperglycemia
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Clinical
Effects of HGH Therapy in Burn Patients
- Increased
muscle formation
- Increased
strength (grip) compared to untreated
post-operative patients
- Decreased
hospital stay (severe burn injury patients)
- Improved
wound healing
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Clinical
Indications for HGH
- Presence
of severe catabolism from burn
- Malnourished
burn patients with a superimposed catabolism
- Acute
loss of > 10% lean body mass (muscle)
- Large
burns or wounds with poor healing
- Only
FDA approval is for short stature: need to
use as orphan drug
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Potential
Complications
- Insulin
resistance (hyperglycemia)
- Fluid
retention (usually self-limiting)
- Hypermetabolism
- Increased
mortality rate in certain critical care
populations
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See
Section VII for Clinical Research on HGH
The
primary stimuli for HGH release are starvation and resistance
exercise. Agents such as glutamine and arginine have
been reported to increase HGH release. The plasma HGH
level is decreased after severe injury or sepsis, thereby
decreasing normal anabolic activity. Numerous studies of
exogenous HGH use in patients with trauma or burns and
other injuries have demonstrated its efficacy for
improving anabolism and the wound healing rate. The
mechanism for improved outcomes appears to be
related to maintenance of lean body mass. The
average dose of HGH used is 0.1 to 0.2 mg/kg of body
weight, or about 10 times the normal endogenous
production. A number of complications have been reported;
the most common is hyperglycemia, due to anti-insulin
activity. Increased insulin is often required. In
addition, HGH is very expensive, and it may increase
morbidity and mortality. It must be given parenterally in
certain populations at critical care.
Exogenous
HGH, now obtained by a genetic engineering process, is
only approved by the US Food and Drug Administration (FDA)
for use in children with short stature or dwarfism.
However, as an orphan drug, it has been used for its
anabolic activity, especially in burn patients and
patients with impaired wound healing.
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Recently,
a multi-center study of the use of HGH in
critically ill patients (mainly non-trauma and
non-burn) demonstrated an increase in mortality
rate. The mechanism remains unclear. This
response has not been reported with the use of
HGH in burn patients.
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