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RESEARCH SUPPORTIVE OF ZMA SUPPLEMENTATION
1. The effect of zinc depletion on muscle
function was tested in 8 male subjects. After receiving
12 mg Zn/day for 17 days, the subjects received 0.3 mg Zn/day
for either 33 or 41 days. The subjects were then divided
into two groups for zinc repletion. Group A subjects received
overnight infusion of 66 mg of Zn on Day 1 and 10 and then
were fed 12 mg Zn/day for another 16 days. Group B subjects
were fed 12 mg Zn/day for 21 days. Peak force and total
work capacity of the knee and shoulder extensor and flexor
muscle groups were assessed using an isokinetic dynamometer
at baseline, at two points during depletion, and at repletion.
Plasma zinc levels decreased by an average of 67% during
depletion and remained 9% below baseline after repletion.
The peak force of the muscle groups was not found to be
significantly affected by acute zinc depletion, however,
shoulder peak force (strength) was found to be reduced by
9.2% in the extensor muscles. Total work capacity (muscle
endurance) for the knee extensor muscles and shoulder extensor
and flexor muscles declined significantly by 28.1%, 24.1%
and 26.4%, respectively. This study demonstrates that muscle
endurance, or total work capacity, declines rapidly with
acute zinc depletion and the degree of the decline was correlated
with the reduction in plasma zinc concentration.
Van Loan, MD, et al. The Effects of
Zinc Depletion on Peak Force and Total Work of Knee and
Shoulder Extensor and Flexor Muscles. Int J of Sport Nutr,
June 1999, Vol. 9, No. 2, 125-135.
2. A study was conducted to determine
the effects of magnesium supplementation on strength development
during a double-blind, 7-week strength training program
in 26 untrained subjects (14=placebo, 12= Mg), 18-30 years
old. Pre and post peak quadriceps torque (leg press) measurements
were made using an isokinetic dynamometer. The leg muscle
strength of the magnesium supplemented group significantly
increased by 26%, compared to only 10% for the placebo group.
Brilla, LR, et al. Effect of Magnesium
Supplementation on Strength Training in Humans. J Am Coll
Nutr, July 1992, Vol 11, No. 3, 326-329
3. Serum zinc levels were determined
in 160 training athletes (103 males and 57 females). In
23.3% of male and 43% of female athletes, serum zinc was
significantly below the "normal range".
Haralambie, G. Serum zinc in athletes
in training. Int J Sports Med 2 (1981) 135-138.
4. Magnesium, zinc and copper status
of 270 US Navy Sea, Air and Land (SEAL) trainees was determined
from dietary intakes and biochemical profiles. The dietary
intakes of 34% and 44% of the trainees were below the RDA
for Mg and Zn, respectively. The blood plasma concentrations
of Mg and Zn were significantly below the "normal range"
for 23% and 24% of the trainees, respectively.
Sing A, et al. Magnesium, Zinc and
Copper status of US Navy SEAL trainees. Am J Clin Nutr 1989;49:695-700.
5. Serum zinc levels were measured in
20 adolescent gymnasts (9 boys, 11 girls, age 12-15). They
had 26% lower serum zinc levels (0.599 +/- 0.026 mg/l) when
compared to 118 matched controls (0.810 +/- 0.014, p < 0.001).
The gymnasts serum zinc levels were positively correlated
with adductor strength (r=0.468, p < 0.05). The 11 of 20
gymnasts with serum zinc < 0.6 mg/L had lower insulin-like
growth factor binding protein 3 levels than the others (2.326
+/- 0.064 vs 2.699 +/- 0.12, p < 0.01). This protein is
supposed to reflect growth hormone activity. Thus, zinc
is lowered in trained adolescent gymnasts and this reduction
could play a role in abnormalities of growth or muscular
performance.
Brun J, et al. Serum zinc in highly
trained adolescent gymnasts. Bio Trac Elem Res, 1995, Vol.
47, 273-278.
6. Twenty-one professional football
(soccer) players underwent a maximal exercise test on a
cycloergometer, with progressively increasing workloads
until VO2max. On the whole these subjects had low serum
zinc because nine (43%) of them had a hypozincemia (0.54
+/- 0.01 mg/L) which suggested a zinc deficiency. The subjects
with low serum zinc had a 26% lower power output (123 +/-
8.71 vs. 166.27 +/- 14.84 watts, p = 0.029) and exhibited
a 35% higher increase in blood lactate (lactic acid) during
exercise (7.51 +/- 0.81 vs. 5.57 +/- 0.33 mmol/L, p <0.04)
resulting in a 24% lower 2 mmol lactate threshold (44.7
+/- 3.9% vs. 58.9 +/- 4.8% of maximal power output p < 0.04).
In conclusion, this study suggests that zinc status may
influence blood rheology (flow) during exercise by an effect
related to lactate accumulation.
Khaled S, et al. Serum zinc and blood
rheology in sportsmen (football players. Clin Hemo and Micro
17 (1997) 47-48.
7. Ten collegiate basketball players
serum mineral levels were measured before official practice
began and immediately following the competitive season.
Diets were monitored and remained the same throughout the
four month period. Mean serum values for Mg and Zn decreased
pre-season to post- season by 16% and 41%, respectively.
Lefavi RG, et al. Reduced serum mineral
levels in basketball players after season. Med and Sci in
Sports and Exer. Vol. 27, No. 5, May 1995
8. Twelve professional volleyball players
and 12 control subjects were studied to determine the effects
of daily physical training on serum, sweat and urine zinc
concentrations. The professional athletes trained every
day in two sessions, one in the morning (work in the gym
for 2 hours) and another in the afternoon (specific work
on the sports field for 3 hours). Simultaneously, 12 male
volunteer university students, who were moderately trained,
participated as the control group. The study was conducted
over a period of 10 weeks. Pre-post tests were made using
a progressive bicycle ergometer (increasing 30 W every 3
minutes to reach a maximum tolerated power). Pre-post blood
samples were obtained at rest and immediately following
exercise. After ten weeks of training, the professional
athletes showed a significant increase in 24 hour urinary
zinc excretion (22% greater losses), in contrast to a slight
decrease (2% less) in the controls. The athletes also showed
a very significant increase in the zinc loses in sweat compared
to the controls. The athletes sweat zinc concentrations
increased by an astounding 300%, compared to only 30% increases
in the control group. The athletes serum zinc levels decreased
by 4%, compared to a 2% decrease in the control group. Finally,
the post exercise cortisol levels of the athletes significantly
increased by 93%, compared to only an 18% increase in the
controls. The authors stated that the athletes "cortisol
levels increased in response to the exercise work load stress,
and this behavior seems to be related to muscular damage".
The authors went on to say that "It seems that the changes
in zinc metabolism found in the study may be damage, increased
protein turnover and increased zinc excretion (via sweat
and urine). Because strenuous exercise during a period of
competition can induce a "catabolic state" and has been
shown to increase skeletal muscle protein turnover, it is
likely that urine zinc is derived from muscle tissue". The
authors concluded by saying that "Zinc supplementation and/or
stress control appear to be indicated in athletes. In our
practical opinion, we think that alterations in zinc metabolism
with increases in zinc excretion and stress levels lead
to a situation of latent fatigue with a decrease of endurance".
Cordova A, et al. Effect of training
on zinc metabolism: changes in serum and sweat concentrations
in sportsmen. Ann Nutr Metab, 1998 42:5, 274-82.
9. Plasma zinc, iron, copper and selenium
levels were measured in 66 Navy SEAL trainees before and
after a 5 day period of sustained physical and psychological
stress called "Hell Week". The trainees pre-post plasma
zinc levels decreased by 33%.
Singh A, et al. Biochemical indices
of selected trace minerals in men: effect of stress. Am
J Clin Nutrition 1991; 53:126-31.
10. Nine healthy, male subjects (18-40
years) were supplemented daily with 365 mg of magnesium
as aspartate for 14 days. Before and after the supplementation
period each subject performed a rigorously identical one
hour ergometer exercise. The magnesium supplementation significantly
reduced the subjects plasma levels of the catabolic "stress"
hormone cortisol by an average of 25% (P < 0.025), which
remained decreased during the exercise. The magnesium also
significantly lowered the subjects' heart rates throughout
the exercise period by an average of 8% (P < 0.03). Golf
SW, et al. Plasma aldosterone, cortisol and electrolyte
concentrations in physical exercise after magnesium supplementation.
Clin Chem Clen Biochem, 1984, Vol. 22, pp. 717-721.
11. Medical students were tested to
determine the acute effect of zinc supplementation on cortisol
levels. The test was started at 7:00 AM after a 12 hour
fast. Serial blood samples were collected from an experimental
zinc group and controls at 30 minute intervals for 240 minutes.
A subgroup of 7 subjects (3 men, 4 women) ingested 25 mg
of zinc immediately after the baseline collection and their
cortisol levels were compared to 8 matched controls who
received a placebo. The control group started out with an
average cortisol level of 11 mcg/dL and fell to 9 mcg/dL
at 240 minutes, which is an 18% reduction. The zinc supplemented
group started out with an average cortisol level of 16 mcg/dL
and significantly dropped to 6.5 mcg/dL, which is a 59%
reduction. In summary, the zinc supplemented group had a
41% greater reduction in cortisol levels compared to controls.
The fact that zinc inhibits basal cortisol secretion in
humans may be related to a direct blockade of cortisol synthesis
and secretion in the adrenal cortex.
Brandao-Neto J, et al. Zinc acutely
and temporarily inhibits adrenal cortisol secretion in humans.
Bio Trace Elem Res, 1990, Vol. 24, 83-89.
12. Nine runners urine zinc and chromium
levels were measured on a run day and compared to the levels
on a non run day. The runners daily losses of zinc in urine
were 50% greater on a run day compared to a non run day.
Anderson, R. Strenuous running. Bio
Trac Elem Res, Vol. 6 (1984) 327- 336.
13. A percentage of testosterone is
converted to dihydrotestosterone (DHT) by the enzyme 5a-reductase.
An invitro study was conducted to determine the inhibition
of 5a-reductase activity by zinc sulphate and azelaic acid.
When added at concentrations of 3 or 9 mmol/l, zinc was
a potent inhibitor of 5a-reductase activity. At a high concentration
of 15 mmol/l, zinc completely inhibited 5a-reductase. The
addition of vitamin B-6 potentiated the effect of zinc and
resulted in a two-fold increase in the inhibition of 5a-reductase.
A moderate concentration of 1.5 mmol/l of zinc in combination
with 0.025% of vitamin B-6 inhibited the 5a-reductase activity
by 90%. The zinc and vitamin B-6 combination may be effective
at limiting DHT production and could represent a potential
therapeutic agent in the treatment of androgen related pathology.
Stamatiadis D, et al. Inhibition of
5a-reductase activity in human skin by zinc and azelaic
acid. Brit J of Derm, 1988, Vol. 119, pp. 627-632.
14. Androgen metabolism and aromatization,
androgen and estrogen receptor binding and circulating levels
of reproductive hormones were studied in zinc deficient
rats. The zinc deficient group had significantly lower serum
concentrations of testosterone (2.8 +/- .07 nmol/L) compared
to the controls (8.7 +/- .07 nmol/L). This represents a
remarkable 68% reduction in circulating testosterone levels.
Scatchard analysis of the receptor binding data showed a
significantly higher number of estrogen receptors in the
zinc deficient group (36.6 +/- 3.4 fmol/mg protein) than
in controls (23.3 +/- 2.4 fmol/mg protein) and a significantly
lower number of androgen binding sites in rats fed the zinc
deficient diet (6.7 +/- o.7 fmol/mg protein) than in controls
(11.3 +/- 1.2 fmol/mg protein). To summarize, zinc deficiency
caused a 41% reduction in the number of androgen binding
sites and a 57% increase in the number of estrogen receptors.
These findings indicate that zinc deficiency significantly
reduces circulating testosterone concentrations and modifies
sex hormone receptor levels.
Om AS, et al. Dietary zinc deficiency
alters 5 alpha-reduction and aromatization of testosterone
and androgen and estrogen receptors. J Nutr, 1996, Apr,
126:4,842-8.
15. Androgen binding was studied in
zinc deficient rats. The experimental group of animals were
maintained on a zinc deficient diet for 3 months. Scatchard
analysis of the data revealed that the number of androgen
binding sites in the zinc deficient rats was 31 +/- 5.2
fmol/mg cytosol protein. This was significantly lower than
that (84 +/- 11.5 fmol/mg protein) of the controls. This
63% decrease in the number of androgen receptor cites in
the zinc deficient state indicates that this metal is extremely
important in the androgen binding process in the target
cells.
Chung KW, et al, Androgen receptors
in ventral prostate glands of zinc deficient rats. Life
Sci,1986, Jan 27, 38:4, 351-356.
16. Nine men participated in an 85 day
zinc depletion/repletion study divided into 3 metabolic
periods: 18 day baseline, a 44 day depletion, and a 23 day
repletion. 12 mg of zinc per day was fed to the men during
baseline and were held constant after adjustments during
the baseline period. Plasma zinc declined from 77.1 +/-
0.03 mcg/dl at baseline to 28.1 +/- 0.07 mcg/dl at depletion;
concentrations returned to 77.9 +/- 0.03 mcg/dl at repletion.
Total body weight, fat, fat-free mass (FFM), and bone mineral
did not change during depletion, but total body water increased
5.3% +/- 1.9%, or about 2 kg or 4.4 lbs (P <0.05) by the
end of the depletion and returned to baseline values at
the end of repletion. The percent water in FFM increased
from 71% +/- 1 to 75% +/- (P <0.05) at the end of depletion
and was associated with a small decrease in body protein.
The data suggest that zinc depletion impairs water balance.
Sutherland B, et al, Effect of experimental
zinc depletion on body composition and basal metabolism
in men. The FASEB Journal, Mar. 10, 1995, Volume 9, Number
4.
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