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from the
New England Journal of Medicine,
Volume 323 July
5, 1990 Number 1
EFFECTS OF
HUMAN GROWTH HORMONE IN MEN OVER 60 YEARS OLD
Daniel Rudman, M.D., Axel G. Feller, M.D., Hoskote S.
Nagraj, M.D., Gregory A. Gergans, M.D., Pardee Y. Lalitha, M.D.,
Allen F. Goldberg, D.D.S., Robert A. Schlenker,
Ph.D., Lester Cohn, M.D., Inge W. Rudman, B.S., and Dale E. Mattson,
Ph.D.
Abstract
Background. The declining activity of the growth
hormone-insulin-like growth factor 1 (IGF-1) axis with advancing age
may contribute to the decrease in lean body mass and the increase in
mass of adipose tissue that occur with aging.
Methods.
To test this hypothesis, we studied IGF-1 plasma with 21 healthy men
from 61 to 81 years old who had plasma IGF-1 concentrations of less
than 350 U per litre during a six-month base-line period and a
six-month treatment period that followed. During the treatment
period, 12 men (group 1) received approximately 0.03 mg of
biosynthetic human growth hormone per kilogram of body weight
subcutaneously three times a week, and 9 men (group 2) received no
treatment. Plasma IGF-1 levels were measured monthly. At the end of
each period, we measured lean body mass, the mass of adipose tissue,
skin thickness (epidermis plus dermis), and bone density at nine
skeletal sites.
Results.
In group 1, the mean plasma IGF-1 level rose into the youthful range
of 500 to 1500 U per litre during treatment, whereas in group 2 it
remained below 350 U per litre. The administration of human growth
hormone for six months in group 1 was accompanied by an 8.8 percent
increase in lean body mass, a 14.4 percent decrease in
adipose-tissue mass, and a 1.6 percent increase in average lumbar
vertebral bone density (P<0.05 in each instance). Skin thickness
increased .1 percent (P = 0.0). There was no significant change in
the bone density of the radius or proximal femur. In group 2 there
was no significant change in lean body mass, the mass of adipose
tissue, skin thickness, or bone density during treatment.
Conclusions.
Diminished secretion of growth hormone is responsible in part for
the decrease of lean body mass, the expansion of adipose-tissue
mass, and the thinning of the skin that occurs in old age. (New
England Journal of Medicine, 1990; 323:1-6).
In middle and late
adulthood, all people experience a series of progressive alterations
in body composition. The lean body mass shrinks and the mass of
adipose tissue expands. The contraction in lean body mass reflects
atrophic processes in skeletal muscle, liver, kidney, spleen, skin,
and bone.
These structural
changes have been considered unavoidable results of aging. It has
recently been proposed, however, that reduced availability of growth
hormone in late adulthood may contribute to such changes. This
proposal is based on two lines of evidence. First, after about the
age of 30, the secretion of growth hormone by the pituitary gland
tends to decline. Since growth hormone is secreted in pulses, mostly
during the early hours of sleep, it is difficult to measure the
24-hour secretion of the substance directly. Growth hormone
secretion can be measured indirectly, however measure the 24-hour
secretion of the substance measure the 24-hour secretion of the
substance directly. Growth hormone secretion can be measured
indirectly, however, by measuring the plasma concentration of
insulin-like growth factor I (IGF-I, also known as somatomedin C),
which is produced and released by the liver and perhaps other
tissues in response to growth hormone. There is little diurnal
variation in the plasma IGF-I concentration, and measurements of it
are therefore a convenient indicator of growth hormone secretion.
Plasma IGF-I concentrations decline with advancing age in healthy
adults. Less than 5 percent of the healthy men 20 to 40 years old
have plasma IGF-I values of less than 350 U per litre, but the
values are below this figure in 30 percent of the healthy men over
60. Likewise, the nocturnal pulses of growth hormone secretion
becomes smaller or disappear with advanced age. If the plasma
concentration of IGF-I falls below 350 U per litre in older adults,
no spontaneous circulating pulses of growth hormone can be detected
by currently available radioimmunoassay methods. The concomitant
decline in plasma concentrations of both hormones supports the view
that the decrease in IGF-I results from diminished growth hormone
secretion. Second, diminished secretion of growth hormone is
accompanied not only by a fall in the plasma IGF-I concentration,
but also by atrophy of the lean body mass and expansion of the mass
of adipose tissue. These alterations in body composition caused by
growth hormone deficiency can be reversed by replacement doses of
the hormone, as experiments in rodents, children, and adults 20 to
50 years old have shown. These findings suggest that the atrophy of
the lean body mass and its component organs and the enlargement of
the mass of adipose tissue that are characteristic of the elderly
result at least in part from diminished secretion of growth hormone.
If so, the age-related changes in body composition should be
correctable in part by the administration of human growth hormone,
now readily available as a biosynthetic product.
In this study we
administered biosynthetic human growth hormone for six months to 12
healthy men from 61 to 81 years old whose plasma IGF-I
concentrations were below 350 U per litre, and we measured the
effects on plasma IGF-I concentration, lean boy mass, adipose-tissue
mass, skin (dermal plus epidermal) thickness, regional bone density,
and mandibular-height ratio (the height of the alveolar ridge
divided by the total height of the mandible). In addition, the men
were monitored for possible adverse effects of the hormone by means
of interviews physical examinations, and standard laboratory tests.
Nine men matched for age and with similar plasma IGF-I
concentrations served as controls.
Methods
Subjects
Healthy men who were 61
or older and living in the community were recruited through
newspaper advertisements followed by an interview. Entry criteria
(available from the authors on request) included body weight of 90
to 120 percent of the standard for age, the ability to administer
growth hormone to oneself subcutaneously, and the absence of
indications of major disease. Ninety-five men who answered the
advertisement met criteria that could be ascertained by interview.
Their plasma IGF-I concentrations were then determined twice at an
interval of four weeks Consistent with the results of a previous
study, the plasma IGF-I values in these men ranged from 100 to 2400
U per litre, with an average of 500 U per litre. Thirty- three of
the men had plasma IGF-I values of less than 350 U per litre on both
occasions. These 33 men were then further evaluated by a
medical-history taking, physical examination, differential blood
count, urinalysis, blood-chemistry tests, chest radiography, and
electrocardiography. Twenty-six subjects (1 black and 25 white) met
all the entry criteria and were enrolled in the 12-month protocol
summarized in Table 1.
Study Periods
The men were seen at
regular intervals and tested as shown in Table 1 during the first
week of the first, third, and sixth months of the base-line period.
Five men dropped out of the study during these six months (four for
personal reasons and one because carcinoma of the prostate was
detected).
Table 1. Schedule of Tests During the Base-Line and
Treatment Periods
SUNDAY, JUNE 16, 1990 7:08:56 AM SUNDAY, JUNE 16, 1990
7:08:56 AM SUNDAY, JUNE 16, 1990 7:08:56 AM
|
Test |
Base Line
Period |
Treatment
Period |
| |
Mo |
Mo |
Mo |
Mo |
Mo |
Mo |
Mo |
Mo |
Mo |
| |
1 |
3 |
6 |
7 |
8 |
9 |
10 |
11 |
12 |
|
Physical
Examination |
x |
x |
x |
x |
x |
x |
x |
x |
x |
|
Haematology* |
x |
x |
x |
x |
x |
x |
x |
x |
x |
|
Urinalysis* |
x |
x |
x |
x |
x |
x |
x |
x |
x |
|
Blood
Chemistry* |
x |
x |
x |
x |
x |
x |
x |
x |
x |
|
Chest
radiography |
x |
|
x |
|
|
|
|
|
x |
|
Electrocardiography |
x |
|
x |
|
|
|
|
|
x |
|
Echocardiography |
x |
|
x |
|
|
|
|
|
x |
|
Total body
potassium† |
|
|
x |
|
|
|
|
|
x |
|
Skin
thickness‡ |
|
|
x |
|
|
|
|
|
x |
|
Bone density*Š |
|
|
x |
|
|
|
|
|
x |
|
Mandibular-height ratio*þ` |
|
|
x |
|
|
|
|
|
x |
|
Plasma IFG1¶ |
x |
x |
x |
x |
x |
x |
x |
x |
x |
|
Biosynthetic
growth hormone** |
|
|
|
x |
x |
x |
x |
x |
x |
†
Total body potassium levels (lean body mass and adipose tissue-mass)
were measured according to the method of Flynn et al. 15
‡ Calculated at the sum of skin
thickness of the right and left dorsal hand and left volar forearm
measured with a Harpenden calliper according to the method of
Lawrence and Shuster.16
*Š Measured according to the
method of Nagraj et al.17
*þ` Measured according to the
method of Goldberg et al.18
¶ Measured at Nichols
Laboratory, Los Angeles, according to the method of Furlanetto et
al.19
** Administered to group 1 only.
At the beginning of the
seventh month, the 21 men who had completed the base-line period
were randomly assigned to group 1 (growth hormone group) or group 2
(control group) in a ratio of 3 to 2. The randomization table was
generated by a computer program such that in each group of five men,
three would be assigned to the growth hormone group and two to the
control group. All 21 men (12 in group 1 and 9 in group 2) completed
the treatment period and continue the study group for this report.
Their clinical characteristics are summarized in Table 2. During the
first week of the seventh month, the men in group 1 were instructed
in the subcutaneous administration of recombinant biosynthetic human
growth hormone (2.6 IU per milligram of hormone; Eli Lilly). The
initial dose was 0.03 mg per kilogram of body weight, injected three
times a week at 8a.m., the interval between injections being either
one or two days. A sample of venous blood for plasma IGF-I assay was
obtained each month 24 hours after a growth hormone injection. If
the IGF-I level was below 500 U per litre, the dose of hormone w as
increased by 25 percent; if the IGF-I level was above 1500 U per
litre, the dose was reduced by 25 percent. The men in group 2
received no injections. The schedule of tests of both groups during
the treatment period is shown in Table 1.
At the start of the
base-line period, the project dietician instructed each man to
follow a diet that furnished 25 to 30 k.cal per kilogram. The
distribution of kilocalories among protein, carbohydrate, and fat
was approximately 15 percent, 50 percent, and 35 percent,
respectively. At each scheduled visit shown in Table 1, the
dietician analysed each man's diet on the basis of a 24-hours
dietary recall and instructed the subjects again about the standard
diet. The men were told not to alter their lifestyles (including
their use of tobacco or alcohol and their level or physical
activity) during the 12-month study period.
The study protocol was
carried out with the informed consent of each subject and with the
approval of the human-research committees of the Medical College of
Wisconsin, the Chicago Medical School, and the Veterans Affairs
Medical Centres in North Chicago and Milwaukee.
Table 2.
Clinical Characteristics of the Study Subjects.
|
Characteristic |
Group1 (N=12) |
Group2 (N=9) |
|
Median age (range) |
67 (61-73) |
68 (65-81) |
|
Percent of ideal body weight- -median (range) |
103 (94-120) |
105 (99-117) |
| |
|
|
|
Medical conditions (no. of subjects) |
|
|
|
Degenerative joint disease |
5 |
2 |
|
Benign prostatic hypertrophy |
3 |
1 |
|
Glaucoma |
1 |
1 |
|
Cataract |
2 |
1 |
|
Arterioscleotic heart disease* |
3 |
1 |
|
Gallstones |
0 |
1 |
|
Kidney stone |
1 |
1 |
|
Hiatus hernia |
0 |
1 |
| |
|
Medications (no. of subjects) |
|
|
|
Nonsteroidal anti-inflammatory drug |
3 |
1 |
|
Pilocarpine eye drops |
1 |
1 |
|
Cimetidine |
0 |
1 |
*
Defined as history of myocardial infraction or electrocardiographic
abnormality ascribed to coronary artery disease.
Statistical
Analysis
The methods used to
measure each response variable and the locations where the tests
were performed are described in Table 1. The interassay coefficients
of variation for the response variables were as follows: plasma
IGF-I, 7.2 percent; lean body mass, 3.6 percent; adipose-tissue
mass, 6.9 percent; skin thickness, 5.4 percent; and bone density,
2.3 percent (average of nine measured sites).
P values based on
two-tailed matched-pair t-tests were calculated for the comparisons
between the 6-month and 12-month values in group1 and group 2. In
addition, for each response variable the 6-month value was
subtracted from the 12-month value to represent the change in each
subject. P values based on two-tailed, unequal variance,
independent-sample t-tests were then calculated for the comparison
of the changes in response variables between groups 1 and 2.
Results
Clinical
Observations
All the men remained healthy, and none had any changes in the
results of differential blood count, urinalysis, blood-chemistry
profile, chest radiography, electrocardiography, or echocardiography
during the 12-month protocol. Specifically, none had oedema, fasting
hyperglycaemia (>6.6 mmol of glucose per litre), an increase in
blood pressure to more than 160/90 mm Hg, ventricular hypertrophy,
or a local reaction to human growth hormone, nor did their serum
cholesterol or triglyceride concentrations change significantly. In
group 1, however, both the men (" SE) systolic blood pressure and
fasting plasma glucose concentration were significantly higher
(P<0.05 by matched-pair t-test) at the end of the experimental
period than at the end of the base-line period (127.2"5.2 vs. 119.1"
3.6mm Hg and 5.8" 0.2 vs. 5.4" 0.2 mmol per litre, respectively).
Table 3. Effect of the Administration of Human Growth
Hormone on Plasma IGF-1 Concentrations in Healthy Older Men*
| |
Plasma IGF-1 |
| |
Base Line Period |
Treatment Period |
| |
Mo
1 |
Mo. 3 |
Mo.6 |
Mo.7 |
Mo.8 |
|
Group 1 |
240 +-86 |
230+-97 |
230+-66 |
830 +-339H |
680+-180H |
| |
Mo. 9 |
Mo.10 |
Mo.11 |
Mo.12 |
|
| |
720+-350H |
810+-305H |
810+-192H |
910+-312H |
|
|
Group 2 |
Mo
1 |
Mo. 3 |
Mo. 6 |
Mo. 7 |
Mo.8 |
| |
240+-69 |
240+-126 |
240+-108 |
200+-126 |
220+-123 |
| |
Mo. 9 |
Mo.10 |
Mo.11 |
Mo.12 |
|
| |
240+-177 |
180+-126 |
240+-186 |
300+-201 |
|
*Values are
means +-SD HP<0.05 for the comparison between groups
Plasma IGF-I
Concentration
In group 1, the mean
plasma IGF-I concentration ranged from 200 to 250 U per litre
throughout the base-line period (Table 3). Within one month after
the administration of growth hormone had been initiated, the mean
IGF-I level rose to 830 U per litre (P<0.05), and it remained near
this value for the next five months. Eight of the 12 men in group 1
required no adjustment in their initial dose of growth hormone. Two
required an upward adjustment of 25 percent, and two required a
downward adjustment of 25 percent. The mean plasma IGF-I
concentration in group 2 remained in the range of 180 to 300 U per
litre throughout the base-line and treatment periods.
Lean Body Mass,
Adipose-Tissue Mass, Skin Thickness, Bone Density and
Mandibular-Height Ratio
Table 4 shows the mean
values for the other response variables at the end of the base-line
period (6 months) and the end of the treatment period (12 months).
There was no significant change in weight in either group. In group
1, several response variables had changed significantly after 12
months. Lean body mass and the average density of the lumbar
vertebrae increased by 8.8 percent (P<0.0005) and 1.6 percent
(P<0.04), respectively, and adipose-tissue mass decreased by 14.4
percent (P<0.005). The sum of skin thicknesses at four sites
increased .1 percent (P = 0.07). The small average change in lumbar
vertebral bone density (only 0.02 g per square centimetre) was
statistically significant because of very little variability in
individual results. The bone density of the radius and proximal
femur and the ratio of the height of the alveolar ridge to total
mandibular height did not change significantly. In group 2 none of
these variables changed significantly. The change in the lean body
mass was significantly greater in group 1 than in group 2 (P<0.018),
but the differences in changes in skin thickness and adipose-tissue
mass between groups did not reach statistical significance in this
small series (P = 0.10 and 0.13, respectively).
Table 4. Effect of
the Administration of Human Growth Hormone on Weight, Lean Body
Mass, Adipose-Tissue Mass, Skin Thickness, and Bone Density in
Healthy Older Men
|
Variable |
Group |
End of Base Line Period |
End of Base Line Period |
P
Value H |
Difference in Changes I |
|
Weight (kg) |
1 2 |
77.2+-11.4 83.3+-11.1 |
78.2+-12.1 83.3+-9.7 |
0.26 0.97 |
+1.0 (-1.4 to 3.4) |
|
Lean Body Mass (kg) |
1 2 |
53.0+-7.4 54.2+-7.1 |
57.7+-9.1 55.2+-7.3 |
0.05 0.17 |
+3.7 (+0.7 to +6.6) |
|
Adipose Tissue Mass (kg) |
1 2 |
24.1+-5.0 29.0+-6.4 |
20.6+-5.6 28.0+-4.0 |
0.05 0.43 |
-2.4 (-5.7 to +0.8) |
|
Sum of Skin Thickness at four Sites (mm) |
1 2 |
9.9+-1.2 9.3+-0.9 |
10.6+-1.5 9.23+-0.80 |
0.07 0.69 |
+0.8 (-0.1 to +1.7) |
|
Bone Density (g/cm2) Mid-shaft radius |
1 2 |
0.74+-0.10 0.76+-0.10 |
0.74+-0.12 0.71+-0.07 |
0.85 0.09 |
+0.40 (-0.02 to +0.10) |
|
Distal radius |
1 2 |
0.37+-0.07 0.34+-0.04 |
0.36+-0.08 0.33+-0.05 |
0.12 0.26 |
-0.004 (-0.03 to +0.02) |
|
Average lumbar vertebrae 1-4 |
1 2 |
1.23+-0.12 1.29+-0.25 |
1.25+-0.13 1.29+-0.26 |
0.04 0.64 |
+0.006 (-0.04 to +0.05) |
|
Ward's Triangle |
1 2 |
0.70+-0.14 0.70+-0.17 |
0.69+-0.13 0.70+-0.17 |
0.15 0.69 |
-0.018 (-0.08 to +0.05) |
|
Greater trochanter |
1 2 |
0.85+-0.13 0.81+-0.15 |
0.85+-0.13 0.81+-0.13 |
0.72 0.55 |
+0.007 (-0.05 to +0.03) |
|
Femoral neck |
1 2 |
0.92+-0.15 0.89+-0.14 |
0.91+-0.14 0.85+-0.14 |
0.53 0.14 |
-0.029 (-0.08 to +0.03) |
|
Mandibular height ratio |
1 2 |
0.45+-0.15 0.47+-0.12 |
0.46+-0.11 0.47+-0.12 |
0.87 0.98 |
-0.003 (-0.07 to +0.06) |
*
Plus-minus values are means +-SD
HP values
are for the change from base line, by matched pair 1-test
I The
difference in changes (12 month value minus 6 month value) is the
average in group 1 minus the average change in group 2. Values in
parentheses are 95 percent confidence intervals, calculated by
independent-sample, unequal-variance 1-test.
Discussion
The 21 men studied were
representative of the approximately one third of all men 60 to 80
years old who have plasma IGF-I concentrations of less than 350 U
per litre (as compared with a range of 500 to 1500 U per litre in
healthy men 20 to 40 years old). Our findings cannot be generalized
to the approximately two thirds of all men over 60 who have plasma
IGFK-I concentrations of more than 350 U per litre or to women of a
similar age. Furthermore, our entry criteria focused the study on an
overly healthy subgroup of older men.
In the absence of
obesity, below-normal weight, or liver disease, a plasma IGF-I
concentration of less than 350 U per litre in older men generally
signifies that they secrete very little growth hormone. To verify
this explanation for the low plasma IGF-I concentration in these
men, it would be necessary to measure serum growth hormone levels at
frequent intervals for 24 hours or to determine the 24-hour urinary
excretion of growth hormone. We did not do this, but Ho et al. found
that the 24-hour integrated serum growth hormone level was markedly
lower in the men over 55 than in men 18 to 33 years old. An
alternative explanation for a low plasma IGF-I concentration is
decreased production of plasma IGF-I binding proteins. Most of the
IGF-I plasma is bound to these proteins, but their concentrations
vary little in healthy people who eat a normal diet.
In the 12 men in group
1, initially low plasma IGF-I concentrations were raised to the
normal range for young adult men by the dose of growth hormone
administered, with no evidence of tachyphylaxis or hormone
resistance. The dose, approximately 0.03 mg per kilogram three times
a week, was based on published estimates of the rate of growth
hormone secretion in young men and was comparable to or smaller than
doses given previously to children with growth hormone deficiency
and young adults. The plasma IGF-I responses to this dose in these
older men were similar in magnitude to those in younger people. That
"replacement" rather than pharmacologic doses were being
administered was confirmed by the plasma IGF-I measurements, which
remained within the range for healthy young adults (500 to 1500 U
per litre) throughout the treatment period (Table 3). We conclude
that in aging men with low plasma IGF-I concentrations hepatic
responsiveness to human growth hormone is not impaired, and the
decline in plasma IGF-1 concentrations in such men results from
growth hormone deficiency rather than growth hormone resistance. The
increase in plasma IGF-1 levels that occurs when growth hormone is
administered to children with growth hormone deficiency reflects not
only augmented hepatic production of IGF-1, but also increased
production of one of the binding proteins that transport IGF-1. The
extent to which the production of IGF-1 binding protein is increased
by the administration of growth hormone has not yet been studied in
adults.
At the beginning of our
study, adverse reactions to human growth hormone were thought to be
unlikely because physiologic doses were being used. Furthermore,
similar or larger doses have not caused undesired reactions in
children or young adults. Nevertheless, it remained possible that
this dose, when given for six months to older subjects, might cause
some manifestation of hypersomatotropism, such as oedema,
hypertension, diabetes,k or cardiomegaly. Although none of these
conditions developed, there were small increases in the mean
systolic blood pressure and fasting plasma glucose concentration of
the group of men who received growth hormone.
The magnitude of the
increases in lean body mass and the decreases in adipose-tissue mass
(8.8 and -14.2 percent above and below base line, respectively) in
the aging men who received human growth hormone for six months was
similar to the magnitude of these responses in children and young
adults treated with similar or lower doses for three to six months,
a comparison that provides further evidence that tissue
responsiveness to growth hormone and IGFK-I is not altered in older
men. Until now, the evidence for such a conclusion came only from
short-term nitrogen-balance experiments.
Salomon et al. reported
that the administration of human growth hormone in a dose of 0.49
unit per kilogram per week (0.19 mg per kilogram per week) for six
months to adults 20 to 50 years old who had growth hormone
deficiency lowered the serum cholesterol concentration
significantly. Serum cholesterol concentrations did not change in
our study, in which the does of growth hormone was about half as
large (0.9 mg per kilogram per week). The divergent results could
reflect differences in the subjects' ages, the degree of growth
hormone deficiency, the dose of hormone, or all three.
In rodents, the
increase in lean body mass in response to growth hormone is due to
increases in the volume of skeletal muscle, skin, liver, kidney, and
spleen. In young human subjects, an enlargement of muscle and kidney
induced by growth hormone has been documented, other organs have not
yet been assessed. The reduction in adipose-tissue mass when
children with growth hormone deficiency are treated with human
growth hormone is associated with a redistribution of adipose tissue
from abdominal to peripheral areas. It is not known however, whether
the increase in lean body mass and the decrease in adipose-tissue
mass are qualitatively as well as quantitatively similar in old and
young human subjects.
Biosynthetic human
growth hormone had no detectable effect on the bone density of the
radius or proximal femur in the aging men but it increased the
density of the lumbar vertebrae by about 1.6 percent. Although the
decrease in bone density with advancing age in men may be due in
part to diminished secretion of growth hormone, longer periods of
administration of human growth hormone will be required before a
final conclusion can be drawn regarding its efficacy in reversing
that decrease. A similar interpretation applies to the lack of
increase in the mandibular-height ratio.
The findings in this
study are consistent with the hypothesis that the decrease in lean
body mass, the increase in adipose-tissue mass, and the thinning of
the skin that occur in older men are caused in part by reduced
activity of the growth hormone - IGF-I axis, and can be restored in
part by the administration of human growth hormone. The effects of
six months of human growth hormone on lean body mass and
adipose-tissue mass were equivalent in magnitude to the changes
incurred during 10 to 20 years of aging. Among the questions that
remain to be addressed are the following: What will be the benefits
and what will be the nature and frequency of any adverse effects
when larger numbers of elderly subjects and other doses of human
growth hormones are studied? What organs are responsible for the
increase in lean body mass, and do their functional capacities
change as well? Only when such questions are answered can the
possible benefits of human growth hormone in the elderly be
explored. Since atrophy of muscle and skin contributes to the
frailty of older people the potential benefits of growth hormone
merit continuing attention and investigation.
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