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A sephadex column radioimmunoassay of unconjugated estriol in pregnancy plasma
327
A SEPHADEX COLUMN RADIOIMMUNOASSAYOF UNCONJUGATED ESTRIOL IN PREGNANCY PLASMA
James E. Christner and Marion C. Fetter Ames Research Laboratory, Ames Company Division of Miles Laboratories, Inc. Elkhart, Indiana 46514 U .S . A. Received:
514174
ABSTRACT A rapid, precise, and accurate radioimmunoassay for unconjugated estriol in pregnancy plasma has been developed which makes use of the adsorptive properties of Sephadex. The estriol is extracted from plasma by adsorption onto a small column of Sephadex. After the proteins and other interfering materials are washed away, the estriol is equilibrated with a limiting amount of specific antibody. The Sephadex column serves as a means of separating the bound from the unbound estriol, the ratio of which is determined by adding to the system tracer amounts of tritium labeled hormone. The sensitivity is about 220 pg in the sample. The intra- and inter-assay coefficient of variation is S-6%. The method correlated well with one which involved purification of the estriol prior to quantitation by radioimmunoassay. INTRODUCTION The human fetus and placenta the biosynthesis
of numerous
amounts of estrogen during
together
steroids
and is responsible
The assay of urinary
used for many years for the assessment called “placental
of pregnancies
insufficiency.
complications
which fall into this category
estriol
in monitorlng
assays
Under normal conditions, three months of pregnancy.
Volwne 24, Number 3
A sudden
S
TDEOXDI
in the urine
estriol
has been
complicated
‘I The various
by
pregnancy
and the clinical value of urinary
fetal risk were reviewed the excretion
out
for the great
found in the maternal blood and excreted
the last half of pregnancy.
what is generally
form a unit which carries
by Bjoro (1).
rate rises steadily downturn
during
the last
can signal impending
September,
1974
328 fetal death.
Because of short-term
bility of excretion
rates, the determinations
samples to be meaningful complete 24-hour necessarily
fluctuations
(2) . The practical
urine specimen
on plasma,
must be done on serial 24-hour problems
are considerable,
delayed by the sample collection
the measurements
in urinary flow and varia-
the collection
of collecting
a
and the results are
period.
However,
inconsistencies
by doing
and delays
would be eliminated. Numerous reports have appeared immunoassays involve
for free plasma estriol
in the literature
(3-7) . All
describing
the reported
ratio-
assays
solvent extraction
of the sample and purification
of the extract by
either Celite or Sephadex
LH-20 column chromatography.
The values for
unconjugated consistently
plasma estriol in the last trimester of pregnancy
range from less than 2 ng per ml at the 20th week to greater
than 10 ng per ml at term and Tulchinsky 32nd week of normal pregnancy,
Recently,
numerous workers
derivatized
at carbon-6
albumin at that position
specific
radioimmunoassays
using an antibody through
carbon-6.
have reported the preparation conjugation
(8-11) . Antibodies
a high degree of specificity
prepared
and promised
which do not involve a rapid,
plasma estriol concentra-
(4) .
allowing
showed
We have developed
and Abraham found that after the
no unconjugated
tions below 4 ng per ml were found
estriol
(3-6) , fairly
accurate
to bovine serum against these antig@ns
the development purification
and precise
raised against estriol conjugated The estriol is first extracted
Of
Of
steps.
radioimmunoassay
to bovine serum albumin
from serum by adsorption
329
onto a small column of Sephadex.
The serum proteins
and some interfering
factors are then washed away, and the antibody is added and allowed to equilibrate attained,
with the hormone on the Sephadex. the antibody
effects separation
labeled
is washed from the column.
of antibody-bound
which is determined
After equilibration The Sephadex
from unbound estriol,
is column
the ratio of
by adding to the system tracer amounts of tritium-
hormone. MATERIALS
Unlabeled estriol, estradiol- 17p, estrone, and progesterone were obtained from Schwarz/Mann, Orangeburg, New York; 1,3,5 (10) -estratrien3,15a, 16a, 178-tetrol (estetrol) from Steraloids, Inc., Pawling, New York; estriol-16a-glucuronide from Ikapharm, Ramat-Gan, Israel; and estriol 3-sulfate from Sigma Chemical Co., St. Louis, Missouri. The purity of these estrogens was determined by thin-layer chromatography on silica gel G plates with at least three solvent systems; ethyl acetate, chloroformacetone (80/20, V/V) , and ethyl-acetate-hexane-ethanol-glacial acetic acid (72/13.5/4.5/1O,v/v). The spots were developed with iodine vapor. Less than 5% impurity could be detected by this method. All the above compounds except the estriol 16a-glucuronide gave only one spot. The estriol 16aglucuronide contained multiple impurities including an estimated 2% unconjugated estriol . The 6, 7-3H estriol was obtained from the New England Nuclear Corporation, Boston. It was greater than 94% pure as determined by TLC in the above three solvent systems. Other chemicals
used were reagent grade unless otherwise
indicated.
The anti-estriol antibody was obtained from Professor H. R. Lindner of the Weizmann Institute of Technology, Rehovot, Israel. The antibody was prepared by immunizing rabbits with estriol-6-carboxymethyloximebovine serum albumin conjugate and had a titer of 1: 5,000 in a radioimmunoassay using a dextran-charcoal separation technique (8) . It was stored at 4’ in undiluted form. METHODS Solutions The buffer used to dilute the antibody,
dilute plasma samples,
prepare standards, and run the assay consisted of 8.66 gm Na HP0 , 4.68 gm KH PO , 9.0 gm NaCl, 1.0 gm sodium aside, and l.Oam gelatin Knox, un f-3avo!ed) dissolved in charcoal-filtered, glass dietiUed water to give a total volume of 1 liter. The gelatin was first dissolved in a small amount of hot water before being added to the total mixture. The liquid scintillation counting solution consisted of 12 gm of 2,5diphenyloxazole (Packard Instruments, Inc.) , 0.3 gm of 1,4-bis-2- (4methyl-5-phenyloxozolyl) -benzene (Packard Instruments) , and 300 ml of Bio-Solve BBS-3 (a nonionic solubilizer obtained from Beckman Instruments) dissolved in 3 liters of scintillation grade toluene (Beckman Instruments). 6, 7-3H estriol was diluted in buffer to give about 13,000 cpm/ml . This solution was prepared fresh each day. Estriol stock standard was prepared in methanol at a concentration of 11 pg/ml. T&ris solution was stable for at least six months when stored in the dark at 4 . This solution was diluted in buffer to give a cos$centration of 22 ng/ml. The aqueous standard was stored in the dark at 4 and was used for one week. The more dilute standards were prepared daily by serial dilution in buffer. Preparation
of Columns
Small columns of Sephadex G-10 were prepared in 3 ml plastic syringe barrels (Pharmaseal Laboratories) fitted at the bottom with porous polyethylene discs (10.7 mm dia) cut from l/16 inch Vyon filter sheets (Atlas Minerals, Chemicals Division, Mertztown, Pa.) . The discs were stirred in 1%B rij-35 (Atlas Chemical Industries) for 60 minutes, blotted, and dried in a forced-air oven at 70’ for one hour before being used. Sephadex G-10 (Pharmacia Fine Chemicals) was allowed to swell in water overnight. After the fines were removed by repeated suspension in water, the supernatant water was removed as completely as possible, and the Sephadex suspended in 0.5 volume of the buffer twice and one volume once. The Sephadex was allowed to settle overnight in a graduated cylinder, the supernatant buffer was removed, and an equal volume of fresh buffer was added to give a 50%suspension. , While the suspension was being vigorously stirred, 2 ml of the slurry After the excess buffer had drained, was pipetted into each syringe barrel. the columns were ready for use. The columns were prepared each day. Procedure
for Radioimmunoassay
of Estriol
Estriol standard or plasma (0.2 ml) was added to 2.0 ml of the 6, 7-3H estriol solution, and 1 ml of this dilution was pipetted onto the Sephadex column. After the sample had flowed into the Sephadex, the
column was washed with 4 ml of distilled water. The syringe outlet was capped, 1 ml of buffer was added, and the Sephadex gel bed was thoroughly mixed with a Vortex mixer. The outlet was then uncapped, and the buffer allowed to flow out. The 6 ml of effluent collected to this point was discarded. The syringe was placed over a test tube, and 0.25 ml of appropriately diluted antiserum was added. After the antiserum had penetrated the gel bed, the column was allowed to stand for 1 hour at room temperature. The column was then washed with 1.75 ml of buffer. The effluent was mixed and 0.5 ml was pipetted into a scintillation vial along with 10 ml of scintillation fluid and 0.05 ml of 4% SnC12 in 0 .lNHCl . Standard curves were constructed relating the fraction bound (FB) to the cold estriol concentration where FB = Net cpm in sample Net cpm in absence of added estriol’ A dilution of antibody was used that would bind 40% of the tritiated estriol in the absence of added cold estriol . Because the gel bed is thoroughly mixed before addition of the antibody, about 8% of the added radioactivity was nonspedfically eluted along with the antibody-bound estriol. Routinely, the nonspecific counts were not subtracted in making the above calculations. RESULTS Extraction
Efficiency
In order to obtain the most reproducible extracted possible.
results,
from the sample onto the column as efficiently Of the added radioactivity,
of effluent with both the standards
the estriol must be and consistently
as
5.1% (f 0.3%) is lost in the first 6 ml
and the plasma samples.
No correction
was applied for this loss. Precision
and Sensitivity
of the Standard
The results from 22 standard curves pooled to give the results shown in Figure Figure deviation intra-assay
Curve run on separate days were 1 and Table 1.
1 shows the mean fraction bound and the intraassay
obtained from 22 standard curves standard deviation
run on separate days.
(Table 1) was calculated
standard The
from the differences
between the duplicate pg/ml
level,
determinations
the coefficient
The sensitivity
of variation
is about 5%.
which gives a response
of the fraction bound at zero concentration
to an estriol concentration lowest detectable
of about 20 pg.
concentration
would give correspondingly
TABLE I.
Mean F.B.
0
1.00 0.874 0.782 0.648 0.504 0.387 0.311
2.
3.
Two
mrrespond
Since a 1: 10 dilution is used,
the
plasma samples.
Less dilution
greater sensitivity.
Inter- and Intra-Assay
Standard Concentration (ng/ml)
(12).
in the sample would be 220 pg which is more
than adequate for last trimester pregnancy
1.
which is
different from that given by the zero concentration
standard deviations
0.063 0.126 0.252 0.505 1.01 2.02
At and above the 126
of the assay method is defined here as the detection
limit -- the smallest concentration significantly
at each level.
Precision
of Standard Curve
InterAssay S.D.’ (kF.B.)
IntraAssay S.D.2 (+F.B.)
Intra-Assay S.D. in ng/ml’ (? ng/ml)
0.018 0.023 0.018 0.013 0.011 0.012
0.024 0.013 0.006 0.010 0.009 0.005 0.006
0.007 0.006 0.013 0.021 0.030 0.115
Intra-Assay C.V.
11.1 4.8 5.2 4.2 3.0 5.8
Calculated from the means of the duplicate determinations done on 22 sets of standards. The pooled standard deviation from the mean of duplicate determinations done on each standard each day: 2 S.D. = + Jwhere d = difference between duplicates, and n = number of pairs (= 22) . The variation in ng/ml was read off the standard curve in Figure 1.
S
333
x'~EOLD-
0.9
0.8
0.7
0.4
0.3 t
1I
163
Figure
1.
0.126
1 I
t1
0.252 0.505 E3 Concentration (ng/ml)
I
1.01
I .-
2.02
Standard Curve. The points correspond to the means of 22 The bars correspond to the pooled standard standard curves. deviations from the mean of the duplicate determinations (see Table I) .
Inter-
and Intra-Assay
Precision
of Analyses
To determine the inter-assay performed
on each of five days.
with the intra-assay coefficients TABLE II.
Pregnancy Plasma #
192
223
Also, differences The results concentration
precision
of variation
precision,
of Plasma Samples five replicate assays were
The results are shown in Table II along for each day.
The inter- and intra-assay
were both in the 4-6% range,
Inter-assay Precision
of the Determination of Plasma Estriol
Date
X (ng/ml)
4/3/73 4/4/73 4/5/73 4/6/73 4/g/73
4.94 4.86 5.42 5.06 4.92
0.313 0.270 0.110 0.219 0.217
6.34 5.56 2.02 4.33 4.41
Inter-assay
5.04
0.225
4.45
4/3/73 4/4/73 4/5/73 4/6/73 4/g/73
11.1 11.0 10.7 10.5 9.96
0.475 1.74 0.449 0.507 0.709
4.29 15.8 4.20 4.84 7.12
Inter-assay
10.7
0.454
4.27
the intra-assay between
standard
the duplicate
are shown
in Table
deviation
results III.
S .D.
was calculated
obtained
The coefficient
range of O-31 ng/ml was 5-6%.
(ng/ml)
C.V.
(%l
from the
on 68 plasma samples. of variation
over
the
335 TABLE III.
Intra-Assay
Precision
of E3 Determinations
Done on Pregnancy Concentration Range
N
Mean (ng/mll
0.0 5 10 15
7 22 22 17
2.12 7.13 12.3 19.4
1.
-
4.9 9.9 14.9 31
See Table
Various
11.0
0.107 0.419 0.612 1.11
5.0 5.9 5.0 5.7
added to aliquots
and each level
IV, good
recovery
of a pool of
was assayed
in tripli-
and reproducibility
were
at each level.
TABLE N. E3 rig/ml Added
were
individuals,
As shown in Table
obtained
C.V. (%)
of Added Estriol
amounts of estriol
plasma from pregnant cate.
S.D.’ (+ ng/mll
I
- Recovery
Accuracy
Samples
Recoveries
of E3 Added
E3 ng/ml Recovered 13.0 11.9 12.4
to a Pregnancy
Plasma Pool
% Recovery
Average
118 108 113
113%
5.50
5.26 5.70 5.43
95.7 104 98.7
99.5%
2.75
2.62 2.62 2.84
95.3 95.3 103.
97.9%
1.38
1.30 1.36 1.58
94.3 98.3 114. Overall
102%
Average
=
103%
Aliquots
of the pregnancy
solution
mntaining
analyses
plasma pool
the indicated
were
amounts
were then done by the standard
estriol
concentration
Accuracy
The accuracy
samples
estriol
is purified
of the Sephadex
had been assayed by Celite
fled by FUA using 39 samples
With a Reference
of plasma samples
These
at different
“parallelism”
since the sample
This indicates
other
potentially
the test.
Such parallelism step was omitted. in the serum.
Method
from Dr. Dan Tulchinsky.
antiserum
(4) ,
2.
This is termed the standard
was obtained
that the various
components
steroids,
could not be obtained
curve.
over a 20-fold of serum,
do not interfere
This was found to be due to the presence
In the absence of serum proteins,
the estriol was spread
over a much larger
in distribution
resulted
in a difference
the antibody.
Therefore,
differences
of
the estriol bound while in their
band.
in the conditions in binding
in
when the gel-bed
to the column in a narrow band at the top of the column, presence,
on the
of the method to give the
is paralleling
cross-reacting
it is quanti-
The correlation
of the sample.
curve
before
is shown in Figure
is the ability
dilutions
including
proteins
The endogenous
obtained
As shown in Table V, good parallelism
mixing
procedure.
The
column FUA method was also tested
from Dr. Tulchinsky
test of accuracy
range.
estriol.
column chromatography
same results
dilution
of unlabeled
by a RIA method in which the extracted
a nonspecific
obtained
Another
1: 10 into 3H-E3
in the pool was 3.54 ng/ml.
- Comparison
by the analysis
diluted
This difference
of equilibration
were observed
among
with
s
337
YrmRoxDm
y = 1.02x,+1.23 r = 0.9144 Sy= f 2.06
4
8 E3 (ng/ml)
12 Tulchinsky
16
20
Comparison between results obtained by the Sephadex column RIA method and results obtained by Dr. Tulchinsky on 39 plasma samples from pregnant women.
solutions
containing
the gel bed,
various
concentrations
the equilibration
so that buffer standards
conditions
of serum proteins.
By mixing
for all samples become identical
could be used with plasma protein-containing
samples. TABLE V. Plasma No.
Parallelism
* Dilution’:
Between
Pregnancy
Plasma and Buffer
Standards
None
l/2
l/4
l/8
l/20
Mean
S.D.
C.V.
104 105
5.3 20.4
5.0 20.9
4.8 21.0
5.1 22.8
5.1 21.1
0.21 0.96
4.1% 4.5%
152
19.8
21.4
21.9
21.6
20.6 18.4 25.3
22.0
2.02
9.2%
1.
The extent to which the plasma was diluted with buffer diluted 1: 10 into the 3H-E3 solution.
before
being
Specificity The cross-reaction known to be present determined. the estriol account
with certain
in pregnancy
for the observed
contained
in Table VI. unconjugated
quantities
Gross-Reaction
estriol
Estriol Estradiol- 178 Estrone Estetrol Estriol-3-sulfate Estriol- 16a-glucuronide Progesterone Reaction
of Various
which
Steroids
% Cross
Steroid
=
was
As stated previously,
cross-reactivity.
TABLE VI.
% Cross
and neutral steroids
plasma in appreciable
The resuIts are shown 16a-glucuronide
phenolic
Reaction
100 0.63 < 0.3 6.6 1.6 1.7 C 0.06
ng of estriol giving 0.5 FB ng of test steroid giving 0.5 FB
could
It had been noted during results
were
obtained
goes
with pregnancy
cross-reactivity, Therefore,
up 3-fold.
material being
removed
known that charged strength
solutions
reactivity
plasma samples
if the 4-ml water
the extent of reaction
it is likely
while
at least part of the interfering
are removed
the uncharged
16a-glucuronide
from Sephadex
species
It is
is due to the contamination
by low ionic
remain adsorbed
cross-reactivity
of the water wash which
of
with the antibody
by the water wash is estriol-3-sulfate.
molecules
The extent of estriol the omission
of the test that high
If the water wash is omitted in the determination
wash was omitted. estriol-3-sulfate
the development
confirms
(13).
is unaffected
by
the idea that its cross-
by estriol.
DISCUSSION Through
the use of the adsorptive
linked
Sephadex
estriol
has been simplified
reproducibly
G-10,
the radioimmunoassay
extracted
use solvent
extraction
but often introduces for extraction
considerably.
which
Also,
By washing
from the column.
compounds
are ionizable
derivatives
is used to separate
siderably
the Sephadex
simpler
eliminating
Presumably,
of estriol.
radioimmunoassay
to run than conventional
methods,
the need to
to correct cross-reacting
these interfering
Finally, estriol
and
cumbersome,
it is not necessary
the antibody-bound column
cross-
is efficiently
the column with water,
are removed
Although
The estriol
not only is manipulatively
interferences.
losses.
of the tightly
of plasma unconjugated
from the plasma thereby
derivatives
column
properties
the Sephadex
from the unbound. method is conthe precision
is
equal to or better
than that reported
extract
from the plasma and dextran-coated
the estriol
separate bility
the antibody-bound
of the present
extraction, entirely there and,
test would
purification,
within one container
since
identical
the standards
conditions,
However,
1: 1 (V/V) .
women
unconjugated
Also,
by organic
losses
solvents,
are necessary.
procedure
extracted
is adequate of pregnancy.
from plasma that
the sensitivity
which would
the
could be ex-
allow the use of the test to
in plasma from normal non-pregnant
(7). The accuracy
estriol
was determined
added to pooled
recovery
was obtained
physiological
column before
of values.
at concentrations
involved
purification
Excellent
The slight
positive
the recovery
from pregnant covering
the Sephadex
it was quantified
antibody.
by determining
plasma obtained
Also,
values.
a method which
specific
Therefore,
estriol
required.
the last trimester
is efficiently
since
are run under essentially
for extraction
in plasma during
by at least five-fold,
measure
being
of the test with the present
estriol
to
steps are done
introduced
and plasma samples
we found that estriol
has been diluted
with
interferences
to
The reproduci-
to be improved
with no transfers
no corrections
The sensitivity for unconjugated
be expected
use solvents charcoal
from the unbound.
and antibody-equilibration
are no unpredictable
tended
tracer
for methods which
the expected
Good range of
column method was compared of the estriol
by radioimmunoassay
correlation
women.
of
was obtained
bias may indicate
on a Celite
using
a non-
over
a broad
the presence
range
of un-
S known
estrogens
cross-reacting
water-wash
remaining
the greatest
tested for cross-reactivity, The estriol: estetrol
extent.
mester of pregnancy
is about 8 (6) .
concentration
be increased
should
sulfate is present that of estriol
step.
would
The contribution will
Although fete-placental
estriol
estriol (2))
function
unconjugated
within two hours.
Therefore,
is observed,
should
is tested.
been used to assess many potential
rapidly
Also,
be quickly
downturn
determination
uncon-
(4) and any reflected
in 0.1 ml of pregnancy
if a slight
coula
column method
column radioimmunoassay
estriol
a second
estriol
to the estriol
of sample collection. very
2.4 times
sample purification
until a pure standard
from the blood
is able to measure
day.
a separate
has traditionally
The Sephadex
estriol-3-
estrogens
of the Sephadex
the assay in plasma offers
in fete-placental
concentration.
concentration
results
such as ease and rapidity is cleared
estriol
Since
the apparent These
to
the last tri-
the apparent
of estriol-16-a-glucuronide
urinary function
estriol
deterioration
l-6%,
by about 4%.
remain a question
reacted
plasma at a concentration
to the method incorporating
concentration
jugated
higher
ratio throughout
Therefore,
reacts
be increased
for the somewhat
advantages
after the
estetrol
by no more than 1%.
in term pregnancy
(14) and it cross
concentration
as compared
on the column
step,
Of the estrogens
account
341
!rB~OXDrn
in the
method plasma
in plasma estriol can be run the same
~.4RrtorxMII
342
Although
the data presented
estriol,
the procedure
of other
compounds
investigating
these
described such
here
relates
to the assay
may be generally
as steroids
of free plasma
applicable
and hormones.
to the assay
We are currently
possibilities. ACKNOWLEDGEMENTS
The authors
are grateful
for Women for his kind values Lindner
for unconjugated for his generous
assistance estriol.
to Dr.
D. Tulchinsky
in supplying We would
gift of anti-estriol
plasma
of the Boston samples
also like to thank
Hospital
and reference Professor
antiserum.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
13. 14.
Bjoro, K., ACTA ENDOCR., Suppl. 161, 5 (1972) . Klopper, A., AMER. J, OBSTET. GYXC, 107, 807 (1970) . Lipsett, M. B., Loriaux, D. L . , Ruder, H. J., Knab, D. Rxnd J . CLIN. ENDOCR . 35, 887 (1972) . Tulchinsky, D. and Abraham, G. E., J. CLIN. ENDOCR. 33, 775 (1971) . Wu, C. H. and Lundy, L. E., STEROIDS Is, 91 (1971). E., J. STEROID Giebenhain, M . E . , Tagatz, G. E. and Gurpide, BIOCHEM. 3, 707 (1972) . Powell, J. E. and Stevens, V. C., CLIN. CHEM. l9_, 210 (1973) . A. and Zeitlin, A., Lindner, H. R., Perel, E., Friedlander, STEROIDS 19, 357 (1972) . S. J. and Wotiz, H. H., STEROIDS 21, 259 Walker, C. S., Clark, (1973) . Kuss, E . and Goebel, R. , STEROIDS 19, 509 (1972) . D. C. and Preedy, J. R. K., STEROIDS 21, Wright, K., Collins, 755 (1973) * Feldman, J . and Rodbard, D., PRINCIPLES OF COMPETITIVE PROTEIN-BINDING, ASSAYS, Editors, W. D. Odell and W. H. Daughaday, Lippincott Co., Philadelphia, 1971, p . 158. Janson, J. C., J, CHROMATOGR. 28, 12 (1967) . Smith, 0. W. and Hagerman, D. D., J. CLIN. ENDOCR. 25, 732 (1965) .
A SEPHADEX COLUMN RADIOIMMUNOASSAYOF UNCONJUGATED ESTRIOL IN PREGNANCY PLASMA
James E. Christner and Marion C. Fetter Ames Research Laboratory, Ames Company Division of Miles Laboratories, Inc. Elkhart, Indiana 46514 U .S . A. Received:
514174
ABSTRACT A rapid, precise, and accurate radioimmunoassay for unconjugated estriol in pregnancy plasma has been developed which makes use of the adsorptive properties of Sephadex. The estriol is extracted from plasma by adsorption onto a small column of Sephadex. After the proteins and other interfering materials are washed away, the estriol is equilibrated with a limiting amount of specific antibody. The Sephadex column serves as a means of separating the bound from the unbound estriol, the ratio of which is determined by adding to the system tracer amounts of tritium labeled hormone. The sensitivity is about 220 pg in the sample. The intra- and inter-assay coefficient of variation is S-6%. The method correlated well with one which involved purification of the estriol prior to quantitation by radioimmunoassay. INTRODUCTION The human fetus and placenta the biosynthesis
of numerous
amounts of estrogen during
together
steroids
and is responsible
The assay of urinary
used for many years for the assessment called “placental
of pregnancies
insufficiency.
complications
which fall into this category
estriol
in monitorlng
assays
Under normal conditions, three months of pregnancy.
Volwne 24, Number 3
A sudden
S
TDEOXDI
in the urine
estriol
has been
complicated
‘I The various
by
pregnancy
and the clinical value of urinary
fetal risk were reviewed the excretion
out
for the great
found in the maternal blood and excreted
the last half of pregnancy.
what is generally
form a unit which carries
by Bjoro (1).
rate rises steadily downturn
during
the last
can signal impending
September,
1974
328 fetal death.
Because of short-term
bility of excretion
rates, the determinations
samples to be meaningful complete 24-hour necessarily
fluctuations
(2) . The practical
urine specimen
on plasma,
must be done on serial 24-hour problems
are considerable,
delayed by the sample collection
the measurements
in urinary flow and varia-
the collection
of collecting
a
and the results are
period.
However,
inconsistencies
by doing
and delays
would be eliminated. Numerous reports have appeared immunoassays involve
for free plasma estriol
in the literature
(3-7) . All
describing
the reported
ratio-
assays
solvent extraction
of the sample and purification
of the extract by
either Celite or Sephadex
LH-20 column chromatography.
The values for
unconjugated consistently
plasma estriol in the last trimester of pregnancy
range from less than 2 ng per ml at the 20th week to greater
than 10 ng per ml at term and Tulchinsky 32nd week of normal pregnancy,
Recently,
numerous workers
derivatized
at carbon-6
albumin at that position
specific
radioimmunoassays
using an antibody through
carbon-6.
have reported the preparation conjugation
(8-11) . Antibodies
a high degree of specificity
prepared
and promised
which do not involve a rapid,
plasma estriol concentra-
(4) .
allowing
showed
We have developed
and Abraham found that after the
no unconjugated
tions below 4 ng per ml were found
estriol
(3-6) , fairly
accurate
to bovine serum against these antig@ns
the development purification
and precise
raised against estriol conjugated The estriol is first extracted
Of
Of
steps.
radioimmunoassay
to bovine serum albumin
from serum by adsorption
329
onto a small column of Sephadex.
The serum proteins
and some interfering
factors are then washed away, and the antibody is added and allowed to equilibrate attained,
with the hormone on the Sephadex. the antibody
effects separation
labeled
is washed from the column.
of antibody-bound
which is determined
After equilibration The Sephadex
from unbound estriol,
is column
the ratio of
by adding to the system tracer amounts of tritium-
hormone. MATERIALS
Unlabeled estriol, estradiol- 17p, estrone, and progesterone were obtained from Schwarz/Mann, Orangeburg, New York; 1,3,5 (10) -estratrien3,15a, 16a, 178-tetrol (estetrol) from Steraloids, Inc., Pawling, New York; estriol-16a-glucuronide from Ikapharm, Ramat-Gan, Israel; and estriol 3-sulfate from Sigma Chemical Co., St. Louis, Missouri. The purity of these estrogens was determined by thin-layer chromatography on silica gel G plates with at least three solvent systems; ethyl acetate, chloroformacetone (80/20, V/V) , and ethyl-acetate-hexane-ethanol-glacial acetic acid (72/13.5/4.5/1O,v/v). The spots were developed with iodine vapor. Less than 5% impurity could be detected by this method. All the above compounds except the estriol 16a-glucuronide gave only one spot. The estriol 16aglucuronide contained multiple impurities including an estimated 2% unconjugated estriol . The 6, 7-3H estriol was obtained from the New England Nuclear Corporation, Boston. It was greater than 94% pure as determined by TLC in the above three solvent systems. Other chemicals
used were reagent grade unless otherwise
indicated.
The anti-estriol antibody was obtained from Professor H. R. Lindner of the Weizmann Institute of Technology, Rehovot, Israel. The antibody was prepared by immunizing rabbits with estriol-6-carboxymethyloximebovine serum albumin conjugate and had a titer of 1: 5,000 in a radioimmunoassay using a dextran-charcoal separation technique (8) . It was stored at 4’ in undiluted form. METHODS Solutions The buffer used to dilute the antibody,
dilute plasma samples,
prepare standards, and run the assay consisted of 8.66 gm Na HP0 , 4.68 gm KH PO , 9.0 gm NaCl, 1.0 gm sodium aside, and l.Oam gelatin Knox, un f-3avo!ed) dissolved in charcoal-filtered, glass dietiUed water to give a total volume of 1 liter. The gelatin was first dissolved in a small amount of hot water before being added to the total mixture. The liquid scintillation counting solution consisted of 12 gm of 2,5diphenyloxazole (Packard Instruments, Inc.) , 0.3 gm of 1,4-bis-2- (4methyl-5-phenyloxozolyl) -benzene (Packard Instruments) , and 300 ml of Bio-Solve BBS-3 (a nonionic solubilizer obtained from Beckman Instruments) dissolved in 3 liters of scintillation grade toluene (Beckman Instruments). 6, 7-3H estriol was diluted in buffer to give about 13,000 cpm/ml . This solution was prepared fresh each day. Estriol stock standard was prepared in methanol at a concentration of 11 pg/ml. T&ris solution was stable for at least six months when stored in the dark at 4 . This solution was diluted in buffer to give a cos$centration of 22 ng/ml. The aqueous standard was stored in the dark at 4 and was used for one week. The more dilute standards were prepared daily by serial dilution in buffer. Preparation
of Columns
Small columns of Sephadex G-10 were prepared in 3 ml plastic syringe barrels (Pharmaseal Laboratories) fitted at the bottom with porous polyethylene discs (10.7 mm dia) cut from l/16 inch Vyon filter sheets (Atlas Minerals, Chemicals Division, Mertztown, Pa.) . The discs were stirred in 1%B rij-35 (Atlas Chemical Industries) for 60 minutes, blotted, and dried in a forced-air oven at 70’ for one hour before being used. Sephadex G-10 (Pharmacia Fine Chemicals) was allowed to swell in water overnight. After the fines were removed by repeated suspension in water, the supernatant water was removed as completely as possible, and the Sephadex suspended in 0.5 volume of the buffer twice and one volume once. The Sephadex was allowed to settle overnight in a graduated cylinder, the supernatant buffer was removed, and an equal volume of fresh buffer was added to give a 50%suspension. , While the suspension was being vigorously stirred, 2 ml of the slurry After the excess buffer had drained, was pipetted into each syringe barrel. the columns were ready for use. The columns were prepared each day. Procedure
for Radioimmunoassay
of Estriol
Estriol standard or plasma (0.2 ml) was added to 2.0 ml of the 6, 7-3H estriol solution, and 1 ml of this dilution was pipetted onto the Sephadex column. After the sample had flowed into the Sephadex, the
column was washed with 4 ml of distilled water. The syringe outlet was capped, 1 ml of buffer was added, and the Sephadex gel bed was thoroughly mixed with a Vortex mixer. The outlet was then uncapped, and the buffer allowed to flow out. The 6 ml of effluent collected to this point was discarded. The syringe was placed over a test tube, and 0.25 ml of appropriately diluted antiserum was added. After the antiserum had penetrated the gel bed, the column was allowed to stand for 1 hour at room temperature. The column was then washed with 1.75 ml of buffer. The effluent was mixed and 0.5 ml was pipetted into a scintillation vial along with 10 ml of scintillation fluid and 0.05 ml of 4% SnC12 in 0 .lNHCl . Standard curves were constructed relating the fraction bound (FB) to the cold estriol concentration where FB = Net cpm in sample Net cpm in absence of added estriol’ A dilution of antibody was used that would bind 40% of the tritiated estriol in the absence of added cold estriol . Because the gel bed is thoroughly mixed before addition of the antibody, about 8% of the added radioactivity was nonspedfically eluted along with the antibody-bound estriol. Routinely, the nonspecific counts were not subtracted in making the above calculations. RESULTS Extraction
Efficiency
In order to obtain the most reproducible extracted possible.
results,
from the sample onto the column as efficiently Of the added radioactivity,
of effluent with both the standards
the estriol must be and consistently
as
5.1% (f 0.3%) is lost in the first 6 ml
and the plasma samples.
No correction
was applied for this loss. Precision
and Sensitivity
of the Standard
The results from 22 standard curves pooled to give the results shown in Figure Figure deviation intra-assay
Curve run on separate days were 1 and Table 1.
1 shows the mean fraction bound and the intraassay
obtained from 22 standard curves standard deviation
run on separate days.
(Table 1) was calculated
standard The
from the differences
between the duplicate pg/ml
level,
determinations
the coefficient
The sensitivity
of variation
is about 5%.
which gives a response
of the fraction bound at zero concentration
to an estriol concentration lowest detectable
of about 20 pg.
concentration
would give correspondingly
TABLE I.
Mean F.B.
0
1.00 0.874 0.782 0.648 0.504 0.387 0.311
2.
3.
Two
mrrespond
Since a 1: 10 dilution is used,
the
plasma samples.
Less dilution
greater sensitivity.
Inter- and Intra-Assay
Standard Concentration (ng/ml)
(12).
in the sample would be 220 pg which is more
than adequate for last trimester pregnancy
1.
which is
different from that given by the zero concentration
standard deviations
0.063 0.126 0.252 0.505 1.01 2.02
At and above the 126
of the assay method is defined here as the detection
limit -- the smallest concentration significantly
at each level.
Precision
of Standard Curve
InterAssay S.D.’ (kF.B.)
IntraAssay S.D.2 (+F.B.)
Intra-Assay S.D. in ng/ml’ (? ng/ml)
0.018 0.023 0.018 0.013 0.011 0.012
0.024 0.013 0.006 0.010 0.009 0.005 0.006
0.007 0.006 0.013 0.021 0.030 0.115
Intra-Assay C.V.
11.1 4.8 5.2 4.2 3.0 5.8
Calculated from the means of the duplicate determinations done on 22 sets of standards. The pooled standard deviation from the mean of duplicate determinations done on each standard each day: 2 S.D. = + Jwhere d = difference between duplicates, and n = number of pairs (= 22) . The variation in ng/ml was read off the standard curve in Figure 1.
S
333
x'~EOLD-
0.9
0.8
0.7
0.4
0.3 t
1I
163
Figure
1.
0.126
1 I
t1
0.252 0.505 E3 Concentration (ng/ml)
I
1.01
I .-
2.02
Standard Curve. The points correspond to the means of 22 The bars correspond to the pooled standard standard curves. deviations from the mean of the duplicate determinations (see Table I) .
Inter-
and Intra-Assay
Precision
of Analyses
To determine the inter-assay performed
on each of five days.
with the intra-assay coefficients TABLE II.
Pregnancy Plasma #
192
223
Also, differences The results concentration
precision
of variation
precision,
of Plasma Samples five replicate assays were
The results are shown in Table II along for each day.
The inter- and intra-assay
were both in the 4-6% range,
Inter-assay Precision
of the Determination of Plasma Estriol
Date
X (ng/ml)
4/3/73 4/4/73 4/5/73 4/6/73 4/g/73
4.94 4.86 5.42 5.06 4.92
0.313 0.270 0.110 0.219 0.217
6.34 5.56 2.02 4.33 4.41
Inter-assay
5.04
0.225
4.45
4/3/73 4/4/73 4/5/73 4/6/73 4/g/73
11.1 11.0 10.7 10.5 9.96
0.475 1.74 0.449 0.507 0.709
4.29 15.8 4.20 4.84 7.12
Inter-assay
10.7
0.454
4.27
the intra-assay between
standard
the duplicate
are shown
in Table
deviation
results III.
S .D.
was calculated
obtained
The coefficient
range of O-31 ng/ml was 5-6%.
(ng/ml)
C.V.
(%l
from the
on 68 plasma samples. of variation
over
the
335 TABLE III.
Intra-Assay
Precision
of E3 Determinations
Done on Pregnancy Concentration Range
N
Mean (ng/mll
0.0 5 10 15
7 22 22 17
2.12 7.13 12.3 19.4
1.
-
4.9 9.9 14.9 31
See Table
Various
11.0
0.107 0.419 0.612 1.11
5.0 5.9 5.0 5.7
added to aliquots
and each level
IV, good
recovery
of a pool of
was assayed
in tripli-
and reproducibility
were
at each level.
TABLE N. E3 rig/ml Added
were
individuals,
As shown in Table
obtained
C.V. (%)
of Added Estriol
amounts of estriol
plasma from pregnant cate.
S.D.’ (+ ng/mll
I
- Recovery
Accuracy
Samples
Recoveries
of E3 Added
E3 ng/ml Recovered 13.0 11.9 12.4
to a Pregnancy
Plasma Pool
% Recovery
Average
118 108 113
113%
5.50
5.26 5.70 5.43
95.7 104 98.7
99.5%
2.75
2.62 2.62 2.84
95.3 95.3 103.
97.9%
1.38
1.30 1.36 1.58
94.3 98.3 114. Overall
102%
Average
=
103%
Aliquots
of the pregnancy
solution
mntaining
analyses
plasma pool
the indicated
were
amounts
were then done by the standard
estriol
concentration
Accuracy
The accuracy
samples
estriol
is purified
of the Sephadex
had been assayed by Celite
fled by FUA using 39 samples
With a Reference
of plasma samples
These
at different
“parallelism”
since the sample
This indicates
other
potentially
the test.
Such parallelism step was omitted. in the serum.
Method
from Dr. Dan Tulchinsky.
antiserum
(4) ,
2.
This is termed the standard
was obtained
that the various
components
steroids,
could not be obtained
curve.
over a 20-fold of serum,
do not interfere
This was found to be due to the presence
In the absence of serum proteins,
the estriol was spread
over a much larger
in distribution
resulted
in a difference
the antibody.
Therefore,
differences
of
the estriol bound while in their
band.
in the conditions in binding
in
when the gel-bed
to the column in a narrow band at the top of the column, presence,
on the
of the method to give the
is paralleling
cross-reacting
it is quanti-
The correlation
of the sample.
curve
before
is shown in Figure
is the ability
dilutions
including
proteins
The endogenous
obtained
As shown in Table V, good parallelism
mixing
procedure.
The
column FUA method was also tested
from Dr. Tulchinsky
test of accuracy
range.
estriol.
column chromatography
same results
dilution
of unlabeled
by a RIA method in which the extracted
a nonspecific
obtained
Another
1: 10 into 3H-E3
in the pool was 3.54 ng/ml.
- Comparison
by the analysis
diluted
This difference
of equilibration
were observed
among
with
s
337
YrmRoxDm
y = 1.02x,+1.23 r = 0.9144 Sy= f 2.06
4
8 E3 (ng/ml)
12 Tulchinsky
16
20
Comparison between results obtained by the Sephadex column RIA method and results obtained by Dr. Tulchinsky on 39 plasma samples from pregnant women.
solutions
containing
the gel bed,
various
concentrations
the equilibration
so that buffer standards
conditions
of serum proteins.
By mixing
for all samples become identical
could be used with plasma protein-containing
samples. TABLE V. Plasma No.
Parallelism
* Dilution’:
Between
Pregnancy
Plasma and Buffer
Standards
None
l/2
l/4
l/8
l/20
Mean
S.D.
C.V.
104 105
5.3 20.4
5.0 20.9
4.8 21.0
5.1 22.8
5.1 21.1
0.21 0.96
4.1% 4.5%
152
19.8
21.4
21.9
21.6
20.6 18.4 25.3
22.0
2.02
9.2%
1.
The extent to which the plasma was diluted with buffer diluted 1: 10 into the 3H-E3 solution.
before
being
Specificity The cross-reaction known to be present determined. the estriol account
with certain
in pregnancy
for the observed
contained
in Table VI. unconjugated
quantities
Gross-Reaction
estriol
Estriol Estradiol- 178 Estrone Estetrol Estriol-3-sulfate Estriol- 16a-glucuronide Progesterone Reaction
of Various
which
Steroids
% Cross
Steroid
=
was
As stated previously,
cross-reactivity.
TABLE VI.
% Cross
and neutral steroids
plasma in appreciable
The resuIts are shown 16a-glucuronide
phenolic
Reaction
100 0.63 < 0.3 6.6 1.6 1.7 C 0.06
ng of estriol giving 0.5 FB ng of test steroid giving 0.5 FB
could
It had been noted during results
were
obtained
goes
with pregnancy
cross-reactivity, Therefore,
up 3-fold.
material being
removed
known that charged strength
solutions
reactivity
plasma samples
if the 4-ml water
the extent of reaction
it is likely
while
at least part of the interfering
are removed
the uncharged
16a-glucuronide
from Sephadex
species
It is
is due to the contamination
by low ionic
remain adsorbed
cross-reactivity
of the water wash which
of
with the antibody
by the water wash is estriol-3-sulfate.
molecules
The extent of estriol the omission
of the test that high
If the water wash is omitted in the determination
wash was omitted. estriol-3-sulfate
the development
confirms
(13).
is unaffected
by
the idea that its cross-
by estriol.
DISCUSSION Through
the use of the adsorptive
linked
Sephadex
estriol
has been simplified
reproducibly
G-10,
the radioimmunoassay
extracted
use solvent
extraction
but often introduces for extraction
considerably.
which
Also,
By washing
from the column.
compounds
are ionizable
derivatives
is used to separate
siderably
the Sephadex
simpler
eliminating
Presumably,
of estriol.
radioimmunoassay
to run than conventional
methods,
the need to
to correct cross-reacting
these interfering
Finally, estriol
and
cumbersome,
it is not necessary
the antibody-bound column
cross-
is efficiently
the column with water,
are removed
Although
The estriol
not only is manipulatively
interferences.
losses.
of the tightly
of plasma unconjugated
from the plasma thereby
derivatives
column
properties
the Sephadex
from the unbound. method is conthe precision
is
equal to or better
than that reported
extract
from the plasma and dextran-coated
the estriol
separate bility
the antibody-bound
of the present
extraction, entirely there and,
test would
purification,
within one container
since
identical
the standards
conditions,
However,
1: 1 (V/V) .
women
unconjugated
Also,
by organic
losses
solvents,
are necessary.
procedure
extracted
is adequate of pregnancy.
from plasma that
the sensitivity
which would
the
could be ex-
allow the use of the test to
in plasma from normal non-pregnant
(7). The accuracy
estriol
was determined
added to pooled
recovery
was obtained
physiological
column before
of values.
at concentrations
involved
purification
Excellent
The slight
positive
the recovery
from pregnant covering
the Sephadex
it was quantified
antibody.
by determining
plasma obtained
Also,
values.
a method which
specific
Therefore,
estriol
required.
the last trimester
is efficiently
since
are run under essentially
for extraction
in plasma during
by at least five-fold,
measure
being
of the test with the present
estriol
to
steps are done
introduced
and plasma samples
we found that estriol
has been diluted
with
interferences
to
The reproduci-
to be improved
with no transfers
no corrections
The sensitivity for unconjugated
be expected
use solvents charcoal
from the unbound.
and antibody-equilibration
are no unpredictable
tended
tracer
for methods which
the expected
Good range of
column method was compared of the estriol
by radioimmunoassay
correlation
women.
of
was obtained
bias may indicate
on a Celite
using
a non-
over
a broad
the presence
range
of un-
S known
estrogens
cross-reacting
water-wash
remaining
the greatest
tested for cross-reactivity, The estriol: estetrol
extent.
mester of pregnancy
is about 8 (6) .
concentration
be increased
should
sulfate is present that of estriol
step.
would
The contribution will
Although fete-placental
estriol
estriol (2))
function
unconjugated
within two hours.
Therefore,
is observed,
should
is tested.
been used to assess many potential
rapidly
Also,
be quickly
downturn
determination
uncon-
(4) and any reflected
in 0.1 ml of pregnancy
if a slight
coula
column method
column radioimmunoassay
estriol
a second
estriol
to the estriol
of sample collection. very
2.4 times
sample purification
until a pure standard
from the blood
is able to measure
day.
a separate
has traditionally
The Sephadex
estriol-3-
estrogens
of the Sephadex
the assay in plasma offers
in fete-placental
concentration.
concentration
results
such as ease and rapidity is cleared
estriol
Since
the apparent These
to
the last tri-
the apparent
of estriol-16-a-glucuronide
urinary function
estriol
deterioration
l-6%,
by about 4%.
remain a question
reacted
plasma at a concentration
to the method incorporating
concentration
jugated
higher
ratio throughout
Therefore,
reacts
be increased
for the somewhat
advantages
after the
estetrol
by no more than 1%.
in term pregnancy
(14) and it cross
concentration
as compared
on the column
step,
Of the estrogens
account
341
!rB~OXDrn
in the
method plasma
in plasma estriol can be run the same
~.4RrtorxMII
342
Although
the data presented
estriol,
the procedure
of other
compounds
investigating
these
described such
here
relates
to the assay
may be generally
as steroids
of free plasma
applicable
and hormones.
to the assay
We are currently
possibilities. ACKNOWLEDGEMENTS
The authors
are grateful
for Women for his kind values Lindner
for unconjugated for his generous
assistance estriol.
to Dr.
D. Tulchinsky
in supplying We would
gift of anti-estriol
plasma
of the Boston samples
also like to thank
Hospital
and reference Professor
antiserum.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
13. 14.
Bjoro, K., ACTA ENDOCR., Suppl. 161, 5 (1972) . Klopper, A., AMER. J, OBSTET. GYXC, 107, 807 (1970) . Lipsett, M. B., Loriaux, D. L . , Ruder, H. J., Knab, D. Rxnd J . CLIN. ENDOCR . 35, 887 (1972) . Tulchinsky, D. and Abraham, G. E., J. CLIN. ENDOCR. 33, 775 (1971) . Wu, C. H. and Lundy, L. E., STEROIDS Is, 91 (1971). E., J. STEROID Giebenhain, M . E . , Tagatz, G. E. and Gurpide, BIOCHEM. 3, 707 (1972) . Powell, J. E. and Stevens, V. C., CLIN. CHEM. l9_, 210 (1973) . A. and Zeitlin, A., Lindner, H. R., Perel, E., Friedlander, STEROIDS 19, 357 (1972) . S. J. and Wotiz, H. H., STEROIDS 21, 259 Walker, C. S., Clark, (1973) . Kuss, E . and Goebel, R. , STEROIDS 19, 509 (1972) . D. C. and Preedy, J. R. K., STEROIDS 21, Wright, K., Collins, 755 (1973) * Feldman, J . and Rodbard, D., PRINCIPLES OF COMPETITIVE PROTEIN-BINDING, ASSAYS, Editors, W. D. Odell and W. H. Daughaday, Lippincott Co., Philadelphia, 1971, p . 158. Janson, J. C., J, CHROMATOGR. 28, 12 (1967) . Smith, 0. W. and Hagerman, D. D., J. CLIN. ENDOCR. 25, 732 (1965) .