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Fluorescent substrate assay for antithrombin III
FLUORESCENT SUBSTF%TE ASSAY FOR ANTITHROMBIN III
Gary A. Mitchell, Patricia M. Hudson, Rolf M. Huseby, Sharon P. Pochron and Robert J. Gargiulo DADE Division American Hospital Supply Corporation Miami, Florida, U.S.A.
(Received
3.11.1977.
Accepted
by
Editor
1i.H. Seegers)
ABSTRACT A sensitive method for the assay of antithrombin III activity is described using a synthetic fluorescent tripeptide, CBZ-gly-pro-arg4-methoxy-gNA, as a substrate for thrombin. The inhibitor activity in 0.5 ul of plasma (not defibrinated) is determined with assay precision comparable to clotting and immunologic methods. Substrate assay values for normal range samples correlate with immunologic test values while abnormally low inhibitor samples give smaller substrate assay results.
INTRODUCTION Recently several procedures have been reported for the functional assay of antithrombin III
using the synthetic chromogenic substrate benzoyl-
(AT-III)
phenylalanine-valine-arginine-p-nitroaniline (1,2,3).
The chromophore is
hydrolyzed from the substrate by thrombin and its release can be measured spectrophotometrically.
Plasma AT-III activity is determined indirectly by
incubation of thrombin with patient plasma followed by the addition of substrate and measurement of the residual thrombin activity. This paper reports the use of a fluorescent peptide substrate, carbobenzoxy-glycine-proline-arginine-4-methoxy-~-naphthylamide, for AT-III assay.
The
peptide portion of this substrate is identical to the amino acid sequence reported for the natural substrate, human fibrinogen, located at a site of thrombin catalyzed cleavage (4).
This substrate is considerably more sensitive
to the measurement of thrombin thereby eliminating some interferences present in the chromogenic assays.
Also, assay precision is superior to that reported 219
221)
hSTITHFtOYBIS
III
ASSAY
VOl.l2,NO.~
for chromogenic substrate inhibitor assays with precision values in the range of clotting and immunologic test methods (5).
MATERIALSAND METHODS Buffer-l: 0.25 M glycine in 0.03 M NaCl with 2 mM K,EDTA and 0.01% thimerosal, pH adjusted to 8.3 with 5 N NaOH.
Used for all dilutions except the thrombin.
Buffer-2: 0.25 M glycine in 0.15 M NaCl with 2 mM K,EDTA and 0.01% thimerosal, pH adjusted to 8.3 with 5 N NaOH.
Used only for thrombin dilutions.
Human thrombin: lyophilized, 100 Ill/vial,no. 70/157, from WHO International Laboratory for Biological Standards, London NW3 6RB, England.
Each vial of
thrombin was reconstituted with 5 ml buffer-2 and 0.25 ml aliquots stored at -20C in siliconized glass vials.
Before use, the thrombin was thawed and
diluted to 1 IU/ml buffer-2. Bovine mucosal heparin: lyophilized, 1,250 IU/vial, no. 63/10 from WHO International Laboratory for Biological Standards, London NW3 6RB, England. Each vial of heparin was reconstituted and diluted with buffer-l to 10 IU/ml and 0.20 ml aliquots stored at -20C in siliconized glass vials.
Before use,
the heparin was thawed and diluted to a working concentration of 2 IU/ml buffer-l.
This concentration was selected following heparin titration
experiments.
Thrombin was not inhibited in the absence of AT-III
when this
concentration was used and greater concentrations gave turbid reaction mixtures, CBZ-glycine-proline-arqinine(HC1)-4-methoxy-B-naphth,ylamide: mol wt 654.1, from Enzyme Systems Products, Inc.,
4155 Rolling Trails, Greenwood, Indiana 46142. A
stock solution was prepared in absolute ethanol at a concentration of 12 mg/ml and stored at 4C.
Before use, the ;tock solution was diluted in buffer-l to a
concentration of 150 mg/l (0.23 mM/l) and warmed to 37C.
A Km value of 8.3 x
10s5 M (37C) was determined within the assay system using the Lineweaver-Burk equation. Blood specimens were collected in plastic or siliconized glass tubes containing one volume of 3.8% trisodium citrate for each nine volumes of blood.
The
specimens were centrifuged at 1,500 to 2,000 g for 10 to 15 minutes to obtain the plasma which was stored at -20C. diluted 1:400 in buffer-l. M-Partigennf Antithrombin III
Before use, the plasmas were thawed and
Diluted plasmas were maintained at 4C until assayed. Kit: radial immunodiffusion test from Behring
Diagnostics, American Hoechst Corp., Somerville, N.J. 08876. Perkin Elmer Model MPF-EA fluorescence spectrophotometer: Norwalk, Connecticut, 06856, with a controlled temperature sample cell holder and recorder model QPD-33.
The excitation and emission wavelength and slit width settings were
?‘-
j-3
,. z,
‘15
r,;;
6 x 12 nm respectively.
37s
13 x i2 x 45 mm rectangular 100 >l of diluted 130 ::1 of the
heoarin
>{armed to 37i.
100
After
incubation
rniniibited
plasma
thrombin
was
was
radial
over
the test their used
allowing
plasmas
normal
89 to 111% range
for
reported
performed value. Internal
the
mean
were
RIG
plasmas
with
and
were
sampie
-,
of
The
an_'
cuvette
zrd
cixec.
solution,
to mix
measurement
interval.
‘-i
used.
conten:s
substrate
inverted
and were
with
partial values
The
supplied
value value
performed
the
:23
reagents.
the release:
inhibitor
acti,iity
time
and
of 48 hours
normal
clotting
ranges,
as 80
RID
test
74
it 2 SD,
to 120% range
to 130%.
for
Dr.
of Michigan,
of thrombotic
Ann
at 25C.
for
the
A.
of 5y
the
samples two
*jere
tes:
substrate
ass?:; and
than
nor+-?1
the
determinations of the
Penner,
Arbor,
episodes
Eigh:
as judgel
These
is narrower All
John
to nanufacf;rer's
values
times.
as a percentage by
x 100
according
thromboplastin
calculated
University histories
was
diffusion
determined
test.
olank-plasma blank
test
by the manufacturer,
Medicine,
individuals
cuve tte was
=
patients
and
normal
ranges
in duplicate Other
the
rj-r
determinations)
to the
added
2.0 ml of
by kinetic
ted
(RID
from
prothrombin
The
blank
added was
a 2-4 minute
inhib
a minimum
were
to establish
methods.
4 ml capacity (for
25
;.;:j
follows:
inlmunodiffusion
instructions
and
determined
? thrombin The
were
1 IU/ml,
at 37C,
added
witn
or buffer
2 IU/ml,
60 seconds
4-methoxy-B-naphthylamine as
sample
solution,
to 37C)
kfas calculated
cuvettes
~1 of thrombin,
for
rrg/l (prewarmed
quartz
rc~c~c~r~~?r joe&
Tie
assay
were nor-ma? yean
Department
Michigan,
or suspected
of
and were ciotting
from problems
RESULTS The triplicate
substrate
assay
precision
assay
of plasma
samples,
ranged Table
from 1.
0.6
to 6.4X
as determined
51,
TABLE 1 Precision of Plasma Antithrombin III Measurements by Fluorescent Substrate Assay Plasma Sample
Relative Fluorescent Rates
: 3 4
0.83, 0.99, 0.89, 0.86 1.01 0.86, 0.90, 0.80 0.72, 0.72, 0.68
6.4 3.0 5.0 2.3
2
0.67, 0.63 0.69, 0.69, 0.65
;::
: 9 Yil
0.61, 0.61, 0.59 0.62, 0.56, 0.60 0.64, 0.59, 0.58 0.61, 0.53, 0.53 0.65, 0.60 0.59, 0.60, 0.57, 0.57
3.0 0.6 3.2 4.2 6.0
12
Precision, CV;:
1.7 x = + 3.4%
Assay specificity was determined by comparison of dilution curves for a pool of plasma from five patient samples with normal clotting times to a WHO purified human AT-III preparation, no. 75/564, Fig. 1.
The slopes of the
response curves are nearly identical. FIG.
1
60
1:&0 Plasma
1:soo or Purified
AT-II.f
1:iOO
I:;00
Dilutions
Fluorescent substrate assay response curves for dilutions of pooled normal plasma and purified antithrombin III.
The s:abi;ity of alasma AT-iii activity after f?eezjnl ;q?s a1j3 fluorescent titive
substrate
freezing
inhibitor
activity
I 2'; for
some
bias
low probability When are
than
gives
the
toward
for
abnormally
larger
analysis
2 and
the
The
pool
and
thawing
one
to three
values
in Tables
are within strates
after
AT-III
Plasma compared
assay.
at -20C
determined 3.
Mean
of normal
at 20-25C
freeze-thaw by RID
values
larger
RID values
low AT-III fluorescent
considerable
bias
samples
fluorescent normal
least
while
the
compared are
substrate
RID
subjected
to repe-
loss
substrate
range
souares paired
assay
samples, analysis
t-test
gives
Table
3, all
RID
results. values
and
The
least
Sample
2
Least
X Normal RID Test
3
Mean
AT-III FS Assay
117.5 114.5 107.1 104.5 104.2 101.1 100.7 97.9 96.7 93.7 92.3 92.2 83.9
116.0 111.7 107.5 105.5 104.1 100.3 108.7 91.7 86.9 97.1 90.4 80.6 84.9
si= 100.5
98.9
squares analysis slope, m = 1.07 y intercept, b = -8.2 t-test, paired P = 0.3 - 0.4 Correlation Coefficient, r = 0.89
values
squares
the difference
Compar -ison of Normal Range Antithrombin III Values Determined Radi al Immunodiffusion Test and Fluorescent Substrate Assay
Plasma
are
Table demon-
the results of the two test methods is significant by the t-test.
TABLE
in
results,
compared,
assay
to larger
was
no detectable
5.i
cycles.
the
The
methods.
in the
and
for
two test
a difference
plasma
with
d>termireti
by
in
2,
\‘01.12,s0.2
TAaLE 3 Comparison of Abnormally Low Antithrombin III Values Determined by Radial Immunodiffusion Test and Fluorescent Substrate Assay
Plasma Sample 1 2 3 4 5
X Normal Mean AT-III RID Test FS Assay 74.3 70.6 66.4 65.4 50.6
65.6 52.8 60.1 27.9 30.0
x = 65.5
47.3
Least squares analysis slope, m = 1.41 y intercept, b = -45.1 t-test paired P = 0.02 - 0.05 Correlation Coefficient, r = 0.73 DISCUSSION Defibrinated plasma, 30 to 100 ~1, is used in some chromogenic substrate assays for AT-III fibrinogen (1,3).
since clotting would result from the use of plasma \:ith The clotting interference is reduced but not eliminated when
the plasma (not defibrinated) is reduced to 13 ul and a high pH and ionic strength buffer is used (2).
The fluorescent substrate used in our assay is
more sensitive to the detection of thrombin and, as a result, only 0.1 IU thrombin and 0.5 Pl plasma (not defibrinated) are employed in each test.
Since
the plasma dilution in the incubation and measurement steps is 1:800 and 1:4,800 respectively, defibrinated plasma is not required in the fluorescent assay. Interference from most icteric, hemolyzed or colored samples is eliminated by the higher plasma dilution.
Mean fluorescent assay precision is 3.4% as
compared to 5.5% for inhibitor assays performed with the chromogenic substrate (5).
The increased precision may be attributed to the elimination of some
plasma interferences as well as the greater specificity of fluorescent measurements as compared to spectrophotometric measurements. The normal range AT-III results, Table 2, show good comparison for the two test methods although there is a slight bias toward higher RID values. The low AT-III samples, Table 3, were abnormal by both test methods, but all RID test results are higher and there is poor correlation between the results of the two methods.
Similar results were reported recently in a comparative
study of immunologic and chromogenic substrate assay values of AT-III
where
the abnormal low samples gave higher values in the immunologic test (6).
Other
reportj
have
SiJgge
jted
the
izminologic tests (7,8).
detection
of
f>;ric:jq2p.a;
: , i~.a~tj!~e
rii-1:
I
by
Our results are in aagreezent with those reports
indicating that measurement of AT-III concentration may be less useful than the &termination
of AT-III activity. REFERENCES
1.
BERGSTRtiM, K. and TAHNGORG, G. The effect of major surgery low doses of heparin and thromboembolism on plasma antithrombin. Comparison of immediate thrombin inhibiting capacity and the antithrombin content. Thromb.Res. 5, 223, 1975.
2.
ODEGARD, M. TIE and ABILDGAARD, U. Heparin cofa ctor activity measured ,:ii:h an amidolytic method. Thromb.Res. 6, 237, 1975.
3.
VINAZZER, H. Photometric assay of antithrcmbin III with a chromogenic substrate. Haemostasis 2, 101, 1975.
4.
BLOMBACK, B., BLOMBkK, M., HESSEL, B. and IWANAGA,S. Structure of Titerminal fragments of fibrinogen and specificity of thrombin. Nature 215, 1445, 1967.
5.
BLOMBkK, M., BLOMBACK, B., OLSSON, P. and SVENDSEN, L. The assay of antithrombin using a synthetic chromogenic substrate for thrombin. Throm.Res. 5, 621, 1974.
6.
IlOrlTGOMERY, B. Automated test measures functional antithrombin, coagulation enzymes. J.Amer.Med.Assoc. 238, 1005, 1977.
7.
SAS, G., BLASK6, G., BANHEGYI, D., JAKO, J.A. and PALOS, I.A. antithrombin III (antithrombin III 'Budapest') as a cause of thrombophilia. Thromb.Diath.Haemorrh. 32_, 105, 1974.
8.
DONATI, M.B., VANDENBERGHE, K., MOLLA, A., deRO0, M., and VERSTRAETE, M. Postoperative antithrombin III, Lancet i, 726, 1973.
Abnormal a familial
Gary A. Mitchell, Patricia M. Hudson, Rolf M. Huseby, Sharon P. Pochron and Robert J. Gargiulo DADE Division American Hospital Supply Corporation Miami, Florida, U.S.A.
(Received
3.11.1977.
Accepted
by
Editor
1i.H. Seegers)
ABSTRACT A sensitive method for the assay of antithrombin III activity is described using a synthetic fluorescent tripeptide, CBZ-gly-pro-arg4-methoxy-gNA, as a substrate for thrombin. The inhibitor activity in 0.5 ul of plasma (not defibrinated) is determined with assay precision comparable to clotting and immunologic methods. Substrate assay values for normal range samples correlate with immunologic test values while abnormally low inhibitor samples give smaller substrate assay results.
INTRODUCTION Recently several procedures have been reported for the functional assay of antithrombin III
using the synthetic chromogenic substrate benzoyl-
(AT-III)
phenylalanine-valine-arginine-p-nitroaniline (1,2,3).
The chromophore is
hydrolyzed from the substrate by thrombin and its release can be measured spectrophotometrically.
Plasma AT-III activity is determined indirectly by
incubation of thrombin with patient plasma followed by the addition of substrate and measurement of the residual thrombin activity. This paper reports the use of a fluorescent peptide substrate, carbobenzoxy-glycine-proline-arginine-4-methoxy-~-naphthylamide, for AT-III assay.
The
peptide portion of this substrate is identical to the amino acid sequence reported for the natural substrate, human fibrinogen, located at a site of thrombin catalyzed cleavage (4).
This substrate is considerably more sensitive
to the measurement of thrombin thereby eliminating some interferences present in the chromogenic assays.
Also, assay precision is superior to that reported 219
221)
hSTITHFtOYBIS
III
ASSAY
VOl.l2,NO.~
for chromogenic substrate inhibitor assays with precision values in the range of clotting and immunologic test methods (5).
MATERIALSAND METHODS Buffer-l: 0.25 M glycine in 0.03 M NaCl with 2 mM K,EDTA and 0.01% thimerosal, pH adjusted to 8.3 with 5 N NaOH.
Used for all dilutions except the thrombin.
Buffer-2: 0.25 M glycine in 0.15 M NaCl with 2 mM K,EDTA and 0.01% thimerosal, pH adjusted to 8.3 with 5 N NaOH.
Used only for thrombin dilutions.
Human thrombin: lyophilized, 100 Ill/vial,no. 70/157, from WHO International Laboratory for Biological Standards, London NW3 6RB, England.
Each vial of
thrombin was reconstituted with 5 ml buffer-2 and 0.25 ml aliquots stored at -20C in siliconized glass vials.
Before use, the thrombin was thawed and
diluted to 1 IU/ml buffer-2. Bovine mucosal heparin: lyophilized, 1,250 IU/vial, no. 63/10 from WHO International Laboratory for Biological Standards, London NW3 6RB, England. Each vial of heparin was reconstituted and diluted with buffer-l to 10 IU/ml and 0.20 ml aliquots stored at -20C in siliconized glass vials.
Before use,
the heparin was thawed and diluted to a working concentration of 2 IU/ml buffer-l.
This concentration was selected following heparin titration
experiments.
Thrombin was not inhibited in the absence of AT-III
when this
concentration was used and greater concentrations gave turbid reaction mixtures, CBZ-glycine-proline-arqinine(HC1)-4-methoxy-B-naphth,ylamide: mol wt 654.1, from Enzyme Systems Products, Inc.,
4155 Rolling Trails, Greenwood, Indiana 46142. A
stock solution was prepared in absolute ethanol at a concentration of 12 mg/ml and stored at 4C.
Before use, the ;tock solution was diluted in buffer-l to a
concentration of 150 mg/l (0.23 mM/l) and warmed to 37C.
A Km value of 8.3 x
10s5 M (37C) was determined within the assay system using the Lineweaver-Burk equation. Blood specimens were collected in plastic or siliconized glass tubes containing one volume of 3.8% trisodium citrate for each nine volumes of blood.
The
specimens were centrifuged at 1,500 to 2,000 g for 10 to 15 minutes to obtain the plasma which was stored at -20C. diluted 1:400 in buffer-l. M-Partigennf Antithrombin III
Before use, the plasmas were thawed and
Diluted plasmas were maintained at 4C until assayed. Kit: radial immunodiffusion test from Behring
Diagnostics, American Hoechst Corp., Somerville, N.J. 08876. Perkin Elmer Model MPF-EA fluorescence spectrophotometer: Norwalk, Connecticut, 06856, with a controlled temperature sample cell holder and recorder model QPD-33.
The excitation and emission wavelength and slit width settings were
?‘-
j-3
,. z,
‘15
r,;;
6 x 12 nm respectively.
37s
13 x i2 x 45 mm rectangular 100 >l of diluted 130 ::1 of the
heoarin
>{armed to 37i.
100
After
incubation
rniniibited
plasma
thrombin
was
was
radial
over
the test their used
allowing
plasmas
normal
89 to 111% range
for
reported
performed value. Internal
the
mean
were
RIG
plasmas
with
and
were
sampie
-,
of
The
an_'
cuvette
zrd
cixec.
solution,
to mix
measurement
interval.
‘-i
used.
conten:s
substrate
inverted
and were
with
partial values
The
supplied
value value
performed
the
:23
reagents.
the release:
inhibitor
acti,iity
time
and
of 48 hours
normal
clotting
ranges,
as 80
RID
test
74
it 2 SD,
to 120% range
to 130%.
for
Dr.
of Michigan,
of thrombotic
Ann
at 25C.
for
the
A.
of 5y
the
samples two
*jere
tes:
substrate
ass?:; and
than
nor+-?1
the
determinations of the
Penner,
Arbor,
episodes
Eigh:
as judgel
These
is narrower All
John
to nanufacf;rer's
values
times.
as a percentage by
x 100
according
thromboplastin
calculated
University histories
was
diffusion
determined
test.
olank-plasma blank
test
by the manufacturer,
Medicine,
individuals
cuve tte was
=
patients
and
normal
ranges
in duplicate Other
the
rj-r
determinations)
to the
added
2.0 ml of
by kinetic
ted
(RID
from
prothrombin
The
blank
added was
a 2-4 minute
inhib
a minimum
were
to establish
methods.
4 ml capacity (for
25
;.;:j
follows:
inlmunodiffusion
instructions
and
determined
? thrombin The
were
1 IU/ml,
at 37C,
added
witn
or buffer
2 IU/ml,
60 seconds
4-methoxy-B-naphthylamine as
sample
solution,
to 37C)
kfas calculated
cuvettes
~1 of thrombin,
for
rrg/l (prewarmed
quartz
rc~c~c~r~~?r joe&
Tie
assay
were nor-ma? yean
Department
Michigan,
or suspected
of
and were ciotting
from problems
RESULTS The triplicate
substrate
assay
precision
assay
of plasma
samples,
ranged Table
from 1.
0.6
to 6.4X
as determined
51,
TABLE 1 Precision of Plasma Antithrombin III Measurements by Fluorescent Substrate Assay Plasma Sample
Relative Fluorescent Rates
: 3 4
0.83, 0.99, 0.89, 0.86 1.01 0.86, 0.90, 0.80 0.72, 0.72, 0.68
6.4 3.0 5.0 2.3
2
0.67, 0.63 0.69, 0.69, 0.65
;::
: 9 Yil
0.61, 0.61, 0.59 0.62, 0.56, 0.60 0.64, 0.59, 0.58 0.61, 0.53, 0.53 0.65, 0.60 0.59, 0.60, 0.57, 0.57
3.0 0.6 3.2 4.2 6.0
12
Precision, CV;:
1.7 x = + 3.4%
Assay specificity was determined by comparison of dilution curves for a pool of plasma from five patient samples with normal clotting times to a WHO purified human AT-III preparation, no. 75/564, Fig. 1.
The slopes of the
response curves are nearly identical. FIG.
1
60
1:&0 Plasma
1:soo or Purified
AT-II.f
1:iOO
I:;00
Dilutions
Fluorescent substrate assay response curves for dilutions of pooled normal plasma and purified antithrombin III.
The s:abi;ity of alasma AT-iii activity after f?eezjnl ;q?s a1j3 fluorescent titive
substrate
freezing
inhibitor
activity
I 2'; for
some
bias
low probability When are
than
gives
the
toward
for
abnormally
larger
analysis
2 and
the
The
pool
and
thawing
one
to three
values
in Tables
are within strates
after
AT-III
Plasma compared
assay.
at -20C
determined 3.
Mean
of normal
at 20-25C
freeze-thaw by RID
values
larger
RID values
low AT-III fluorescent
considerable
bias
samples
fluorescent normal
least
while
the
compared are
substrate
RID
subjected
to repe-
loss
substrate
range
souares paired
assay
samples, analysis
t-test
gives
Table
3, all
RID
results. values
and
The
least
Sample
2
Least
X Normal RID Test
3
Mean
AT-III FS Assay
117.5 114.5 107.1 104.5 104.2 101.1 100.7 97.9 96.7 93.7 92.3 92.2 83.9
116.0 111.7 107.5 105.5 104.1 100.3 108.7 91.7 86.9 97.1 90.4 80.6 84.9
si= 100.5
98.9
squares analysis slope, m = 1.07 y intercept, b = -8.2 t-test, paired P = 0.3 - 0.4 Correlation Coefficient, r = 0.89
values
squares
the difference
Compar -ison of Normal Range Antithrombin III Values Determined Radi al Immunodiffusion Test and Fluorescent Substrate Assay
Plasma
are
Table demon-
the results of the two test methods is significant by the t-test.
TABLE
in
results,
compared,
assay
to larger
was
no detectable
5.i
cycles.
the
The
methods.
in the
and
for
two test
a difference
plasma
with
d>termireti
by
in
2,
\‘01.12,s0.2
TAaLE 3 Comparison of Abnormally Low Antithrombin III Values Determined by Radial Immunodiffusion Test and Fluorescent Substrate Assay
Plasma Sample 1 2 3 4 5
X Normal Mean AT-III RID Test FS Assay 74.3 70.6 66.4 65.4 50.6
65.6 52.8 60.1 27.9 30.0
x = 65.5
47.3
Least squares analysis slope, m = 1.41 y intercept, b = -45.1 t-test paired P = 0.02 - 0.05 Correlation Coefficient, r = 0.73 DISCUSSION Defibrinated plasma, 30 to 100 ~1, is used in some chromogenic substrate assays for AT-III fibrinogen (1,3).
since clotting would result from the use of plasma \:ith The clotting interference is reduced but not eliminated when
the plasma (not defibrinated) is reduced to 13 ul and a high pH and ionic strength buffer is used (2).
The fluorescent substrate used in our assay is
more sensitive to the detection of thrombin and, as a result, only 0.1 IU thrombin and 0.5 Pl plasma (not defibrinated) are employed in each test.
Since
the plasma dilution in the incubation and measurement steps is 1:800 and 1:4,800 respectively, defibrinated plasma is not required in the fluorescent assay. Interference from most icteric, hemolyzed or colored samples is eliminated by the higher plasma dilution.
Mean fluorescent assay precision is 3.4% as
compared to 5.5% for inhibitor assays performed with the chromogenic substrate (5).
The increased precision may be attributed to the elimination of some
plasma interferences as well as the greater specificity of fluorescent measurements as compared to spectrophotometric measurements. The normal range AT-III results, Table 2, show good comparison for the two test methods although there is a slight bias toward higher RID values. The low AT-III samples, Table 3, were abnormal by both test methods, but all RID test results are higher and there is poor correlation between the results of the two methods.
Similar results were reported recently in a comparative
study of immunologic and chromogenic substrate assay values of AT-III
where
the abnormal low samples gave higher values in the immunologic test (6).
Other
reportj
have
SiJgge
jted
the
izminologic tests (7,8).
detection
of
f>;ric:jq2p.a;
: , i~.a~tj!~e
rii-1:
I
by
Our results are in aagreezent with those reports
indicating that measurement of AT-III concentration may be less useful than the &termination
of AT-III activity. REFERENCES
1.
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Abnormal a familial