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*** Magyar ***
Description - 100 test kit
The hTSH [125I] IRMA system provides a direct quantitative in vitro determination of human thyroid stimulating hormone (hTSH) in human serum. hTSH can be assayed in the range 0-100 µIU/ml using 100 or 200 µl serum samples. Each kit contains materials sufficient for 100 assay tubes permitting the construction of one standard curve and the assay of 40 unknowns in duplicate.
Introduction
The thyroid stimulating hormone (thyrotropin or TSH) is a glycoprotein with a molecular weight of 28000, secreted by the adenohypophysis. Like other glycoprotein hormones (FSH, LH and HCG), TSH contains two different subunits, an alpha- and a ß-chain, linked by noncovalent bounds. The primary structure of alpha subunits of TSH and of the gonadotropins is the same, whilst their ß subunits are different. The ß subunits are responsible for the immunological and biological specificity of these hormones.
The synthesis and the release of TSH are controlled by the circulatory level of thyroid hormones; triiodothyronine (T3) and thyroxin (T4) and by the hypothalamic thyrotropin releasing hormone (TRH). Thyroid hormones regulate the secretion of TSH by a negative feedback mechanism. An elevation of T3 or T4 will suppress, and their fall will, in turn, increase the level of TSH in serum. The increased concentration of TSH in the serum is the earliest and best indicator of primary hypothyroidism.
The determination of TSH by immunoassay methods plays a crucial role in the diagnosis of thyroid disorders and in the evaluation of the functional integrity of the hypothalamic-pituitary axis.
The outstanding sensitivity of the present hTSH IRMA system makes it particularly suitable for the measurement of subnormal hTSH levels, a key to both the diagnosis and treatment follow up of hyperthyroid patients.
Principle of method
The technology uses two high affinity monoclonal antibodies in an immunoradiometric assay (IRMA) system.
The 125I labelled signal-antibody binds to an epitope of the TSH molecule spatially different from that recognised by the biotin-capture-antibody. The two antibodies react simultaneously with the antigen present in standards or samples, which leads to the formation of a capture antibody - antigen - signal antibody complex, also referred to as a “sandwich”.
During a 1-hour incubation period immuno-complex is immobilized to the reactive surface of streptavidin-coated test tubes. Reaction mixture is then discarded, test tubes washed exhaustively, and the radioactivity is measured in a gamma counter.
The concentration of antigen is directly proportional to the radioactivity measured in test tubes. By constructing a calibration curve plotting binding values against a series of calibrators containing known amount of hTSH, the unknown concentration of hTSH in patient samples can determined.
Contents of the kit
| 1 bottle | TRACER,
ready to use. 21 ml, containing < 900 kBq 125I-signal and capture antibody in buffer with red dye and 0.1% NaN3. |
| 8 vials | STANDARD 1.0 ml per vial, containing 0 (S0), 0.06 (S0.06), 0.15 (S0.15), 0.6 (S0.6), 2.5 (S2.5), 15 (S15), 50 (S50) and 100 (S100) µIU/ml hTSH (WHO 2nd IRP 80/558) in serum with 0.1% NaN3 |
| 2 vials | CONTROL
SERUM low (CI) and high (CII) 1.0 ml, containing 0.1% NaN3 The concentration of the control serum is specified in the quality certificate enclosed. |
| 2 boxes | COATED
TUBE, ready to use. 2 x 50 reactive test tubes, 12x75 mm, packed in plastic boxes. |
| 1 bottle | WASH
BUFFER CONCENTRATE 20 ml, containing 0.1% NaN3. See Preparation of reagents |
| 1 pc | Quality certificate |
| 1 pc | Pack leaflet |
Materials, tools and equipment required
Test
tube rack
Precision pipettes with disposable tips (100, 200 µl and 2 ml)
Distilled water
Vortex mixer
Shaker
Plastic foil
Absorbent tissue
Gamma counter
Recommended tools and equipment
Repeating
pipettes (e.g., Eppendorf)
Dispenser with 1-L reservoir (instead of the 2 ml pipette)
Specimen collection and storage
Serum samples can be prepared according to common procedures used routinely in clinical laboratory practice. Samples can be stored at 2-8 °C if the assay is carried out within 24 hours, otherwise aliquots should be prepared and stored deep frozen (-20 °C). Frozen samples should be thawed and thoroughly mixed before assaying. Repeated freezing and thawing should be avoided. Do not use lipemic, hemolyzed or turbid specimens.
Preparation of reagents, storage
Add the wash buffer concentrate (20 ml) to 1000 ml distilled water to obtain 1020 ml wash solution. Upon dilution store at 2-8 °C until expiration.
Store the rest of reagents between 2-8 °C after opening. At this temperature each reagent is stable until expiry date. The actual expiry date is given on the package label and in the quality certificate.
CAUTION! Equilibrate all reagents and serum samples to room temperature. Mix all reagents and samples thoroughly before use. Avoid excessive foaming.
The Way of Use
The assay can be used in different procedures. There are three options for running the assay. The procedures are labelled as “A”, “B” and “C”.
Working in accordance to “A” and “B” you need a good laboratory shaker. In case of option "C" you need a water bath thermostat. The test tubes must be in contact with the water so air conditioned thermostat is not applicable.
Patient sample values and expected values are the same for all procedures.
OPTION “A”: The Basic Procedure
It is very economical on sample consumption. Only 100 µl sample volume is needed. The sensitivity attainable is 0.011 µIU/ml. When the kit has less then 3 weeks to its expiration standard 0.06 µIU/ml can be omitted. However if sample consumption is not critical we recommend you to work according to OPTION B. Shaking is needed.
Standard solution 50 µIU/ml can also be omitted if the curve-fitting algorithm of the gamma counter gives similar results with or without this point.
OPTION “B”: The 3rd Generation Method
It
works in the same way as OPTION “A” except the sample volume, which is 200 µl. The
sensitivity attainable is 0.005 µIU/ml. Shaking is needed.
OPTION “C”: The Water Bath Procedure
No shaking is applied during incubation. A good laboratory thermostat is important. The sensitivity attainable is 0.020 µIU/ml. When the kit has less then 3 weeks to its expiration standard 0.06 µIU/ml can be omitted. Use this method if you have problems with your shakers but you need the results quickly. Use 200 µl sample volume only!
OPTION A - The Basic Procedure
(For a quick guide, refer to Table 1.)
| 1 | Equilibrate reagents & samples to room temperature before use. |
| 2 | Label coated tubes in duplicate for each standard, control serum & samples. |
| 3 | Homogenize all reagents & samples by gentle mixing to avoid foaming. |
| 4 | Pipette 100 µl of standards, control & samples into the properly labeled tubes. Use rack to hold the tubes. Do not touch or scratch the inner bottom of the tubes with pipette tip. |
| 5 | Pipette 200 µl of tracer into each tube. (Set aside 2 tubes for total counts.) |
| 6 | Fix the test tube rack firmly onto the shaker plate. Turn on the shaker and adjust an adequate speed so that liquid is constantly rotating or shaking in each tube. |
| 7 | Incubate tubes for 1 hour shaking at room temperature. |
| 8 | Add 2.0 ml of diluted wash buffer to each tube. Decant the supernatant from all tubes by the inversion of the rack. In the upside down position place the rack on an absorbent paper for 2 minutes. |
| 9 | Return the tube rack to an upright position, and repeat Step 8 two more times. |
| 10 | Count each tube for at least 60 seconds in a gamma counter. |
| 11 | Calculate the hTSH concentrations. |
Table 1. Assay Protocol - Pipetting Guide for OPTION A. All volumes are in microliters (µl).
Tube |
Total |
Standard |
Sample |
Control |
Standard |
100 |
|||
Sample |
100 |
|||
Control serum |
100 |
|||
Tracer |
(200) |
200 |
200 |
200 |
Shake for 1 hour at room temperature. |
||||
Wash buffer |
2000 |
2000 |
2000 |
|
Decant the fluid and blot on filter paper |
||||
Wash buffer |
2000 |
2000 |
2000 |
|
Decant the fluid and blot on filter paper |
||||
Wash buffer |
2000 |
2000 |
2000 |
|
Decant the fluid and blot on filter paper |
||||
Count radioactivity (60 sec/tube) |
||||
Calculate the results |
||||
Characterization of the assay for OPTION A
Figure 1.
OPTION A. Typical standard curve corresponding to Table 2.
(Do not use to calculate sample values!)
Table 2. Typical assay data for OPTION A
CPM |
CPM |
CPM |
B/T% |
|
Total |
406194 |
404399 |
405297 |
- |
S0 (NSB) |
58 |
67 |
63 |
0.015 |
S0.06 |
265 |
297 |
281 |
0.069 |
S0.15 |
615 |
587 |
601 |
0.148 |
S0.6 |
2158 |
2218 |
2188 |
0.54 |
S2.5 |
8377 |
8490 |
8434 |
2.08 |
S15 |
48394 |
50214 |
49304 |
12.16 |
S50 |
146568 |
147342 |
146955 |
36.26 |
S100 (Bmax) |
243184 |
240624 |
241904 |
59.68 |
CI |
1144 |
1201 |
1173 |
0.31 |
CII |
62189 |
63957 |
63073 |
19.4 |
Sensitivity
The analytical sensitivity or minimum detectable limit is calculated by the interpolation of the mean counts of zero standard plus 2 standard deviation from the standard curve. Determination was carried out using 20 replicates of zero standard response.
The value of analytical sensitivity is 0.011 µIU/ml measured using fresh tracer.
The functional sensitivity is a measure of the hTSH concentration that is significantly different from zero as determined by the inter-assay precision profile (22% CV).
The value of functional sensitivity is: 0.07 µIU/ml.
Hook effect
There is no high dose hook effect up to an hTSH concentration 500 µIU/ml.
Precision
The
within-assay (intra-assay) precision was determined with 15 replicates within a single run
using pooled human serum samples. CV values are summarized below:
Table 3/1.
intra-assay |
||
sample No. |
mean (µIU/ml) |
CV % |
1 |
0.179 |
3.8 |
2 |
0.738 |
3.5 |
3 |
1.01 |
1.7 |
4 |
1.22 |
1.4 |
5 |
1.86 |
2.4 |
6 |
3.04 |
2.1 |
7 |
6.25 |
4.2 |
The
between-assay (inter-assay) precision was determined using pooled human serum samples in
independent assay runs. The number of measurements on a sample was a function of sample
volume available. Three different operators took part in the investigation process and
four different tracer batches were used at different ages of the reagents. Four different
lots of coated tubes were used to determine the inter-assay precision profile. Results are
presented below.
Table 3/2.
inter-assay |
||
number of assay runs |
mean (µIU/ml) |
CV % |
18 |
0.019 |
27.5 |
19 |
0.047 |
26.8 |
18 |
0.068 |
19.7 |
20 |
0.109 |
11.5 |
19 |
0.174 |
9.6 |
20 |
0.711 |
3.4 |
20 |
1.82 |
3.0 |
19 |
6.13 |
4.3 |
19 |
20.37 |
7.4 |
Linearity – dilution test
Individual human serum samples were diluted with the zero standard of the kit. The diluted samples were measured according to kit protocol.
Table 4.
sample |
dilution factor |
expected µIU/ml |
observed µIU/ml |
recovery |
1 |
1 |
27.46 |
||
1 |
2.00 |
13.74 |
13.85 |
100.9 |
1 |
4.02 |
6.82 |
7.38 |
108.2 |
1 |
8.05 |
3.41 |
3.67 |
107.4 |
2 |
1 |
13.07 |
||
2 |
2.02 |
6.48 |
6.68 |
103.0 |
2 |
4.06 |
3.22 |
3.33 |
103.2 |
2 |
8.14 |
1.60 |
1.55 |
96.5 |
3 |
1 |
56.18 |
||
3 |
2.00 |
28.02 |
27.82 |
99.3 |
3 |
4.02 |
13.97 |
13.78 |
98.6 |
3 |
8.02 |
7.01 |
7.57 |
108.1 |
4 |
1 |
1.12 |
||
4 |
2.02 |
0.556 |
0.581 |
104.4 |
4 |
4.07 |
0.276 |
0.302 |
109.5 |
4 |
8.18 |
0.137 |
0.155 |
113.0 |
5 |
1 |
8.74 |
||
5 |
2.01 |
4.35 |
4.40 |
101.1 |
5 |
4.03 |
2.17 |
2.08 |
96.0 |
5 |
8.17 |
1.07 |
1.01 |
94.8 |
Recovery – addition test
Individual human serum samples were spiked with known amount of an elevated stock sample. Recovery % is to be interpreted as = (observed-base)/added*100. The results are summarized below.
Table 5.
sample |
base µIU/ml |
added µIU/ml |
expected µIU/ml |
observed µIU/ml |
recovery |
1 |
8.28 |
17.18 |
25.46 |
25.00 |
97.3 |
2 |
7.50 |
18.60 |
26.09 |
26.65 |
103.0 |
3 |
8.65 |
18.44 |
27.08 |
26.21 |
95.3 |
4 |
9.11 |
16.29 |
25.40 |
24.57 |
94.9 |
5 |
5.79 |
17.87 |
23.66 |
23.92 |
101.5 |
OPTION B - The 3rd Generation Method
(For a quick guide, refer to Table 6.)
| 1 | Equilibrate reagents & samples to room temperature before use. |
| 2 | Label coated tubes in duplicate for each standard, control serum & samples. |
| 3 | Homogenize all reagents & samples by gentle mixing to avoid foaming. |
| 4 | Pipette 200 µl of standards, control & samples into the properly labeled tubes. Use rack to hold the tubes. Do not touch or scratch the inner bottom of the tubes with pipette tip. |
| 5 | Pipette 200 µl of tracer into each tube. (Set aside 2 tubes for total counts.) |
| 6 | Fix the test tube rack firmly onto the shaker plate. Turn on the shaker and adjust an adequate speed so that liquid is constantly rotating or shaking in each tube. |
| 7 | Incubate tubes for 1 hour shaking at room temperature. |
| 8 | Add 2.0 ml of diluted wash buffer to each tube. Decant the supernatant from all tubes by the inversion of the rack. In the upside down position place the rack on an absorbent paper for 2 minutes. |
| 9 | Return the tube rack to an upright position, and repeat Step 8 two more times. |
| 10 | Count each tube for at least 60 seconds in a gamma counter. |
| 11 | Calculate the hTSH concentrations. |
Table
6. Assay Protocol - Pipetting Guide for OPTION B
All volumes are in microliters (µl).
Tube |
Total |
Standard |
Sample |
Control serum |
Standard |
200 |
|||
Sample |
200 |
|||
Control serum |
200 |
|||
Tracer |
(200) |
200 |
200 |
200 |
Shake for 1 hour at room temperature. |
||||
Wash buffer |
2000 |
2000 |
2000 |
|
Decant the fluid and blot on filter paper |
||||
Wash buffer |
2000 |
2000 |
2000 |
|
Decant the fluid and blot on filter paper |
||||
Wash buffer |
2000 |
2000 |
2000 |
|
Decant the fluid and blot on filter paper |
||||
Count radioactivity (60 sec/tube) |
||||
Calculate the results |
||||
Characterization of the assay for OPTION B
Figure 2.
OPTION B. Typical standard curve corresponding to Table 7.
(Do not use to calculate sample values!)
Table 7. Typical assay data for OPTION B
CPM |
CPM |
CPM |
TSH |
|
Total |
405254 |
402194 |
403724 |
- |
S0 (NSB) |
57 |
49 |
53 |
0.013 |
S0.06 |
468 |
435 |
452 |
0.069 |
S0.15 |
1095 |
1035 |
1065 |
0.264 |
S0.6 |
3936 |
4151 |
4044 |
1.00 |
S2.5 |
16214 |
15233 |
15724 |
3.89 |
S15 |
86741 |
88695 |
87718 |
21.73 |
S50 |
232356 |
229654 |
231005 |
57.22 |
S100 (Bmax) |
311395 |
312518 |
311957 |
77.27 |
CI |
2256 |
2099 |
2177 |
0.33 |
CII |
115658 |
118590 |
117124 |
19.9 |
Sensitivity
The analytical sensitivity or minimum detectable limit is calculated by the interpolation of the mean counts of zero standard plus 2 standard deviation from the standard curve. Determination was carried out using 20 replicates of zero standard response.
The value of analytical sensitivity is 0.005 µIU/ml measured using fresh tracer.
The functional sensitivity is a measure of the hTSH concentration that is significantly different from zero as determined by the inter-assay precision profile (22% CV).
The value of functional sensitivity is: 0.03 µIU/ml.
Hook effect
There is no high dose hook effect up to an hTSH concentration 500 µIU/ml.
Precision
The
within-assay (intra-assay) precision was determined with 15 replicates within a single run
using pooled human serum samples. CV values are summarized below:
Table 8/1.
intra-assay |
|
mean (µIU/ml) |
CV % |
0.019 |
29.7 |
0.043 |
15.3 |
0.091 |
8.3 |
0.168 |
8.0 |
0.249 |
4.0 |
0.527 |
3.2 |
0.900 |
3.1 |
1.66 |
2.6 |
5.99 |
3.6 |
18.55 |
2.1 |
The
between-assay (inter-assay) precision was determined using pooled human serum samples in
independent assay runs. The number of measurements on a sample was a function of sample
volume available. Three different operators took part in the investigation process and
four different tracer batches were used at different ages of the reagents. Four different
lots of coated tubes were used to determine the inter-assay precision profile. Results are
presented below.
Table 8/2.
inter-assay |
||
number of assay runs |
mean (µIU/ml) |
CV % |
22 |
0.020 |
31.9 |
22 |
0.039 |
9.2 |
15 |
0.079 |
6.5 |
22 |
0.106 |
8.8 |
21 |
0.165 |
7.4 |
22 |
0.236 |
6.3 |
22 |
0.525 |
5.6 |
22 |
0.964 |
4.8 |
21 |
5.67 |
4.9 |
22 |
18.83 |
2.6 |
Linearity – dilution test
Individual
human serum samples were diluted with the zero standard of the kit. The diluted samples
were measured according to kit protocol.
Table 9.
sample |
dilution factor |
expected µIU/ml |
observed µIU/ml |
recovery |
1 |
1 |
27.73 |
||
1 |
2.00 |
13.87 |
13.71 |
98.8 |
1 |
4.02 |
6.89 |
7.35 |
106.6 |
1 |
8.05 |
3.45 |
3.39 |
98.4 |
2 |
1 |
13.07 |
||
2 |
2.02 |
6.48 |
6.69 |
103.3 |
2 |
4.06 |
3.22 |
3.31 |
102.8 |
2 |
8.14 |
1.60 |
1.54 |
96.1 |
3 |
1 |
57.14 |
||
3 |
2.00 |
28.49 |
26.71 |
93.7 |
3 |
4.02 |
14.21 |
13.81 |
97.2 |
3 |
8.02 |
7.13 |
7.24 |
101.6 |
4 |
1 |
1.16 |
||
4 |
2.02 |
0.573 |
0.536 |
93.6 |
4 |
4.07 |
0.284 |
0.259 |
91.2 |
4 |
8.18 |
0.141 |
0.126 |
89.2 |
5 |
1 |
8.42 |
||
5 |
2.01 |
4.19 |
4.44 |
105.9 |
5 |
4.03 |
2.09 |
2.08 |
99.7 |
5 |
8.17 |
1.03 |
1.03 |
100.2 |
Recovery – addition test
Individual
human serum samples were spiked with known amount of an elevated stock sample. Recovery %
is to be interpreted as = (observed-base)/added*100. The results are summarised below.
Table 10.
sample |
base µIU/ml |
added µIU/ml |
expected µIU/ml |
observed µIU/ml |
recovery |