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P. L. Storring
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Gaines Das R. E.
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ABSTRACT

The International Standard for Pituitary FSH (IS; in ampoules coded 83/575) was assayed in terms of the Second International Reference Preparation of Human Pituitary FSH and LH for Bioassay (IRP 78/549) by 27 laboratories in 13 countries using bioassays, receptor assays and immunoassays. Estimates of the FSH content of the IS by in-vivo bioassay were homogeneous both within and between laboratories and gave a combined geometric mean (with 95% fiducial limits) of 79·9 (74·6–85·4) i.u./ampoule. Estimates by different in-vitro bioassays and receptor assays were also homogeneous between assays and laboratories, and gave a combined geometric mean (with 95% fiducial limits) of 31·2 (28·8–33·9) i.u./ampoule. However, estimates by the 19 different immunoassay systems were heterogeneous and varied between 5 and 31 i.u./ampoule.

The material in ampoules coded 83/575 was established by the World Health Organization as the International Standard for Pituitary FSH. It was assigned a unitage of 80 i.u./ampoule on the basis of its calibration by in-vivo bioassay, because this assay best identifies and defines the hormone. However, the introduction of the new IS will necessitate the recalibration of immunoassay kits.

FSH 84/530, prepared in the same way as the IS from the same FSH preparation, did not differ significantly from the IS in any of the assay systems studied and appeared to be equally suitable as a standard.

Four highly purified preparations of human FSH (FSH A–D), differing in their isoform compositions and in their in-vivo: in-vitro bioactivity ratios, were also studied. The ranking order of the specific activities of FSH A–D by in-vitro bioassays paralleled their order by receptor assays and the order of their content of FSH isoforms with isoelectric points > 4·5. (Potency estimates of FSH B and C in terms of the IS were greater by receptor assay than by in-vitro bioassay.) The overall ranking order of the specific activities of FSH A–D by immunoassays was different. Contrary to expectation, estimates in terms of the IS of specific activities by immunoassay differed more between preparations than those by in-vitro bioassay or receptor assay.

Differences in specificity between immunoassay systems were demonstrated not only in the calibration of the IS in terms of the crude FSH of IRP 78/549 but also in the comparisons of the highly purified FSH in the IS and FSH A–D. The differences in the immunoreactivities and bioactivities of FSH preparations differing in their isoform compositions greatly complicate the standardization of assays for FSH.

Journal of Endocrinology (1989) 123, 275–293

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P. L. Storring
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R. E. Gaines Das
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ABSTRACT

The second International Standard for Human Pituitary LH (in ampoules coded 80/552; 2nd IS) and LH 81/535 (prepared in the same way as the 2nd IS from the same LH preparation) were compared with the International Reference Preparation of Human Pituitary LH for Immunoassay (IRP 68/40) by 19 laboratories in 11 countries, using in-vivo and in-vitro bioassays, a receptor assay and immunoassays.

Geometric mean estimates of the LH content of the 2nd IS (with 95% fiducial limits) in terms of IRP 68/40 were: 34·6 (29·1–41·0) IU/ampoule by in-vivo bioassays; 35·8 (27·0–47·4) IU/ampoule by in-vitro bioassays; 58·6 IU/ampoule by one receptor assay; and 36·8 (35·5–38·1) IU/ampoule by immunoassays. The close agreement between the relative activities of the 2nd IS and IRP 68/40 in the wide range of assay systems studied appears to reflect the fact that both standards contain highly purified LH with similar isoform compositions as judged by isoelectric focusing.

Estimates of the LH content of LH 81/535 in terms of IRP 68/40 and in terms of the 2nd IS tended to be lower than those for the 2nd IS across all methods, but the differences were not statistically significant.

The 2nd IS was found to be as suitable as IRP 68/40 as a standard for the in-vitro bioassay and immunoassay of LH in the two serum samples studied. However, the mean estimates of serum LH in terms of either of these standards were more than 150% larger by in-vitro bioassays than by immunoassays and more than 50% larger by one-site than by two-site immunoassays. This may be a reflection of the differences in the isoform composition of the highly purified LH of the 2nd IS and IRP 68/40 and that of the LH in the sera. The significant intra- and inter-laboratory variability observed in this study for LH estimates, especially by in-vitro bioassays but also by immunoassays, is very pertinent to the interpretation of published comparisons of LH bioactivity and immunoreactivity.

Estimates of the LH content of ampoules of the 2nd IS and LH 81/535 kept at elevated temperatures showed that both the 2nd IS and LH 81/535 appeared to be adequately stable under normal storage conditions; the in-vivo and in-vitro bioactivities and receptor binding activities of LH were more sensitive than its immunoreactivities to thermal degradation of the LH structure.

On the basis of these results, the World Health Organization Expert Committee on Biological Standardization established the preparation in ampoules coded 80/552 as the second International Standard for Human Pituitary Luteinizing Hormone, and assigned an activity of 35 International Units of human pituitary LH to the contents of each ampoule.

Journal of Endocrinology (1993) 138, 345–359

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R. E. Gaines Das
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A. F. Bristow
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ABSTRACT

Four batches of ampouled materials in ampoules coded 80/558, 81/502, 81/565 and 81/615 were evaluated by 22 laboratories in nine countries in an international collaborative study for their suitability to serve as a replacement for the First International Reference Preparation (IRP) of TSH, Human, for Immunoassay. The ampouled preparations were calibrated by immunoassay and bioassay. The preparation coded 80/558 had satisfactory stability and contained acceptably low levels of contamination with FSH and LH. Estimates of the immunoreactive TSH content of a set of specimens of serum in terms of 80/558 showed agreement in ranking order and no increase in variability compared with estimates made by assay against the First IRP. On the basis of these results, with the agreement of the participants in the study, and with the authorization of the Expert Committee on Biological Standardization of the World Health Organization, the preparation coded 80/558 was established in 1983 as the Second International Reference Preparation of TSH, Human, for Immunoassay, with a defined potency of 37 mi.u./ampoule. Preparations coded 81/502, 81/565 and 81/615 were found suitable to serve as working standards.

J. Endocr. (1985) 104, 367–379

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P. L. Storring
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R. E. Gaines Das
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ABSTRACT

The International Standard (IS) for Recombinant DNA-Derived (rDNA) Erythropoietin (EPO) (in ampoules coded 87/684) and three other rDNA EPO preparations in ampoules coded 87/690, 87/696 and 88/574 respectively, were compared with two preparations of highly purified human urinary (HU) EPO and the 2nd International Reference Preparation of Human Urinary Erythropoietin for Bioassay (2nd IRP) by 26 laboratories in 11 countries using a wide range of in-vivo and in-vitro bioassays and immunoassays. These EPO preparations were also compared by electrophoresis and isoelectric focusing.

Estimates of EPO content in terms of the 2nd IRP by all in-vivo bioassay methods gave combined unweighted geometric means (with 95% fiducial limits) of: 86 (75–99) IU/ampoule for the IS, 81 (70–94) IU/ampoule for 87/690, 58 (48–71) IU/ampoule for 87/696 and 120 (100–143) IU/ampoule for 88/574. Mean estimates of EPO content in terms of the 2nd IRP by in-vitro bioassays (except receptor assays) were larger than, and those by immunoassays were similar to, the mean estimates by in-vivo bioassays.

The use of purified rDNA or HU EPO as standards in place of the 2nd IRP reduced the inter-laboratory variability of estimates of purified EPO preparations by in-vivo and in-vitro bioassays and by immunoassays, and reduced the variability of overall mean estimates for each of these preparations between the three types of method. The inter-laboratory variability of immunoassay estimates of human serum EPO was similar whether the 2nd IRP or one of the purified EPOs was used as standard.

Significant differences in in-vivo and in-vitro biological, immunological and physicochemical properties were found between these four rDNA EPO preparations and between them and the HU EPO in the two purified preparations and in the 2nd IRP. There were also differences between the immunoreactivities of the two serum EPO samples included in the study, and between them and the immunoreactivities of the purified EPOs. The differences between rDNA EPOs appeared to be related to differences between the cells used for their biosynthesis, but may also be the result of differences in purification methods and of inter-batch variations.

Significant differences in assay specificity were observed within each of the three general types of method. The specificity of the in-vivo bioassays was influenced by the route of hormone administration. The specificities of the mouse spleen cell in-vitro bioassays differed from that of the mouse spleen receptor-binding assay. The specificity of one-site immunoassays differed with the type of EPO used as antigen or tracer, with most notable differences between assays using antisera to rDNA and HU EPO. Two-site immunoassays gave significantly lower estimates for serum EPO than one-site immunoassays.

On the basis of these results, the World Health Organization (WHO) Expert Committee on Biological Standardization established the preparation in ampoules coded 87/684 as the International Standard for Recombinant DNA-Derived Erythropoietin with an activity of 86 IU Erythropoietin, rDNA-Derived, per ampoule. It also recommended that the WHO keep under consideration the establishment of separate standards for naturally occurring EPO and for rDNA EPO produced in different cell lines.

Journal of Endocrinology (1992) 134, 459–484

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A. F. Bristow
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R. P. Gooding
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R. E. Gaines Das
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ABSTRACT

Three preparations of recombinant DNA-derived insulin-like growth factor-I (IGF-I) were obtained, prepared in ampoules coded 86/522, 86/720 or 87/518, and evaluated as candidate International Reference Reagents in an international collaborative study (nine laboratories in four countries) in response to a request by the World Health Organization (WHO).

Immunoassay dose–response curves for each of the three preparations did not in general differ significantly from those of local standards or from those of ampouled preparations of serum-derived IGF-I which were included in the study. The estimates of ampoule contents in terms of local standards showed considerable heterogeneity; the between-laboratory variability of estimates in terms of local standards was ten times greater than the inherent variability of estimates from these systems as estimated from comparisons of coded duplicates. Bioassay data were limited, and those available were inconsistent with immunoassay data. Of the three preparations, ampoules coded 86/720 were derived from an IGF-I preparation that was heterogeneous by high-performance liquid chromatography, and stability data for the preparation 86/522 were anomalous.

As a result, the ampouled preparation coded 87/518 has been established by WHO as the International Reference Reagent for IGF-I for immunoassay, with an assigned ampoule content of 3·1 μg/ampoule, and is available from the National Institute for Biological Standards and Control.

Journal of Endocrinology (1990) 125, 191–197

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D. Schulster
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R. E. Gaines Das
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S. L. Jeffcoate
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ABSTRACT

Three ampouled preparations of purified human prolactin were assessed by 20 laboratories in eight countries for their suitability to serve as International Standards for the estimation of human prolactin in serum. Bioassays (pigeon crop sac assays and NB2 cell assays) were carried out in two laboratories, radioreceptor assays by one laboratory and radioimmunoassays by 17 laboratories.

By physicochemical analysis the preparations appeared similar. Each preparation contained small amounts of contaminants and/or prolactin variants. No major differences among the three preparations were detected by immunoassay although, in one radioreceptor assay system, one of the preparations was found to differ from the other two.

On the basis of all the available information, the Expert Committee on Biological Standardization of the World Health Organization (ECBS) in 1986 established the preparation in ampoules coded 83/562 as the Second International Standard for Prolactin and in October 1988 established the preparation in ampoules coded 84/500 as the Third International Standard for Prolactin. A value of 0·053 IU (53 mIU) prolactin activity/ampoule was assigned to both the Second and Third IS on the basis that this unitage would, insofar as possible, maintain continuity of the IU defined by the First International Reference Preparation of Prolactin, human, for Immunoassay (coded 75/504).

Journal of Endocrinology (1989) 121, 157–166

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P. L. Storring
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G. Witthaus
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R. E. Gaines Das
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W. Stamm
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ABSTRACT

The preparation and nature of the International Reference Preparation of Tetracosactide for Bioassay (IRP; in ampoules coded 80/590) are described. The IRP was studied by six laboratories in five countries using in-vivo and in-vitro bioassays and various physicochemical methods.

The bulk (1–24)corticotrophin-tetracosapeptide (batch 000179) from which the IRP was prepared contained 10·4% (w/w) acetic acid and 8·3% (w/w) water; its (1–24)corticotrophin-tetracosapeptide content was estimated to be 71·7% (w/w) by amino acid analysis, 74·2% (w/w) by high performance liquid chromatography (HPLC) and 77·5% (w/w) by spectrophotometry.

(1–24)Corticotrophin-tetracosapeptide accounted for more than 90% (w/w) of the total peptide in the IRP as judged by HPLC, thin-layer chromatography, carboxymethyl-cellulose chromatography, isoelectric focusing (IEF) and electrophoresis. The homogeneity of the peptide in the IRP was similar by all methods to that in batch 000179 from which it was prepared.

The (1–24)corticotrophin-tetracosapeptide content of the IRP (with 95% confidence limits), in terms of batch 000179, was found to be 491 μg/ampoule by HPLC and spectrophotometry, 473 (433–513) μg/ ampoule by IEF and 505 (473–539) μg/ampoule by the in-vitro rat adrenocortical cell assay. A comparison in the same bioassay system of the IRP with a laboratory house standard of (1–24)corticotrophin-tetracosapeptide, which originated from a different manufacturer, gave similar results.

Accelerated thermal degradation studies of the IRP by adrenocortical cell assay, HPLC and IEF suggested that more than 99·9% of its original content of (1–24)corticotrophin-tetracosapeptide would remain after 10 years under normal storage conditions of − 20 °C in the dark. Bioassay estimates of samples of the IRP which had undergone significant degradation were higher than estimates by HPLC, indicating that molecular species other than (1–24)corticotrophin-tetracosapeptide contributed to their corticotrophic activity.

The corticotrophic activity of the IRP was demonstrated by cytochemical bioassay and by in-vivo bioassay as well as by the adrenocortical cell assay. After consideration of these data, the Expert Committee on Biological Standardization of the World Health Organization established the ampouled preparation, coded 80/590, as the International Reference Preparation of Tetracosactide for Bioassay and assigned to it a potency of 490 i.u./ampoule; thus the i.u. is represented by 1 μg (1–24)corticotrophin-tetracosapeptide.

J. Endocr. (1984) 100, 51–60

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P. L. STORRING
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ROSE E. GAINES-DAS
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D. R. BANGHAM
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The preparation and nature of the International Reference Preparation of Human Chorionic Gonadotrophin (HCG) for Immunoassay (IRP), as well as that of a second batch of ampoules (HCG 75/589) prepared identically from the same HCG preparation, are described.

A collaborative study of these materials was carried out by 11 laboratories in eight countries, using different bioassay and immunoassay methods. Using the various in-vivo and in-vitro bioassays and receptor assays, the mean log potency estimates for each method within each laboratory of the HCG content of ampoules of the IRP, in terms of the Second International Standard of Human Chorionic Gonadotrophin for Bioassay (IS), were homogeneous and gave an overall weighted geometric mean (95% confidence limits) of 650 (632–669) International Units (i.u.)/ampoule.

There was considerable heterogeneity of potency estimates of the IRP in terms of the IS both within and between many of the immunoassay systems (reflecting the impurity of the IS), and hence attempts to calibrate the IRP with immunoassay systems of different specificities were invalid.

Immunoassay estimates of the HCG content of preparations of serum and urine, in terms of the IRP, showed considerable heterogeneity between assay systems (although the degree of this heterogeneity was no greater than that observed using the IS as standard), but the ranking order between preparations was consistent.

Confirmation was obtained that contamination of the IRP with HCG-α and HCG-β subunits was insignificant. Accelerated degradation studies of the IRP stored at increased temperatures suggested that its stability under normal storage conditions would be satisfactory.

It was agreed that the IRP was suitable to serve as an international reference preparation for immunoassay, and it was assigned a unitage of 650 i.u./ampoule on the basis of bioassay calibration.

Since the ampoules of HCG (75/589) did not differ significantly from the IRP in any of the assay systems studied, it appeared to be equally suitable as a reference preparation.

The International Reference Preparations of the α and β Subunits of Human Chorionic Gonadotrophin for Immunoassay are also described.

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M. Zaidi
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T. J. Chambers
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R. E. Gaines Das
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H. R. Morris
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I. MacIntyre
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ABSTRACT

The calcitonin gene encodes a small family of peptides: calcitonin, calcitonin gene-related peptide (CGRP) and katacalcin. Whereas calcitonin is concerned with skeletal maintenance, the function, if any, of katacalcin is still unknown. In the present study we have assessed resorption of human cortical bone substrate by isolated rat osteoclasts and have shown that CGRP acts directly on the osteoclast to inhibit bone resorption. The three CGRP peptides (rat, human(a) and human(β)) caused an almost equivalent decrease in osteoclastic bone resorption and were approximately 1000-fold less potent than human calcitonin in this respect. The responses of human calcitonin and human CGRP(α) were additive. Furthermore, prior treatment with trypsin to destroy receptors abolished the responsiveness of osteoclasts to CGRP and calcitonin. The carboxyl- and amino-terminal fragments of CGRP were found not to inhibit bone resorption, suggesting that the whole molecule of CGRP is necessary for biological activity. We have therefore suggested that the calcitonin-like effects of CGRP, seen both in vivo in the rat bioassay and in vitro in organ cultures, are due to the direct action of CGRP on the osteoclast, probably mediated through the calcitonin receptor. Though it is unlikely that CGRP is involved in the regulation of plasma calcium, the peptide may be an important local regulator of bone cell function.

J. Endocr. (1987) 115,511–518

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P. L. STORRING
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ROSE E. GAINES-DAS
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R. J. TIPLADY
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BRIDGET E. STENNING
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Y. MISTRY
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The corticotrophin activity of ampoules of the Third International Standard for Corticotrophin (IS) kept at 20 and 37 °C for 15 years was compared with that of ampoules of the IS stored under normal conditions (−20 °C in the dark), using adrenal ascorbate depletion assays after subcutaneous administration of the hormone, assays of an increase in plasma corticosterone after intravenous administration of the hormone and in-vitro adrenal cell corticosterone production assays. Estimates of activity by all three methods are homogeneous and give combined weighted geometric means (with 95% confidence limits), as per cent of the activity in the IS stored at −20 °C, of 92·1 (84·8–100) and 77·8 (71·6–84·5) for the 20 and 37 °C degradation samples respectively.

Isoelectric focusing studies of the ampoule contents of the three preparations showed that ampoules of the IS stored at 20 and 37 °C contained 90 and 79% respectively, of the component representing native corticotrophin found in the IS. These estimates of corticotrophin content are comparable to the estimates of biological activity of these preparations.

The stability of the IS was calculated from the combined bioassay data assuming that degradation follows first order kinetics. The predicted half-life for the activity of the IS is 2800 years with an approximate lower 95% confidence limit of 500 years; the predicted activity of the IS remaining now, after 20 years at −20 °C, is 99·5% of the original activity with an approximate lower 95% confidence limit of 97·3%

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